+ +
+ +
+

Welcome to the HPX documentation!#

+

If you’re new to HPX you can get started with the Quick start guide. +Don’t forget to read the Terminology section to learn about the most +important concepts in HPX. The Examples give you a feel for how it is +to write real HPX applications and the Manual contains detailed +information about everything from building HPX to debugging it. There are +links to blog posts and videos about HPX in Additional material.

+

You can find a comprehensive list of contact options on Support for deploying +and using HPX. Do not hesitate to contact us if you +can’t find what you are looking for in the documentation!

+

See Citing HPX for details on how to cite HPX in publications. See +HPX users for a list of institutions and projects using HPX.

+

There are also available a PDF version of this documentation as +well as a Single HTML Page.

+
+

What is HPX?#

+

HPX is a C++ Standard Library for Concurrency and Parallelism. It implements +all of the corresponding facilities as defined by the C++ Standard. +Additionally, in HPX we implement functionalities proposed as part of the +ongoing C++ standardization process. We also extend the C++ Standard APIs to the +distributed case. HPX is developed by the STE||AR group (see People).

+

The goal of HPX is to create a high quality, freely available, open source +implementation of a new programming model for conventional systems, such as +classic Linux based Beowulf clusters or multi-socket highly parallel SMP nodes. +At the same time, we want to have a very modular and well designed runtime +system architecture which would allow us to port our implementation onto new +computer system architectures. We want to use real-world applications to drive +the development of the runtime system, coining out required functionalities and +converging onto a stable API which will provide a smooth migration path for +developers.

+

The API exposed by HPX is not only modeled after the interfaces defined by the +C++11/14/17/20 ISO standard. It also adheres to the programming guidelines used +by the Boost collection of C++ libraries. We aim to improve the scalability of +today’s applications and to expose new levels of parallelism which are necessary +to take advantage of the exascale systems of the future.

+
+
+

What’s so special about HPX?#

+
    +
  • HPX exposes a uniform, standards-oriented API for ease of programming parallel +and distributed applications.

  • +
  • It enables programmers to write fully asynchronous code using hundreds of +millions of threads.

  • +
  • HPX provides unified syntax and semantics for local and remote operations.

  • +
  • HPX makes concurrency manageable with dataflow and future based +synchronization.

  • +
  • It implements a rich set of runtime services supporting a broad range of use +cases.

  • +
  • HPX exposes a uniform, flexible, and extendable performance counter framework +which can enable runtime adaptivity

  • +
  • It is designed to solve problems conventionally considered to be +scaling-impaired.

  • +
  • HPX has been designed and developed for systems of any scale, from +hand-held devices to very large scale systems.

  • +
  • It is the first fully functional implementation of the ParalleX execution +model.

  • +
  • HPX is published under a liberal open-source license and has an open, active, +and thriving developer community.

  • +
+
+
+

Quick start#

+

The following steps will help you get started with HPX. Before getting started, make sure you have +all the necessary prerequisites, which are listed in _prerequisites. After Installing HPX, +you can check how to run a simple example Hello, World!. Writing task-based applications +explains how you can get started with HPX. You can refer to our Migration guide if you use +other APIs for parallelism (like OpenMP, MPI or Intel Threading Building Blocks (TBB)) and you would like to convert your code to +HPX code.

+
+

Installing HPX#

+

The easiest way to install HPX on your system is by choosing one of the steps +below:

+

#.* * vcpkg * *

+
+

You can download and install HPX using the vcpkg dependency manager:

+
$ vcpkg install hpx
+
+
+
+

#.* * Spack * *

+
+

Another way to install HPX is using +Spack:

+
$ spack install hpx
+
+
+
+

#.* * Fedora * *

+
+

Installation can be done with +Fedora as well:

+
$ dnf install hpx*
+
+
+
+

#.* * Arch Linux * *

+
+

HPX is available in the +Arch User Repository (AUR) +as hpx too.

+
+

More information or alternatives regarding the installation can be found in the +Building HPX, a detailed guide with thorough explanation of ways to build +and use HPX.

+
+
+

Hello, World!#

+

To get started with this minimal example you need to create a new project +directory and a file CMakeLists.txt with the contents below in order to +build an executable using CMake and HPX:

+
cmake_minimum_required(VERSION 3.19)
+project(my_hpx_project CXX)
+find_package(HPX REQUIRED)
+add_executable(my_hpx_program main.cpp)
+target_link_libraries(my_hpx_program HPX::hpx HPX::wrap_main HPX::iostreams_component)
+
+
+

The next step is to create a main.cpp with the contents below:

+
// Including 'hpx/hpx_main.hpp' instead of the usual 'hpx/hpx_init.hpp' enables
+// to use the plain C-main below as the direct main HPX entry point.
+#include <hpx/hpx_main.hpp>
+#include <hpx/iostream.hpp>
+
+int main()
+{
+    // Say hello to the world!
+    hpx::cout << "Hello World!\n" << std::flush;
+    return 0;
+}
+
+
+

Then, in your project directory run the following:

+
$ mkdir build && cd build
+$ cmake -DHPX_DIR=</path/to/hpx/installation> ..
+$ make all
+$ ./my_hpx_program
+
+
+
$ ./my_hpx_program
+Hello World!
+
+
+

The program looks almost like a regular C++ hello world with the exception of +the two includes and hpx::cout.

+
    +
  • When you include hpx_main.hpp HPX makes sure that main actually gets +launched on the HPX runtime. So while it looks almost the same you can now use +futures, async, parallel algorithms and more which make use of the HPX +runtime with lightweight threads.

  • +
  • hpx::cout is a replacement for std::cout to make sure printing never blocks +a lightweight thread. You can read more about hpx::cout in The HPX I/O-streams component.

  • +
+
+

Note

+
    +
  • You will most likely have more than one main.cpp file in your project. +See the section on Using HPX with CMake-based projects for more details on how to use +add_hpx_executable.

  • +
  • HPX::wrap_main is required if you are implicitly using main() as the +runtime entry point. See Re-use the main() function as the main HPX entry point for more information.

  • +
  • HPX::iostreams_component is optional for a minimal project but lets us +use the HPX equivalent of std::cout, i.e., the HPX The HPX I/O-streams component +functionality in our application.

  • +
  • You do not have to let HPX take over your main function like in the +example. See Starting the HPX runtime for more details on how to initialize and run +the HPX runtime.

  • +
+
+
+

Caution

+

Ensure that HPX is installed with HPX_WITH_DISTRIBUTED_RUNTIME=ON to +prevent encountering an error indicating that the HPX::iostreams_component +target is not found.

+

When including hpx_main.hpp the user-defined main gets renamed and +the real main function is defined by HPX. This means that the +user-defined main must include a return statement, unlike the real +main. If you do not include the return statement, you may end up with +confusing compile time errors mentioning user_main or even runtime +errors.

+
+
+
+

Writing task-based applications#

+

So far we haven’t done anything that can’t be done using the C++ standard +library. In this section we will give a short overview of what you can do with +HPX on a single node. The essence is to avoid global synchronization and break +up your application into small, composable tasks whose dependencies control the +flow of your application. Remember, however, that HPX allows you to write +distributed applications similarly to how you would write applications for a +single node (see Why HPX? and +Writing distributed applications).

+

If you are already familiar with async and future from the C++ standard +library, the same functionality is available in HPX.

+

The following terminology is essential when talking about task-based C++ +programs:

+
    +
  • lightweight thread: Essential for good performance with task-based programs. +Lightweight refers to smaller stacks and faster context switching compared to +OS threads. Smaller overheads allow the program to be broken up into smaller +tasks, which in turns helps the runtime fully utilize all processing units.

  • +
  • async: The most basic way of launching tasks asynchronously. Returns a +future<T>.

  • +
  • future<T>: Represents a value of type T that will be ready in the future. +The value can be retrieved with get (blocking) and one can check if the +value is ready with is_ready (non-blocking).

  • +
  • shared_future<T>: Same as future<T> but can be copied (similar to +std::unique_ptr vs std::shared_ptr).

  • +
  • continuation: A function that is to be run after a previous task has run +(represented by a future). then is a method of future<T> that takes a +function to run next. Used to build up dataflow DAGs (directed acyclic +graphs). shared_futures help you split up nodes in the DAG and functions +like when_all help you join nodes in the DAG.

  • +
+

The following example is a collection of the most commonly used functionality in +HPX:

+
#include <hpx/algorithm.hpp>
+#include <hpx/future.hpp>
+#include <hpx/init.hpp>
+
+#include <iostream>
+#include <random>
+#include <vector>
+
+void final_task(hpx::future<hpx::tuple<hpx::future<double>, hpx::future<void>>>)
+{
+    std::cout << "in final_task" << std::endl;
+}
+
+int hpx_main()
+{
+    // A function can be launched asynchronously. The program will not block
+    // here until the result is available.
+    hpx::future<int> f = hpx::async([]() { return 42; });
+    std::cout << "Just launched a task!" << std::endl;
+
+    // Use get to retrieve the value from the future. This will block this task
+    // until the future is ready, but the HPX runtime will schedule other tasks
+    // if there are tasks available.
+    std::cout << "f contains " << f.get() << std::endl;
+
+    // Let's launch another task.
+    hpx::future<double> g = hpx::async([]() { return 3.14; });
+
+    // Tasks can be chained using the then method. The continuation takes the
+    // future as an argument.
+    hpx::future<double> result = g.then([](hpx::future<double>&& gg) {
+        // This function will be called once g is ready. gg is g moved
+        // into the continuation.
+        return gg.get() * 42.0 * 42.0;
+    });
+
+    // You can check if a future is ready with the is_ready method.
+    std::cout << "Result is ready? " << result.is_ready() << std::endl;
+
+    // You can launch other work in the meantime. Let's sort a vector.
+    std::vector<int> v(1000000);
+
+    // We fill the vector synchronously and sequentially.
+    hpx::generate(hpx::execution::seq, std::begin(v), std::end(v), &std::rand);
+
+    // We can launch the sort in parallel and asynchronously.
+    hpx::future<void> done_sorting =
+        hpx::sort(hpx::execution::par(          // In parallel.
+                      hpx::execution::task),    // Asynchronously.
+            std::begin(v), std::end(v));
+
+    // We launch the final task when the vector has been sorted and result is
+    // ready using when_all.
+    auto all = hpx::when_all(result, done_sorting).then(&final_task);
+
+    // We can wait for all to be ready.
+    all.wait();
+
+    // all must be ready at this point because we waited for it to be ready.
+    std::cout << (all.is_ready() ? "all is ready!" : "all is not ready...")
+              << std::endl;
+
+    return hpx::local::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    return hpx::local::init(hpx_main, argc, argv);
+}
+
+
+

Try copying the contents to your main.cpp file and look at the output. It can +be a good idea to go through the program step by step with a debugger. You can +also try changing the types or adding new arguments to functions to make sure +you can get the types to match. The type of the then method can be especially +tricky to get right (the continuation needs to take the future as an argument).

+
+

Note

+

HPX programs accept command line arguments. The most important one is +--hpx:threads=N to set the number of OS threads used by +HPX. HPX uses one thread per core by default. Play around with the +example above and see what difference the number of threads makes on the +sort function. See Launching and configuring HPX applications for more details on +how and what options you can pass to HPX.

+
+
+

Tip

+

The example above used the construction hpx::when_all(...).then(...). For +convenience and performance it is a good idea to replace uses of +hpx::when_all(...).then(...) with dataflow. See +Dataflow for more details on dataflow.

+
+
+

Tip

+

If possible, try to use the provided parallel algorithms instead of +writing your own implementation. This can save you time and the resulting +program is often faster.

+
+
+
+

Next steps#

+

If you haven’t done so already, reading the Terminology section will help +you get familiar with the terms used in HPX.

+

The Examples section contains small, self-contained walkthroughs of +example HPX programs. The Local to remote example is a thorough, +realistic example starting from a single node implementation and going stepwise +to a distributed implementation.

+

The Manual contains detailed information on writing, building and running +HPX applications.

+
+
+
+

Examples#

+

The following sections analyze some examples to help you get familiar with the +HPX style of programming. We start off with simple examples that utilize basic +HPX elements and then begin to expose the reader to the more complex and +powerful HPX concepts. Section Building tests and examples shows how you +can build the examples.

+
+
+

Asynchronous execution#

+

The Fibonacci sequence is a sequence of numbers starting with 0 and 1 where +every subsequent number is the sum of the previous two numbers. In this example, +we will use HPX to calculate the value of the n-th element of the Fibonacci +sequence. In order to compute this problem in parallel, we will use a facility +known as a future.

+

As shown in the Fig. 1 below, a future encapsulates a +delayed computation. It acts as a proxy for a result initially not known, most +of the time because the computation of the result has not completed yet. The +future synchronizes the access of this value by optionally suspending any +HPX-threads requesting the result until the value is available. When a future +is created, it spawns a new HPX-thread (either remotely with a parcel +or locally by placing it into the thread queue) which, when run, will execute +the function associated with the future. The arguments of the function are bound +when the future is created.

+
+_images/future_schematics.png +
+

Fig. 1 Schematic of a future execution.#

+
+
+

Once the function has finished executing, a write operation is performed on the +future. The write operation marks the future as completed, and optionally stores +data returned by the function. When the result of the delayed computation is +needed, a read operation is performed on the future. If the future’s function +hasn’t completed when a read operation is performed on it, the reader +HPX-thread is suspended until the future is ready. The future facility allows +HPX to schedule work early in a program so that when the function value is +needed it will already be calculated and available. We use this property in our +Fibonacci example below to enable its parallel execution.

+
+
Setup#
+

The source code for this example can be found here: +fibonacci_local.cpp.

+

To compile this program, go to your HPX build directory (see +Building HPX for information on configuring and building HPX) and +enter:

+
$ make examples.quickstart.fibonacci_local
+
+
+

To run the program type:

+
$ ./bin/fibonacci_local
+
+
+

This should print (time should be approximate):

+
fibonacci(10) == 55
+elapsed time: 0.002430 [s]
+
+
+

This run used the default settings, which calculate the tenth element of the +Fibonacci sequence. To declare which Fibonacci value you want to calculate, use +the --n-value option. Additionally you can use the --hpx:threads +option to declare how many OS-threads you wish to use when running the program. +For instance, running:

+
$ ./bin/fibonacci --n-value 20 --hpx:threads 4
+
+
+

Will yield:

+
fibonacci(20) == 6765
+elapsed time: 0.062854 [s]
+
+
+
+
+
Walkthrough#
+

Now that you have compiled and run the code, let’s look at how the code works. +Since this code is written in C++, we will begin with the main() function. +Here you can see that in HPX, main() is only used to initialize the +runtime system. It is important to note that application-specific command line +options are defined here. HPX uses Boost.Program_options for command line +processing. You can see that our programs --n-value option is set by calling +the add_options() method on an instance of +hpx::program_options::options_description. The default value of the +variable is set to 10. This is why when we ran the program for the first time +without using the --n-value option the program returned the 10th value of +the Fibonacci sequence. The constructor argument of the description is the text +that appears when a user uses the --hpx:help option to see what +command line options are available. HPX_APPLICATION_STRING is a macro that +expands to a string constant containing the name of the HPX application +currently being compiled.

+

In HPX main() is used to initialize the runtime system and pass the +command line arguments to the program. If you wish to add command line options +to your program you would add them here using the instance of the Boost class +options_description, and invoking the public member function +.add_options() (see Boost Documentation for more details). hpx::init +calls hpx_main() after setting up HPX, which is where the logic of our +program is encoded.

+
int main(int argc, char* argv[])
+{
+    // Configure application-specific options
+    hpx::program_options::options_description desc_commandline(
+        "Usage: " HPX_APPLICATION_STRING " [options]");
+
+    // clang-format off
+    desc_commandline.add_options()
+        ("n-value",
+            hpx::program_options::value<std::uint64_t>()->default_value(10),
+            "n value for the Fibonacci function")
+        ;
+    // clang-format on
+
+    // Initialize and run HPX
+    hpx::local::init_params init_args;
+    init_args.desc_cmdline = desc_commandline;
+
+    return hpx::local::init(hpx_main, argc, argv, init_args);
+}
+
+
+

The hpx::init function in main() starts the runtime system, and +invokes hpx_main() as the first HPX-thread. Below we can see that the +basic program is simple. The command line option --n-value is read in, a +timer (hpx::chrono::high_resolution_timer) is set up to record the +time it takes to do the computation, the fibonacci function is invoked +synchronously, and the answer is printed out.

+
int hpx_main(hpx::program_options::variables_map& vm)
+{
+    hpx::threads::add_scheduler_mode(
+        hpx::threads::policies::scheduler_mode::fast_idle_mode);
+
+    // extract command line argument, i.e. fib(N)
+    std::uint64_t n = vm["n-value"].as<std::uint64_t>();
+
+    {
+        // Keep track of the time required to execute.
+        hpx::chrono::high_resolution_timer t;
+
+        std::uint64_t r = fibonacci(n);
+
+        char const* fmt = "fibonacci({1}) == {2}\nelapsed time: {3} [s]\n";
+        hpx::util::format_to(std::cout, fmt, n, r, t.elapsed());
+    }
+
+    return hpx::local::finalize();    // Handles HPX shutdown
+}
+
+
+

The fibonacci function itself is synchronous as the work done inside is +asynchronous. To understand what is happening we have to look inside the +fibonacci function:

+
std::uint64_t fibonacci(std::uint64_t n)
+{
+    if (n < 2)
+        return n;
+
+    hpx::future<std::uint64_t> n1 = hpx::async(fibonacci, n - 1);
+    std::uint64_t n2 = fibonacci(n - 2);
+
+    return n1.get() + n2;    // wait for the Future to return their values
+}
+
+
+

This block of code looks similar to regular C++ code. First, if (n < 2), +meaning n is 0 or 1, then we return 0 or 1 (recall the first element of the +Fibonacci sequence is 0 and the second is 1). If n is larger than 1 we spawn two +new tasks whose results are contained in n1 and n2. This is done using +hpx::async which takes as arguments a function (function pointer, +object or lambda) and the arguments to the function. Instead of returning a +std::uint64_t like fibonacci does, hpx::async returns a future of a +std::uint64_t, i.e. hpx::future<std::uint64_t>. Each of these futures +represents an asynchronous, recursive call to fibonacci. After we’ve created +the futures, we wait for both of them to finish computing, we add them together, +and return that value as our result. We get the values from the futures using +the get method. The recursive call tree will continue until n is equal to 0 +or 1, at which point the value can be returned because it is implicitly known. +When this termination condition is reached, the futures can then be added up, +producing the n-th value of the Fibonacci sequence.

+

Note that calling get potentially blocks the calling HPX-thread, and lets +other HPX-threads run in the meantime. There are, however, more efficient ways +of doing this. examples/quickstart/fibonacci_futures.cpp contains many more +variations of locally computing the Fibonacci numbers, where each method makes +different tradeoffs in where asynchrony and parallelism is applied. To get +started, however, the method above is sufficient and optimizations can be +applied once you are more familiar with HPX. The example +Dataflow presents dataflow, which is a way to more +efficiently chain together multiple tasks.

+
+
+
+

Parallel algorithms#

+

This program will perform a matrix multiplication in parallel. The output will look something like this:

+
Matrix A is :
+4 9 6
+1 9 8
+
+Matrix B is :
+4 9
+6 1
+9 8
+
+Resultant Matrix is :
+124 93
+130 82
+
+
+
+
Setup#
+

The source code for this example can be found here: +matrix_multiplication.cpp.

+

To compile this program, go to your HPX build directory (see +Building HPX for information on configuring and building HPX) and +enter:

+
$ make examples.quickstart.matrix_multiplication
+
+
+

To run the program type:

+
$ ./bin/matrix_multiplication
+
+
+

or:

+
$ ./bin/matrix_multiplication --n 2 --m 3 --k 2 --s 100 --l 0 --u 10
+
+
+

where the first matrix is n x m and the second m x k, s is the seed for creating the random values of +the matrices and the range of these values is [l,u]

+

This should print:

+
Matrix A is :
+4 9 6
+1 9 8
+
+Matrix B is :
+4 9
+6 1
+9 8
+
+Resultant Matrix is :
+124 93
+130 82
+
+
+

Notice that the numbers may be different because of the random initialization of the matrices.

+
+
+
Walkthrough#
+

Now that you have compiled and run the code, let’s look at how the code works.

+

First, main() is used to initialize the runtime system and pass the command line arguments to the program. +hpx::init calls hpx_main() after setting up HPX, which is where our program is implemented.

+
int main(int argc, char* argv[])
+{
+    using namespace hpx::program_options;
+    options_description cmdline("usage: " HPX_APPLICATION_STRING " [options]");
+    // clang-format off
+    cmdline.add_options()
+        ("n",
+        hpx::program_options::value<std::size_t>()->default_value(2),
+        "Number of rows of first matrix")
+        ("m",
+        hpx::program_options::value<std::size_t>()->default_value(3),
+        "Number of columns of first matrix (equal to the number of rows of "
+        "second matrix)")
+        ("k",
+        hpx::program_options::value<std::size_t>()->default_value(2),
+        "Number of columns of second matrix")
+        ("seed,s",
+        hpx::program_options::value<unsigned int>(),
+        "The random number generator seed to use for this run")
+        ("l",
+        hpx::program_options::value<int>()->default_value(0),
+        "Lower limit of range of values")
+        ("u",
+        hpx::program_options::value<int>()->default_value(10),
+        "Upper limit of range of values");
+    // clang-format on
+    hpx::local::init_params init_args;
+    init_args.desc_cmdline = cmdline;
+
+    return hpx::local::init(hpx_main, argc, argv, init_args);
+}
+
+
+

Proceeding to the hpx_main() function, we can see that matrix multiplication can be done very easily.

+
int hpx_main(hpx::program_options::variables_map& vm)
+{
+    using element_type = int;
+
+    // Define matrix sizes
+    std::size_t const rowsA = vm["n"].as<std::size_t>();
+    std::size_t const colsA = vm["m"].as<std::size_t>();
+    std::size_t const rowsB = colsA;
+    std::size_t const colsB = vm["k"].as<std::size_t>();
+    std::size_t const rowsR = rowsA;
+    std::size_t const colsR = colsB;
+
+    // Initialize matrices A and B
+    std::vector<int> A(rowsA * colsA);
+    std::vector<int> B(rowsB * colsB);
+    std::vector<int> R(rowsR * colsR);
+
+    // Define seed
+    unsigned int seed = std::random_device{}();
+    if (vm.count("seed"))
+        seed = vm["seed"].as<unsigned int>();
+
+    gen.seed(seed);
+    std::cout << "using seed: " << seed << std::endl;
+
+    // Define range of values
+    int const lower = vm["l"].as<int>();
+    int const upper = vm["u"].as<int>();
+
+    // Matrices have random values in the range [lower, upper]
+    std::uniform_int_distribution<element_type> dis(lower, upper);
+    auto generator = std::bind(dis, gen);
+    hpx::ranges::generate(A, generator);
+    hpx::ranges::generate(B, generator);
+
+    // Perform matrix multiplication
+    hpx::experimental::for_loop(hpx::execution::par, 0, rowsA, [&](auto i) {
+        hpx::experimental::for_loop(0, colsB, [&](auto j) {
+            R[i * colsR + j] = 0;
+            hpx::experimental::for_loop(0, rowsB, [&](auto k) {
+                R[i * colsR + j] += A[i * colsA + k] * B[k * colsB + j];
+            });
+        });
+    });
+
+    // Print all 3 matrices
+    print_matrix(A, rowsA, colsA, "A");
+    print_matrix(B, rowsB, colsB, "B");
+    print_matrix(R, rowsR, colsR, "R");
+
+    return hpx::local::finalize();
+}
+
+
+

First, the dimensions of the matrices are defined. If they were not given as command-line arguments, their default +values are 2 x 3 for the first matrix and 3 x 2 for the second. We use standard vectors to define the matrices +to be multiplied as well as the resultant matrix.

+

To give some random initial values to our matrices, we use std::uniform_int_distribution. Then, std::bind() is used +along with hpx::ranges::generate() to yield two matrices A and B, which contain values in the range of [0, 10] or in +the range defined by the user at the command-line arguments. The seed to generate the values can also be defined by the user.

+

The next step is to perform the matrix multiplication in parallel. This can be done by just using an hpx::experimental::for_loop +combined with a parallel execution policy hpx::execution::par as the outer loop of the multiplication. Note that the execution +of hpx::experimental::for_loop without specifying an execution policy is equivalent to specifying hpx::execution::seq +as the execution policy.

+

Finally, the matrices A, B that are multiplied as well as the resultant matrix R are printed using the following function.

+
void print_matrix(std::vector<int> const& M, std::size_t rows, std::size_t cols,
+    char const* message)
+{
+    std::cout << "\nMatrix " << message << " is:" << std::endl;
+    for (std::size_t i = 0; i < rows; i++)
+    {
+        for (std::size_t j = 0; j < cols; j++)
+            std::cout << M[i * cols + j] << " ";
+        std::cout << "\n";
+    }
+}
+
+
+
+
+
+

Asynchronous execution with actions#

+

This example extends the previous example by +introducing actions: functions that can be run remotely. In this +example, however, we will still only run the action locally. The mechanism to +execute actions stays the same: hpx::async. Later +examples will demonstrate running actions on remote localities +(e.g. Remote execution with actions).

+
+
Setup#
+

The source code for this example can be found here: +fibonacci.cpp.

+

To compile this program, go to your HPX build directory (see +Building HPX for information on configuring and building HPX) and +enter:

+
$ make examples.quickstart.fibonacci
+
+
+

To run the program type:

+
$ ./bin/fibonacci
+
+
+

This should print (time should be approximate):

+
fibonacci(10) == 55
+elapsed time: 0.00186288 [s]
+
+
+

This run used the default settings, which calculate the tenth element of the +Fibonacci sequence. To declare which Fibonacci value you want to calculate, use +the --n-value option. Additionally you can use the --hpx:threads +option to declare how many OS-threads you wish to use when running the program. +For instance, running:

+
$ ./bin/fibonacci --n-value 20 --hpx:threads 4
+
+
+

Will yield:

+
fibonacci(20) == 6765
+elapsed time: 0.233827 [s]
+
+
+
+
+
Walkthrough#
+

The code needed to initialize the HPX runtime is the same as in the +previous example:

+
int main(int argc, char* argv[])
+{
+    // Configure application-specific options
+    hpx::program_options::options_description desc_commandline(
+        "Usage: " HPX_APPLICATION_STRING " [options]");
+
+    desc_commandline.add_options()("n-value",
+        hpx::program_options::value<std::uint64_t>()->default_value(10),
+        "n value for the Fibonacci function");
+
+    // Initialize and run HPX
+    hpx::init_params init_args;
+    init_args.desc_cmdline = desc_commandline;
+
+    return hpx::init(argc, argv, init_args);
+}
+
+
+

The hpx::init function in main() starts the runtime system, and +invokes hpx_main() as the first HPX-thread. The command line option +--n-value is read in, a timer +(hpx::chrono::high_resolution_timer) is set up to record the time it +takes to do the computation, the fibonacci action is invoked +synchronously, and the answer is printed out.

+
int hpx_main(hpx::program_options::variables_map& vm)
+{
+    // extract command line argument, i.e. fib(N)
+    std::uint64_t n = vm["n-value"].as<std::uint64_t>();
+
+    {
+        // Keep track of the time required to execute.
+        hpx::chrono::high_resolution_timer t;
+
+        // Wait for fib() to return the value
+        fibonacci_action fib;
+        std::uint64_t r = fib(hpx::find_here(), n);
+
+        char const* fmt = "fibonacci({1}) == {2}\nelapsed time: {3} [s]\n";
+        hpx::util::format_to(std::cout, fmt, n, r, t.elapsed());
+    }
+
+    return hpx::finalize();    // Handles HPX shutdown
+}
+
+
+

Upon a closer look we see that we’ve created a std::uint64_t to store the +result of invoking our fibonacci_action fib. This action will +launch synchronously (as the work done inside of the action will be +asynchronous itself) and return the result of the Fibonacci sequence. But wait, +what is an action? And what is this fibonacci_action? For starters, +an action is a wrapper for a function. By wrapping functions, HPX can +send packets of work to different processing units. These vehicles allow users +to calculate work now, later, or on certain nodes. The first argument to our +action is the location where the action should be run. In this +case, we just want to run the action on the machine that we are +currently on, so we use hpx::find_here. To +further understand this we turn to the code to find where fibonacci_action +was defined:

+
// forward declaration of the Fibonacci function
+std::uint64_t fibonacci(std::uint64_t n);
+
+// This is to generate the required boilerplate we need for the remote
+// invocation to work.
+HPX_PLAIN_ACTION(fibonacci, fibonacci_action)
+
+
+

A plain action is the most basic form of action. Plain +actions wrap simple global functions which are not associated with any +particular object (we will discuss other types of actions in +Components and actions). In this block of code the function fibonacci() +is declared. After the declaration, the function is wrapped in an action +in the declaration HPX_PLAIN_ACTION. This function takes two +arguments: the name of the function that is to be wrapped and the name of the +action that you are creating.

+

This picture should now start making sense. The function fibonacci() is +wrapped in an action fibonacci_action, which was run synchronously +but created asynchronous work, then returns a std::uint64_t representing the +result of the function fibonacci(). Now, let’s look at the function +fibonacci():

+
std::uint64_t fibonacci(std::uint64_t n)
+{
+    if (n < 2)
+        return n;
+
+    // We restrict ourselves to execute the Fibonacci function locally.
+    hpx::id_type const locality_id = hpx::find_here();
+
+    // Invoking the Fibonacci algorithm twice is inefficient.
+    // However, we intentionally demonstrate it this way to create some
+    // heavy workload.
+
+    fibonacci_action fib;
+    hpx::future<std::uint64_t> n1 = hpx::async(fib, locality_id, n - 1);
+    hpx::future<std::uint64_t> n2 = hpx::async(fib, locality_id, n - 2);
+
+    return n1.get() +
+        n2.get();    // wait for the Futures to return their values
+}
+
+
+

This block of code is much more straightforward and should look familiar from +the previous example. First, if (n < 2), +meaning n is 0 or 1, then we return 0 or 1 (recall the first element of the +Fibonacci sequence is 0 and the second is 1). If n is larger than 1 we spawn two +tasks using hpx::async. Each of these futures represents an +asynchronous, recursive call to fibonacci. As previously we wait for both +futures to finish computing, get the results, add them together, and return that +value as our result. The recursive call tree will continue until n is equal to 0 +or 1, at which point the value can be returned because it is implicitly known. +When this termination condition is reached, the futures can then be added up, +producing the n-th value of the Fibonacci sequence.

+
+
+
+

Remote execution with actions#

+

This program will print out a hello world message on every OS-thread on every +locality. The output will look something like this:

+
hello world from OS-thread 1 on locality 0
+hello world from OS-thread 1 on locality 1
+hello world from OS-thread 0 on locality 0
+hello world from OS-thread 0 on locality 1
+
+
+
+
Setup#
+

The source code for this example can be found here: +hello_world_distributed.cpp.

+

To compile this program, go to your HPX build directory (see +Building HPX for information on configuring and building HPX) and +enter:

+
$ make examples.quickstart.hello_world_distributed
+
+
+

To run the program type:

+
$ ./bin/hello_world_distributed
+
+
+

This should print:

+
hello world from OS-thread 0 on locality 0
+
+
+

To use more OS-threads use the command line option --hpx:threads and +type the number of threads that you wish to use. For example, typing:

+
$ ./bin/hello_world_distributed --hpx:threads 2
+
+
+

will yield:

+
hello world from OS-thread 1 on locality 0
+hello world from OS-thread 0 on locality 0
+
+
+

Notice how the ordering of the two print statements will change with +subsequent runs. To run this program on multiple localities please see the +section How to use HPX applications with PBS.

+
+
+
Walkthrough#
+

Now that you have compiled and run the code, let’s look at how the code works, +beginning with main():

+
// Here is the main entry point. By using the include 'hpx/hpx_main.hpp' HPX
+// will invoke the plain old C-main() as its first HPX thread.
+int main()
+{
+    // Get a list of all available localities.
+    std::vector<hpx::id_type> localities = hpx::find_all_localities();
+
+    // Reserve storage space for futures, one for each locality.
+    std::vector<hpx::future<void>> futures;
+    futures.reserve(localities.size());
+
+    for (hpx::id_type const& node : localities)
+    {
+        // Asynchronously start a new task. The task is encapsulated in a
+        // future, which we can query to determine if the task has
+        // completed.
+        typedef hello_world_foreman_action action_type;
+        futures.push_back(hpx::async<action_type>(node));
+    }
+
+    // The non-callback version of hpx::wait_all takes a single parameter,
+    // a vector of futures to wait on. hpx::wait_all only returns when
+    // all of the futures have finished.
+    hpx::wait_all(futures);
+    return 0;
+}
+
+
+

In this excerpt of the code we again see the use of futures. This time the +futures are stored in a vector so that they can easily be accessed. +hpx::wait_all is a family of functions that wait on for an +std::vector<> of futures to become ready. In this piece of code, we are +using the synchronous version of hpx::wait_all, which takes one +argument (the std::vector<> of futures to wait on). This function will not +return until all the futures in the vector have been executed.

+

In Asynchronous execution with actions we used hpx::find_here to specify the +target of our actions. Here, we instead use +hpx::find_all_localities, which returns an std::vector<> +containing the identifiers of all the machines in the system, including the one +that we are on.

+

As in Asynchronous execution with actions our futures are set using +hpx::async<>. The hello_world_foreman_action is declared +here:

+
// Define the boilerplate code necessary for the function 'hello_world_foreman'
+// to be invoked as an HPX action.
+HPX_PLAIN_ACTION(hello_world_foreman, hello_world_foreman_action)
+
+
+

Another way of thinking about this wrapping technique is as follows: functions +(the work to be done) are wrapped in actions, and actions can be executed +locally or remotely (e.g. on another machine participating in the computation).

+

Now it is time to look at the hello_world_foreman() function which was +wrapped in the action above:

+
void hello_world_foreman()
+{
+    // Get the number of worker OS-threads in use by this locality.
+    std::size_t const os_threads = hpx::get_os_thread_count();
+
+    // Populate a set with the OS-thread numbers of all OS-threads on this
+    // locality. When the hello world message has been printed on a particular
+    // OS-thread, we will remove it from the set.
+    std::set<std::size_t> attendance;
+    for (std::size_t os_thread = 0; os_thread < os_threads; ++os_thread)
+        attendance.insert(os_thread);
+
+    // As long as there are still elements in the set, we must keep scheduling
+    // HPX-threads. Because HPX features work-stealing task schedulers, we have
+    // no way of enforcing which worker OS-thread will actually execute
+    // each HPX-thread.
+    while (!attendance.empty())
+    {
+        // Each iteration, we create a task for each element in the set of
+        // OS-threads that have not said "Hello world". Each of these tasks
+        // is encapsulated in a future.
+        std::vector<hpx::future<std::size_t>> futures;
+        futures.reserve(attendance.size());
+
+        for (std::size_t worker : attendance)
+        {
+            // Asynchronously start a new task. The task is encapsulated in a
+            // future that we can query to determine if the task has completed.
+            //
+            // We give the task a hint to run on a particular worker thread
+            // (core) and suggest binding the scheduled thread to the given
+            // core, but no guarantees are given by the scheduler that the task
+            // will actually run on that worker thread. It will however try as
+            // hard as possible to place the new task on the given worker
+            // thread.
+            hpx::execution::parallel_executor exec(
+                hpx::threads::thread_priority::bound);
+
+            hpx::threads::thread_schedule_hint hint(
+                hpx::threads::thread_schedule_hint_mode::thread,
+                static_cast<std::int16_t>(worker));
+
+            futures.push_back(
+                hpx::async(hpx::execution::experimental::with_hint(exec, hint),
+                    hello_world_worker, worker));
+        }
+
+        // Wait for all of the futures to finish. The callback version of the
+        // hpx::wait_each function takes two arguments: a vector of futures,
+        // and a binary callback.  The callback takes two arguments; the first
+        // is the index of the future in the vector, and the second is the
+        // return value of the future. hpx::wait_each doesn't return until
+        // all the futures in the vector have returned.
+        hpx::spinlock mtx;
+        hpx::wait_each(hpx::unwrapping([&](std::size_t t) {
+            if (std::size_t(-1) != t)
+            {
+                std::lock_guard<hpx::spinlock> lk(mtx);
+                attendance.erase(t);
+            }
+        }),
+            futures);
+    }
+}
+
+
+

Now, before we discuss hello_world_foreman(), let’s talk about the +hpx::wait_each function. +The version of hpx::wait_each invokes a callback function +provided by the user, supplying the callback function with the result of the +future.

+

In hello_world_foreman(), an std::set<> called attendance keeps +track of which OS-threads have printed out the hello world message. When the +OS-thread prints out the statement, the future is marked as ready, and +hpx::wait_each in hello_world_foreman(). If it is not +executing on the correct OS-thread, it returns a value of -1, which causes +hello_world_foreman() to leave the OS-thread id in attendance.

+
std::size_t hello_world_worker(std::size_t desired)
+{
+    // Returns the OS-thread number of the worker that is running this
+    // HPX-thread.
+    std::size_t current = hpx::get_worker_thread_num();
+    if (current == desired)
+    {
+        // The HPX-thread has been run on the desired OS-thread.
+        char const* msg = "hello world from OS-thread {1} on locality {2}\n";
+
+        hpx::util::format_to(hpx::cout, msg, desired, hpx::get_locality_id())
+            << std::flush;
+
+        return desired;
+    }
+
+    // This HPX-thread has been run by the wrong OS-thread, make the foreman
+    // try again by rescheduling it.
+    return std::size_t(-1);
+}
+
+
+

Because HPX features work stealing task schedulers, there is no way to +guarantee that an action will be scheduled on a particular OS-thread. This is +why we must use a guess-and-check approach.

+
+
+
+

Components and actions#

+

The accumulator examples demonstrate the use of components. Components are C++ +classes that expose methods as a type of HPX action. These actions are called +component actions. There are three examples: +- accumulator +- template accumulator +- template function accumulator

+

Components are globally named, meaning that a component action can be called +remotely (e.g., from another machine). There are two accumulator examples in +HPX.

+

In the Asynchronous execution with actions and the Remote execution with actions, we +introduced plain actions, which wrapped global functions. The target of a plain +action is an identifier which refers to a particular machine involved in the +computation. For plain actions, the target is the machine where the action will +be executed.

+

Component actions, however, do not target machines. Instead, they target +component instances. The instance may live on the machine that we’ve invoked the +component action from, or it may live on another machine.

+

The components in these examples expose three different functions:

+
    +
  • reset() - Resets the accumulator value to 0.

  • +
  • add(arg) - Adds arg to the accumulators value.

  • +
  • query() - Queries the value of the accumulator.

  • +
+

These examples create an instance of the (template or template function) accumulator, +and then allow the user to enter commands at a prompt, which subsequently invoke actions +on the accumulator instance.

+
+
Accumulator#
+
+
Setup#
+

The source code for this example can be found here: +accumulator_client.cpp.

+

To compile this program, go to your HPX build directory (see +Building HPX for information on configuring and building HPX) and +enter:

+
$ make examples.accumulators.accumulator
+
+
+

To run the program type:

+
$ ./bin/accumulator_client
+
+
+

Once the program starts running, it will print the following prompt and then +wait for input. An example session is given below:

+
commands: reset, add [amount], query, help, quit
+> add 5
+> add 10
+> query
+15
+> add 2
+> query
+17
+> reset
+> add 1
+> query
+1
+> quit
+
+
+
+
+
Walkthrough#
+

Now, let’s take a look at the source code of the accumulator example. This +example consists of two parts: an HPX component library (a library that +exposes an HPX component) and a client application which uses the library. +This walkthrough will cover the HPX component library. The code for the client +application can be found here: accumulator_client.cpp.

+

An HPX component is represented by two C++ classes:

+
    +
  • A server class - The implementation of the component’s functionality.

  • +
  • A client class - A high-level interface that acts as a proxy for an +instance of the component.

  • +
+

Typically, these two classes both have the same name, but the server class +usually lives in different sub-namespaces (server). For example, the full +names of the two classes in accumulator are:

+
    +
  • examples::server::accumulator (server class)

  • +
  • examples::accumulator (client class)

  • +
+
+The server class# +

The following code is from +server/accumulator.hpp.

+

All HPX component server classes must inherit publicly from the HPX +component base class: hpx::components::component_base

+

The accumulator component inherits from +hpx::components::locking_hook. This allows the runtime system to +ensure that all action invocations are serialized. That means that the system +ensures that no two actions are invoked at the same time on a given component +instance. This makes the component thread safe and no additional locking has to +be implemented by the user. Moreover, an accumulator component is a component +because it also inherits from hpx::components::component_base (the +template argument passed to locking_hook is used as its base class). The +following snippet shows the corresponding code:

+
    class accumulator
+      : public hpx::components::locking_hook<
+            hpx::components::component_base<accumulator>>
+
+
+

Our accumulator class will need a data member to store its value in, so let’s +declare a data member:

+
        argument_type value_;
+
+
+

The constructor for this class simply initializes value_ to 0:

+
        accumulator()
+          : value_(0)
+        {
+        }
+
+
+

Next, let’s look at the three methods of this component that we will be exposing +as component actions:

+

Here are the action types. These types wrap the methods we’re exposing. The +wrapping technique is very similar to the one used in the +Asynchronous execution with actions and the Remote execution with actions:

+
        HPX_DEFINE_COMPONENT_ACTION(accumulator, reset)
+        HPX_DEFINE_COMPONENT_ACTION(accumulator, add)
+        HPX_DEFINE_COMPONENT_ACTION(accumulator, query)
+
+
+

The last piece of code in the server class header is the declaration of the +action type registration code:

+
HPX_REGISTER_ACTION_DECLARATION(
+    examples::server::accumulator::reset_action, accumulator_reset_action)
+
+HPX_REGISTER_ACTION_DECLARATION(
+    examples::server::accumulator::add_action, accumulator_add_action)
+
+HPX_REGISTER_ACTION_DECLARATION(
+    examples::server::accumulator::query_action, accumulator_query_action)
+
+
+
+

Note

+

The code above must be placed in the global namespace.

+
+

The rest of the registration code is in +accumulator.cpp

+
///////////////////////////////////////////////////////////////////////////////
+// Add factory registration functionality.
+HPX_REGISTER_COMPONENT_MODULE()
+
+///////////////////////////////////////////////////////////////////////////////
+typedef hpx::components::component<examples::server::accumulator>
+    accumulator_type;
+
+HPX_REGISTER_COMPONENT(accumulator_type, accumulator)
+
+///////////////////////////////////////////////////////////////////////////////
+// Serialization support for accumulator actions.
+HPX_REGISTER_ACTION(
+    accumulator_type::wrapped_type::reset_action, accumulator_reset_action)
+HPX_REGISTER_ACTION(
+    accumulator_type::wrapped_type::add_action, accumulator_add_action)
+HPX_REGISTER_ACTION(
+    accumulator_type::wrapped_type::query_action, accumulator_query_action)
+
+
+
+

Note

+

The code above must be placed in the global namespace.

+
+
+
+The client class# +

The following code is from +accumulator.hpp

+

The client class is the primary interface to a component instance. Client classes +are used to create components:

+
// Create a component on this locality.
+examples::accumulator c = hpx::new_<examples::accumulator>(hpx::find_here());
+
+
+

and to invoke component actions:

+
c.add(hpx::launch::apply, 4);
+
+
+

Clients, like servers, need to inherit from a base class, this time, +hpx::components::client_base:

+
    class accumulator
+      : public hpx::components::client_base<accumulator, server::accumulator>
+
+
+

For readability, we typedef the base class like so:

+
        typedef hpx::components::client_base<accumulator, server::accumulator>
+            base_type;
+
+
+

Here are examples of how to expose actions through a client class:

+

There are a few different ways of invoking actions:

+
    +
  • Non-blocking: For actions that don’t have return types, or when we do not +care about the result of an action, we can invoke the action using +fire-and-forget semantics. This means that once we have asked HPX to compute +the action, we forget about it completely and continue with our computation. +We use hpx::post to invoke an action in a non-blocking fashion.

  • +
+
        void reset(hpx::launch::apply_policy)
+        {
+            HPX_ASSERT(this->get_id());
+
+            typedef server::accumulator::reset_action action_type;
+            hpx::post(action_type(), this->get_id());
+        }
+
+
+ +
        hpx::future<argument_type> query(hpx::launch::async_policy)
+        {
+            HPX_ASSERT(this->get_id());
+
+            typedef server::accumulator::query_action action_type;
+            return hpx::async(action_type(), this->get_id());
+        }
+
+
+
    +
  • Synchronous: To invoke an action in a fully synchronous manner, we can +simply call hpx::sync which is semantically equivalent to +hpx::async().get() (i.e., create a future and immediately +wait on it to be ready). Here’s an example from the accumulator +client class:

  • +
+
        void add(argument_type arg)
+        {
+            HPX_ASSERT(this->get_id());
+
+            typedef server::accumulator::add_action action_type;
+            action_type()(this->get_id(), arg);
+        }
+
+
+

Note that this->get_id() references a data member of the +hpx::components::client_base base class which identifies the server +accumulator instance.

+

hpx::naming::id_type is a type which represents a global identifier +in HPX. This type specifies the target of an action. This is the type that is +returned by hpx::find_here in which case it represents the +locality the code is running on.

+
+
+
+
+
Template accumulator#
+
+
Walkthrough#
+
+The server class# +

The following code is from +server/template_accumulator.hpp.

+

Similarly to the accumulator example, the component server class +inherits publicly from hpx::components::component_base and from +hpx::components::locking_hook ensuring thread-safe method invocations.

+
    template <typename T>
+    class template_accumulator
+      : public hpx::components::locking_hook<
+            hpx::components::component_base<template_accumulator<T>>>
+
+
+

The body of the template accumulator class remains mainly the same as the accumulator with +the difference that it uses templates in the data types.

+
        typedef T argument_type;
+
+        template_accumulator()
+          : value_(0)
+        {
+        }
+
+        ///////////////////////////////////////////////////////////////////////
+        // Exposed functionality of this component.
+
+        /// Reset the components value to 0.
+        void reset()
+        {
+            //  set value_ to 0.
+            value_ = 0;
+        }
+
+        /// Add the given number to the accumulator.
+        void add(argument_type arg)
+        {
+            //  add value_ to arg, and store the result in value_.
+            value_ += arg;
+        }
+
+        /// Return the current value to the caller.
+        argument_type query() const
+        {
+            // Get the value of value_.
+            return value_;
+        }
+
+        ///////////////////////////////////////////////////////////////////////
+        // Each of the exposed functions needs to be encapsulated into an
+        // action type, generating all required boilerplate code for threads,
+        // serialization, etc.
+        HPX_DEFINE_COMPONENT_ACTION(template_accumulator, reset)
+        HPX_DEFINE_COMPONENT_ACTION(template_accumulator, add)
+        HPX_DEFINE_COMPONENT_ACTION(template_accumulator, query)
+
+
+

The last piece of code in the server class header is the declaration of the +action type registration code. REGISTER_TEMPLATE_ACCUMULATOR_DECLARATION(type) declares +actions for the specified type, while REGISTER_TEMPLATE_ACCUMULATOR(type) registers the +actions and the component for the specified type, using macros to handle boilerplate code.

+
#define REGISTER_TEMPLATE_ACCUMULATOR_DECLARATION(type)                        \
+    HPX_REGISTER_ACTION_DECLARATION(                                           \
+        examples::server::template_accumulator<type>::reset_action,            \
+        HPX_PP_CAT(__template_accumulator_reset_action_, type))                \
+                                                                               \
+    HPX_REGISTER_ACTION_DECLARATION(                                           \
+        examples::server::template_accumulator<type>::add_action,              \
+        HPX_PP_CAT(__template_accumulator_add_action_, type))                  \
+                                                                               \
+    HPX_REGISTER_ACTION_DECLARATION(                                           \
+        examples::server::template_accumulator<type>::query_action,            \
+        HPX_PP_CAT(__template_accumulator_query_action_, type))                \
+    /**/
+
+#define REGISTER_TEMPLATE_ACCUMULATOR(type)                                    \
+    HPX_REGISTER_ACTION(                                                       \
+        examples::server::template_accumulator<type>::reset_action,            \
+        HPX_PP_CAT(__template_accumulator_reset_action_, type))                \
+                                                                               \
+    HPX_REGISTER_ACTION(                                                       \
+        examples::server::template_accumulator<type>::add_action,              \
+        HPX_PP_CAT(__template_accumulator_add_action_, type))                  \
+                                                                               \
+    HPX_REGISTER_ACTION(                                                       \
+        examples::server::template_accumulator<type>::query_action,            \
+        HPX_PP_CAT(__template_accumulator_query_action_, type))                \
+                                                                               \
+    typedef ::hpx::components::component<                                      \
+        examples::server::template_accumulator<type>>                          \
+        HPX_PP_CAT(__template_accumulator_, type);                             \
+    HPX_REGISTER_COMPONENT(HPX_PP_CAT(__template_accumulator_, type))          \
+    /**/
+
+
+
+

Note

+

The code above must be placed in the global namespace.

+
+

Finally, HPX_REGISTER_COMPONENT_MODULE() in file +server/template_accumulator.cpp +adds the factory registration functionality.

+
+
+The client class# +

The client class of the template accumulator can be found in +template_accumulator.hpp and is very similar to +the client class of the accumulator with the only difference that it uses templates +and hence can work with different types.

+
+
+
+
+
Template function accumulator#
+
+
Walkthrough#
+
+The server class# +

The following code is from +server/template_function_accumulator.hpp.

+

The component server class inherits publicly from hpx::components::component_base.

+
    class template_function_accumulator
+      : public hpx::components::component_base<template_function_accumulator>
+
+
+

typedef hpx::spinlock mutex_type defines a mutex_type as hpx::spinlock for thread safety, +while the code that follows exposes the functionality of this component.

+
        ///////////////////////////////////////////////////////////////////////
+        // Exposed functionality of this component.
+
+        /// Reset the value to 0.
+        void reset()
+        {
+            // Atomically set value_ to 0.
+            std::lock_guard<mutex_type> l(mtx_);
+            value_ = 0;
+        }
+
+        /// Add the given number to the accumulator.
+        template <typename T>
+        void add(T arg)
+        {
+            // Atomically add value_ to arg, and store the result in value_.
+            std::lock_guard<mutex_type> l(mtx_);
+            value_ += static_cast<double>(arg);
+        }
+
+        /// Return the current value to the caller.
+        double query() const
+        {
+            // Get the value of value_.
+            std::lock_guard<mutex_type> l(mtx_);
+            return value_;
+        }
+
+
+
    +
  • reset(): Resets the accumulator value to 0 in a thread-safe manner using +std::lock_guard.

  • +
  • add(): Adds a value to the accumulator, allowing any type T that can be cast to double.

  • +
  • query(): Returns the current value of the accumulator in a thread-safe manner.

  • +
+

To define the actions for reset() and query() we can use the macro HPX_DEFINE_COMPONENT_ACTION. +However, actions with template arguments require special type definitions. Therefore, we use +make_action() to define add().

+
        ///////////////////////////////////////////////////////////////////////
+        // Each of the exposed functions needs to be encapsulated into an
+        // action type, generating all required boilerplate code for threads,
+        // serialization, etc.
+
+        HPX_DEFINE_COMPONENT_ACTION(template_function_accumulator, reset)
+        HPX_DEFINE_COMPONENT_ACTION(template_function_accumulator, query)
+
+        // Actions with template arguments (see add<>() above) require special
+        // type definitions. The simplest way to define such an action type is
+        // by deriving from the HPX facility make_action.
+        template <typename T>
+        struct add_action
+          : hpx::actions::make_action<void (template_function_accumulator::*)(
+                                          T),
+                &template_function_accumulator::template add<T>,
+                add_action<T>>::type
+        {
+        };
+
+
+

The last piece of code in the server class header is the action registration:

+
HPX_REGISTER_ACTION_DECLARATION(
+    examples::server::template_function_accumulator::reset_action,
+    managed_accumulator_reset_action)
+
+HPX_REGISTER_ACTION_DECLARATION(
+    examples::server::template_function_accumulator::query_action,
+    managed_accumulator_query_action)
+
+
+
+

Note

+

The code above must be placed in the global namespace.

+
+

The rest of the registration code is in +accumulator.cpp

+
///////////////////////////////////////////////////////////////////////////////
+// Add factory registration functionality.
+HPX_REGISTER_COMPONENT_MODULE()
+
+///////////////////////////////////////////////////////////////////////////////
+typedef hpx::components::component<
+    examples::server::template_function_accumulator>
+    accumulator_type;
+
+HPX_REGISTER_COMPONENT(accumulator_type, template_function_accumulator)
+
+///////////////////////////////////////////////////////////////////////////////
+// Serialization support for managed_accumulator actions.
+HPX_REGISTER_ACTION(accumulator_type::wrapped_type::reset_action,
+    managed_accumulator_reset_action)
+HPX_REGISTER_ACTION(accumulator_type::wrapped_type::query_action,
+    managed_accumulator_query_action)
+
+
+
+

Note

+

The code above must be placed in the global namespace.

+
+
+
+The client class# +

The client class of the template accumulator can be found in +template_function_accumulator.hpp and is very similar +to the client class of the accumulator with the only difference that it uses templates +and hence can work with different types.

+
+
+
+
+
+

Dataflow#

+

HPX provides its users with several different tools to simply express parallel +concepts. One of these tools is a local control object (LCO) +called dataflow. An LCO is a type of component that can spawn a new +thread when triggered. They are also distinguished from other components by a +standard interface that allow users to understand and use them easily. +A Dataflow, being an LCO, is triggered when the values it depends on +become available. For instance, if you have a calculation X that depends on the +results of three other calculations, you could set up a dataflow that would begin +the calculation X as soon as the other three calculations have returned their +values. Dataflows are set up to depend on other dataflows. It is this property +that makes dataflow a powerful parallelization tool. If you understand the +dependencies of your calculation, you can devise a simple algorithm that sets +up a dependency tree to be executed. In this example, we calculate compound +interest. To calculate compound interest, one must calculate the interest made +in each compound period, and then add that interest back to the principal before +calculating the interest made in the next period. A practical person would, of +course, use the formula for compound interest:

+
+\[F = P(1 + i) ^ n\]
+

where \(F\) is the future value, \(P\) is the principal value, \(i\) +is the interest rate, and \(n\) is the number of compound periods.

+

However, for the sake of this example, we have chosen to manually calculate the +future value by iterating:

+
+\[I = Pi\]
+

and

+
+\[P = P + I\]
+
+
Setup#
+

The source code for this example can be found here: +interest_calculator.cpp.

+

To compile this program, go to your HPX build directory (see +Building HPX for information on configuring and building HPX) and +enter:

+
$ make examples.quickstart.interest_calculator
+
+
+

To run the program type:

+
$ ./bin/interest_calculator --principal 100 --rate 5 --cp 6 --time 36
+Final amount: 134.01
+Amount made: 34.0096
+
+
+
+
+
Walkthrough#
+

Let us begin with main. Here we can see that we again are using +Boost.Program_options to set our command line variables (see +Asynchronous execution with actions for more details). These options set the principal, +rate, compound period, and time. It is important to note that the units of time +for cp and time must be the same.

+
int main(int argc, char** argv)
+{
+    options_description cmdline("Usage: " HPX_APPLICATION_STRING " [options]");
+
+    cmdline.add_options()("principal", value<double>()->default_value(1000),
+        "The principal [$]")("rate", value<double>()->default_value(7),
+        "The interest rate [%]")("cp", value<int>()->default_value(12),
+        "The compound period [months]")("time",
+        value<int>()->default_value(12 * 30),
+        "The time money is invested [months]");
+
+    hpx::init_params init_args;
+    init_args.desc_cmdline = cmdline;
+
+    return hpx::init(argc, argv, init_args);
+}
+
+
+

Next we look at hpx_main.

+
int hpx_main(variables_map& vm)
+{
+    {
+        using hpx::dataflow;
+        using hpx::make_ready_future;
+        using hpx::shared_future;
+        using hpx::unwrapping;
+        hpx::id_type here = hpx::find_here();
+
+        double init_principal =
+            vm["principal"].as<double>();              //Initial principal
+        double init_rate = vm["rate"].as<double>();    //Interest rate
+        int cp = vm["cp"].as<int>();     //Length of a compound period
+        int t = vm["time"].as<int>();    //Length of time money is invested
+
+        init_rate /= 100;    //Rate is a % and must be converted
+        t /= cp;    //Determine how many times to iterate interest calculation:
+            //How many full compound periods can fit in the time invested
+
+        // In non-dataflow terms the implemented algorithm would look like:
+        //
+        // int t = 5;    // number of time periods to use
+        // double principal = init_principal;
+        // double rate = init_rate;
+        //
+        // for (int i = 0; i < t; ++i)
+        // {
+        //     double interest = calc(principal, rate);
+        //     principal = add(principal, interest);
+        // }
+        //
+        // Please note the similarity with the code below!
+
+        shared_future<double> principal = make_ready_future(init_principal);
+        shared_future<double> rate = make_ready_future(init_rate);
+
+        for (int i = 0; i < t; ++i)
+        {
+            shared_future<double> interest =
+                dataflow(unwrapping(calc), principal, rate);
+            principal = dataflow(unwrapping(add), principal, interest);
+        }
+
+        // wait for the dataflow execution graph to be finished calculating our
+        // overall interest
+        double result = principal.get();
+
+        std::cout << "Final amount: " << result << std::endl;
+        std::cout << "Amount made: " << result - init_principal << std::endl;
+    }
+
+    return hpx::finalize();
+}
+
+
+

Here we find our command line variables read in, the rate is converted from a +percent to a decimal, the number of calculation iterations is determined, and +then our shared_futures are set up. Notice that we first place our principal and +rate into shares futures by passing the variables init_principal and +init_rate using hpx::make_ready_future.

+

In this way hpx::shared_future<double> principal +and rate will be initialized to init_principal and init_rate when +hpx::make_ready_future<double> returns a future containing +those initial values. These shared futures then enter the for loop and are +passed to interest. Next principal and interest are passed to the +reassignment of principal using a hpx::dataflow. A dataflow +will first wait for its arguments to be ready before launching any callbacks, so +add in this case will not begin until both principal and interest +are ready. This loop continues for each compound period that must be calculated. +To see how interest and principal are calculated in the loop, let us look +at calc_action and add_action:

+
// Calculate interest for one period
+double calc(double principal, double rate)
+{
+    return principal * rate;
+}
+
+///////////////////////////////////////////////////////////////////////////////
+// Add the amount made to the principal
+double add(double principal, double interest)
+{
+    return principal + interest;
+}
+
+
+

After the shared future dependencies have been defined in hpx_main, we see the +following statement:

+
double result = principal.get();
+
+
+

This statement calls hpx::future::get on the shared future +principal which had its value calculated by our for loop. The program will wait +here until the entire dataflow tree has been calculated and the value assigned +to result. The program then prints out the final value of the investment and the +amount of interest made by subtracting the final value of the investment from +the initial value of the investment.

+
+
+
+

Local to remote#

+

When developers write code they typically begin with a simple serial code and +build upon it until all of the required functionality is present. The following +set of examples were developed to demonstrate this iterative process of evolving +a simple serial program to an efficient, fully-distributed HPX application. For +this demonstration, we implemented a 1D heat distribution problem. This +calculation simulates the diffusion of heat across a ring from an initialized +state to some user-defined point in the future. It does this by breaking each +portion of the ring into discrete segments and using the current segment’s +temperature and the temperature of the surrounding segments to calculate the +temperature of the current segment in the next timestep as shown by +Fig. 2 below.

+
+_images/1d_stencil_program_flow.png +
+

Fig. 2 Heat diffusion example program flow.#

+
+
+

We parallelize this code over the following eight examples:

+ +

The first example is straight serial code. In this code we instantiate a vector +U that contains two vectors of doubles as seen in the structure +stepper.

+
struct stepper
+{
+    // Our partition type
+    typedef double partition;
+
+    // Our data for one time step
+    typedef std::vector<partition> space;
+
+    // Our operator
+    static double heat(double left, double middle, double right)
+    {
+        return middle + (k * dt / (dx * dx)) * (left - 2 * middle + right);
+    }
+
+    // do all the work on 'nx' data points for 'nt' time steps
+    space do_work(std::size_t nx, std::size_t nt)
+    {
+        // U[t][i] is the state of position i at time t.
+        std::vector<space> U(2);
+        for (space& s : U)
+            s.resize(nx);
+
+        // Initial conditions: f(0, i) = i
+        for (std::size_t i = 0; i != nx; ++i)
+            U[0][i] = double(i);
+
+        // Actual time step loop
+        for (std::size_t t = 0; t != nt; ++t)
+        {
+            space const& current = U[t % 2];
+            space& next = U[(t + 1) % 2];
+
+            next[0] = heat(current[nx - 1], current[0], current[1]);
+
+            for (std::size_t i = 1; i != nx - 1; ++i)
+                next[i] = heat(current[i - 1], current[i], current[i + 1]);
+
+            next[nx - 1] = heat(current[nx - 2], current[nx - 1], current[0]);
+        }
+
+        // Return the solution at time-step 'nt'.
+        return U[nt % 2];
+    }
+};
+
+
+

Each element in the vector of doubles represents a single grid point. To +calculate the change in heat distribution, the temperature of each grid point, +along with its neighbors, is passed to the function heat. In order to +improve readability, references named current and next are created +which, depending on the time step, point to the first and second vector of +doubles. The first vector of doubles is initialized with a simple heat ramp. +After calling the heat function with the data in the current vector, the +results are placed into the next vector.

+

In example 2 we employ a technique called futurization. Futurization is a method +by which we can easily transform a code that is serially executed into a code +that creates asynchronous threads. In the simplest case this involves replacing +a variable with a future to a variable, a function with a future to a function, +and adding a .get() at the point where a value is actually needed. The code +below shows how this technique was applied to the struct stepper.

+
struct stepper
+{
+    // Our partition type
+    typedef hpx::shared_future<double> partition;
+
+    // Our data for one time step
+    typedef std::vector<partition> space;
+
+    // Our operator
+    static double heat(double left, double middle, double right)
+    {
+        return middle + (k * dt / (dx * dx)) * (left - 2 * middle + right);
+    }
+
+    // do all the work on 'nx' data points for 'nt' time steps
+    hpx::future<space> do_work(std::size_t nx, std::size_t nt)
+    {
+        using hpx::dataflow;
+        using hpx::unwrapping;
+
+        // U[t][i] is the state of position i at time t.
+        std::vector<space> U(2);
+        for (space& s : U)
+            s.resize(nx);
+
+        // Initial conditions: f(0, i) = i
+        for (std::size_t i = 0; i != nx; ++i)
+            U[0][i] = hpx::make_ready_future(double(i));
+
+        auto Op = unwrapping(&stepper::heat);
+
+        // Actual time step loop
+        for (std::size_t t = 0; t != nt; ++t)
+        {
+            space const& current = U[t % 2];
+            space& next = U[(t + 1) % 2];
+
+            // WHEN U[t][i-1], U[t][i], and U[t][i+1] have been computed, THEN we
+            // can compute U[t+1][i]
+            for (std::size_t i = 0; i != nx; ++i)
+            {
+                next[i] =
+                    dataflow(hpx::launch::async, Op, current[idx(i, -1, nx)],
+                        current[i], current[idx(i, +1, nx)]);
+            }
+        }
+
+        // Now the asynchronous computation is running; the above for-loop does not
+        // wait on anything. There is no implicit waiting at the end of each timestep;
+        // the computation of each U[t][i] will begin as soon as its dependencies
+        // are ready and hardware is available.
+
+        // Return the solution at time-step 'nt'.
+        return hpx::when_all(U[nt % 2]);
+    }
+};
+
+
+

In example 2, we redefine our partition type as a shared_future and, in +main, create the object result, which is a future to a vector of +partitions. We use result to represent the last vector in a string of +vectors created for each timestep. In order to move to the next timestep, the +values of a partition and its neighbors must be passed to heat once the +futures that contain them are ready. In HPX, we have an LCO (Local Control +Object) named Dataflow that assists the programmer in expressing this +dependency. Dataflow allows us to pass the results of a set of futures to a +specified function when the futures are ready. Dataflow takes three types of +arguments, one which instructs the dataflow on how to perform the function call +(async or sync), the function to call (in this case Op), and futures to the +arguments that will be passed to the function. When called, dataflow immediately +returns a future to the result of the specified function. This allows users to +string dataflows together and construct an execution tree.

+

After the values of the futures in dataflow are ready, the values must be pulled +out of the future container to be passed to the function heat. In order to +do this, we use the HPX facility unwrapping, which underneath calls +.get() on each of the futures so that the function heat will be passed +doubles and not futures to doubles.

+

By setting up the algorithm this way, the program will be able to execute as +quickly as the dependencies of each future are met. Unfortunately, this example +runs terribly slow. This increase in execution time is caused by the overheads +needed to create a future for each data point. Because the work done within each +call to heat is very small, the overhead of creating and scheduling each of the +three futures is greater than that of the actual useful work! In order to +amortize the overheads of our synchronization techniques, we need to be able to +control the amount of work that will be done with each future. We call this +amount of work per overhead grain size.

+

In example 3, we return to our serial code to figure out how to control the +grain size of our program. The strategy that we employ is to create “partitions” +of data points. The user can define how many partitions are created and how many +data points are contained in each partition. This is accomplished by creating +the struct partition, which contains a member object data_, a vector of +doubles that holds the data points assigned to a particular instance of +partition.

+

In example 4, we take advantage of the partition setup by redefining space +to be a vector of shared_futures with each future representing a partition. In +this manner, each future represents several data points. Because the user can +define how many data points are in each partition, and, therefore, how +many data points are represented by one future, a user can control the +grainsize of the simulation. The rest of the code is then futurized in the same +manner as example 2. It should be noted how strikingly similar +example 4 is to example 2.

+

Example 4 finally shows good results. This code scales equivalently to the +OpenMP version. While these results are promising, there are more opportunities +to improve the application’s scalability. Currently, this code only runs on one +locality, but to get the full benefit of HPX, we need to be able to +distribute the work to other machines in a cluster. We begin to add this +functionality in example 5.

+

In order to run on a distributed system, a large amount of boilerplate code must +be added. Fortunately, HPX provides us with the concept of a component, +which saves us from having to write quite as much code. A component is an object +that can be remotely accessed using its global address. Components are made of +two parts: a server and a client class. While the client class is not required, +abstracting the server behind a client allows us to ensure type safety instead +of having to pass around pointers to global objects. Example 5 renames example +4’s struct partition to partition_data and adds serialization support. +Next, we add the server side representation of the data in the structure +partition_server. Partition_server inherits from +hpx::components::component_base, which contains a server-side component +boilerplate. The boilerplate code allows a component’s public members to be +accessible anywhere on the machine via its Global Identifier (GID). To +encapsulate the component, we create a client side helper class. This object +allows us to create new instances of our component and access its members +without having to know its GID. In addition, we are using the client class to +assist us with managing our asynchrony. For example, our client class +partition‘s member function get_data() returns a future to +partition_data get_data(). This struct inherits its boilerplate code from +hpx::components::client_base.

+

In the structure stepper, we have also had to make some changes to +accommodate a distributed environment. In order to get the data from a +particular neighboring partition, which could be remote, we must retrieve the data from all +of the neighboring partitions. These retrievals are asynchronous and the function +heat_part_data, which, amongst other things, calls heat, should not be +called unless the data from the neighboring partitions have arrived. Therefore, +it should come as no surprise that we synchronize this operation with another +instance of dataflow (found in heat_part). This dataflow receives futures +to the data in the current and surrounding partitions by calling get_data() +on each respective partition. When these futures are ready, dataflow passes them +to the unwrapping function, which extracts the shared_array of doubles and +passes them to the lambda. The lambda calls heat_part_data on the +locality, which the middle partition is on.

+

Although this example could run distributed, it only runs on one +locality, as it always uses hpx::find_here() as the target for the +functions to run on.

+

In example 6, we begin to distribute the partition data on different nodes. This +is accomplished in stepper::do_work() by passing the GID of the +locality where we wish to create the partition to the partition +constructor.

+
    for (std::size_t i = 0; i != np; ++i)
+        U[0][i] = partition(localities[locidx(i, np, nl)], nx, double(i));
+
+
+

We distribute the partitions evenly based on the number of localities used, +which is described in the function locidx. Because some of the data needed +to update the partition in heat_part could now be on a new locality, +we must devise a way of moving data to the locality of the middle +partition. We accomplished this by adding a switch in the function +get_data() that returns the end element of the buffer data_ if it is +from the left partition or the first element of the buffer if the data is from +the right partition. In this way only the necessary elements, not the whole +buffer, are exchanged between nodes. The reader should be reminded that this +exchange of end elements occurs in the function get_data() and, therefore, is +executed asynchronously.

+

Now that we have the code running in distributed, it is time to make some +optimizations. The function heat_part spends most of its time on two tasks: +retrieving remote data and working on the data in the middle partition. Because +we know that the data for the middle partition is local, we can overlap the work +on the middle partition with that of the possibly remote call of get_data(). +This algorithmic change, which was implemented in example 7, can be seen below:

+
    // The partitioned operator, it invokes the heat operator above on all elements
+    // of a partition.
+    static partition heat_part(
+        partition const& left, partition const& middle, partition const& right)
+    {
+        using hpx::dataflow;
+        using hpx::unwrapping;
+
+        hpx::shared_future<partition_data> middle_data =
+            middle.get_data(partition_server::middle_partition);
+
+        hpx::future<partition_data> next_middle = middle_data.then(
+            unwrapping([middle](partition_data const& m) -> partition_data {
+                HPX_UNUSED(middle);
+
+                // All local operations are performed once the middle data of
+                // the previous time step becomes available.
+                std::size_t size = m.size();
+                partition_data next(size);
+                for (std::size_t i = 1; i != size - 1; ++i)
+                    next[i] = heat(m[i - 1], m[i], m[i + 1]);
+                return next;
+            }));
+
+        return dataflow(hpx::launch::async,
+            unwrapping([left, middle, right](partition_data next,
+                           partition_data const& l, partition_data const& m,
+                           partition_data const& r) -> partition {
+                HPX_UNUSED(left);
+                HPX_UNUSED(right);
+
+                // Calculate the missing boundary elements once the
+                // corresponding data has become available.
+                std::size_t size = m.size();
+                next[0] = heat(l[size - 1], m[0], m[1]);
+                next[size - 1] = heat(m[size - 2], m[size - 1], r[0]);
+
+                // The new partition_data will be allocated on the same locality
+                // as 'middle'.
+                return partition(middle.get_id(), std::move(next));
+            }),
+            std::move(next_middle),
+            left.get_data(partition_server::left_partition), middle_data,
+            right.get_data(partition_server::right_partition));
+    }
+
+
+

Example 8 completes the futurization process and utilizes the full potential of +HPX by distributing the program flow to multiple localities, usually defined as +nodes in a cluster. It accomplishes this task by running an instance of HPX main +on each locality. In order to coordinate the execution of the program, +the struct stepper is wrapped into a component. In this way, each +locality contains an instance of stepper that executes its own instance +of the function do_work(). This scheme does create an interesting +synchronization problem that must be solved. When the program flow was being +coordinated on the head node, the GID of each component was known. However, when +we distribute the program flow, each partition has no notion of the GID of its +neighbor if the next partition is on another locality. In order to make +the GIDs of neighboring partitions visible to each other, we created two buffers +to store the GIDs of the remote neighboring partitions on the left and right +respectively. These buffers are filled by sending the GID of newly created +edge partitions to the right and left buffers of the neighboring localities.

+

In order to finish the simulation, the solution vectors named result are then +gathered together on locality 0 and added into a vector of spaces +overall_result using the HPX functions gather_id and gather_here.

+

Example 8 completes this example series, which takes the serial code of example 1 +and incrementally morphs it into a fully distributed parallel code. This +evolution was guided by the simple principles of futurization, the knowledge of +grainsize, and utilization of components. Applying these techniques easily +facilitates the scalable parallelization of most applications.

+
+
+

Serializing user-defined types#

+

In order to facilitate the sending and receiving of complex datatypes HPX provides a +serialization abstraction.

+

Just like boost, hpx allows users to serialize user-defined types by either +providing the serializer as a member function or defining the serialization as a +free function.

+

Unlike Boost HPX doesn’t acknowledge second unsigned int parameter, it is solely there to preserve +API compatibility with Boost Serialization

+

This is tutorial was heavily inspired by +Boost’s serialization concepts.

+
+
Setup#
+

The source code for this example can be found here: +custom_serialization.cpp.

+

To compile this program, go to your HPX build directory (see +Building HPX for information on configuring and building HPX) and +enter:

+
$ make examples.quickstart.custom_serialization
+
+
+

To run the program type:

+
$ ./bin/custom_serialization
+
+
+

This should print:

+
Rectangle(Point(x=0,y=0),Point(x=0,y=5))
+gravity.g = 9.81%
+
+
+
+
+
Serialization Requirements#
+

In order to serialize objects in HPX, at least one of the following criteria must be met:

+

In the case of default constructible objects:

+
    +
  • The object is an empty type.

  • +
  • Has a serialization function as shown in this tutorial.

  • +
  • All members are accessible publicly and they can be used in structured binding contexts.

  • +
+

Otherwise:

+
    +
  • They need to have special serialization support.

  • +
+
+
Member function serialization#
+
struct point_member_serialization
+{
+    int x{0};
+    int y{0};
+
+    // Required when defining the serialization function as private
+    // In this case it isn't
+    // Provides serialization access to HPX
+    friend class hpx::serialization::access;
+
+    // Second argument exists solely for compatibility with boost serialize
+    // it is NOT processed by HPX in any way.
+    template <typename Archive>
+    void serialize(Archive& ar, const unsigned int)
+    {
+        // clang-format off
+        ar & x & y;
+        // clang-format on
+    }
+};
+
+// Allow bitwise serialization
+HPX_IS_BITWISE_SERIALIZABLE(point_member_serialization)
+
+
+

Notice that point_member_serialization is defined as bitwise serializable +(see Bitwise serialization for bitwise copyable data for more details). +HPX is also able to recursively serialize composite classes and structs +given that its members are serializable.

+
struct rectangle_member_serialization
+{
+    point_member_serialization top_left;
+    point_member_serialization lower_right;
+
+    template <typename Archive>
+    void serialize(Archive& ar, const unsigned int)
+    {
+        // clang-format off
+        ar & top_left & lower_right;
+        // clang-format on
+    }
+};
+
+
+
+
+
Free function serialization#
+

In order to decouple your models from HPX, HPX also allows for the definition +of free function serializers.

+
struct rectangle_free
+{
+    point_member_serialization top_left;
+    point_member_serialization lower_right;
+};
+
+template <typename Archive>
+void serialize(Archive& ar, rectangle_free& pt, const unsigned int)
+{
+    // clang-format off
+    ar & pt.lower_right & pt.top_left;
+    // clang-format on
+}
+
+
+

Even if you can’t modify a class to befriend it, you can still be able to +serialize your class provided that your class is default constructable +and you are able to reconstruct it yourself.

+
class point_class
+{
+public:
+    point_class(int x, int y)
+      : x(x)
+      , y(y)
+    {
+    }
+
+    point_class() = default;
+
+    [[nodiscard]] int get_x() const noexcept
+    {
+        return x;
+    }
+
+    [[nodiscard]] int get_y() const noexcept
+    {
+        return y;
+    }
+
+private:
+    int x;
+    int y;
+};
+
+template <typename Archive>
+void load(Archive& ar, point_class& pt, const unsigned int)
+{
+    int x, y;
+    ar >> x >> y;
+    pt = point_class(x, y);
+}
+
+template <typename Archive>
+void save(Archive& ar, point_class const& pt, const unsigned int)
+{
+    ar << pt.get_x() << pt.get_y();
+}
+
+// This tells HPX that you have spilt your serialize function into
+// load and save
+HPX_SERIALIZATION_SPLIT_FREE(point_class)
+
+
+
+
+
Serializing non default constructable classes#
+

Some classes don’t provide any default constructor.

+
class planet_weight_calculator
+{
+public:
+    explicit planet_weight_calculator(double g)
+      : g(g)
+    {
+    }
+
+    template <class Archive>
+    friend void save_construct_data(
+        Archive&, planet_weight_calculator const*, unsigned int);
+
+    [[nodiscard]] double get_g() const
+    {
+        return g;
+    }
+
+private:
+    // Provides serialization access to HPX
+    friend class hpx::serialization::access;
+    template <class Archive>
+    void serialize(Archive&, const unsigned int)
+    {
+        // Serialization will be done in the save_construct_data
+        // Still needs to be defined
+    }
+
+    double g;
+};
+
+
+

In this case you have to define a save_construct_data and load_construct_data in which you +do the serialization yourself.

+
template <class Archive>
+inline void save_construct_data(Archive& ar,
+    planet_weight_calculator const* weight_calc, const unsigned int)
+{
+    ar << weight_calc->g;    // Do all of your serialization here
+}
+
+template <class Archive>
+inline void load_construct_data(
+    Archive& ar, planet_weight_calculator* weight_calc, const unsigned int)
+{
+    double g;
+    ar >> g;
+
+    // ::new(ptr) construct new object at given address
+    hpx::construct_at(weight_calc, g);
+}
+
+
+
+
+
Bitwise serialization for bitwise copyable data#
+

When sending non arithmetic types not defined by +std::is_arithmetic, HPX has to (de)serialize each object +separately. However, if the class you are trying to send classes consists only of bitwise copyable datatypes, +you may mark your class as such. +Then HPX will serialize your object bitwise instead of element wise. +This has enormous benefits, especially when sending a vector/array of your class. +To define your class as such you need to call HPX_IS_BITWISE_SERIALIZABLE(T) with your desired custom class.

+
struct point_member_serialization
+{
+    int x{0};
+    int y{0};
+
+    // Required when defining the serialization function as private
+    // In this case it isn't
+    // Provides serialization access to HPX
+    friend class hpx::serialization::access;
+
+    // Second argument exists solely for compatibility with boost serialize
+    // it is NOT processed by HPX in any way.
+    template <typename Archive>
+    void serialize(Archive& ar, const unsigned int)
+    {
+        // clang-format off
+        ar & x & y;
+        // clang-format on
+    }
+};
+
+// Allow bitwise serialization
+HPX_IS_BITWISE_SERIALIZABLE(point_member_serialization)
+
+
+
+
+
+
+
+
+

Manual#

+

The manual is your comprehensive guide to HPX. It contains detailed +information on how to build and use HPX in different scenarios.

+
+
+

Prerequisites#

+
+
Supported platforms#
+

At this time, HPX supports the following platforms. Other platforms may +work, but we do not test HPX with other platforms, so please be warned.

+ + +++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 1 Supported Platforms for HPX#

Name

Minimum Version

Architectures

Linux

2.6

x86-32, x86-64, k1om

BlueGeneQ

V1R2M0

PowerPC A2

Windows

Any Windows system

x86-32, x86-64

Mac OSX

Any OSX system

x86-64

ARM

Any ARM system

Any architecture

RISC-V

Any RISC-V system

Any architecture

+
+
+
Supported compilers#
+

The table below shows the supported compilers for HPX.

+ + ++++ + + + + + + + + + + + + + + + + +
Table 2 Supported Compilers for HPX#

Name

Minimum Version

GNU Compiler Collection (g++)

9.0

clang: a C language family frontend for LLVM

10.0

Visual C++ (x64)

2019

+
+
+
Software and libraries#
+

The table below presents all the necessary prerequisites for building HPX.

+ + +++++ + + + + + + + + + + + + + + + + + + + + +
Table 3 Software prerequisites for HPX#

Name

Minimum Version

Build System

CMake

3.18

Required Libraries

Boost

1.71.0

Portable Hardware Locality (HWLOC)

1.5

+

The most important dependencies are Boost and Portable Hardware Locality (HWLOC). The installation of Boost +is described in detail in Boost’s Getting Started +document. A recent version of hwloc is required in order to support thread +pinning and NUMA awareness and can be found in Hwloc Downloads.

+

HPX is written in 99.99% Standard C++ (the remaining 0.01% is platform +specific assembly code). As such, HPX is compilable with almost any standards +compliant C++ compiler. The code base takes advantage of C++ language and +standard library features when available.

+
+

Note

+

When building Boost using gcc, please note that it is required to specify a +cxxflags=-std=c++17 command line argument to b2 (bjam).

+
+
+

Note

+

In most configurations, HPX depends only on header-only Boost. +Boost.Filesystem is required if the standard library does not support +filesystem. The following are not needed by default, but are required in +certain configurations: Boost.Chrono, Boost.DateTime, Boost.Log, +Boost.LogSetup, Boost.Regex, and Boost.Thread.

+
+

Depending on the options you chose while building and installing HPX, +you will find that HPX may depend on several other libraries such as those +listed below.

+
+

Note

+

In order to use a high speed parcelport, we currently recommend configuring +HPX to use MPI so that MPI can be used for communication between different +localities. Please set the CMake variable MPI_CXX_COMPILER to your MPI +C++ compiler wrapper if not detected automatically.

+
+ + ++++ + + + + + + + + + + + + + + + + + +
Table 4 Optional software prerequisites for HPX#

Name

Minimum version

google-perftools

1.7.1

jemalloc

2.1.0

mi-malloc

1.0.0

Performance Application Programming Interface (PAPI)

+
+
+
+

Getting HPX#

+

Download a tarball of the latest release from HPX Downloads and +unpack it or clone the repository directly using git:

+
$ git clone https://github.com/STEllAR-GROUP/hpx.git
+
+
+

It is also recommended that you check out the latest stable tag:

+
$ cd hpx
+
+
+
$ git checkout v1.11.0
+
+
+

Building HPX#

+
+
Basic information#
+

The build system for HPX is based on CMake, a cross-platform +build-generator tool which is not responsible for building the project +but rather generates the files needed by your build tool (GNU make, Visual +Studio, etc.) for building HPX. If CMake is not already installed in your +system, you can download it and install it here: CMake Downloads.

+

Once CMake has been run, the build process can be started. The build process consists of the following parts:

+
    +
  • The HPX core libraries (target core): This forms the basic set of HPX +libraries.

  • +
  • HPX Examples (target examples): This target is enabled by default and +builds all HPX examples (disable by setting +HPX_WITH_EXAMPLES:BOOL=Off). HPX examples are part of the +all target and are included in the installation if enabled.

  • +
  • HPX Tests (target tests): This target builds the HPX test suite and is +enabled by default (disable by setting HPX_WITH_TESTS:BOOL +=Off). They are not built by the all target and have to be built +separately.

  • +
  • HPX Documentation (target docs): This target builds the documentation, +and is not enabled by default (enable by setting +HPX_WITH_DOCUMENTATION:BOOL=On. For more information see +Documentation.

  • +
+

The HPX build process is highly configurable through CMake, and various CMake variables +influence the build process. A list with the most important CMake variables can be found in +the section that follows, while the complete list of available CMake variables is in +CMake options. These variables can be used to refine the recipes that can be found at +Platform specific build recipes, a section that shows some basic steps on how to build HPX for a +specific platform.

+

In order to use HPX, only the core libraries are required. In order to use the optional +libraries, you need to specify them as link dependencies in your build (See +Creating HPX projects).

+
+
+
Most important CMake options#
+

While building HPX, you are provided with multiple CMake options which correspond +to different configurations. Below, there is a set of the most important and frequently +used CMake options.

+
+
+HPX_WITH_MALLOC#
+

Use a custom allocator. Using a custom allocator tuned for multithreaded applications is very +important for the performance of HPX applications. When debugging applications, it’s useful to set +this to system, as custom allocators can hide some memory-related bugs. Note that setting this to +something other than system requires an external dependency.

+
+ +
+
+HPX_WITH_CUDA#
+

Enable support for CUDA. Use CMAKE_CUDA_COMPILER to set the CUDA compiler. This is a standard +CMake variable, like CMAKE_CXX_COMPILER.

+
+ +
+
+HPX_WITH_PARCELPORT_MPI#
+

Enable the MPI parcelport. This enables the use of MPI for the networking operations in the HPX runtime. +The default value is OFF because it’s not available on all systems and/or requires another dependency. However, +it is the recommended parcelport.

+
+ +
+
+HPX_WITH_PARCELPORT_TCP#
+

Enable the TCP parcelport. Enables the use of TCP for networking in the runtime. The default value is ON. +However, it’s only recommended for debugging purposes, as it is slower than the MPI parcelport.

+
+ +
+
+HPX_WITH_PARCELPORT_LCI#
+

Enable the LCI parcelport. This enables the use of LCI for the networking operations in the HPX runtime. +The default value is OFF because it’s not available on all systems and/or requires another dependency. However, +this experimental parcelport may provide better performance than the MPI parcelport. Please refer to +Using the LCI parcelport for more information about the LCI parcelport.

+
+ +
+
+HPX_WITH_APEX#
+

Enable APEX integration. APEX can be used to profile HPX +applications. In particular, it provides information about individual tasks in the HPX runtime.

+
+ +
+
+HPX_WITH_GENERIC_CONTEXT_COROUTINES#
+

Enable Boost. Context for task context switching. It must be enabled for non-x86 architectures such as ARM and Power.

+
+ +
+
+HPX_WITH_MAX_CPU_COUNT#
+

Set the maximum CPU count supported by HPX. The default value is 64, and should be set to a number at least as +high as the number of cores on a system including virtual cores such as hyperthreads.

+
+ +
+
+HPX_WITH_CXX_STANDARD#
+

Set a specific C++ standard version e.g. HPX_WITH_CXX_STANDARD=20. The default and minimum value is 17.

+
+ +
+
+HPX_WITH_EXAMPLES#
+

Build examples.

+
+ +
+
+HPX_WITH_TESTS#
+

Build tests.

+
+ +

For a complete list of available CMake variables that influence the build of +HPX, see CMake options.

+
+
+
Build types#
+

CMake can be configured to generate project files suitable for builds that +have enabled debugging support or for an optimized build (without debugging +support). The CMake variable used to set the build type is +CMAKE_BUILD_TYPE (for more information see the CMake Documentation). +Available build types are:

+
    +
  • Debug: Full debug symbols are available as well as additional assertions to +help debugging. To enable the debug build type for the HPX API, the C++ Macro +HPX_DEBUG is defined.

  • +
  • RelWithDebInfo: Release build with debugging symbols. This is most useful +for profiling applications

  • +
  • Release: Release build. This disables assertions and enables default +compiler optimizations.

  • +
  • RelMinSize: Release build with optimizations for small binary sizes.

  • +
+
+

Important

+

We currently don’t guarantee ABI compatibility between Debug and Release +builds. Please make sure that applications built against HPX use the same +build type as you used to build HPX. For CMake builds, this means that +the CMAKE_BUILD_TYPE variables have to match and for projects not using +CMake, the HPX_DEBUG macro has to be set in debug mode.

+
+
+
+
Platform specific build recipes#
+
+
Unix variants#
+

Once you have the source code and the dependencies and assuming all your dependencies are in paths +known to CMake, the following gets you started:

+
    +
  1. First, set up a separate build directory to configure the project:

    +
    $ mkdir build && cd build
    +
    +
    +
  2. +
  3. To configure the project you have the following options:

    +
      +
    • To build the core HPX libraries and examples, and install them to your chosen location (recommended):

    • +
    +
    +
    $ cmake -DCMAKE_INSTALL_PREFIX=/install/path ..
    +
    +
    +
    +

    Tip

    +

    If you want to change CMake variables for your build, it is usually a good +idea to start with a clean build directory to avoid configuration problems. +It is especially important that you use a clean build directory when changing +between Release and Debug modes.

    +
    +
    +
      +
    • To install HPX to the default system folders, simply leave out the CMAKE_INSTALL_PREFIX option:

    • +
    +
    +
    $ cmake ..
    +
    +
    +
    +
      +
    • If your dependencies are in custom locations, you may need to tell CMake +where to find them by passing one or more options to CMake as shown below:

    • +
    +
    +
    $ cmake -DBoost_ROOT=/path/to/boost
    +      -DHwloc_ROOT=/path/to/hwloc
    +      -DTcmalloc_ROOT=/path/to/tcmalloc
    +      -DJemalloc_ROOT=/path/to/jemalloc
    +      [other CMake variable definitions]
    +      /path/to/source/tree
    +
    +
    +

    For instance:

    +
    $ cmake -DBoost_ROOT=~/packages/boost -DHwloc_ROOT=/packages/hwloc -DCMAKE_INSTALL_PREFIX=~/packages/hpx ~/downloads/hpx_1.5.1
    +
    +
    +
    +
      +
    • If you want to try HPX without using a custom allocator pass -DHPX_WITH_MALLOC=system to CMake:

    • +
    +
    +
    $ cmake -DCMAKE_INSTALL_PREFIX=/install/path -DHPX_WITH_MALLOC=system ..
    +
    +
    +
    +

    Note

    +

    Please pay special attention to the section about HPX_WITH_MALLOC:STRING as this is crucial for getting decent performance.

    +
    +
    +
    +

    Important

    +

    If you are building HPX for a system with more than 64 processing units, +you must change the CMake variable HPX_WITH_MAX_CPU_COUNT (to a value at least as big as the +number of (virtual) cores on your system). Note that the default value is 64.

    +
    +
    +

    Caution

    +

    Compiling and linking HPX needs a considerable amount of memory. It is +advisable that at least 2 GB of memory per parallel process is available.

    +
    +
  4. +
  5. Once the configuration is complete, to build the project you run:

  6. +
+
+
$ cmake --build . --target install
+
+
+
+
+
+
Windows#
+
+

Note

+

The following build recipes are mostly user-contributed and may be outdated. +We always welcome updated and new build recipes.

+
+

To build HPX under Windows 10 x64 with Visual Studio 2015:

+
    +
  • Download the CMake V3.18.1 installer (or latest version) from here

  • +
  • Download the hwloc V1.11.0 (or the latest version) from here +and unpack it.

  • +
  • Download the latest Boost libraries from here and unpack them.

  • +
  • Build the Boost DLLs and LIBs by using these commands from Command Line (or +PowerShell). Open CMD/PowerShell inside the Boost dir and type in:

    +
    .\bootstrap.bat
    +
    +
    +

    This batch file will set up everything needed to create a successful build. +Now execute:

    +
    .\b2.exe link=shared variant=release,debug architecture=x86 address-model=64 threading=multi --build-type=complete install
    +
    +
    +

    This command will start a (very long) build of all available Boost libraries. +Please, be patient.

    +
  • +
  • Open CMake-GUI.exe and set up your source directory (input field ‘Where is the +source code’) to the base directory of the source code you downloaded from +HPX’s GitHub pages. Here’s an example of CMake path settings, which point to +the Documents/GitHub/hpx folder:

    +
    +_images/cmake_settings1.png +
    +

    Fig. 3 Example CMake path settings.#

    +
    +
    +

    Inside ‘Where is the source-code’ enter the base directory of your HPX +source directory (do not enter the “src” sub-directory!). Inside ‘Where to +build the binaries’ you should put in the path where all the building processes +will happen. This is important because the building machinery will do an +“out-of-tree” build. CMake will not touch or change the original source files +in any way. Instead, it will generate Visual Studio Solution Files, which +will build HPX packages out of the HPX source tree.

    +
  • +
  • Set new configuration variables (in CMake, not in Windows environment): +Boost_ROOT, Hwloc_ROOT, Asio_ROOT, CMAKE_INSTALL_PREFIX. The meaning of +these variables is as follows:

    +
      +
    • Boost_ROOT the HPX root directory of the unpacked Boost headers/cpp files.

    • +
    • Hwloc_ROOT the HPX root directory of the unpacked Portable Hardware Locality +files.

    • +
    • Asio_ROOT the HPX root directory of the unpacked ASIO files. Alternatively use +HPX_WITH_FETCH_ASIO with value True.

    • +
    • CMAKE_INSTALL_PREFIX the HPX root directory where the future builds of HPX +should be installed.

      +
      +

      Note

      +

      HPX is a very large software collection, so it is not recommended to use the +default C:\Program Files\hpx. Many users may prefer to use simpler paths without +whitespace, like C:\bin\hpx or D:\bin\hpx etc.

      +
      +
    • +
    +

    To insert new env-vars click on “Add Entry” and then insert the name inside +“Name”, select PATH as Type and put the path-name in the “Path” text field. +Repeat this for the first three variables.

    +

    This is how variable insertion will look:

    +
    +_images/cmake_settings2.png +
    +

    Fig. 4 Example CMake adding entry.#

    +
    +
    +

    Alternatively, users could provide Boost_LIBRARYDIR instead of +Boost_ROOT; the difference is that Boost_LIBRARYDIR should point to +the subdirectory inside Boost root where all the compiled DLLs/LIBs are. For +example, Boost_LIBRARYDIR may point to the bin.v2 subdirectory under +the Boost rootdir. It is important to keep the meanings of these two variables +separated from each other: Boost_DIR points to the ROOT folder of the +Boost library. Boost_LIBRARYDIR points to the subdir inside the Boost root +folder where the compiled binaries are.

    +
  • +
  • Click the ‘Configure’ button of CMake-GUI. You will be immediately presented with a +small window where you can select the C++ compiler to be used within Visual +Studio. This has been tested using the latest v14 (a.k.a C++ 2015) but older +versions should be sufficient too. Make sure to select the 64Bit compiler.

  • +
  • After the generate process has finished successfully, click the ‘Generate’ +button. Now, CMake will put new VS Solution files into the BUILD folder you +selected at the beginning.

  • +
  • Open Visual Studio and load the HPX.sln from your build folder.

  • +
  • Go to CMakePredefinedTargets and build the INSTALL project:

    +
    +_images/vs_targets_install.png +
    +

    Fig. 5 Visual Studio INSTALL target.#

    +
    +
    +

    It will take some time to compile everything, and in the end you should see an +output similar to this one:

    +
    +_images/vs_build_output.png +
    +

    Fig. 6 Visual Studio build output.#

    +
    +
    +
  • +
+
+
+
+
+

CMake options#

+

In order to configure HPX, you can set a variety of options to allow CMake to +generate your specific makefiles/project files. A list of the most important +CMake options can be found in Most important CMake options, while this section +includes the comprehensive list.

+
+
Variables that influence how HPX is built#
+

The options are split into these categories:

+ +
+
+
Generic options#
+ +
+
+HPX_WITH_AUTOMATIC_SERIALIZATION_REGISTRATION:BOOL#
+

Use automatic serialization registration for actions and functions. This affects compatibility between HPX applications compiled with different compilers (default ON)

+
+ +
+
+HPX_WITH_BENCHMARK_SCRIPTS_PATH:PATH#
+

Directory to place batch scripts in

+
+ +
+
+HPX_WITH_BUILD_BINARY_PACKAGE:BOOL#
+

Build HPX on the build infrastructure on any LINUX distribution (default: OFF).

+
+ +
+
+HPX_WITH_CHECK_MODULE_DEPENDENCIES:BOOL#
+

Verify that no modules are cross-referenced from a different module category (default: OFF)

+
+ +
+
+HPX_WITH_COMPILER_WARNINGS:BOOL#
+

Enable compiler warnings (default: ON)

+
+ +
+
+HPX_WITH_COMPILER_WARNINGS_AS_ERRORS:BOOL#
+

Turn compiler warnings into errors (default: OFF)

+
+ +
+
+HPX_WITH_COMPRESSION_BZIP2:BOOL#
+

Enable bzip2 compression for parcel data (default: OFF).

+
+ +
+
+HPX_WITH_COMPRESSION_SNAPPY:BOOL#
+

Enable snappy compression for parcel data (default: OFF).

+
+ +
+
+HPX_WITH_COMPRESSION_ZLIB:BOOL#
+

Enable zlib compression for parcel data (default: OFF).

+
+ +
+
+HPX_WITH_CUDA:BOOL#
+

Enable support for CUDA (default: OFF)

+
+ +
+
+HPX_WITH_CXX_STANDARD:STRING#
+

Set the C++ standard to use when compiling HPX itself. (default: 17)

+
+ +
+
+HPX_WITH_DATAPAR:BOOL#
+

Enable data parallel algorithm support using Vc library (default: ON)

+
+ +
+
+HPX_WITH_DATAPAR_BACKEND:STRING#
+

Define which vectorization library should be used. Options are: VC, EVE, STD_EXPERIMENTAL_SIMD, SVE; NONE

+
+ +
+
+HPX_WITH_DATAPAR_VC_NO_LIBRARY:BOOL#
+

Don’t link with the Vc static library (default: OFF)

+
+ +
+
+HPX_WITH_DEPRECATION_WARNINGS:BOOL#
+

Enable warnings for deprecated facilities (default: ON).

+
+ +
+
+HPX_WITH_DISABLED_SIGNAL_EXCEPTION_HANDLERS:BOOL#
+

Disables the mechanism that produces debug output for caught signals and unhandled exceptions (default: OFF)

+
+ +
+
+HPX_WITH_DYNAMIC_HPX_MAIN:BOOL#
+

Enable dynamic overload of system main() (Linux and Apple only, default: ON)

+
+ +
+
+HPX_WITH_FAULT_TOLERANCE:BOOL#
+

Build HPX to tolerate failures of nodes, i.e. ignore errors in active communication channels (default: OFF)

+
+ +
+
+HPX_WITH_FULL_RPATH:BOOL#
+

Build and link HPX libraries and executables with full RPATHs (default: ON)

+
+ +
+
+HPX_WITH_GCC_VERSION_CHECK:BOOL#
+

Don’t ignore version reported by gcc (default: ON)

+
+ +
+
+HPX_WITH_GENERIC_CONTEXT_COROUTINES:BOOL#
+

Use Boost.Context as the underlying coroutines context switch implementation.

+
+ +
+
+HPX_WITH_HIDDEN_VISIBILITY:BOOL#
+

Use -fvisibility=hidden for builds on platforms which support it (default OFF)

+
+ +
+
+HPX_WITH_HIP:BOOL#
+

Enable compilation with HIPCC (default: OFF)

+
+ +
+
+HPX_WITH_HIPSYCL:BOOL#
+

Use hipsycl cmake integration (default: OFF)

+
+ +
+
+HPX_WITH_IGNORE_COMPILER_COMPATIBILITY:BOOL#
+

Ignore compiler incompatibility in dependent projects (default: ON).

+
+ +
+
+HPX_WITH_LOGGING:BOOL#
+

Build HPX with logging enabled (default: ON).

+
+ +
+
+HPX_WITH_MALLOC:STRING#
+

Define which allocator should be linked in. Options are: system, tcmalloc, jemalloc, mimalloc, tbbmalloc, and custom (default is: tcmalloc)

+
+ +
+
+HPX_WITH_MODULES_AS_STATIC_LIBRARIES:BOOL#
+

Compile HPX modules as STATIC (whole-archive) libraries instead of OBJECT libraries (Default: ON)

+
+ +
+
+HPX_WITH_NICE_THREADLEVEL:BOOL#
+

Set HPX worker threads to have high NICE level (may impact performance) (default: OFF)

+
+ +
+
+HPX_WITH_PARCEL_COALESCING:BOOL#
+

Enable the parcel coalescing plugin (default: ON).

+
+ +
+
+HPX_WITH_PKGCONFIG:BOOL#
+

Enable generation of pkgconfig files (default: ON on Linux without CUDA/HIP, otherwise OFF)

+
+ +
+
+HPX_WITH_PRECOMPILED_HEADERS:BOOL#
+

Enable precompiled headers for certain build targets (experimental) (default OFF)

+
+ +
+
+HPX_WITH_RUN_MAIN_EVERYWHERE:BOOL#
+

Run hpx_main by default on all localities (default: OFF).

+
+ +
+
+HPX_WITH_STACKOVERFLOW_DETECTION:BOOL#
+

Enable stackoverflow detection for HPX threads/coroutines (default: OFF, debug: ON).

+
+ +
+
+HPX_WITH_STATIC_LINKING:BOOL#
+

Compile HPX statically linked libraries (Default: OFF)

+
+ +
+
+HPX_WITH_SUPPORT_NO_UNIQUE_ADDRESS_ATTRIBUTE:BOOL#
+

Enable the use of the [[no_unique_address]] attribute (default: ON)

+
+ +
+
+HPX_WITH_SYCL:BOOL#
+

Enable support for Sycl (default: OFF)

+
+ +
+
+HPX_WITH_SYCL_FLAGS:STRING#
+

Sycl compile flags for selecting specific targets (default: empty)

+
+ +
+
+HPX_WITH_UNITY_BUILD:BOOL#
+

Enable unity build for certain build targets (default OFF)

+
+ +
+
+HPX_WITH_VIM_YCM:BOOL#
+

Generate HPX completion file for VIM YouCompleteMe plugin

+
+ +
+
+HPX_WITH_ZERO_COPY_SERIALIZATION_THRESHOLD:STRING#
+

The threshold in bytes to when perform zero copy optimizations (default: 8192)

+
+ +
+
+
Build Targets options#
+ +
+
+HPX_WITH_ASIO_TAG:STRING#
+

Asio repository tag or branch

+
+ +
+
+HPX_WITH_COMPILE_ONLY_TESTS:BOOL#
+

Create build system support for compile time only HPX tests (default ON)

+
+ +
+
+HPX_WITH_DISTRIBUTED_RUNTIME:BOOL#
+

Enable the distributed runtime (default: ON). Turning off the distributed runtime completely disallows the creation and use of components and actions. Turning this option off is experimental!

+
+ +
+
+HPX_WITH_DOCUMENTATION:BOOL#
+

Build the HPX documentation (default OFF).

+
+ +
+
+HPX_WITH_DOCUMENTATION_OUTPUT_FORMATS:STRING#
+

List of documentation output formats to generate. Valid options are html;singlehtml;latexpdf;man. Multiple values can be separated with semicolons. (default html).

+
+ +
+
+HPX_WITH_EXAMPLES:BOOL#
+

Build the HPX examples (default ON)

+
+ +
+
+HPX_WITH_EXAMPLES_HDF5:BOOL#
+

Enable examples requiring HDF5 support (default: OFF).

+
+ +
+
+HPX_WITH_EXAMPLES_OPENMP:BOOL#
+

Enable examples requiring OpenMP support (default: OFF).

+
+ +
+
+HPX_WITH_EXAMPLES_QT4:BOOL#
+

Enable examples requiring Qt4 support (default: OFF).

+
+ +
+
+HPX_WITH_EXAMPLES_QTHREADS:BOOL#
+

Enable examples requiring QThreads support (default: OFF).

+
+ +
+
+HPX_WITH_EXAMPLES_TBB:BOOL#
+

Enable examples requiring TBB support (default: OFF).

+
+ +
+
+HPX_WITH_EXECUTABLE_PREFIX:STRING#
+

Executable prefix (default none), ‘hpx_’ useful for system install.

+
+ +
+
+HPX_WITH_FAIL_COMPILE_TESTS:BOOL#
+

Create build system support for fail compile HPX tests (default ON)

+
+ +
+
+HPX_WITH_FETCH_APEX:BOOL#
+

Use FetchContent to fetch APEX. By default an installed APEX will be used. (default: OFF)

+
+ +
+
+HPX_WITH_FETCH_ASIO:BOOL#
+

Use FetchContent to fetch Asio. By default an installed Asio will be used. (default: OFF)

+
+ +
+
+HPX_WITH_FETCH_BOOST:BOOL#
+

Use FetchContent to fetch Boost. By default an installed Boost will be used. (default: OFF)

+
+ +
+
+HPX_WITH_FETCH_GASNET:BOOL#
+

Use FetchContent to fetch GASNET. By default an installed GASNET will be used. (default: OFF).

+
+ +
+
+HPX_WITH_FETCH_HWLOC:BOOL#
+

Use FetchContent to fetch Hwloc. By default an installed Hwloc will be used. (default: OFF)

+
+ +
+
+HPX_WITH_FETCH_LCI:BOOL#
+

Use FetchContent to fetch LCI. By default an installed LCI will be used. (default: OFF)

+
+ +
+
+HPX_WITH_IO_COUNTERS:BOOL#
+

Enable IO counters (default: ON)

+
+ +
+
+HPX_WITH_LCI_TAG:STRING#
+

LCI repository tag or branch

+
+ +
+
+HPX_WITH_NANOBENCH:BOOL#
+

Use Nanobench for performance tests. Nanobench will be fetched using FetchContent (default: OFF)

+
+ +
+ +

Number of Parallel link jobs while building hpx (only for Ninja as generator) (default 2)

+
+ +
+
+HPX_WITH_TESTS:BOOL#
+

Build the HPX tests (default ON)

+
+ +
+
+HPX_WITH_TESTS_BENCHMARKS:BOOL#
+

Build HPX benchmark tests (default: ON)

+
+ +
+
+HPX_WITH_TESTS_EXAMPLES:BOOL#
+

Add HPX examples as tests (default: ON)

+
+ +
+
+HPX_WITH_TESTS_EXTERNAL_BUILD:BOOL#
+

Build external cmake build tests (default: ON)

+
+ +
+
+HPX_WITH_TESTS_HEADERS:BOOL#
+

Build HPX header tests (default: OFF)

+
+ +
+
+HPX_WITH_TESTS_REGRESSIONS:BOOL#
+

Build HPX regression tests (default: ON)

+
+ +
+
+HPX_WITH_TESTS_UNIT:BOOL#
+

Build HPX unit tests (default: ON)

+
+ +
+
+HPX_WITH_TOOLS:BOOL#
+

Build HPX tools (default: OFF)

+
+ +
+
+
Thread Manager options#
+ +
+
+HPX_COROUTINES_WITH_SWAP_CONTEXT_EMULATION:BOOL#
+

Emulate SwapContext API for coroutines (Windows only, default: OFF)

+
+ +
+
+HPX_COROUTINES_WITH_THREAD_SCHEDULE_HINT_RUNS_AS_CHILD:BOOL#
+

Futures attempt to run associated threads directly if those have not been started (default: OFF)

+
+ +
+
+HPX_WITH_COROUTINE_COUNTERS:BOOL#
+

Enable keeping track of coroutine creation and rebind counts (default: OFF)

+
+ +
+
+HPX_WITH_IO_POOL:BOOL#
+

Disable internal IO thread pool, do not change if not absolutely necessary (default: ON)

+
+ +
+
+HPX_WITH_MAX_CPU_COUNT:STRING#
+

HPX applications will not use more that this number of OS-Threads (empty string means dynamic) (default: “”)

+
+ +
+
+HPX_WITH_MAX_NUMA_DOMAIN_COUNT:STRING#
+

HPX applications will not run on machines with more NUMA domains (default: 8)

+
+ +
+
+HPX_WITH_SCHEDULER_LOCAL_STORAGE:BOOL#
+

Enable scheduler local storage for all HPX schedulers (default: OFF)

+
+ +
+
+HPX_WITH_SPINLOCK_DEADLOCK_DETECTION:BOOL#
+

Enable spinlock deadlock detection (default: OFF)

+
+ +
+
+HPX_WITH_SPINLOCK_POOL_NUM:STRING#
+

Number of elements a spinlock pool manages (default: 128)

+
+ +
+
+HPX_WITH_STACKTRACES:BOOL#
+

Attach backtraces to HPX exceptions (default: ON)

+
+ +
+
+HPX_WITH_STACKTRACES_DEMANGLE_SYMBOLS:BOOL#
+

Thread stack back trace symbols will be demangled (default: ON)

+
+ +
+
+HPX_WITH_STACKTRACES_STATIC_SYMBOLS:BOOL#
+

Thread stack back trace will resolve static symbols (default: OFF)

+
+ +
+
+HPX_WITH_THREAD_BACKTRACE_DEPTH:STRING#
+

Thread stack back trace depth being captured (default: 20)

+
+ +
+
+HPX_WITH_THREAD_BACKTRACE_ON_SUSPENSION:BOOL#
+

Enable thread stack back trace being captured on suspension (default: OFF)

+
+ +
+
+HPX_WITH_THREAD_CREATION_AND_CLEANUP_RATES:BOOL#
+

Enable measuring thread creation and cleanup times (default: OFF)

+
+ +
+
+HPX_WITH_THREAD_CUMULATIVE_COUNTS:BOOL#
+

Enable keeping track of cumulative thread counts in the schedulers (default: ON)

+
+ +
+
+HPX_WITH_THREAD_IDLE_RATES:BOOL#
+

Enable measuring the percentage of overhead times spent in the scheduler (default: OFF)

+
+ +
+
+HPX_WITH_THREAD_LOCAL_STORAGE:BOOL#
+

Enable thread local storage for all HPX threads (default: OFF)

+
+ +
+
+HPX_WITH_THREAD_MANAGER_IDLE_BACKOFF:BOOL#
+

HPX scheduler threads do exponential backoff on idle queues (default: ON)

+
+ +
+
+HPX_WITH_THREAD_QUEUE_WAITTIME:BOOL#
+

Enable collecting queue wait times for threads (default: OFF)

+
+ +
+
+HPX_WITH_THREAD_STACK_MMAP:BOOL#
+

Use mmap for stack allocation on appropriate platforms

+
+ +
+
+HPX_WITH_THREAD_STEALING_COUNTS:BOOL#
+

Enable keeping track of counts of thread stealing incidents in the schedulers (default: OFF)

+
+ +
+
+HPX_WITH_THREAD_TARGET_ADDRESS:BOOL#
+

Enable storing target address in thread for NUMA awareness (default: OFF)

+
+ +
+
+HPX_WITH_TIMER_POOL:BOOL#
+

Disable internal timer thread pool, do not change if not absolutely necessary (default: ON)

+
+ +
+
+HPX_WITH_WORK_REQUESTING_SCHEDULERS:BOOL#
+

Enable work requesting scheduler (default: ON)

+
+ +
+
+
AGAS options#
+ +
+
+HPX_WITH_AGAS_DUMP_REFCNT_ENTRIES:BOOL#
+

Enable dumps of the AGAS refcnt tables to logs (default: OFF)

+
+ +
+
+
Parcelport options#
+ +
+
+HPX_WITH_NETWORKING:BOOL#
+

Enable support for networking and multi-node runs (default: ON)

+
+ +
+
+HPX_WITH_PARCELPORT_ACTION_COUNTERS:BOOL#
+

Enable performance counters reporting parcelport statistics on a per-action basis.

+
+ +
+
+HPX_WITH_PARCELPORT_COUNTERS:BOOL#
+

Enable performance counters reporting parcelport statistics.

+
+ +
+
+HPX_WITH_PARCELPORT_GASNET:BOOL#
+

Enable the GASNET based parcelport.

+
+ +
+
+HPX_WITH_PARCELPORT_LCI:BOOL#
+

Enable the LCI based parcelport.

+
+ +
+
+HPX_WITH_PARCELPORT_LCI_LOG:STRING#
+

Enable the LCI-parcelport-specific logger

+
+ +
+
+HPX_WITH_PARCELPORT_LCI_PCOUNTER:STRING#
+

Enable the LCI-parcelport-specific performance counter

+
+ +
+
+HPX_WITH_PARCELPORT_LIBFABRIC:BOOL#
+

Enable the libfabric based parcelport. This is currently an experimental feature

+
+ +
+
+HPX_WITH_PARCELPORT_MPI:BOOL#
+

Enable the MPI based parcelport.

+
+ +
+
+HPX_WITH_PARCELPORT_TCP:BOOL#
+

Enable the TCP based parcelport.

+
+ +
+
+HPX_WITH_PARCEL_PROFILING:BOOL#
+

Enable profiling data for parcels

+
+ +
+
+
Profiling options#
+ +
+
+HPX_WITH_APEX:BOOL#
+

Enable APEX instrumentation support.

+
+ +
+
+HPX_WITH_ITTNOTIFY:BOOL#
+

Enable Amplifier (ITT) instrumentation support.

+
+ +
+
+HPX_WITH_PAPI:BOOL#
+

Enable the PAPI based performance counter.

+
+ +
+
+
Debugging options#
+ +
+
+HPX_WITH_ATTACH_DEBUGGER_ON_TEST_FAILURE:BOOL#
+

Break the debugger if a test has failed (default: OFF)

+
+ +
+
+HPX_WITH_PARALLEL_TESTS_BIND_NONE:BOOL#
+

Pass –hpx:bind=none to tests that may run in parallel (cmake -j flag) (default: OFF)

+
+ +
+
+HPX_WITH_SANITIZERS:BOOL#
+

Configure with sanitizer instrumentation support.

+
+ +
+
+HPX_WITH_TESTS_COMMAND_LINE:STRING#
+

Add given command line options to all tests run

+
+ +
+
+HPX_WITH_TESTS_DEBUG_LOG:BOOL#
+

Turn on debug logs (–hpx:debug-hpx-log) for tests (default: OFF)

+
+ +
+
+HPX_WITH_TESTS_DEBUG_LOG_DESTINATION:STRING#
+

Destination for test debug logs (default: cout)

+
+ +
+
+HPX_WITH_TESTS_MAX_THREADS_PER_LOCALITY:STRING#
+

Maximum number of threads to use for tests (default: 0, use the number of threads specified by the test)

+
+ +
+
+HPX_WITH_THREAD_DEBUG_INFO:BOOL#
+

Enable thread debugging information (default: OFF, implicitly enabled in debug builds)

+
+ +
+
+HPX_WITH_THREAD_DESCRIPTION_FULL:BOOL#
+

Use function address for thread description (default: OFF)

+
+ +
+
+HPX_WITH_THREAD_GUARD_PAGE:BOOL#
+

Enable thread guard page (default: ON)

+
+ +
+
+HPX_WITH_VALGRIND:BOOL#
+

Enable Valgrind instrumentation support.

+
+ +
+
+HPX_WITH_VERIFY_LOCKS:BOOL#
+

Enable lock verification code (default: OFF, enabled in debug builds)

+
+ +
+
+HPX_WITH_VERIFY_LOCKS_BACKTRACE:BOOL#
+

Enable thread stack back trace being captured on lock registration (to be used in combination with HPX_WITH_VERIFY_LOCKS=ON, default: OFF)

+
+ +
+
+
Modules options#
+ +
+
+HPX_ALLOCATOR_SUPPORT_WITH_CACHING:BOOL#
+

Enable caching allocator. (default: ON)

+
+ +
+
+HPX_COMMAND_LINE_HANDLING_LOCAL_WITH_JSON_CONFIGURATION_FILES:BOOL#
+
+

Enable reading JSON formatted configuration files on the command line.

+
+

(default: On)

+
+ +
+
+HPX_DATASTRUCTURES_WITH_ADAPT_STD_TUPLE:BOOL#
+

Enable compatibility of hpx::get with std::tuple. (default: ON)

+
+ +
+
+HPX_DATASTRUCTURES_WITH_ADAPT_STD_VARIANT:BOOL#
+
+

Enable compatibility of hpx::get with std::variant.

+
+

(default: OFF)

+
+ +
+
+HPX_FILESYSTEM_WITH_BOOST_FILESYSTEM_COMPATIBILITY:BOOL#
+

Enable Boost.FileSystem compatibility. (default: OFF)

+
+ +
+
+HPX_ITERATOR_SUPPORT_WITH_BOOST_ITERATOR_TRAVERSAL_TAG_COMPATIBILITY:BOOL#
+

Enable Boost.Iterator traversal tag compatibility. (default: OFF)

+
+ +
+
+HPX_LOGGING_WITH_SEPARATE_DESTINATIONS:BOOL#
+

Enable separate logging channels for AGAS, timing, and parcel transport. (default: ON)

+
+ +
+
+HPX_SERIALIZATION_WITH_ALLOW_CONST_TUPLE_MEMBERS:BOOL#
+

Enable serializing std::tuple with const members. (default: OFF)

+
+ +
+
+HPX_SERIALIZATION_WITH_ALLOW_RAW_POINTER_SERIALIZATION:BOOL#
+

Enable serializing raw pointers. (default: OFF)

+
+ +
+
+HPX_SERIALIZATION_WITH_ALL_TYPES_ARE_BITWISE_SERIALIZABLE:BOOL#
+

Assume all types are bitwise serializable. (default: OFF)

+
+ +
+
+HPX_SERIALIZATION_WITH_BOOST_TYPES:BOOL#
+

Enable serialization of certain Boost types. (default: OFF)

+
+ +
+
+HPX_SERIALIZATION_WITH_SUPPORTS_ENDIANESS:BOOL#
+

Support endian conversion on inout and output archives. (default: OFF)

+
+ +
+
+HPX_TOPOLOGY_WITH_ADDITIONAL_HWLOC_TESTING:BOOL#
+
+

Enable HWLOC filtering that makes it report no cores, this is purely an

+
+

option supporting better testing - do not enable under normal circumstances. +(default: OFF)

+
+ +
+
+HPX_WITH_POWER_COUNTER:BOOL#
+

Enable use of performance counters based on pwr library (default: OFF)

+
+ +
+
+
Additional tools and libraries used by HPX#
+

Here is a list of additional libraries and tools that are either optionally +supported by the build system or are optionally required for certain examples or +tests. These libraries and tools can be detected by the HPX build system.

+

Each of the tools or libraries listed here will be automatically detected if +they are installed in some standard location. If a tool or library is installed +in a different location, you can specify its base directory by appending +_ROOT to the variable name as listed below. For instance, to configure a +custom directory for Boost, specify Boost_ROOT=/custom/boost/root.

+
+
+Boost_ROOT:PATH#
+

Specifies where to look for the Boost installation to be used for +compiling HPX. Set this if CMake is not able to locate a suitable version of +Boost. The directory specified here can be either the root of an installed +Boost distribution or the directory where you unpacked and built Boost +without installing it (with staged libraries).

+
+ +
+
+Hwloc_ROOT:PATH#
+

Specifies where to look for the hwloc library. Set this if CMake is not +able to locate a suitable version of hwloc. Hwloc provides platform- +independent support for extracting information about the used hardware +architecture (number of cores, number of NUMA domains, hyperthreading, etc.). +HPX utilizes this information if available.

+
+ +
+
+Papi_ROOT:PATH#
+

Specifies where to look for the PAPI library. The PAPI library is +needed to compile a special component exposing PAPI hardware events and +counters as HPX performance counters. This is not available on the Windows +platform.

+
+ +
+
+Amplifier_ROOT:PATH#
+

Specifies where to look for one of the tools of the Intel Parallel Studio +product, either Intel Amplifier or Intel Inspector. This should be +set if the CMake variable HPX_USE_ITT_NOTIFY is set to ON. Enabling +ITT support in HPX will integrate any application with the mentioned Intel +tools, which customizes the generated information for your application and +improves the generated diagnostics.

+
+ +

In addition, some of the examples may need the following variables:

+
+
+Hdf5_ROOT:PATH#
+

Specifies where to look for the Hierarchical Data Format V5 (HDF5) include files and libraries.

+
+ +
+
+
+

Migration guide#

+

The Migration Guide serves as a valuable resource for developers seeking to transition their +parallel computing applications from different APIs (i.e. OpenMP, Intel Threading Building Blocks (TBB), MPI) to HPX. HPX, an +advanced C++ library, offers a versatile and high-performance platform for parallel and distributed +computing, providing a wide range of features and capabilities. This guide aims to assist developers +in understanding the key differences between different APIs and HPX, and it provides step-by-step +instructions for converting code to HPX code effectively.

+

Some general steps that can be used to migrate code to HPX code are the following:

+
    +
  1. Install HPX using the Quick start guide.

  2. +
  3. Include the HPX header files:

    +

    Add the necessary header files for HPX at the beginning of your code, such as:

    +
    +
    #include <hpx/init.hpp>
    +
    +
    +
    +
  4. +
  5. Replace your code with HPX code using the guide that follows.

  6. +
  7. Use HPX-specific features and APIs:

    +

    HPX provides additional features and APIs that can be used to take advantage of the library’s +capabilities. For example, you can use the HPX asynchronous execution to express fine-grained +tasks and dependencies, or utilize HPX’s distributed computing features for distributed memory systems.

    +
  8. +
  9. Compile and run the HPX code:

    +

    Compile the converted code with the HPX library and run it using the appropriate HPX runtime environment.

    +
  10. +
+
+
OpenMP#
+

The OpenMP API supports multi-platform shared-memory parallel programming in C/C++. Typically it is used for +loop-level parallelism, but it also supports function-level parallelism. Below are some examples on how to +convert OpenMP to HPX code:

+
+
OpenMP parallel for loop#
+
+Parallel for loop# +

OpenMP code:

+
#pragma omp parallel for
+for (int i = 0; i < n; ++i) {
+    // loop body
+}
+
+
+

HPX equivalent:

+
#include <hpx/algorithm.hpp>
+
+hpx::experimental::for_loop(hpx::execution::par, 0, n, [&](int i) {
+    // loop body
+});
+
+
+

In the above code, the OpenMP #pragma omp parallel for directive is replaced with +hpx::experimental::for_loop from the HPX library. The loop body within the lambda +function will be executed in parallel for each iteration.

+
+
+Private variables# +

OpenMP code:

+
int x = 0;
+
+#pragma omp parallel for private(x)
+for (int i = 0; i < n; ++i) {
+    // loop body
+}
+
+
+

HPX equivalent:

+
#include <hpx/algorithm.hpp>
+
+hpx::experimental::for_loop(hpx::execution::par, 0, n, [&](int i) {
+        int x = 0; // Declare 'x' as a local variable inside the loop body
+        // loop body
+});
+
+
+

The variable x is declared as a local variable inside the loop body, ensuring that +it is private to each thread.

+
+
+Shared variables# +

OpenMP code:

+
int x = 0;
+
+#pragma omp parallel for shared(x)
+for (int i = 0; i < n; ++i) {
+    // loop body
+}
+
+
+

HPX equivalent:

+
#include <hpx/algorithm.hpp>
+
+std::atomic<int> x = 0; // Declare 'x' as a shared variable outside the loop
+
+hpx::experimental::for_loop(hpx::execution::par, 0, n, [&](int i) {
+    // loop body
+});
+
+
+

To ensure variable x is shared among all threads, you simply have to declare it as an +atomic variable outside the for_loop.

+
+
+Number of threads# +

OpenMP code:

+
#pragma omp parallel for num_threads(2)
+for (int i = 0; i < n; ++i) {
+    // loop body
+}
+
+
+

HPX equivalent:

+
#include <hpx/algorithm.hpp>
+#include <hpx/execution.hpp>
+
+hpx::execution::experimental::num_cores nc(2);
+
+hpx::experimental::for_loop(hpx::execution::par.with(nc), 0, n, [&](int i) {
+    // loop body
+});
+
+
+

To declare the number of threads to be used for the parallel region, you can use +hpx::execution::experimental::num_cores and pass the number of cores (nc) to +hpx::experimental::for_loop using hpx::execution::par.with(nc). +This example uses 2 threads for the parallel loop.

+
+
+Reduction# +

OpenMP code:

+
int s = 0;
+
+#pragma omp parallel for reduction(+: s)
+for (int i = 0; i < n; ++i) {
+    s += i;
+    // loop body
+}
+
+
+

HPX equivalent:

+
#include <hpx/algorithm.hpp>
+#include <hpx/execution.hpp>
+
+int s = 0;
+
+hpx::experimental::for_loop(hpx::execution::par, 0, n, reduction(s, 0, plus<>()), [&](int i, int& accum) {
+    accum += i;
+    // loop body
+});
+
+
+

The reduction clause specifies that the variable s` should be reduced across iterations using the plus<>` operation. +It initializes s to 0 at the beginning of the loop and accumulates the values of s from each iteration using the ++ operator. The lambda function representing the loop body takes two parameters: i, which represents the loop index, +and accum, which is the reduction variable s. The lambda function is executed for each iteration of the loop. +The reduction ensures that the accum value is correctly accumulated across different iterations and threads.

+
+
+Schedule# +

OpenMP code:

+
int s = 0;
+
+// static scheduling with chunk size 1000
+#pragma omp parallel for schedule(static, 1000)
+for (int i = 0; i < n; ++i) {
+    // loop body
+}
+
+
+

HPX equivalent:

+
#include <hpx/algorithm.hpp>
+#include <hpx/execution.hpp>
+
+hpx::execution::experimental::static_chunk_size cs(1000);
+
+hpx::experimental::for_loop(hpx::execution::par.with(cs), 0, n, [&](int i) {
+    // loop body
+});
+
+
+

To define the scheduling type, you can use the corresponding execution policy from +hpx::execution::experimental, define the chunk size (cs, here declared as 1000) and pass +it to the to hpx::experimental::for_loop using hpx::execution::par.with(cs).

+

Accordingly, other types of scheduling are available and can be used in a similar manner:

+
#include <hpx/execution.hpp>
+hpx::execution::experimental::dynamic_chunk_size cs(1000);
+
+
+
#include <hpx/execution.hpp>
+hpx::execution::experimental::guided_chunk_size cs(1000);
+
+
+
#include <hpx/execution.hpp>
+hpx::execution::experimental::auto_chunk_size cs(1000);
+
+
+
+
+
+
OpenMP single thread#
+

OpenMP code:

+
{   // parallel code
+    #pragma omp single
+    {
+        // single-threaded code
+    }
+    // more parallel code
+}
+
+
+

HPX equivalent:

+
#include <hpx/mutex.hpp>
+
+hpx::mutex mtx;
+
+{   // parallel code
+    {   // single-threaded code
+        std::scoped_lock l(mtx);
+    }
+    // more parallel code
+}
+
+
+

To make sure that only one thread accesses a specific code within a parallel section +you can use hpx::mutex and std::scoped_lock to take ownership of the given +mutex mtx. For more information about mutexes please refer to Mutex.

+
+
+
OpenMP tasks#
+
+Simple tasks# +

OpenMP code:

+
// executed asynchronously by any available thread
+#pragma omp task
+{
+    // task code
+}
+
+
+

HPX equivalent:

+
#include <hpx/future.hpp>
+
+auto future = hpx::async([](){
+    // task code
+});
+
+
+

or

+
#include <hpx/future.hpp>
+
+hpx::post([](){
+    // task code
+}); // fire and forget
+
+
+

The tasks in HPX can be defined simply by using the async function and passing as argument +the code you wish to run asynchronously. Another alternative is to use post which is a +fire-and-forget method.

+
+

Tip

+

If you think you will like to synchronize your tasks later on, we suggest you use +hpx::async which provides synchronization options, while hpx::post +explicitly states that there is no return value or way to synchronize with the function +execution. Synchronization options are listed below.

+
+
+
+Task wait# +

OpenMP code:

+
#pragma omp task
+{
+    // task code
+}
+
+#pragma omp taskwait
+// code after completion of task
+
+
+

HPX equivalent:

+
#include <hpx/future.hpp>
+
+hpx::async([](){
+    // task code
+}).get(); // wait for the task to complete
+
+// code after completion of task
+
+
+

The get() function can be used to ensure that the task created with hpx::async +is completed before the code continues executing beyond that point.

+
+
+Multiple tasks synchronization# +

OpenMP code:

+
#pragma omp task
+{
+    // task 1 code
+}
+
+#pragma omp task
+{
+    // task 2 code
+}
+
+#pragma omp taskwait
+// code after completion of both tasks 1 and 2
+
+
+

HPX equivalent:

+
#include <hpx/future.hpp>
+
+auto future1 = hpx::async([](){
+    // task 1 code
+});
+
+auto future2 = hpx::async([](){
+    // task 2 code
+});
+
+auto future = hpx::when_all(future1, future2).then([](auto&&){
+    // code after completion of both tasks 1 and 2
+});
+
+
+

If you would like to synchronize multiple tasks, you can use the hpx::when_all function +to define which futures have to be ready and the then() function to declare what should +be executed once these futures are ready.

+
+
+Dependencies# +

OpenMP code:

+
int a = 10;
+int b = 20;
+int c = 0;
+
+#pragma omp task depend(in: a, b) depend(out: c)
+{
+    // task code
+    c = 100;
+}
+
+
+

HPX equivalent:

+
#include <hpx/future.hpp>
+
+int a = 10;
+int b = 20;
+int c = 0;
+
+// Create a future representing 'a'
+auto future_a = hpx::make_ready_future(a);
+
+// Create a future representing 'b'
+auto future_b = hpx::make_ready_future(b);
+
+// Create a task that depends on 'a' and 'b' and executes 'task_code'
+auto future_c = hpx::dataflow(
+    []() {
+        // task code
+        return 100;
+    },
+    future_a, future_b);
+
+c = future_c.get();
+
+
+

If one of the arguments of hpx::dataflow is a future, then it will wait for the +future to be ready to launch the thread. Hence, to define the dependencies of tasks +you have to create futures representing the variables that create dependencies and pass +them as arguments to hpx::dataflow. get() is used to save the result of the future +to the desired variable.

+
+
+Nested tasks# +

OpenMP code:

+
#pragma omp task
+{
+    // Outer task code
+    #pragma omp task
+    {
+        // Inner task code
+    }
+}
+
+
+

HPX equivalent:

+
#include <hpx/future.hpp>
+
+auto future_outer = hpx::async([](){
+    // Outer task code
+
+    hpx::async([](){
+        // Inner task code
+    });
+});
+
+
+

or

+
#include <hpx/future.hpp>
+
+auto future_outer = hpx::post([](){ // fire and forget
+    // Outer task code
+
+    hpx::post([](){ // fire and forget
+        // Inner task code
+    });
+});
+
+
+

If you have nested tasks, you can simply use nested hpx::async or +hpx::post calls. The implementation is similar if you want to take +care of synchronization:

+

OpenMP code:

+
#pragma omp taskwait
+{
+    // Outer task code
+    #pragma omp taskwait
+    {
+        // Inner task code
+    }
+}
+
+
+

HPX equivalent:

+
#include <hpx/future.hpp>
+
+auto future_outer = hpx::async([]() {
+    // Outer task code
+
+    hpx::async([]() {
+        // Inner task code
+    }).get();    // Wait for the inner task to complete
+});
+
+future_outer.get();    // Wait for the outer task to complete
+
+
+
+
+Task yield# +

OpenMP code:

+
#pragma omp task
+{
+    // code before yielding
+    #pragma omp taskyield
+    // code after yielding
+}
+
+
+

HPX equivalent:

+
#include <hpx/future.hpp>
+#include <hpx/thread.hpp>
+
+auto future = hpx::async([](){
+    // code before yielding
+});
+
+// yield execution to potentially allow other tasks to run
+hpx::this_thread::yield();
+
+// code after yielding
+
+
+

After creating a task using hpx::async, hpx::this_thread::yield +can be used to reschedule the execution of threads, allowing other threads to run.

+
+
+Task group# +

OpenMP code:

+
#pragma omp taskgroup
+{
+    #pragma omp task
+    {
+        // task 1 code
+    }
+
+    #pragma omp task
+    {
+        // task 2 code
+    }
+}
+
+
+

HPX equivalent:

+
#include <hpx/task_group.hpp>
+
+// Declare a task group
+hpx::experimental::task_group tg;
+
+// Run the tasks
+tg.run([](){
+    // task 1 code
+});
+tg.run(
+    // task 2 code
+});
+
+// Wait for the task group
+tg.wait();
+
+
+

To create task groups, you can use hpx::experimental::task_group. The function +run() can be used to run each task within the task group, while wait() can be used to +achieve synchronization. If you do not care about waiting for the task group to complete +its execution, you can simply remove the wait() function.

+
+
+
+
OpenMP sections#
+

OpenMP code:

+
#pragma omp sections
+{
+    #pragma omp section
+    // section 1 code
+    #pragma omp section
+    // section 2 code
+} // implicit synchronization
+
+
+

HPX equivalent:

+
#include <hpx/future.hpp>
+
+auto future_section1 = hpx::async([](){
+    // section 1 code
+});
+auto future_section2 = hpx::async([](){
+    // section 2 code
+);
+
+// synchronization: wait for both sections to complete
+hpx::wait_all(future_section1, future_section2);
+
+
+

Unlike tasks, there is an implicit synchronization barrier at the end of each sections` +directive in OpenMP. This synchronization is achieved using hpx::wait_all function.

+
+

Note

+

If the nowait clause is used in the sections directive, then you can just remove +the hpx::wait_all function while keeping the rest of the code as it is.

+
+
+
+
+
Intel Threading Building Blocks (TBB)#
+

Intel Threading Building Blocks (TBB) provides a high-level interface for parallelism and concurrent programming using +standard ISO C++ code. Below are some examples on how to convert Intel Threading Building Blocks (TBB) to HPX code:

+
+
parallel_for#
+

Intel Threading Building Blocks (TBB) code:

+
auto values = std::vector<double>(10000);
+
+tbb::parallel_for( tbb::blocked_range<int>(0,values.size()),
+                    [&](tbb::blocked_range<int> r)
+{
+    for (int i=r.begin(); i<r.end(); ++i)
+    {
+        // loop body
+    }
+});
+
+
+

HPX equivalent:

+
#include <hpx/algorithm.hpp>
+
+auto values = std::vector<double>(10000);
+
+hpx::experimental::for_loop(hpx::execution::par, 0, values.size(), [&](int i) {
+    // loop body
+});
+
+
+

In the above code, tbb::parallel_for is replaced with hpx::experimental::for_loop +from the HPX library. The loop body within the lambda function will be executed in +parallel for each iteration.

+
+
+
parallel_for_each#
+

Intel Threading Building Blocks (TBB) code:

+
auto values = std::vector<double>(10000);
+
+tbb::parallel_for_each(values.begin(), values.end(), [&](){
+    // loop body
+});
+
+
+

HPX equivalent:

+
#include <hpx/algorithm.hpp>
+
+auto values = std::vector<double>(10000);
+
+hpx::for_each(hpx::execution::par, values.begin(), values.end(), [&](){
+    // loop body
+});
+
+
+

By utilizing hpx::for_each` and specifying a parallel execution policy with +hpx::execution::par, it is possible to transform tbb::parallel_for_each` into its +equivalent counterpart in HPX.

+
+
+
parallel_invoke#
+

Intel Threading Building Blocks (TBB) code:

+
tbb::parallel_invoke(task1, task2, task3);
+
+
+

HPX equivalent:

+
#include <hpx/future.hpp>
+
+hpx::wait_all(hpx::async(task1), hpx::async(task2), hpx::async(task3));
+
+
+

To convert tbb::parallel_invoke to HPX, we use hpx::async to asynchronously +execute each task, which returns a future representing the result of each task. +We then pass these futures to hpx::when_all, which waits for all the futures +to complete before returning.

+
+
+
parallel_pipeline#
+

Intel Threading Building Blocks (TBB) code:

+
tbb::parallel_pipeline(4,
+    tbb::make_filter<void, int>(tbb::filter::serial_in_order,
+        [](tbb::flow_control& fc) -> int {
+            // Generate numbers from 1 to 10
+            static int i = 1;
+            if (i <= 10) {
+                return i++;
+            }
+            else {
+                fc.stop();
+                return 0;
+            }
+        }) &
+    tbb::make_filter<int, int>(tbb::filter::parallel,
+        [](int num) -> int {
+            // Multiply each number by 2
+            return num * 2;
+        }) &
+    tbb::make_filter<int, void>(tbb::filter::serial_in_order,
+        [](int num) {
+            // Print the results
+            std::cout << num << " ";
+        })
+);
+
+
+

HPX equivalent:

+
#include <iostream>
+#include <vector>
+#include <ranges>
+#include <hpx/algorithm.hpp>
+
+// generate the values
+auto range = std::views::iota(1) | std::views::take(10);
+
+// materialize the output vector
+std::vector<int> results(10);
+
+// in parallel execution of pipeline and transformation
+hpx::ranges::transform(
+    hpx::execution::par, range, result.begin(), [](int i) { return 2 * i; });
+
+// print the modified vector
+for (int i : result)
+{
+    std::cout << i << " ";
+}
+std::cout << std::endl;
+
+
+

The line auto range = std::views::iota(1) | std::views::take(10); generates a range of values using +the std::views::iota function. It starts from the value 1 and generates an infinite sequence of +incrementing values. The std::views::take(10) function is then applied to limit the sequence to the +first 10 values. The result is stored in the range variable.

+
+

Hint

+

A view is a lightweight object that represents a particular view of a sequence or range. It acts as +a read-only interface to the original data, providing a way to query and traverse the elements +without making any copies or modifications.

+

Views can be composed and chained together to form complex pipelines of operations. These operations +are evaluated lazily, meaning that the actual computation is performed only when the result is +needed or consumed.

+
+

Since views perform lazy evaluation, we use std::vector<int> results(10); to meterialize the vector +that will store the transformed values. The hpx::ranges::transform function is then used to perform +a parallel transformation on the range. The transformed values will be written to the results vector.

+
+

Hint

+

Ranges enable loop fusion by combining multiple operations into a single parallel loop, eliminating +waiting time and reducing overhead. Using ranges, you can express these operations as a pipeline of +transformations on a sequence of elements. This pipeline is evaluated in a single pass, performing +all the desired operations in parallel without the need to wait between them.

+

In addition, HPX enhances the benefits of range fusion by offering parallel execution policies, +which can be used to optimize the execution of the fused loop across multiple threads.

+
+
+
+
parallel_reduce#
+
+Reduction# +

Intel Threading Building Blocks (TBB) code:

+
auto values = std::vector<double>{1,2,3,4,5,6,7,8,9};
+
+auto total = tbb::parallel_reduce(
+                tbb::blocked_range<int>(0,values.size()),
+                0.0,
+                [&](tbb::blocked_range<int> r, double running_total)
+                {
+                    for (int i=r.begin(); i<r.end(); ++i)
+                    {
+                        running_total += values[i];
+                    }
+
+
+                    return running_total;
+                },
+                std::plus<double>());
+
+
+

HPX equivalent:

+
#include <hpx/numeric.hpp>
+
+auto values = std::vector<double>{1,2,3,4,5,6,7,8,9};
+
+auto total = hpx::reduce(
+    hpx::execution::par, values.begin(), values.end(), 0, std::plus{});
+
+
+

By utilizing hpx::reduce and specifying a parallel execution policy with +hpx::execution::par, it is possible to transform tbb::parallel_reduce` into its +equivalent counterpart in HPX. As demonstrated in the previous example, the management +of intermediate results is seamlessly handled internally by HPX, eliminating the need +for explicit consideration.

+
+
+Transformation & Reduction# +

Intel Threading Building Blocks (TBB) code:

+
auto values = std::vector<double>{1,2,3,4,5,6,7,8,9};
+
+auto transform_function(double current_value){
+    // transformation code
+}
+
+auto total = tbb::parallel_reduce(
+                tbb::blocked_range<int>(0,values.size()),
+                0.0,
+                [&](tbb::blocked_range<int> r, double transformed_val)
+                {
+                    for (int i=r.begin(); i<r.end(); ++i)
+                    {
+                        transformed_val += transform_function(values[i]);
+                    }
+                    return transformed_val;
+                },
+                std::plus<double>());
+
+
+

HPX equivalent:

+
#include <hpx/numeric.hpp>
+
+auto values = std::vector<double>{1,2,3,4,5,6,7,8,9};
+
+auto transform_function(double current_value)
+{
+    // transformation code
+}
+
+auto total = hpx::transform_reduce(hpx::execution::par, values.begin(),
+    values.end(), 0, std::plus{},
+    [&](double current_value) { return transform_function(current_value); });
+
+
+

In situations where certain values require transformation before the reduction process, +HPX provides a straightforward solution through hpx::transform_reduce. The +transform_function() allows for the application of the desired transformation to each value.

+
+
+
+
parallel_scan#
+

Intel Threading Building Blocks (TBB) code:

+
tbb::parallel_scan(tbb::blocked_range<size_t>(0, input.size()),
+    0,
+    [&input, &output](const tbb::blocked_range<size_t>& range, int& partial_sum, bool is_final_scan) {
+        for (size_t i = range.begin(); i != range.end(); ++i) {
+            partial_sum += input[i];
+            if (is_final_scan) {
+                output[i] = partial_sum;
+            }
+        }
+        return partial_sum;
+    },
+    [](int left_sum, int right_sum) {
+        return left_sum + right_sum;
+    }
+);
+
+
+

HPX equivalent:

+
#include <hpx/numeric.hpp>
+
+hpx::inclusive_scan(hpx::execution::par, input.begin(), input.end(),
+    output.begin(),
+    [](const int& left, const int& right) { return left + right; });
+
+
+

hpx::inclusive_scan with hpx::execution::par as execution policy +can be used to perform a prefix scan in parallel. The management of intermediate +results is seamlessly handled internally by HPX, eliminating the need +for explicit consideration. input.begin() and input.end() refer to the beginning +and end of the sequence of elements the algorithm will be applied to respectively. +output.begin() refers to the beginning of the destination, while the last argument +specifies the function which will be invoked for each of the values of the input sequence.

+

Apart from hpx::inclusive_scan, HPX provides its users with hpx::exclusive_scan. +The key difference between inclusive scan and exclusive scan lies in the treatment of the current element +during the scan operation. In an inclusive scan, each element in the output sequence includes the +contribution of the corresponding element in the input sequence, while in an exclusive scan, the current +element in the input sequence does not contribute to the corresponding element in the output sequence.

+
+
+
parallel_sort#
+

Intel Threading Building Blocks (TBB) code:

+
std::vector<int> numbers = {9, 2, 7, 1, 5, 3};
+
+tbb::parallel_sort(numbers.begin(), numbers.end());
+
+
+

HPX equivalent:

+
#include <hpx/algorithm.hpp>
+
+std::vector<int> numbers = {9, 2, 7, 1, 5, 3};
+
+hpx::sort(hpx::execution::par, numbers.begin(), numbers.end());
+
+
+

hpx::sort provides an equivalent functionality to tbb::parallel_sort. +When given a parallel execution policy with hpx::execution::par, the algorithm employs +parallel execution, allowing for efficient sorting across available threads.

+
+
+
task_group#
+

Intel Threading Building Blocks (TBB) code:

+
// Declare a task group
+tbb::task_group tg;
+
+// Run the tasks
+tg.run(task1);
+tg.run(task2);
+
+// Wait for the task group
+tg.wait();
+
+
+

HPX equivalent:

+
#include <hpx/task_group.hpp>
+
+// Declare a task group
+hpx::experimental::task_group tg;
+
+// Run the tasks
+tg.run(task1);
+tg.run(task2);
+
+// Wait for the task group
+tg.wait();
+
+
+

HPX drew inspiration from Intel Threading Building Blocks (TBB) to introduce the hpx::experimental::task_group +feature. Therefore, utilizing hpx::experimental::task_group provides an +equivalent functionality to tbb::task_group.

+
+
+
+
MPI#
+

MPI is a standardized communication protocol and library that allows multiple processes or +nodes in a parallel computing system to exchange data and coordinate their execution.

+
+
List of MPI-HPX functions#
+
+
++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +

MPI function

HPX equivalent

MPI_Allgather

hpx::collectives::all_gather

MPI_Allreduce

hpx::collectives::all_reduce

MPI_Alltoall

hpx::collectives::all_to_all

MPI_Barrier

hpx::distributed::barrier

MPI_Bcast

hpx::collectives::broadcast_to() and hpx::collectives::broadcast_from() used with get()

MPI_Comm_size

hpx::get_num_localities

MPI_Comm_rank

hpx::get_locality_id()

MPI_Exscan

hpx::collectives::exclusive_scan() used with get()

MPI_Gather

hpx::collectives::gather_here() and hpx::collectives::gather_there() used with get()

MPI_Irecv

hpx::collectives::get()

MPI_Isend

hpx::collectives::set()

MPI_Reduce

hpx::collectives::reduce_here and hpx::collectives::reduce_there used with get()

MPI_Scan

hpx::collectives::inclusive_scan() used with get()

MPI_Scatter

hpx::collectives::scatter_to() and hpx::collectives::scatter_from()

MPI_Wait

hpx::collectives::get() used with a future i.e. setf.get()

+
+
+
+
MPI_Send & MPI_Recv#
+

Let’s assume we have the following simple message passing code where each process sends a +message to the next process in a circular manner. The exchanged message is modified and printed +to the console.

+

MPI code:

+
#include <cstddef>
+#include <cstdint>
+#include <iostream>
+#include <mpi.h>
+#include <vector>
+
+constexpr int times = 2;
+
+int main(int argc, char *argv[]) {
+MPI_Init(&argc, &argv);
+
+int num_localities;
+MPI_Comm_size(MPI_COMM_WORLD, &num_localities);
+
+int this_locality;
+MPI_Comm_rank(MPI_COMM_WORLD, &this_locality);
+
+int next_locality = (this_locality + 1) % num_localities;
+std::vector<int> msg_vec = {0, 1};
+
+int cnt = 0;
+int msg = msg_vec[this_locality];
+
+int recv_msg;
+MPI_Request request_send, request_recv;
+MPI_Status status;
+
+while (cnt < times) {
+    cnt += 1;
+
+    MPI_Isend(&msg, 1, MPI_INT, next_locality, cnt, MPI_COMM_WORLD,
+            &request_send);
+    MPI_Irecv(&recv_msg, 1, MPI_INT, next_locality, cnt, MPI_COMM_WORLD,
+            &request_recv);
+
+    MPI_Wait(&request_send, &status);
+    MPI_Wait(&request_recv, &status);
+
+    std::cout << "Time: " << cnt << ", Locality " << this_locality
+            << " received msg: " << recv_msg << "\n";
+
+    recv_msg += 10;
+    msg = recv_msg;
+}
+
+MPI_Finalize();
+return 0;
+}
+
+
+

HPX equivalent:

+
#include <hpx/config.hpp>
+
+#if !defined(HPX_COMPUTE_DEVICE_CODE)
+#include <hpx/algorithm.hpp>
+#include <hpx/hpx_init.hpp>
+#include <hpx/modules/collectives.hpp>
+
+#include <cstddef>
+#include <cstdint>
+#include <iostream>
+#include <utility>
+#include <vector>
+
+using namespace hpx::collectives;
+
+constexpr char const* channel_communicator_name =
+    "/example/channel_communicator/";
+
+// the number of times
+constexpr int times = 2;
+
+int hpx_main()
+{
+    std::uint32_t num_localities = hpx::get_num_localities(hpx::launch::sync);
+    std::uint32_t this_locality = hpx::get_locality_id();
+
+    // allocate channel communicator
+    auto comm = create_channel_communicator(hpx::launch::sync,
+        channel_communicator_name, num_sites_arg(num_localities),
+        this_site_arg(this_locality));
+
+    std::uint32_t next_locality = (this_locality + 1) % num_localities;
+    std::vector<int> msg_vec = {0, 1};
+
+    int cnt = 0;
+    int msg = msg_vec[this_locality];
+
+    // send values to another locality
+    auto setf = set(comm, that_site_arg(next_locality), msg, tag_arg(cnt));
+    auto got_msg = get<int>(comm, that_site_arg(next_locality), tag_arg(cnt));
+
+    setf.get();
+
+    while (cnt < times)
+    {
+        cnt += 1;
+
+        auto done_msg = got_msg.then([&](auto&& f) {
+            int rec_msg = f.get();
+            std::cout << "Time: " << cnt << ", Locality " << this_locality
+                      << " received msg: " << rec_msg << "\n";
+
+            // change msg by adding 10
+            rec_msg += 10;
+
+            // start next round
+            setf =
+                set(comm, that_site_arg(next_locality), rec_msg, tag_arg(cnt));
+            got_msg =
+                get<int>(comm, that_site_arg(next_locality), tag_arg(cnt));
+            setf.get();
+        });
+
+        done_msg.get();
+    }
+
+    return hpx::finalize();
+}
+#endif
+
+int main(int argc, char* argv[])
+{
+#if !defined(HPX_COMPUTE_DEVICE_CODE)
+    hpx::init_params params;
+    params.cfg = {"--hpx:run-hpx-main"};
+    return hpx::init(argc, argv, params);
+#else
+    (void) argc;
+    (void) argv;
+    return 0;
+#endif
+}
+
+
+

To perform message passing between different processes in HPX we can use a channel communicator. +To understand this example, let’s focus on the hpx_main() function:

+
    +
  • hpx::get_num_localities(hpx::launch::sync) retrieves the number of localities, while +hpx::get_locality_id() returns the ID of the current locality.

  • +
  • create_channel_communicator function is used to create a channel to serve the communication. +This function takes several arguments, including the launch policy (hpx::launch::sync), the +name of the communicator (channel_communicator_name), the number of localities, and the ID +of the current locality.

  • +
  • The communication follows a ring pattern, where each process (or locality) sends a message to +its neighbor in a circular manner. This means that the messages circulate around the localities, +ensuring that the communication wraps around when reaching the end of the locality sequence. +To achieve this, the next_locality variable is calculated as the ID of the next locality in +the ring.

  • +
  • The initial values for the communication are set (msg_vec, cnt, msg).

  • +
  • The set() function is called to send the message to the next locality in the ring. The message +is sent asynchronously and is associated with a tag (cnt).

  • +
  • The get() function is called to receive a message from the next locality. It is also associated +with the same tag as the set() operation.

  • +
  • The setf.get() call blocks until the message sending operation is complete.

  • +
  • A continuation is set up using the function then() to handle the received message. +Inside the continuation:

    +
      +
    • The received message value (rec_msg) is retrieved using f.get().

    • +
    • The received message is printed to the console and then modified by adding 10.

    • +
    • The set() and get() operations are repeated to send and receive the modified message to +the next locality.

    • +
    • The setf.get() call blocks until the new message sending operation is complete.

    • +
    +
  • +
  • The done_msg.get() call blocks until the continuation is complete for the current loop iteration.

  • +
+

Having said that, we conclude to the following table:

+
+
+
MPI_Gather#
+

The following code gathers data from all processes to the root process and verifies +the gathered data in the root process.

+

MPI code:

+
#include <iostream>
+#include <mpi.h>
+#include <numeric>
+#include <vector>
+
+int main(int argc, char *argv[]) {
+    MPI_Init(&argc, &argv);
+
+    int num_localities, this_locality;
+    MPI_Comm_size(MPI_COMM_WORLD, &num_localities);
+    MPI_Comm_rank(MPI_COMM_WORLD, &this_locality);
+
+    std::vector<int> local_data; // Data to be gathered
+
+    if (this_locality == 0) {
+        local_data.resize(num_localities); // Resize the vector on the root process
+    }
+
+    // Each process calculates its local data value
+    int my_data = 42 + this_locality;
+
+    for (std::uint32_t i = 0; i != 10; ++i) {
+
+        // Gather data from all processes to the root process (process 0)
+        MPI_Gather(&my_data, 1, MPI_INT, local_data.data(), 1, MPI_INT, 0,
+                MPI_COMM_WORLD);
+
+        // Only the root process (process 0) will print the gathered data
+        if (this_locality == 0) {
+        std::cout << "Gathered data on the root: ";
+        for (int i = 0; i < num_localities; ++i) {
+            std::cout << local_data[i] << " ";
+        }
+        std::cout << std::endl;
+        }
+    }
+    std::cout << std::endl;
+
+    MPI_Finalize();
+    return 0;
+}
+
+
+

HPX equivalent:

+
std::uint32_t num_localities = hpx::get_num_localities(hpx::launch::sync);
+std::uint32_t this_locality = hpx::get_locality_id();
+
+// test functionality based on immediate local result value
+auto gather_direct_client = create_communicator(gather_direct_basename,
+    num_sites_arg(num_localities), this_site_arg(this_locality));
+
+for (std::uint32_t i = 0; i != 10; ++i)
+{
+    if (this_locality == 0)
+    {
+        hpx::future<std::vector<std::uint32_t>> overall_result =
+            gather_here(gather_direct_client, std::uint32_t(42));
+
+        std::vector<std::uint32_t> sol = overall_result.get();
+        std::cout << "Gathered data on the root:";
+
+        for (std::size_t j = 0; j != sol.size(); ++j)
+        {
+            HPX_TEST(j + 42 == sol[j]);
+            std::cout << " " << sol[j];
+        }
+        std::cout << std::endl;
+    }
+    else
+    {
+        hpx::future<void> overall_result =
+            gather_there(gather_direct_client, this_locality + 42);
+        overall_result.get();
+    }
+
+}
+
+
+

This code will print 10 times the following message:

+
Gathered data on the root: 42 43
+
+
+

HPX uses two functions to implement the functionality of MPI_Gather: gather_here and +gather_there. gather_here is gathering data from all localities to the locality +with ID 0 (root locality). gather_there allows non-root localities to participate in the +gather operation by sending data to the root locality. In more detail:

+
    +
  • hpx::get_num_localities(hpx::launch::sync) retrieves the number of localities, while +hpx::get_locality_id() returns the ID of the current locality.

  • +
  • The function create_communicator() is used to create a communicator called +gather_direct_client.

  • +
  • If the current locality is the root (its ID is equal to 0):

    +
      +
    • The gather_here function is used to perform the gather operation. It collects data from all +other localities into the overall_result future object. The function arguments provide the necessary +information, such as the base name for the gather operation (gather_direct_basename), the value +to be gathered (value), the number of localities (num_localities), the current locality ID +(this_locality), and the generation number (related to the gather operation).

    • +
    • The get() member function of the overall_result future is used to retrieve the gathered data.

    • +
    • The next for loop is used to verify the correctness of the gathered data (sol). HPX_TEST +is a macro provided by the HPX testing utilities to perform similar testing with the Standard +C++ macro assert.

    • +
    +
  • +
  • If the current locality is not the root:

    +
      +
    • The gather_there function is used to participate in the gather operation initiated by +the root locality. It sends the data (in this case, the value this_locality + 42) to the root +locality, indicating that it should be included in the gathering.

    • +
    • The get() member function of the overall_result future is used to wait for the gather operation +to complete for this locality.

    • +
    +
  • +
+
+
+
MPI_Scatter#
+

The following code gathers data from all processes to the root process and verifies +the gathered data in the root process.

+

MPI code:

+
#include <iostream>
+#include <mpi.h>
+#include <vector>
+
+int main(int argc, char *argv[]) {
+    MPI_Init(&argc, &argv);
+
+    int num_localities, this_locality;
+    MPI_Comm_size(MPI_COMM_WORLD, &num_localities);
+    MPI_Comm_rank(MPI_COMM_WORLD, &this_locality);
+
+    int num_localities = num_localities;
+    std::vector<int> data(num_localities);
+
+    if (this_locality == 0) {
+        // Fill the data vector on the root locality (locality 0)
+        for (int i = 0; i < num_localities; ++i) {
+        data[i] = 42 + i;
+        }
+    }
+
+    int local_data; // Variable to store the received data
+
+    // Scatter data from the root locality to all other localities
+    MPI_Scatter(&data[0], 1, MPI_INT, &local_data, 1, MPI_INT, 0, MPI_COMM_WORLD);
+
+    // Now, each locality has its own local_data
+
+    // Print the local_data on each locality
+    std::cout << "Locality " << this_locality << " received " << local_data
+                << std::endl;
+
+    MPI_Finalize();
+    return 0;
+}
+
+
+

HPX equivalent:

+
std::uint32_t num_localities = hpx::get_num_localities(hpx::launch::sync);
+HPX_TEST_LTE(std::uint32_t(2), num_localities);
+
+std::uint32_t this_locality = hpx::get_locality_id();
+
+auto scatter_direct_client =
+    hpx::collectives::create_communicator(scatter_direct_basename,
+        num_sites_arg(num_localities), this_site_arg(this_locality));
+
+// test functionality based on immediate local result value
+for (std::uint32_t i = 0; i != 10; ++i)
+{
+    if (this_locality == 0)
+    {
+        std::vector<std::uint32_t> data(num_localities);
+        std::iota(data.begin(), data.end(), 42 + i);
+
+        hpx::future<std::uint32_t> result =
+            scatter_to(scatter_direct_client, std::move(data));
+
+        HPX_TEST_EQ(i + 42 + this_locality, result.get());
+    }
+    else
+    {
+        hpx::future<std::uint32_t> result =
+            scatter_from<std::uint32_t>(scatter_direct_client);
+
+        HPX_TEST_EQ(i + 42 + this_locality, result.get());
+
+        std::cout << "Locality " << this_locality << " received "
+                  << i + 42 + this_locality << std::endl;
+    }
+}
+
+
+

For num_localities = 2 and since we run for 10 iterations this code will print +the following message:

+
Locality 1 received 43
+Locality 1 received 44
+Locality 1 received 45
+Locality 1 received 46
+Locality 1 received 47
+Locality 1 received 48
+Locality 1 received 49
+Locality 1 received 50
+Locality 1 received 51
+Locality 1 received 52
+
+
+

HPX uses two functions to implement the functionality of MPI_Scatter: hpx::scatter_to and +hpx::scatter_from. hpx::scatter_to is distributing the data from the locality with ID 0 +(root locality) to all other localities. hpx::scatter_from allows non-root localities to receive +the data from the root locality. In more detail:

+
    +
  • hpx::get_num_localities(hpx::launch::sync) retrieves the number of localities, while +hpx::get_locality_id() returns the ID of the current locality.

  • +
  • The function hpx::collectives::create_communicator() is used to create a communicator called +scatter_direct_client.

  • +
  • If the current locality is the root (its ID is equal to 0):

    +
      +
    • The data vector is filled with values ranging from 42 + i to 42 + i + num_localities - 1.

    • +
    • The hpx::scatter_to function is used to perform the scatter operation using the communicator +scatter_direct_client. This scatters the data vector to other localities and +returns a future representing the result.

    • +
    • HPX_TEST_EQ is a macro provided by the HPX testing utilities to test the distributed values.

    • +
    +
  • +
  • If the current locality is not the root:

    +
      +
    • The hpx::scatter_from function is used to collect the data by the root locality.

    • +
    • HPX_TEST_EQ is a macro provided by the HPX testing utilities to test the collected values.

    • +
    +
  • +
+
+
+
MPI_Allgather#
+

The following code gathers data from all processes and sends the data to all +processes.

+

MPI code:

+
#include <cstdint>
+#include <iostream>
+#include <mpi.h>
+#include <vector>
+
+int main(int argc, char **argv) {
+    MPI_Init(&argc, &argv);
+
+    int rank, size;
+    MPI_Comm_rank(MPI_COMM_WORLD, &rank);
+    MPI_Comm_size(MPI_COMM_WORLD, &size);
+
+    // Get the number of MPI processes
+    int num_localities = size;
+
+    // Get the MPI process rank
+    int here = rank;
+
+    std::uint32_t value = here;
+
+    std::vector<std::uint32_t> r(num_localities);
+
+    // Perform an all-gather operation to gather values from all processes.
+    MPI_Allgather(&value, 1, MPI_UINT32_T, r.data(), 1, MPI_UINT32_T,
+                    MPI_COMM_WORLD);
+
+    // Print the result.
+    std::cout << "Locality " << here << " has values:";
+    for (size_t j = 0; j < r.size(); ++j) {
+        std::cout << " " << r[j];
+    }
+    std::cout << std::endl;
+
+    MPI_Finalize();
+    return 0;
+}
+
+
+

HPX equivalent:

+
std::uint32_t num_localities = hpx::get_num_localities(hpx::launch::sync);
+std::uint32_t here = hpx::get_locality_id();
+
+// test functionality based on immediate local result value
+auto all_gather_direct_client =
+    create_communicator(all_gather_direct_basename,
+        num_sites_arg(num_localities), this_site_arg(here));
+
+std::uint32_t value = here;
+
+hpx::future<std::vector<std::uint32_t>> overall_result =
+    all_gather(all_gather_direct_client, value);
+
+std::vector<std::uint32_t> r = overall_result.get();
+
+std::cout << "Locality " << here << " has values:";
+for (std::size_t j = 0; j != r.size(); ++j)
+{
+    std::cout << " " << j;
+}
+std::cout << std::endl;
+
+
+

For num_localities = 2 this code will print the following message:

+
Locality 0 has values: 0 1
+Locality 1 has values: 0 1
+
+
+

HPX uses the function all_gather to implement the functionality of MPI_Allgather. In more +detail:

+
    +
  • hpx::get_num_localities(hpx::launch::sync) retrieves the number of localities, while +hpx::get_locality_id() returns the ID of the current locality.

  • +
  • The function hpx::collectives::create_communicator() is used to create a communicator called +all_gather_direct_client.

  • +
  • The values that the localities exchange with each other are equal to each locality’s ID.

  • +
  • The gather operation is performed using all_gather. The result is stored in an hpx::future +object called overall_result, which represents a future result that can be retrieved later when +needed.

  • +
  • The get() function waits until the result is available and then stores it in the vector called r.

  • +
+
+
+
MPI_Allreduce#
+

The following code combines values from all processes and distributes the result back to all processes.

+

MPI code:

+
#include <cstdint>
+#include <iostream>
+#include <mpi.h>
+
+int main(int argc, char **argv) {
+    MPI_Init(&argc, &argv);
+
+    int rank, size;
+    MPI_Comm_rank(MPI_COMM_WORLD, &rank);
+    MPI_Comm_size(MPI_COMM_WORLD, &size);
+
+    // Get the number of MPI processes
+    int num_localities = size;
+
+    // Get the MPI process rank
+    int here = rank;
+
+    // Create a communicator for the all reduce operation.
+    MPI_Comm all_reduce_direct_client;
+    MPI_Comm_split(MPI_COMM_WORLD, 0, rank, &all_reduce_direct_client);
+
+    // Perform the all reduce operation to calculate the sum of 'here' values.
+    std::uint32_t value = here;
+    std::uint32_t res = 0;
+    MPI_Allreduce(&value, &res, 1, MPI_UINT32_T, MPI_SUM,
+                    all_reduce_direct_client);
+
+    std::cout << "Locality " << rank << " has value: " << res << std::endl;
+
+    MPI_Finalize();
+    return 0;
+}
+
+
+

HPX equivalent:

+
std::uint32_t const num_localities =
+    hpx::get_num_localities(hpx::launch::sync);
+std::uint32_t const here = hpx::get_locality_id();
+
+auto const all_reduce_direct_client =
+    create_communicator(all_reduce_direct_basename,
+        num_sites_arg(num_localities), this_site_arg(here));
+
+std::uint32_t value = here;
+
+hpx::future<std::uint32_t> overall_result =
+    all_reduce(all_reduce_direct_client, value, std::plus<std::uint32_t>{});
+
+std::uint32_t res = overall_result.get();
+std::cout << "Locality " << here << " has value: " << res << std::endl;
+
+
+

For num_localities = 2 this code will print the following message:

+
Locality 0 has value: 1
+Locality 1 has value: 1
+
+
+

HPX uses the function all_reduce to implement the functionality of MPI_Allreduce. In more +detail:

+
    +
  • hpx::get_num_localities(hpx::launch::sync) retrieves the number of localities, while +hpx::get_locality_id() returns the ID of the current locality.

  • +
  • The function hpx::collectives::create_communicator() is used to create a communicator called +all_reduce_direct_client.

  • +
  • The value of each locality is equal to its ID.

  • +
  • The reduce operation is performed using all_reduce. The result is stored in an hpx::future +object called overall_result, which represents a future result that can be retrieved later when +needed.

  • +
  • The get() function waits until the result is available and then stores it in the variable res.

  • +
+
+
+
MPI_Alltoall#
+

The following code gathers data from and scatters data to all processes.

+

MPI code:

+
#include <algorithm>
+#include <cstdint>
+#include <iostream>
+#include <mpi.h>
+#include <vector>
+
+int main(int argc, char **argv) {
+    MPI_Init(&argc, &argv);
+
+    int rank, size;
+    MPI_Comm_rank(MPI_COMM_WORLD, &rank);
+    MPI_Comm_size(MPI_COMM_WORLD, &size);
+
+    // Get the number of MPI processes
+    int num_localities = size;
+
+    // Get the MPI process rank
+    int this_locality = rank;
+
+    // Create a communicator for all-to-all operation.
+    MPI_Comm all_to_all_direct_client;
+    MPI_Comm_split(MPI_COMM_WORLD, 0, rank, &all_to_all_direct_client);
+
+    std::vector<std::uint32_t> values(num_localities);
+    std::fill(values.begin(), values.end(), this_locality);
+
+    // Create vectors to store received values.
+    std::vector<std::uint32_t> r(num_localities);
+
+    // Perform an all-to-all operation to exchange values with other localities.
+    MPI_Alltoall(values.data(), 1, MPI_UINT32_T, r.data(), 1, MPI_UINT32_T,
+                all_to_all_direct_client);
+
+    // Print the results.
+    std::cout << "Locality " << this_locality << " has values:";
+    for (std::size_t j = 0; j != r.size(); ++j) {
+        std::cout << " " << r[j];
+    }
+    std::cout << std::endl;
+
+    MPI_Finalize();
+    return 0;
+}
+
+
+

HPX equivalent:

+
std::uint32_t num_localities = hpx::get_num_localities(hpx::launch::sync);
+std::uint32_t this_locality = hpx::get_locality_id();
+
+auto all_to_all_direct_client =
+    create_communicator(all_to_all_direct_basename,
+        num_sites_arg(num_localities), this_site_arg(this_locality));
+
+std::vector<std::uint32_t> values(num_localities);
+std::fill(values.begin(), values.end(), this_locality);
+
+hpx::future<std::vector<std::uint32_t>> overall_result =
+    all_to_all(all_to_all_direct_client, std::move(values));
+
+std::vector<std::uint32_t> r = overall_result.get();
+std::cout << "Locality " << this_locality << " has values:";
+
+for (std::size_t j = 0; j != r.size(); ++j)
+{
+    std::cout << " " << r[j];
+}
+std::cout << std::endl;
+
+
+

For num_localities = 2 this code will print the following message:

+
Locality 0 has values: 0 1
+Locality 1 has values: 0 1
+
+
+

HPX uses the function all_to_all to implement the functionality of MPI_Alltoall. In more +detail:

+
    +
  • hpx::get_num_localities(hpx::launch::sync) retrieves the number of localities, while +hpx::get_locality_id() returns the ID of the current locality.

  • +
  • The function hpx::collectives::create_communicator() is used to create a communicator called +all_to_all_direct_client.

  • +
  • The value each locality sends is equal to its ID.

  • +
  • The all-to-all operation is performed using all_to_all. The result is stored in an hpx::future +object called overall_result, which represents a future result that can be retrieved later when +needed.

  • +
  • The get() function waits until the result is available and then stores it in the variable r.

  • +
+
+
+
MPI_Barrier#
+

The following code shows how barrier is used to synchronize multiple processes.

+

MPI code:

+
#include <cstdlib>
+#include <iostream>
+#include <mpi.h>
+
+int main(int argc, char **argv) {
+    MPI_Init(&argc, &argv);
+
+    std::size_t iterations = 5;
+
+    int rank, size;
+    MPI_Comm_rank(MPI_COMM_WORLD, &rank);
+    MPI_Comm_size(MPI_COMM_WORLD, &size);
+
+    for (std::size_t i = 0; i != iterations; ++i) {
+        MPI_Barrier(MPI_COMM_WORLD);
+        if (rank == 0) {
+        std::cout << "Iteration " << i << " completed." << std::endl;
+        }
+    }
+
+    MPI_Finalize();
+    return 0;
+}
+
+
+

HPX equivalent:

+
std::size_t iterations = 5;
+std::uint32_t this_locality = hpx::get_locality_id();
+
+char const* const barrier_test_name = "/test/barrier/multiple";
+
+hpx::distributed::barrier b(barrier_test_name);
+for (std::size_t i = 0; i != iterations; ++i)
+{
+    b.wait();
+    if (this_locality == 0)
+    {
+        std::cout << "Iteration " << i << " completed." << std::endl;
+    }
+}
+
+
+

This code will print the following message:

+
Iteration 0 completed.
+Iteration 1 completed.
+Iteration 2 completed.
+Iteration 3 completed.
+Iteration 4 completed.
+
+
+

HPX uses the function barrier to implement the functionality of MPI_Barrier. In more +detail:

+
    +
  • After defining the number of iterations, we use +hpx::get_locality_id() to get the ID of the current locality.

  • +
  • char const* const barrier_test_name = “/test/barrier/multiple”: This line defines a constant +character array as the name of the barrier. This name is used to identify the barrier across +different localities. All participating threads that use this name will synchronize +at this barrier.

  • +
  • Using hpx::distributed::barrier b(barrier_test_name), we create an instance of the distributed +barrier with the previously defined name. This barrier will be used to synchronize the execution +of threads across different localities.

  • +
  • Running for all the desired iterations, we use b.wait() to synchronize the threads. +Each thread waits until all other threads also reach this point before any of them can proceed +further.

  • +
+
+
+
MPI_Bcast#
+

The following code broadcasts data from one process to all other processes.

+

MPI code:

+
#include <iostream>
+#include <mpi.h>
+
+int main(int argc, char *argv[]) {
+    MPI_Init(&argc, &argv);
+
+    int num_localities;
+    MPI_Comm_size(MPI_COMM_WORLD, &num_localities);
+
+    int here;
+    MPI_Comm_rank(MPI_COMM_WORLD, &here);
+
+    int value;
+
+    for (int i = 0; i < 5; ++i) {
+        if (here == 0) {
+            value = i + 42;
+        }
+
+        // Broadcast the value from process 0 to all other processes
+        MPI_Bcast(&value, 1, MPI_INT, 0, MPI_COMM_WORLD);
+
+        if (here != 0) {
+            std::cout << "Locality " << here << " received " << value << std::endl;
+        }
+
+    }
+
+    MPI_Finalize();
+    return 0;
+}
+
+
+

HPX equivalent:

+
std::uint32_t num_localities = hpx::get_num_localities(hpx::launch::sync);
+
+std::uint32_t here = hpx::get_locality_id();
+
+auto broadcast_direct_client =
+    create_communicator(broadcast_direct_basename,
+        num_sites_arg(num_localities), this_site_arg(here));
+
+// test functionality based on immediate local result value
+for (std::uint32_t i = 0; i != 5; ++i)
+{
+    if (here == 0)
+    {
+        hpx::future<std::uint32_t> result =
+            broadcast_to(broadcast_direct_client, i + 42);
+
+        result.get();
+    }
+    else
+    {
+        hpx::future<std::uint32_t> result =
+            hpx::collectives::broadcast_from<std::uint32_t>(
+                broadcast_direct_client);
+
+        uint32_t r = result.get();
+
+        std::cout << "Locality " << here << " received " << r << std::endl;
+    }
+}
+
+
+

For num_localities = 2 this code will print the following message:

+
Locality 1 received 42
+Locality 1 received 43
+Locality 1 received 44
+Locality 1 received 45
+Locality 1 received 46
+
+
+

HPX uses two functions to implement the functionality of MPI_Bcast: broadcast_to and +broadcast_from. broadcast_to is broadcasting the data from the root locality to all +other localities. broadcast_from allows non-root localities to collect the data sent by +the root locality. In more detail:

+
    +
  • hpx::get_num_localities(hpx::launch::sync) retrieves the number of localities, while +hpx::get_locality_id() returns the ID of the current locality.

  • +
  • The function create_communicator() is used to create a communicator called +broadcast_direct_client.

  • +
  • If the current locality is the root (its ID is equal to 0):

    +
      +
    • The broadcast_to function is used to perform the broadcast operation using the communicator +broadcast_direct_client. This sends the data to other localities and +returns a future representing the result.

    • +
    • The get() member function of the result future is used to wait for and retrieve the result.

    • +
    +
  • +
  • If the current locality is not the root:

    +
      +
    • The broadcast_from function is used to collect the data by the root locality.

    • +
    • The get() member function of the result future is used to wait for the result.

    • +
    +
  • +
+
+
+
MPI_Exscan#
+

The following code computes the exclusive scan (partial reductions) of data on a +collection of processes.

+

MPI code:

+
#include <iostream>
+#include <mpi.h>
+#include <numeric>
+#include <vector>
+
+int main(int argc, char *argv[]) {
+    MPI_Init(&argc, &argv);
+
+    int num_localities;
+    MPI_Comm_size(MPI_COMM_WORLD, &num_localities);
+
+    int here;
+    MPI_Comm_rank(MPI_COMM_WORLD, &here);
+
+    // Calculate the value for this locality (here)
+    int value = here;
+
+    // Perform an exclusive scan
+    std::vector<int> result(num_localities);
+    MPI_Exscan(&value, &result[0], 1, MPI_INT, MPI_SUM, MPI_COMM_WORLD);
+
+    if (here != 0) {
+        int r = result[here - 1]; // Result is in the previous rank's slot
+
+        std::cout << "Locality " << here << " has value " << r << std::endl;
+    }
+
+    MPI_Finalize();
+    return 0;
+}
+
+
+

HPX equivalent:

+
std::uint32_t num_localities = hpx::get_num_localities(hpx::launch::sync);
+std::uint32_t here = hpx::get_locality_id();
+
+auto exclusive_scan_client = create_communicator(exclusive_scan_basename,
+    num_sites_arg(num_localities), this_site_arg(here));
+
+// test functionality based on immediate local result value
+std::uint32_t value = here;
+
+hpx::future<std::uint32_t> overall_result = exclusive_scan(
+    exclusive_scan_client, value, std::plus<std::uint32_t>{});
+
+uint32_t r = overall_result.get();
+
+if (here != 0)
+{
+    std::cout << "Locality " << here << " has value " << r << std::endl;
+}
+
+
+

For num_localities = 2 this code will print the following message:

+
Locality 1 has value 0
+
+
+

HPX uses the function exclusive_scan to implement MPI_Exscan. In more detail:

+
    +
  • hpx::get_num_localities(hpx::launch::sync) retrieves the number of localities, while +hpx::get_locality_id() returns the ID of the current locality.

  • +
  • The function create_communicator() is used to create a communicator called +exclusive_scan_client.

  • +
  • The exclusive_scan function is used to perform the exclusive scan operation +using the communicator exclusive_scan_client. std::plus<std::uint32_t>{} +specifies the binary associative operator to use for the scan. In this case, +it’s addition for summing values.

  • +
  • The get() member function of the overall_result future is used to wait for the result.

  • +
+
+
+
MPI_Scan#
+

The following code Computes the inclusive scan (partial reductions) of data on a collection +of processes.

+

MPI code:

+
#include <iostream>
+#include <mpi.h>
+#include <numeric>
+#include <vector>
+
+int main(int argc, char *argv[]) {
+    MPI_Init(&argc, &argv);
+
+    int num_localities;
+    MPI_Comm_size(MPI_COMM_WORLD, &num_localities);
+
+    int here;
+    MPI_Comm_rank(MPI_COMM_WORLD, &here);
+
+    // Calculate the value for this locality (here)
+    int value = here;
+
+    std::vector<int> result(num_localities);
+
+    MPI_Scan(&value, &result[0], 1, MPI_INT, MPI_SUM, MPI_COMM_WORLD);
+
+    std::cout << "Locality " << here << " has value " << result[0] << std::endl;
+
+    MPI_Finalize();
+    return 0;
+}
+
+
+

HPX equivalent:

+
std::uint32_t num_localities = hpx::get_num_localities(hpx::launch::sync);
+std::uint32_t here = hpx::get_locality_id();
+
+auto inclusive_scan_client = create_communicator(inclusive_scan_basename,
+    num_sites_arg(num_localities), this_site_arg(here));
+
+std::uint32_t value = here;
+
+hpx::future<std::uint32_t> overall_result = inclusive_scan(
+    inclusive_scan_client, value, std::plus<std::uint32_t>{});
+
+uint32_t r = overall_result.get();
+
+std::cout << "Locality " << here << " has value " << r << std::endl;
+
+
+

For num_localities = 2 this code will print the following message:

+
Locality 0 has value 0
+Locality 1 has value 1
+
+
+

HPX uses the function inclusive_scan to implement MPI_Scan. In more detail:

+
    +
  • hpx::get_num_localities(hpx::launch::sync) retrieves the number of localities, while +hpx::get_locality_id() returns the ID of the current locality.

  • +
  • The function create_communicator() is used to create a communicator called +inclusive_scan_client.

  • +
  • The inclusive_scan function is used to perform the exclusive scan operation +using the communicator inclusive_scan_client. std::plus<std::uint32_t>{} +specifies the binary associative operator to use for the scan. In this case, +it’s addition for summing values.

  • +
  • The get() member function of the overall_result future is used to wait for the result.

  • +
+
+
+
MPI_Reduce#
+

The following code performs a global reduce operation across all processes.

+

MPI code:

+
#include <iostream>
+#include <mpi.h>
+
+int main(int argc, char *argv[]) {
+    MPI_Init(&argc, &argv);
+
+    int num_processes;
+    MPI_Comm_size(MPI_COMM_WORLD, &num_processes);
+
+    int this_rank;
+    MPI_Comm_rank(MPI_COMM_WORLD, &this_rank);
+
+    int value = this_rank;
+
+    int result = 0;
+
+    // Perform the reduction operation
+    MPI_Reduce(&value, &result, 1, MPI_INT, MPI_SUM, 0, MPI_COMM_WORLD);
+
+    // Print the result for the root process (process 0)
+    if (this_rank == 0) {
+        std::cout << "Locality " << this_rank << " has value " << result
+                << std::endl;
+    }
+
+    MPI_Finalize();
+    return 0;
+}
+
+
+

HPX equivalent:

+
std::uint32_t num_localities = hpx::get_num_localities(hpx::launch::sync);
+std::uint32_t this_locality = hpx::get_locality_id();
+
+auto reduce_direct_client = create_communicator(reduce_direct_basename,
+    num_sites_arg(num_localities), this_site_arg(this_locality));
+
+std::uint32_t value = hpx::get_locality_id();
+
+if (this_locality == 0)
+{
+    hpx::future<std::uint32_t> overall_result = reduce_here(
+        reduce_direct_client, value, std::plus<std::uint32_t>{});
+
+    uint32_t r = overall_result.get();
+
+    std::cout << "Locality " << this_locality << " has value " << r
+              << std::endl;
+}
+else
+{
+    hpx::future<void> overall_result =
+        reduce_there(reduce_direct_client, std::move(value));
+    overall_result.get();
+}
+
+
+

This code will print the following message:

+
Locality 0 has value 1
+
+
+

HPX uses two functions to implement the functionality of MPI_Reduce: reduce_here and +reduce_there. reduce_here is gathering data from all localities to the locality +with ID 0 (root locality) and then performs the defined reduction operation. reduce_there +allows non-root localities to participate in the reduction operation by sending data to the +root locality. In more detail:

+
    +
  • hpx::get_num_localities(hpx::launch::sync) retrieves the number of localities, while +hpx::get_locality_id() returns the ID of the current locality.

  • +
  • The function create_communicator() is used to create a communicator called +reduce_direct_client.

  • +
  • If the current locality is the root (its ID is equal to 0):

    +
      +
    • The reduce_here function initiates a reduction operation with addition (std::plus) as the +reduction operator. The result is stored in overall_result.

    • +
    • The get() member function of the overall_result future is used to wait for the result.

    • +
    +
  • +
  • If the current locality is not the root:

    +
      +
    • The reduce_there initiates a remote reduction operation.

    • +
    • The get() member function of the overall_result future is used to wait for the remote +reduction operation to complete. This is done to ensure synchronization among localities.

    • +
    +
  • +
+
+
+
+
+

Building tests and examples#

+
+
Tests#
+

To build the tests:

+
$ cmake --build . --target tests
+
+
+

To control which tests to run use ctest:

+
    +
  • To run single tests, for example a test for for_loop:

  • +
+
$ ctest --output-on-failure -R tests.unit.modules.algorithms.algorithms.for_loop
+
+
+
    +
  • To run a whole group of tests:

  • +
+
$ ctest --output-on-failure -R tests.unit
+
+
+
+
+
Examples#
+
    +
  • To build (and install) all examples invoke:

  • +
+
$ cmake -DHPX_WITH_EXAMPLES=On .
+$ make examples
+$ make install
+
+
+
    +
  • To build the hello_world_1 example run:

  • +
+
$ make hello_world_1
+
+
+

HPX executables end up in the bin directory in your build directory. You +can now run hello_world_1 and should see the following output:

+
$ ./bin/hello_world_1
+Hello World!
+
+
+

You’ve just run an example which prints Hello World! from the HPX runtime. +The source for the example is in examples/quickstart/hello_world_1.cpp. The +hello_world_distributed example (also available in the +examples/quickstart directory) is a distributed hello world program, which is +described in Remote execution with actions. It provides a gentle introduction to +the distributed aspects of HPX.

+
+

Tip

+

Most build targets in HPX have two names: a simple name and +a hierarchical name corresponding to what type of example or +test the target is. If you are developing HPX it is often helpful to run +make help to get a list of available targets. For example, make help | +grep hello_world outputs the following:

+
... examples.quickstart.hello_world_2
+... hello_world_2
+... examples.quickstart.hello_world_1
+... hello_world_1
+... examples.quickstart.hello_world_distributed
+... hello_world_distributed
+
+
+

It is also possible to build, for instance, all quickstart examples using make +examples.quickstart.

+
+
+
+
+

Creating HPX projects#

+
+
Using HPX with pkg-config#
+
+
How to build HPX applications with pkg-config#
+

After you are done installing HPX, you should be able to build the following +program. It prints Hello World! on the locality you run it on.

+
// Including 'hpx/hpx_main.hpp' instead of the usual 'hpx/hpx_init.hpp' enables
+// to use the plain C-main below as the direct main HPX entry point.
+#include <hpx/hpx_main.hpp>
+#include <hpx/iostream.hpp>
+
+int main()
+{
+    // Say hello to the world!
+    hpx::cout << "Hello World!\n" << std::flush;
+    return 0;
+}
+
+
+

Copy the text of this program into a file called hello_world.cpp.

+

Now, in the directory where you put hello_world.cpp, issue the following +commands (where $HPX_LOCATION is the build directory or +CMAKE_INSTALL_PREFIX you used while building HPX):

+
$ export PKG_CONFIG_PATH=$PKG_CONFIG_PATH:$HPX_LOCATION/lib/pkgconfig
+$ c++ -o hello_world hello_world.cpp \
+   `pkg-config --cflags --libs hpx_application`\
+    -lhpx_iostreams -DHPX_APPLICATION_NAME=hello_world
+
+
+
+

Important

+

When using pkg-config with HPX, the pkg-config flags must go after the +-o flag.

+
+
+

Note

+

HPX libraries have different names in debug and release mode. If you want +to link against a debug HPX library, you need to use the _debug suffix +for the pkg-config name. That means instead of hpx_application or +hpx_component, you will have to use hpx_application_debug or +hpx_component_debug Moreover, all referenced HPX components need to +have an appended d suffix. For example, instead of -lhpx_iostreams you will +need to specify -lhpx_iostreamsd.

+
+
+

Important

+

If the HPX libraries are in a path that is not found by the dynamic +linker, you will need to add the path $HPX_LOCATION/lib to your linker search +path (for example LD_LIBRARY_PATH on Linux).

+
+

To test the program, type:

+
$ ./hello_world
+
+
+

which should print Hello World! and exit.

+
+
+
How to build HPX components with pkg-config#
+

Let’s try a more complex example involving an HPX component. An HPX +component is a class that exposes HPX actions. HPX components are compiled +into dynamically loaded modules called component libraries. Here’s the source +code:

+

hello_world_component.cpp

+
#include <hpx/config.hpp>
+#if !defined(HPX_COMPUTE_DEVICE_CODE)
+#include <hpx/iostream.hpp>
+#include "hello_world_component.hpp"
+
+#include <iostream>
+
+namespace examples { namespace server {
+    void hello_world::invoke()
+    {
+        hpx::cout << "Hello HPX World!" << std::endl;
+    }
+}}    // namespace examples::server
+
+HPX_REGISTER_COMPONENT_MODULE()
+
+typedef hpx::components::component<examples::server::hello_world>
+    hello_world_type;
+
+HPX_REGISTER_COMPONENT(hello_world_type, hello_world)
+
+HPX_REGISTER_ACTION(
+    examples::server::hello_world::invoke_action, hello_world_invoke_action)
+#endif
+
+
+

hello_world_component.hpp

+
#pragma once
+
+#include <hpx/config.hpp>
+#if !defined(HPX_COMPUTE_DEVICE_CODE)
+#include <hpx/hpx.hpp>
+#include <hpx/include/actions.hpp>
+#include <hpx/include/components.hpp>
+#include <hpx/include/lcos.hpp>
+#include <hpx/serialization.hpp>
+
+#include <utility>
+
+namespace examples { namespace server {
+    struct HPX_COMPONENT_EXPORT hello_world
+      : hpx::components::component_base<hello_world>
+    {
+        void invoke();
+        HPX_DEFINE_COMPONENT_ACTION(hello_world, invoke)
+    };
+}}    // namespace examples::server
+
+HPX_REGISTER_ACTION_DECLARATION(
+    examples::server::hello_world::invoke_action, hello_world_invoke_action)
+
+namespace examples {
+    struct hello_world
+      : hpx::components::client_base<hello_world, server::hello_world>
+    {
+        typedef hpx::components::client_base<hello_world, server::hello_world>
+            base_type;
+
+        hello_world(hpx::future<hpx::id_type>&& f)
+          : base_type(std::move(f))
+        {
+        }
+
+        hello_world(hpx::id_type&& f)
+          : base_type(std::move(f))
+        {
+        }
+
+        void invoke()
+        {
+            hpx::async<server::hello_world::invoke_action>(this->get_id())
+                .get();
+        }
+    };
+}    // namespace examples
+
+#endif
+
+
+

hello_world_client.cpp

+
#include <hpx/config.hpp>
+#if defined(HPX_COMPUTE_HOST_CODE)
+#include <hpx/wrap_main.hpp>
+
+#include "hello_world_component.hpp"
+
+int main()
+{
+    {
+        // Create a single instance of the component on this locality.
+        examples::hello_world client =
+            hpx::new_<examples::hello_world>(hpx::find_here());
+
+        // Invoke the component's action, which will print "Hello World!".
+        client.invoke();
+    }
+
+    return 0;
+}
+#endif
+
+
+

Copy the three source files above into three files (called +hello_world_component.cpp, hello_world_component.hpp and +hello_world_client.cpp, respectively).

+

Now, in the directory where you put the files, run the following command to +build the component library. (where $HPX_LOCATION is the build directory or +CMAKE_INSTALL_PREFIX you used while building HPX):

+
$ export PKG_CONFIG_PATH=$PKG_CONFIG_PATH:$HPX_LOCATION/lib/pkgconfig
+$ c++ -o libhpx_hello_world.so hello_world_component.cpp \
+   `pkg-config --cflags --libs hpx_component` \
+    -lhpx_iostreams -DHPX_COMPONENT_NAME=hpx_hello_world
+
+
+

Now pick a directory in which to install your HPX component libraries. For +this example, we’ll choose a directory named my_hpx_libs:

+
$ mkdir ~/my_hpx_libs
+$ mv libhpx_hello_world.so ~/my_hpx_libs
+
+
+
+

Note

+

HPX libraries have different names in debug and release mode. If you want +to link against a debug HPX library, you need to use the _debug suffix +for the pkg-config name. That means instead of hpx_application or +hpx_component you will have to use hpx_application_debug or +hpx_component_debug. Moreover, all referenced HPX components need to +have a appended d suffix, e.g. instead of -lhpx_iostreams you will +need to specify -lhpx_iostreamsd.

+
+
+

Important

+

If the HPX libraries are in a path that is not found by the dynamic linker. +You need to add the path $HPX_LOCATION/lib to your linker search path +(for example LD_LIBRARY_PATH on Linux).

+
+

Now, to build the application that uses this component (hello_world_client.cpp), +we do:

+
$ export PKG_CONFIG_PATH=$PKG_CONFIG_PATH:$HPX_LOCATION/lib/pkgconfig
+$ c++ -o hello_world_client hello_world_client.cpp \
+   ``pkg-config --cflags --libs hpx_application``\
+    -L${HOME}/my_hpx_libs -lhpx_hello_world -lhpx_iostreams
+
+
+
+

Important

+

When using pkg-config with HPX, the pkg-config flags must go after the +-o flag.

+
+

Finally, you’ll need to set your LD_LIBRARY_PATH before you can run the program. +To run the program, type:

+
$ export LD_LIBRARY_PATH="$LD_LIBRARY_PATH:$HOME/my_hpx_libs"
+$ ./hello_world_client
+
+
+

which should print Hello HPX World! and exit.

+
+
+
+
Using HPX with CMake-based projects#
+

In addition to the pkg-config support discussed on the previous pages, HPX +comes with full CMake support. In order to integrate HPX into existing or +new CMakeLists.txt, you can leverage the find_package command +integrated into CMake. Following, is a Hello World component example using CMake.

+

Let’s revisit what we have. We have three files that compose our example +application:

+
    +
  • hello_world_component.hpp

  • +
  • hello_world_component.cpp

  • +
  • hello_world_client.hpp

  • +
+

The basic structure to include HPX into your CMakeLists.txt is shown here:

+
# Require a recent version of cmake
+cmake_minimum_required(VERSION 3.18 FATAL_ERROR)
+
+# This project is C++ based.
+project(your_app CXX)
+
+# Instruct cmake to find the HPX settings
+find_package(HPX)
+
+
+

In order to have CMake find HPX, it needs to be told where to look for the +HPXConfig.cmake file that is generated when HPX is built or installed. It is +used by find_package(HPX) to set up all the necessary macros needed to use +HPX in your project. The ways to achieve this are:

+
    +
  • Set the HPX_DIR CMake variable to point to the directory containing the +HPXConfig.cmake script on the command line when you invoke CMake:

    +
    $ cmake -DHPX_DIR=$HPX_LOCATION/lib/cmake/HPX ...
    +
    +
    +

    where $HPX_LOCATION is the build directory or CMAKE_INSTALL_PREFIX you +used when building/configuring HPX.

    +
  • +
  • Set the CMAKE_PREFIX_PATH variable to the root directory of your HPX +build or install location on the command line when you invoke CMake:

    +
    $ cmake -DCMAKE_PREFIX_PATH=$HPX_LOCATION ...
    +
    +
    +

    The difference between CMAKE_PREFIX_PATH and HPX_DIR is that CMake +will add common postfixes, such as lib/cmake/<project, to the +CMAKE_PREFIX_PATH and search in these locations too. Note that if your +project uses HPX as well as other CMake-managed projects, the paths to the +locations of these multiple projects may be concatenated in the +CMAKE_PREFIX_PATH.

    +
  • +
  • The variables above may be set in the CMake GUI or curses ccmake interface +instead of the command line.

  • +
+

Additionally, if you wish to require HPX for your project, replace the +find_package(HPX) line with find_package(HPX REQUIRED).

+

You can check if HPX was successfully found with the HPX_FOUND CMake variable.

+
+
Using CMake targets#
+

The recommended way of setting up your targets to use HPX is to link to the +HPX::hpx CMake target:

+
target_link_libraries(hello_world_component PUBLIC HPX::hpx)
+
+
+

This requires that you have already created the target like this:

+
add_library(hello_world_component SHARED hello_world_component.cpp)
+target_include_directories(hello_world_component PUBLIC ${CMAKE_CURRENT_SOURCE_DIR})
+
+
+

When you link your library to the HPX::hpx CMake target, you will be able +use HPX functionality in your library. To use main() as the implicit entry +point in your application you must additionally link your application to the +CMake target HPX::wrap_main. This target is automatically linked to +executables if you are using the macros described below +(Using macros to create new targets). See Re-use the main() function as the main HPX entry point for more information on +implicitly using main() as the entry point.

+

Creating a component requires setting two additional compile definitions:

+
target_compile_options(hello_world_component
+  HPX_COMPONENT_NAME=hello_world
+  HPX_COMPONENT_EXPORTS)
+
+
+

Instead of setting these definitions manually you may link to the +HPX::component target, which sets HPX_COMPONENT_NAME to +hpx_<target_name>, where <target_name> is the target name of your +library. Note that these definitions should be PRIVATE to make sure these +definitions are not propagated transitively to dependent targets.

+

In addition to making your library a component you can make it a plugin. To do +so link to the HPX::plugin target. Similarly to HPX::component this will +set HPX_PLUGIN_NAME to hpx_<target_name>. This definition should also be +PRIVATE. Unlike regular shared libraries, plugins are loaded at runtime from +certain directories and will not be found without additional configuration. +Plugins should be installed into a directory containing only plugins. For +example, the plugins created by HPX itself are installed into the hpx +subdirectory in the library install directory (typically lib or lib64). +When using the HPX::plugin target you need to install your plugins into an +appropriate directory. You may also want to set the location of your plugin in +the build directory with the *_OUTPUT_DIRECTORY* CMake target properties to +be able to load the plugins in the build directory. Once you’ve set the install +or output directory of your plugin you need to tell your executable where to +find it at runtime. You can do this either by setting the environment variable +HPX_COMPONENT_PATHS or the ini setting hpx.component_paths (see +--hpx:ini) to the directory containing your plugin.

+
+
+
Using macros to create new targets#
+

In addition to the targets described above, HPX provides convenience macros +to hide optional boilerplate code that may be useful for your project. The link +to the targets described above. We recommend that you use the targets directly +whenever possible as they tend to compose better with other targets.

+

The macro for adding an HPX component is add_hpx_component. It can be +used in your CMakeLists.txt file like this:

+
# build your application using HPX
+add_hpx_component(hello_world
+    SOURCES hello_world_component.cpp
+    HEADERS hello_world_component.hpp
+    COMPONENT_DEPENDENCIES iostreams)
+
+
+
+

Note

+

add_hpx_component adds a _component suffix to the target name. In the +example above, a hello_world_component target will be created.

+
+

The available options to add_hpx_component are:

+
    +
  • SOURCES: The source files for that component

  • +
  • HEADERS: The header files for that component

  • +
  • DEPENDENCIES: Other libraries or targets this component depends on

  • +
  • COMPONENT_DEPENDENCIES: The components this component depends on

  • +
  • PLUGIN: Treats this component as a plugin-able library

  • +
  • COMPILE_FLAGS: Additional compiler flags

  • +
  • LINK_FLAGS: Additional linker flags

  • +
  • FOLDER: Adds the headers and source files to this Source Group folder

  • +
+
    +
  • EXCLUDE_FROM_ALL: Do not build this component as part of the all target

  • +
+

After adding the component, the way you add the executable is as follows:

+
# build your application using HPX
+add_hpx_executable(hello_world
+    SOURCES hello_world_client.cpp
+    COMPONENT_DEPENDENCIES hello_world)
+
+
+
+

Note

+

add_hpx_executable automatically adds a _component suffix to dependencies +specified in COMPONENT_DEPENDENCIES, meaning you can directly use the name given +when adding a component using add_hpx_component.

+
+

When you configure your application, all you need to do is set the HPX_DIR +variable to point to the installation of HPX.

+
+

Note

+

All library targets built with HPX are exported and readily available to be +used as arguments to target_link_libraries +in your targets. The HPX include directories are available with the +HPX_INCLUDE_DIRS CMake variable.

+
+
+
+
Using the HPX compiler wrapper hpxcxx#
+

The hpxcxx compiler wrapper helps to compile a HPX component, application, +or object file, based on the arguments passed to it.

+
$ hpxcxx [--exe=<APPLICATION_NAME> | --comp=<COMPONENT_NAME> | -c] FLAGS FILES
+
+
+

The hpxcxx command requires that either an application or a component is +built or -c flag is specified. If the build is against a debug build, the +-g is to be specified while building.

+
+Optional FLAGS# +
    +
  • -l <LIBRARY> | -l<LIBRARY>: Links <LIBRARY> to the build

  • +
  • -g: Specifies that the application or component build is against a debug +build

  • +
  • -rd: Sets release-with-debug-info option

  • +
  • -mr: Sets minsize-release option

  • +
+

All other flags (like -o OUTPUT_FILE) are directly passed to the underlying +C++ compiler.

+
+
+
+
Using macros to set up existing targets to use HPX#
+

In addition to the add_hpx_component and add_hpx_executable, you can use +the hpx_setup_target macro to have an already existing target to be used +with the HPX libraries:

+
hpx_setup_target(target)
+
+
+

Optional parameters are:

+
    +
  • EXPORT: Adds it to the CMake export list HPXTargets

  • +
  • INSTALL: Generates an install rule for the target

  • +
  • PLUGIN: Treats this component as a plugin-able library

  • +
  • TYPE: The type can be: EXECUTABLE, LIBRARY or COMPONENT

  • +
  • DEPENDENCIES: Other libraries or targets this component depends on

  • +
  • COMPONENT_DEPENDENCIES: The components this component depends on

  • +
  • COMPILE_FLAGS: Additional compiler flags

  • +
  • LINK_FLAGS: Additional linker flags

  • +
+

If you do not use CMake, you can still build against HPX, but you should refer +to the section on How to build HPX components with pkg-config.

+
+

Note

+

Since HPX relies on dynamic libraries, the dynamic linker needs to know +where to look for them. If HPX isn’t installed into a path that is +configured as a linker search path, external projects need to either set +RPATH or adapt LD_LIBRARY_PATH to point to where the HPX libraries +reside. In order to set RPATHs, you can include HPX_SetFullRPATH in +your project after all libraries you want to link against have been added. +Please also consult the CMake documentation here.

+
+
+
+
+
Using HPX with Makefile#
+

A basic project building with HPX is through creating makefiles. The process +of creating one can get complex depending upon the use of cmake parameter +HPX_WITH_HPX_MAIN (which defaults to ON).

+
+
How to build HPX applications with makefile#
+

If HPX is installed correctly, you should be able to build and run a simple +Hello World program. It prints Hello World! on the locality you +run it on.

+
// Including 'hpx/hpx_main.hpp' instead of the usual 'hpx/hpx_init.hpp' enables
+// to use the plain C-main below as the direct main HPX entry point.
+#include <hpx/hpx_main.hpp>
+#include <hpx/iostream.hpp>
+
+int main()
+{
+    // Say hello to the world!
+    hpx::cout << "Hello World!\n" << std::flush;
+    return 0;
+}
+
+
+

Copy the content of this program into a file called hello_world.cpp.

+

Now, in the directory where you put hello_world.cpp, create a Makefile. +Add the following code:

+
CXX=(CXX)  # Add your favourite compiler here or let makefile choose default.
+
+CXXFLAGS=-O3 -std=c++17
+
+Boost_ROOT=/path/to/boost
+Hwloc_ROOT=/path/to/hwloc
+Tcmalloc_ROOT=/path/to/tcmalloc
+HPX_ROOT=/path/to/hpx
+
+INCLUDE_DIRECTIVES=$(HPX_ROOT)/include $(Boost_ROOT)/include $(Hwloc_ROOT)/include
+
+LIBRARY_DIRECTIVES=-L$(HPX_ROOT)/lib $(HPX_ROOT)/lib/libhpx_init.a $(HPX_ROOT)/lib/libhpx.so $(Boost_ROOT)/lib/libboost_atomic-mt.so $(Boost_ROOT)/lib/libboost_filesystem-mt.so $(Boost_ROOT)/lib/libboost_program_options-mt.so $(Boost_ROOT)/lib/libboost_regex-mt.so $(Boost_ROOT)/lib/libboost_system-mt.so -lpthread $(Tcmalloc_ROOT)/libtcmalloc_minimal.so $(Hwloc_ROOT)/libhwloc.so -ldl -lrt
+
+LINK_FLAGS=$(HPX_ROOT)/lib/libhpx_wrap.a -Wl,-wrap=main  # should be left empty for HPX_WITH_HPX_MAIN=OFF
+
+hello_world: hello_world.o
+   $(CXX) $(CXXFLAGS) -o hello_world hello_world.o $(LIBRARY_DIRECTIVES) $(LINK_FLAGS)
+
+hello_world.o:
+   $(CXX) $(CXXFLAGS) -c -o hello_world.o hello_world.cpp $(INCLUDE_DIRECTIVES)
+
+
+
+

Important

+

LINK_FLAGS should be left empty if HPX_WITH_HPX_MAIN is set to OFF. +Boost in the above example is build with --layout=tagged. Actual Boost +flags may vary on your build of Boost.

+
+

To build the program, type:

+
$ make
+
+
+

A successful build should result in hello_world binary. To test, type:

+
$ ./hello_world
+
+
+
+
+
How to build HPX components with makefile#
+

Let’s try a more complex example involving an HPX component. An HPX +component is a class that exposes HPX actions. HPX components are compiled +into dynamically-loaded modules called component libraries. Here’s the source +code:

+

hello_world_component.cpp

+
#include <hpx/config.hpp>
+#if !defined(HPX_COMPUTE_DEVICE_CODE)
+#include <hpx/iostream.hpp>
+#include "hello_world_component.hpp"
+
+#include <iostream>
+
+namespace examples { namespace server {
+    void hello_world::invoke()
+    {
+        hpx::cout << "Hello HPX World!" << std::endl;
+    }
+}}    // namespace examples::server
+
+HPX_REGISTER_COMPONENT_MODULE()
+
+typedef hpx::components::component<examples::server::hello_world>
+    hello_world_type;
+
+HPX_REGISTER_COMPONENT(hello_world_type, hello_world)
+
+HPX_REGISTER_ACTION(
+    examples::server::hello_world::invoke_action, hello_world_invoke_action)
+#endif
+
+
+

hello_world_component.hpp

+
#pragma once
+
+#include <hpx/config.hpp>
+#if !defined(HPX_COMPUTE_DEVICE_CODE)
+#include <hpx/hpx.hpp>
+#include <hpx/include/actions.hpp>
+#include <hpx/include/components.hpp>
+#include <hpx/include/lcos.hpp>
+#include <hpx/serialization.hpp>
+
+#include <utility>
+
+namespace examples { namespace server {
+    struct HPX_COMPONENT_EXPORT hello_world
+      : hpx::components::component_base<hello_world>
+    {
+        void invoke();
+        HPX_DEFINE_COMPONENT_ACTION(hello_world, invoke)
+    };
+}}    // namespace examples::server
+
+HPX_REGISTER_ACTION_DECLARATION(
+    examples::server::hello_world::invoke_action, hello_world_invoke_action)
+
+namespace examples {
+    struct hello_world
+      : hpx::components::client_base<hello_world, server::hello_world>
+    {
+        typedef hpx::components::client_base<hello_world, server::hello_world>
+            base_type;
+
+        hello_world(hpx::future<hpx::id_type>&& f)
+          : base_type(std::move(f))
+        {
+        }
+
+        hello_world(hpx::id_type&& f)
+          : base_type(std::move(f))
+        {
+        }
+
+        void invoke()
+        {
+            hpx::async<server::hello_world::invoke_action>(this->get_id())
+                .get();
+        }
+    };
+}    // namespace examples
+
+#endif
+
+
+

hello_world_client.cpp

+
#include <hpx/config.hpp>
+#if defined(HPX_COMPUTE_HOST_CODE)
+#include <hpx/wrap_main.hpp>
+
+#include "hello_world_component.hpp"
+
+int main()
+{
+    {
+        // Create a single instance of the component on this locality.
+        examples::hello_world client =
+            hpx::new_<examples::hello_world>(hpx::find_here());
+
+        // Invoke the component's action, which will print "Hello World!".
+        client.invoke();
+    }
+
+    return 0;
+}
+#endif
+
+
+

Now, in the directory, create a Makefile. Add the following code:

+
CXX=(CXX)  # Add your favourite compiler here or let makefile choose default.
+
+CXXFLAGS=-O3 -std=c++17
+
+Boost_ROOT=/path/to/boost
+Hwloc_ROOT=/path/to/hwloc
+Tcmalloc_ROOT=/path/to/tcmalloc
+HPX_ROOT=/path/to/hpx
+
+INCLUDE_DIRECTIVES=$(HPX_ROOT)/include $(Boost_ROOT)/include $(Hwloc_ROOT)/include
+
+LIBRARY_DIRECTIVES=-L$(HPX_ROOT)/lib $(HPX_ROOT)/lib/libhpx_init.a $(HPX_ROOT)/lib/libhpx.so $(Boost_ROOT)/lib/libboost_atomic-mt.so $(Boost_ROOT)/lib/libboost_filesystem-mt.so $(Boost_ROOT)/lib/libboost_program_options-mt.so $(Boost_ROOT)/lib/libboost_regex-mt.so $(Boost_ROOT)/lib/libboost_system-mt.so -lpthread $(Tcmalloc_ROOT)/libtcmalloc_minimal.so $(Hwloc_ROOT)/libhwloc.so -ldl -lrt
+
+LINK_FLAGS=$(HPX_ROOT)/lib/libhpx_wrap.a -Wl,-wrap=main  # should be left empty for HPX_WITH_HPX_MAIN=OFF
+
+hello_world_client: libhpx_hello_world hello_world_client.o
+  $(CXX) $(CXXFLAGS) -o hello_world_client $(LIBRARY_DIRECTIVES) libhpx_hello_world $(LINK_FLAGS)
+
+hello_world_client.o: hello_world_client.cpp
+  $(CXX) $(CXXFLAGS) -o hello_world_client.o hello_world_client.cpp $(INCLUDE_DIRECTIVES)
+
+libhpx_hello_world: hello_world_component.o
+  $(CXX) $(CXXFLAGS) -o libhpx_hello_world hello_world_component.o $(LIBRARY_DIRECTIVES)
+
+hello_world_component.o: hello_world_component.cpp
+  $(CXX) $(CXXFLAGS) -c -o hello_world_component.o hello_world_component.cpp $(INCLUDE_DIRECTIVES)
+
+
+

To build the program, type:

+
$ make
+
+
+

A successful build should result in hello_world binary. To test, type:

+
$ ./hello_world
+
+
+
+

Note

+

Due to high variations in CMake flags and library dependencies, it is +recommended to build HPX applications and components with pkg-config +or CMakeLists.txt. Writing Makefile may result in broken builds if +due care is not taken. +pkg-config files and CMake systems are configured with CMake build of +HPX. Hence, they are stable when used together and provide better support overall.

+
+
+
+
+
+

Starting the HPX runtime#

+

In order to write an application that uses services from the HPX runtime +system, you need to initialize the HPX library by inserting certain calls +into the code of your application. Depending on your use case, this can be done +in 3 different ways:

+
    +
  • Minimally invasive: Re-use the main() function as the +main HPX entry point.

  • +
  • Balanced use case: Supply your own main HPX entry point +while blocking the main thread.

  • +
  • Most flexibility: Supply your own main HPX entry point +while avoiding blocking the main thread.

  • +
  • Suspend and resume: As above but suspend and resume +the HPX runtime to allow for other runtimes to be used.

  • +
+
+
Re-use the main() function as the main HPX entry point#
+

This method is the least intrusive to your code. However, it provides you with +the smallest flexibility in terms of initializing the HPX runtime system. The +following code snippet shows what a minimal HPX application using this +technique looks like:

+
#include <hpx/hpx_main.hpp>
+
+int main(int argc, char* argv[])
+{
+    return 0;
+}
+
+
+

The only change to your code you have to make is to include the file +hpx/hpx_main.hpp. In this case the function main() will be invoked as +the first HPX thread of the application. The runtime system will be +initialized behind the scenes before the function main() is executed and +will automatically stop after main() has returned. For this method to work +you must link your application to the CMake target HPX::wrap_main. This is +done automatically if you are using the provided macros +(Using macros to create new targets) to set up your application, but must be done +explicitly if you are using targets directly (Using CMake targets). +All HPX API functions can be used from within the main() function now.

+
+

Note

+

The function main() does not need to expect receiving argc and +argv as shown above, but could expose the signature int main(). This +is consistent with the usually allowed prototypes for the function main() +in C++ applications.

+
+

All command line arguments specific to HPX will still be processed by the +HPX runtime system as usual. However, those command line options will be +removed from the list of values passed to argc/argv of the function +main(). The list of values passed to main() will hold only the +commandline options that are not recognized by the HPX runtime system (see +the section HPX Command Line Options for more details on what options are recognized +by HPX).

+
+

Note

+

In this mode all one-letter shortcuts that are normally +available on the HPX command line are disabled (such as -t or -l see +HPX Command Line Options). This is done to minimize any possible interaction +between the command line options recognized by the HPX runtime system and +any command line options defined by the application.

+
+

The value returned from the function main() as shown above will be returned +to the operating system as usual.

+
+

Important

+

To achieve this seamless integration, the header file hpx/hpx_main.hpp +defines a macro:

+
#define main hpx_startup::user_main
+
+
+

which could result in unexpected behavior.

+
+
+

Important

+

To achieve this seamless integration, we use different implementations for +different operating systems. In case of Linux or macOS, the code present in +hpx_wrap.cpp is put into action. We hook into the system function in case +of Linux and provide alternate entry point in case of macOS. For other +operating systems we rely on a macro:

+
#define main hpx_startup::user_main
+
+
+

provided in the header file hpx/hpx_main.hpp. This implementation can +result in unexpected behavior.

+
+
+

Caution

+

We make use of an override variable include_libhpx_wrap in the header +file hpx/hpx_main.hpp to swiftly choose the function call stack at +runtime. Therefore, the header file should only be included in the main +executable. Including it in the components will result in multiple definition +of the variable.

+
+
+
+
Supply your own main HPX entry point while blocking the main thread#
+

With this method you need to provide an explicit main-thread function named +hpx_main at global scope. This function will be invoked as the main entry +point of your HPX application on the console locality only (this +function will be invoked as the first HPX thread of your application). All +HPX API functions can be used from within this function.

+

The thread executing the function hpx::init will block waiting for +the runtime system to exit. The value returned from hpx_main will be +returned from hpx::init after the runtime system has stopped.

+

The function hpx::finalize has to be called on one of the HPX +localities in order to signal that all work has been scheduled and the runtime +system should be stopped after the scheduled work has been executed.

+

This method of invoking HPX has the advantage of the user being able to decide +which version of hpx::init to call. This allows to pass +additional configuration parameters while initializing the HPX runtime system.

+
#include <hpx/hpx_init.hpp>
+
+int hpx_main(int argc, char* argv[])
+{
+    // Any HPX application logic goes here...
+    return hpx::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    // Initialize HPX, run hpx_main as the first HPX thread, and
+    // wait for hpx::finalize being called.
+    return hpx::init(argc, argv);
+}
+
+
+
+

Note

+

The function hpx_main does not need to expect receiving argc/argv +as shown above, but could expose one of the following signatures:

+
int hpx_main();
+int hpx_main(int argc, char* argv[]);
+int hpx_main(hpx::program_options::variables_map& vm);
+
+
+

This is consistent with (and extends) the usually allowed prototypes for the +function main() in C++ applications.

+
+

The header file to include for this method of using HPX is +hpx/hpx_init.hpp.

+

There are many additional overloads of hpx::init available, such as +the ability to provide your own entry-point function instead of hpx_main. +Please refer to the function documentation for more details (see: hpx/hpx_init.hpp).

+
+
+
Supply your own main HPX entry point while avoiding blocking the main thread#
+

With this method you need to provide an explicit main thread function named +hpx_main at global scope. This function will be invoked as the main entry +point of your HPX application on the console locality only (this +function will be invoked as the first HPX thread of your application). All +HPX API functions can be used from within this function.

+

The thread executing the function hpx::start will not block +waiting for the runtime system to exit, but will return immediately. +The function hpx::finalize has to be called on one of the HPX +localities in order to signal that all work has been scheduled and the runtime +system should be stopped after the scheduled work has been executed.

+

This method of invoking HPX is useful for applications where the main thread +is used for special operations, such a GUIs. The function hpx::stop +can be used to wait for the HPX runtime system to exit and should at least be +used as the last function called in main(). The value returned from +hpx_main will be returned from hpx::stop after the runtime +system has stopped.

+
#include <hpx/hpx_start.hpp>
+
+int hpx_main(int argc, char* argv[])
+{
+    // Any HPX application logic goes here...
+    return hpx::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    // Initialize HPX, run hpx_main.
+    hpx::start(argc, argv);
+
+    // ...Execute other code here...
+
+    // Wait for hpx::finalize being called.
+    return hpx::stop();
+}
+
+
+
+

Note

+

The function hpx_main does not need to expect receiving argc/argv +as shown above, but could expose one of the following signatures:

+
int hpx_main();
+int hpx_main(int argc, char* argv[]);
+int hpx_main(hpx::program_options::variables_map& vm);
+
+
+

This is consistent with (and extends) the usually allowed prototypes for the +function main() in C++ applications.

+
+

The header file to include for this method of using HPX is +hpx/hpx_start.hpp.

+

There are many additional overloads of hpx::start available, such as +the option for users to provide their own entry point function instead of hpx_main. +Please refer to the function documentation for more details (see: +hpx/hpx_start.hpp).

+
+
+
Supply your own explicit startup function as the main HPX entry point#
+

There is also a way to specify any function (besides hpx_main) to be used as +the main entry point for your HPX application:

+
#include <hpx/hpx_init.hpp>
+
+int application_entry_point(int argc, char* argv[])
+{
+    // Any HPX application logic goes here...
+    return hpx::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    // Initialize HPX, run application_entry_point as the first HPX thread,
+    // and wait for hpx::finalize being called.
+    return hpx::init(&application_entry_point, argc, argv);
+}
+
+
+
+

Note

+

The function supplied to hpx::init must have one of the following +prototypes:

+
+

int application_entry_point(int argc, char* argv[]); +int application_entry_point(hpx::program_options::variables_map& vm);

+
+
+
+

Note

+

If nullptr is used as the function argument, HPX will not run any +startup function on this locality.

+
+
+
+
Suspending and resuming the HPX runtime#
+

In some applications it is required to combine HPX with other runtimes. To +support this use case, HPX provides two functions: hpx::suspend and +hpx::resume. hpx::suspend is a blocking call which will +wait for all scheduled tasks to finish executing and then put the thread pool OS +threads to sleep. hpx::resume simply wakes up the sleeping threads +so that they are ready to accept new work. hpx::suspend and +hpx::resume can be found in the header hpx/hpx_suspend.hpp.

+
#include <hpx/hpx_start.hpp>
+#include <hpx/hpx_suspend.hpp>
+
+int main(int argc, char* argv[])
+{
+
+   // Initialize HPX, don't run hpx_main
+    hpx::start(nullptr, argc, argv);
+
+    // Schedule a function on the HPX runtime
+    hpx::post(&my_function, ...);
+
+    // Wait for all tasks to finish, and suspend the HPX runtime
+    hpx::suspend();
+
+    // Execute non-HPX code here
+
+    // Resume the HPX runtime
+    hpx::resume();
+
+    // Schedule more work on the HPX runtime
+
+    // hpx::finalize has to be called from the HPX runtime before hpx::stop
+    hpx::post([]() { hpx::finalize(); });
+    return hpx::stop();
+}
+
+
+
+

Note

+

hpx::suspend does not wait for hpx::finalize to be +called. Only call hpx::finalize when you wish to fully stop the +HPX runtime.

+
+
+

Warning

+
+
hpx::suspend only waits for local tasks, i.e. tasks on the

current locality, to finish executing. When using hpx::suspend +in a multi-locality scenario the user is responsible for ensuring that any +work required from other localities has also finished.

+
+
+
+

HPX also supports suspending individual thread pools and threads. For details +on how to do that, see the documentation for hpx::threads::thread_pool_base.

+
+
Automatically suspending worker threads#
+

The previous method guarantees that the worker threads are suspended when you +ask for it and that they stay suspended. An alternative way to achieve the same +effect is to tweak how quickly HPX suspends its worker threads when they run +out of work. The following configuration values make sure that HPX idles very +quickly:

+
hpx.max_idle_backoff_time = 1000
+hpx.max_idle_loop_count = 0
+
+
+

They can be set on the command line using +--hpx:ini=hpx.max_idle_backoff_time=1000 and +--hpx:ini=hpx.max_idle_loop_count=0. See Launching and configuring HPX applications +for more details on how to set configuration parameters.

+

After setting idling parameters the previous example could now be written like +this instead:

+
#include <hpx/hpx_start.hpp>
+
+int main(int argc, char* argv[])
+{
+
+   // Initialize HPX, don't run hpx_main
+    hpx::start(nullptr, argc, argv);
+
+    // Schedule some functions on the HPX runtime
+    // NOTE: run_as_hpx_thread blocks until completion.
+    hpx::run_as_hpx_thread(&my_function, ...);
+    hpx::run_as_hpx_thread(&my_other_function, ...);
+
+    // hpx::finalize has to be called from the HPX runtime before hpx::stop
+    hpx::post([]() { hpx::finalize(); });
+    return hpx::stop();
+}
+
+
+

In this example each call to hpx::run_as_hpx_thread acts as a +“parallel region”.

+
+
+
+
Working of hpx_main.hpp#
+

In order to initialize HPX from main(), we make use of linker tricks.

+

It is implemented differently for different operating systems. The method of +implementation is as follows:

+
    +
  • Linux: Using linker --wrap option.

  • +
  • Mac OSX: Using the linker -e option.

  • +
  • Windows: Using #define main +hpx_startup::user_main

  • +
+
+
Linux implementation#
+

We make use of the Linux linker ld‘s --wrap option to wrap the +main() function. This way any calls to main() are redirected to our own +implementation of main. It is here that we check for the existence of +hpx_main.hpp by making use of a shadow variable include_libhpx_wrap. The +value of this variable determines the function stack at runtime.

+

The implementation can be found in libhpx_wrap.a.

+
+

Important

+

It is necessary that hpx_main.hpp be not included more than once. +Multiple inclusions can result in multiple definition of +include_libhpx_wrap.

+
+
+
+
Mac OSX implementation#
+

Here we make use of yet another linker option -e to change the entry point +to our custom entry function initialize_main. We initialize the HPX +runtime system from this function and call main from the initialized system. We +determine the function stack at runtime by making use of the shadow variable +include_libhpx_wrap.

+

The implementation can be found in libhpx_wrap.a.

+
+

Important

+

It is necessary that hpx_main.hpp be not included more than once. +Multiple inclusions can result in multiple definition of +include_libhpx_wrap.

+
+
+
+
Windows implementation#
+

We make use of a macro #define main hpx_startup::user_main to take care of +the initializations.

+

This implementation could result in unexpected behaviors.

+
+
+
+
+

Launching and configuring HPX applications#

+
+
Configuring HPX applications#
+

All HPX applications can be configured using special command line options +and/or using special configuration files. This section describes the available +options, the configuration file format, and the algorithm used to locate +possible predefined configuration files. Additionally, this section describes the +defaults assumed if no external configuration information is supplied.

+

During startup any HPX application applies a predefined search pattern to +locate one or more configuration files. All found files will be read and merged +in the sequence they are found into one single internal database holding all +configuration properties. This database is used during the execution of the +application to configure different aspects of the runtime system.

+

In addition to the ini files, any application can supply its own configuration +files, which will be merged with the configuration database as well. Moreover, +the user can specify additional configuration parameters on the command line +when executing an application. The HPX runtime system will merge all command +line configuration options (see the description of the --hpx:ini, +--hpx:config, and --hpx:app-config command line options).

+
+
The HPX ini file format#
+

All HPX applications can be configured using a special file format that is +similar to the well-known Windows INI file format. This is a structured text format +that allows users to group key/value pairs (properties) into sections. The basic element +contained in an ini file is the property. Every property has a name and a +value, delimited by an equal sign '='. The name appears to the left of the +equal sign:

+
name=value
+
+
+

The value may contain equal signs as only the first '=' character +is interpreted as the delimiter between name and value. Whitespace before +the name, after the value and immediately before and after the delimiting equal +sign is ignored. Whitespace inside the value is retained.

+

Properties may be grouped into arbitrarily named sections. The section name +appears on a line by itself, in square brackets. All properties after the section +declaration are associated with that section. There is no explicit “end of section” +delimiter; sections end at the next section declaration or the end of the file:

+
[section]
+
+
+

In HPX sections can be nested. A nested section has a name composed of +all section names it is embedded in. The section names are concatenated using +a dot '.':

+
[outer_section.inner_section]
+
+
+

Here, inner_section is logically nested within outer_section.

+

It is possible to use the full section name concatenated with the property +name to refer to a particular property. For example, in:

+
[a.b.c]
+d = e
+
+
+

the property value of d can be referred to as a.b.c.d=e.

+

In HPX ini files can contain comments. Hash signs '#' at the beginning +of a line indicate a comment. All characters starting with '#' until the +end of the line are ignored.

+

If a property with the same name is reused inside a section, the second +occurrence of this property name will override the first occurrence (discard the +first value). Duplicate sections simply merge their properties together, as if +they occurred contiguously.

+

In HPX ini files a property value ${FOO:default} will use the environmental +variable FOO to extract the actual value if it is set and default otherwise. +No default has to be specified. Therefore, ${FOO} refers to the environmental +variable FOO. If FOO is not set or empty, the overall expression will evaluate +to an empty string. A property value $[section.key:default] refers to the value +held by the property section.key if it exists and default otherwise. No +default has to be specified. Therefore $[section.key] refers to the property +section.key. If the property section.key is not set or empty, the overall +expression will evaluate to an empty string.

+
+

Note

+

Any property $[section.key:default] is evaluated whenever it is queried +and not when the configuration data is initialized. This allows for lazy +evaluation and relaxes initialization order of different sections. The only +exception are recursive property values, e.g., values referring to the very +key they are associated with. Those property values are evaluated at +initialization time to avoid infinite recursion.

+
+
+
+
Built-in default configuration settings#
+

During startup any HPX application applies a predefined search pattern to +locate one or more configuration files. All found files will be read and merged +in the sequence they are found into one single internal data structure holding +all configuration properties.

+

As a first step the internal configuration database is filled with a set of +default configuration properties. Those settings are described on a section +by section basis below.

+
+

Note

+

You can print the default configuration settings used for an executable +by specifying the command line option --hpx:dump-config.

+
+
+The system configuration section# +
[system]
+pid = <process-id>
+prefix = <current prefix path of core HPX library>
+executable = <current prefix path of executable>
+
+
+ ++++ + + + + + + + + + + + + + + +

Property

Description

system.pid

This is initialized to store the current OS-process id of the application +instance.

system.prefix

This is initialized to the base directory HPX has been loaded from.

system.executable_prefix

This is initialized to the base directory the current executable has been +loaded from.

+
+
+The HPX configuration section# +
[hpx]
+location = ${HPX_LOCATION:$[system.prefix]}
+component_path = $[hpx.location]/lib/hpx:$[system.executable_prefix]/lib/hpx:$[system.executable_prefix]/../lib/hpx
+master_ini_path = $[hpx.location]/share/hpx-<version>:$[system.executable_prefix]/share/hpx-<version>:$[system.executable_prefix]/../share/hpx-<version>
+ini_path = $[hpx.master_ini_path]/ini
+os_threads = 1
+cores = all
+localities = 1
+program_name =
+cmd_line =
+lock_detection = ${HPX_LOCK_DETECTION:0}
+throw_on_held_lock = ${HPX_THROW_ON_HELD_LOCK:1}
+minimal_deadlock_detection = <debug>
+spinlock_deadlock_detection = <debug>
+spinlock_deadlock_detection_limit = ${HPX_SPINLOCK_DEADLOCK_DETECTION_LIMIT:1000000}
+max_background_threads = ${HPX_MAX_BACKGROUND_THREADS:$[hpx.os_threads]}
+max_idle_loop_count = ${HPX_MAX_IDLE_LOOP_COUNT:<hpx_idle_loop_count_max>}
+max_busy_loop_count = ${HPX_MAX_BUSY_LOOP_COUNT:<hpx_busy_loop_count_max>}
+max_idle_backoff_time = ${HPX_MAX_IDLE_BACKOFF_TIME:<hpx_idle_backoff_time_max>}
+exception_verbosity = ${HPX_EXCEPTION_VERBOSITY:2}
+trace_depth = ${HPX_TRACE_DEPTH:20}
+handle_signals = ${HPX_HANDLE_SIGNALS:1}
+handle_failed_new = ${HPX_HANDLE_FAILED_NEW:1}
+
+[hpx.stacks]
+small_size = ${HPX_SMALL_STACK_SIZE:<hpx_small_stack_size>}
+medium_size = ${HPX_MEDIUM_STACK_SIZE:<hpx_medium_stack_size>}
+large_size = ${HPX_LARGE_STACK_SIZE:<hpx_large_stack_size>}
+huge_size = ${HPX_HUGE_STACK_SIZE:<hpx_huge_stack_size>}
+use_guard_pages = ${HPX_THREAD_GUARD_PAGE:1}
+
+
+ ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +

Property

Description

hpx.location

This is initialized to the id of the locality this application +instance is running on.

hpx.component_path

Duplicates are discarded. +This property can refer to a list of directories separated by ':' +(Linux, Android, and MacOS) or by ';' (Windows).

hpx.master_ini_path

This is initialized to the list of default paths of the main hpx.ini +configuration files. This property can refer to a list of directories +separated by ':' (Linux, Android, and MacOS) or using ';' +(Windows).

hpx.ini_path

This is initialized to the default path where HPX will look for more +ini configuration files. This property can refer to a list of directories +separated by ':' (Linux, Android, and MacOS) or using ';' +(Windows).

hpx.os_threads

This setting reflects the number of OS threads used for running +HPX threads. Defaults to number of detected cores (not hyperthreads/PUs).

hpx.cores

This setting reflects the number of cores used for running +HPX threads. Defaults to number of detected cores (not hyperthreads/PUs).

hpx.localities

This setting reflects the number of localities the application is running +on. Defaults to 1.

hpx.program_name

This setting reflects the program name of the application instance. +Initialized from the command line argv[0].

hpx.cmd_line

This setting reflects the actual command line used to launch this +application instance.

hpx.lock_detection

This setting verifies that no locks are being held while a HPX thread +is suspended. This setting is applicable only if +HPX_WITH_VERIFY_LOCKS is set during configuration in CMake.

hpx.throw_on_held_lock

This setting causes an exception if during lock detection at least one +lock is being held while a HPX thread is suspended. This setting is +applicable only if HPX_WITH_VERIFY_LOCKS is set during configuration +in CMake. This setting has no effect if hpx.lock_detection=0.

hpx.minimal_deadlock_detection

This setting enables support for minimal deadlock detection for +HPX threads. By default this is set to 1 (for Debug builds) or to +0 (for Release, RelWithDebInfo, RelMinSize builds). This setting is +effective only if HPX_WITH_THREAD_DEADLOCK_DETECTION is set during +configuration in CMake.

hpx.spinlock_deadlock_detection

This setting verifies that spinlocks don’t spin longer than specified +using the hpx.spinlock_deadlock_detection_limit. This setting is +applicable only if HPX_WITH_SPINLOCK_DEADLOCK_DETECTION is set during +configuration in CMake. By default this is set to 1 (for Debug +builds) or to 0 (for Release, RelWithDebInfo, RelMinSize builds).

hpx.spinlock_deadlock_detection_limit

This setting specifies the upper limit of the allowed number of spins that +spinlocks are allowed to perform. This setting is applicable only if +HPX_WITH_SPINLOCK_DEADLOCK_DETECTION is set during configuration in +CMake. By default this is set to 1000000.

hpx.max_background_threads

This setting defines the number of threads in the scheduler, which are +used to execute background work. By default this is the same as the +number of cores used for the scheduler.

hpx.max_idle_loop_count

By default this is defined by the preprocessor constant +HPX_IDLE_LOOP_COUNT_MAX. This is an internal setting that you should +change only if you know exactly what you are doing.

hpx.max_busy_loop_count

This setting defines the maximum value of the busy-loop counter in the +scheduler. By default this is defined by the preprocessor constant +HPX_BUSY_LOOP_COUNT_MAX. This is an internal setting that you should +change only if you know exactly what you are doing.

hpx.max_idle_backoff_time

This setting defines the maximum time (in milliseconds) for the scheduler +to sleep after being idle for hpx.max_idle_loop_count iterations. +This setting is applicable only if +HPX_WITH_THREAD_MANAGER_IDLE_BACKOFF is set during configuration in +CMake. By default this is defined by the preprocessor constant +HPX_IDLE_BACKOFF_TIME_MAX. This is an internal setting that you +should change only if you know exactly what you are doing.

hpx.exception_verbosity

This setting defines the verbosity of exceptions. Valid values are +integers. A setting of 2 or higher prints all available information. +A setting of 1 leaves out the build configuration and environment +variables. A setting of 0 or lower prints only the description of the +thrown exception and the file name, function, and line number where the +exception was thrown. The default value is 2 or the value of the +environment variable HPX_EXCEPTION_VERBOSITY.

hpx.trace_depth

This setting defines the number of stack-levels printed in generated +stack backtraces. This defaults to 20, but can be changed using the +cmake HPX_WITH_THREAD_BACKTRACE_DEPTH configuration setting.

hpx.handle_signals

This setting defines whether HPX will register signal handlers that will +print the configuration information (stack backtrace, system information, +etc.) whenever a signal is raised. The default is 1. Setting this +value to 0 can be useful in cases when generating a core-dump on +segmentation faults or similar signals is desired.

hpx.handle_failed_new

This setting defines whether HPX will register a handler for failed +allocationsthat will print the configuration information +(stack backtrace, system information, etc.) whenever an allocation fails. +The default is 1. Setting this value to 0 can be useful in cases +when generating a core-dump on segmentation faults or similar signals +is desired.

hpx.stacks.small_size

This is initialized to the small stack size to be used by HPX threads. +Set by default to the value of the compile time preprocessor constant +HPX_SMALL_STACK_SIZE (defaults to 0x8000). This value is used for +all HPX threads by default, except for the thread running hpx_main +(which runs on a large stack).

hpx.stacks.medium_size

This is initialized to the medium stack size to be used by HPX threads. +Set by default to the value of the compile time preprocessor constant +HPX_MEDIUM_STACK_SIZE (defaults to 0x20000).

hpx.stacks.large_size

This is initialized to the large stack size to be used by HPX threads. +Set by default to the value of the compile time preprocessor constant +HPX_LARGE_STACK_SIZE (defaults to 0x200000). This setting is used +by default for the thread running hpx_main only.

hpx.stacks.huge_size

This is initialized to the huge stack size to be used by HPX threads. +Set by default to the value of the compile time preprocessor constant +HPX_HUGE_STACK_SIZE (defaults to 0x2000000).

hpx.stacks.use_guard_pages

This entry controls whether the coroutine library will generate stack +guard pages or not. This entry is applicable on Linux only and only if +the HPX_USE_GENERIC_COROUTINE_CONTEXT option is not enabled and the +HPX_WITH_THREAD_GUARD_PAGE is set to 1 while configuring the build +system. It is set by default to 1.

+
+
+The hpx.threadpools configuration section# +
[hpx.threadpools]
+io_pool_size = ${HPX_NUM_IO_POOL_SIZE:2}
+parcel_pool_size = ${HPX_NUM_PARCEL_POOL_SIZE:2}
+timer_pool_size = ${HPX_NUM_TIMER_POOL_SIZE:2}
+
+
+ ++++ + + + + + + + + + + + + + + +

Property

Description

hpx.threadpools.io_pool_size

The value of this property defines the number of OS threads created for +the internal I/O thread pool.

hpx.threadpools.parcel_pool_size

The value of this property defines the number of OS threads created for +the internal parcel thread pool.

hpx.threadpools.timer_pool_size

The value of this property defines the number of OS threads created for +the internal timer thread pool.

+
+
+The hpx.thread_queue configuration section# +
+

Important

+

These are the setting control internal values used by the thread scheduling queues +in the HPX scheduler. You should not modify these settings unless you know +exactly what you are doing.

+
+
[hpx.thread_queue]
+min_tasks_to_steal_pending = ${HPX_THREAD_QUEUE_MIN_TASKS_TO_STEAL_PENDING:0}
+min_tasks_to_steal_staged = ${HPX_THREAD_QUEUE_MIN_TASKS_TO_STEAL_STAGED:0}
+min_add_new_count = ${HPX_THREAD_QUEUE_MIN_ADD_NEW_COUNT:10}
+max_add_new_count = ${HPX_THREAD_QUEUE_MAX_ADD_NEW_COUNT:10}
+max_delete_count = ${HPX_THREAD_QUEUE_MAX_DELETE_COUNT:1000}
+
+
+ ++++ + + + + + + + + + + + + + + + + + + + + +

Property

Description

hpx.thread_queue.min_tasks_to_steal_pending

The value of this property defines the number of pending HPX threads +that have to be available before neighboring cores are allowed to steal +work. The default is to allow stealing always.

hpx.thread_queue.min_tasks_to_steal_staged

The value of this property defines the number of staged HPX tasks that +need to be available before neighboring cores are allowed to steal work. +The default is to allow stealing always.

hpx.thread_queue.min_add_new_count

The value of this property defines the minimal number of tasks to be +converted into HPX threads whenever the thread queues for a core have +run empty.

hpx.thread_queue.max_add_new_count

The value of this property defines the maximal number of tasks to be +converted into HPX threads whenever the thread queues for a core have +run empty.

hpx.thread_queue.max_delete_count

The value of this property defines the number of terminated HPX +threads to discard during each invocation of the corresponding function.

+
+
+The hpx.components configuration section# +
[hpx.components]
+load_external = ${HPX_LOAD_EXTERNAL_COMPONENTS:1}
+
+
+ ++++ + + + + + + + + +

Property

Description

hpx.components.load_external

This entry defines whether external components will be loaded on this +locality. This entry is normally set to 1, and usually there is +no need to directly change this value. It is automatically set to 0 for +a dedicated AGAS server locality.

+

Additionally, the section hpx.components will be populated with the +information gathered from all found components. The information loaded for each +of the components will contain at least the following properties:

+
[hpx.components.<component_instance_name>]
+name = <component_name>
+path = <full_path_of_the_component_module>
+enabled = $[hpx.components.load_external]
+
+
+ ++++ + + + + + + + + + + + + + + +

Property

Description

hpx.components.<component_instance_name>.name

This is the name of a component, usually the same as the second argument +to the macro used while registering the component with +HPX_REGISTER_COMPONENT. Set by the component factory.

hpx.components.<component_instance_name>.path

This is either the full path file name of the component module or the +directory the component module is located in. In this case, the component +module name will be derived from the property +hpx.components.<component_instance_name>.name. Set by the component +factory.

hpx.components.<component_instance_name>.enabled

This setting explicitly enables or disables the component. This is an +optional property. HPX assumes that the component is enabled if it is +not defined.

+

The value for <component_instance_name> is usually the same as for the +corresponding name property. However, generally it can be defined to any +arbitrary instance name. It is used to distinguish between different ini +sections, one for each component.

+
+
+The hpx.parcel configuration section# +
[hpx.parcel]
+address = ${HPX_PARCEL_SERVER_ADDRESS:<hpx_initial_ip_address>}
+port = ${HPX_PARCEL_SERVER_PORT:<hpx_initial_ip_port>}
+bootstrap = ${HPX_PARCEL_BOOTSTRAP:<hpx_parcel_bootstrap>}
+max_connections = ${HPX_PARCEL_MAX_CONNECTIONS:<hpx_parcel_max_connections>}
+max_connections_per_locality = ${HPX_PARCEL_MAX_CONNECTIONS_PER_LOCALITY:<hpx_parcel_max_connections_per_locality>}
+max_message_size = ${HPX_PARCEL_MAX_MESSAGE_SIZE:<hpx_parcel_max_message_size>}
+max_outbound_message_size = ${HPX_PARCEL_MAX_OUTBOUND_MESSAGE_SIZE:<hpx_parcel_max_outbound_message_size>}
+array_optimization = ${HPX_PARCEL_ARRAY_OPTIMIZATION:1}
+zero_copy_optimization = ${HPX_PARCEL_ZERO_COPY_OPTIMIZATION:$[hpx.parcel.array_optimization]}
+zero_copy_receive_optimization = ${HPX_PARCEL_ZERO_COPY_RECEIVE_OPTIMIZATION:$[hpx.parcel.array_optimization]}
+async_serialization = ${HPX_PARCEL_ASYNC_SERIALIZATION:1}
+message_handlers = ${HPX_PARCEL_MESSAGE_HANDLERS:0}
+
+
+ ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +

Property

Description

hpx.parcel.address

This property defines the default IP address to be used for the parcel +layer to listen to. This IP address will be used as long as no other +values are specified (for instance, using the --hpx:hpx command +line option). The expected format is any valid IP address or domain name +format that can be resolved into an IP address. The default depends on +the compile time preprocessor constant HPX_INITIAL_IP_ADDRESS +("127.0.0.1").

hpx.parcel.port

This property defines the default IP port to be used for the parcel layer +to listen to. This IP port will be used as long as no other values are +specified (for instance using the --hpx:hpx command line +option). The default depends on the compile time preprocessor +constant HPX_INITIAL_IP_PORT (7910).

hpx.parcel.bootstrap

This property defines which parcelport type should be used during +application bootstrap. The default depends on the compile time +preprocessor constant HPX_PARCEL_BOOTSTRAP ("tcp").

hpx.parcel.max_connections

This property defines how many network connections between different +localities are overall kept alive by each locality. The +default depends on the compile time preprocessor constant +HPX_PARCEL_MAX_CONNECTIONS (512).

hpx.parcel.max_connections_per_locality

This property defines the maximum number of network connections that one +locality will open to another locality. The default depends +on the compile time preprocessor constant +HPX_PARCEL_MAX_CONNECTIONS_PER_LOCALITY (4).

hpx.parcel.max_message_size

This property defines the maximum allowed message size that will be +transferrable through the parcel layer. The default depends on the +compile time preprocessor constant HPX_PARCEL_MAX_MESSAGE_SIZE +(1000000000 bytes).

hpx.parcel.max_outbound_message_size

This property defines the maximum allowed outbound coalesced message size +that will be transferrable through the parcel layer. The default depends +on the compile time preprocessor constant +HPX_PARCEL_MAX_OUTBOUND_MESSAGE_SIZE (1000000 bytes).

hpx.parcel.array_optimization

This property defines whether this locality is allowed to utilize +array optimizations during serialization of parcel data. The default is +1.

hpx.parcel.zero_copy_optimization

This property defines whether this locality is allowed to utilize +zero copy optimizations during serialization of parcel data. The default +is the same value as set for hpx.parcel.array_optimization.

hpx.parcel.zero_copy_receive_optimization

This property defines whether this locality is allowed to utilize +zero copy optimizations on the receiving end during de-serialization of +parcel data. The default is the same value as set for +hpx.parcel.zero_copy_optimization.

hpx.parcel.zero_copy_serialization_threshold

This property defines the threshold value (in bytes) starting at which the +serialization layer will apply zero-copy optimizations for serialized +entities. The default value is defined by the preprocessor constant +HPX_ZERO_COPY_SERIALIZATION_THRESHOLD.

hpx.parcel.async_serialization

This property defines whether this locality is allowed to spawn a +new thread for serialization (this is both for encoding and decoding +parcels). The default is 1.

hpx.parcel.message_handlers

This property defines whether message handlers are loaded. The default is +0.

hpx.parcel.max_background_threads

This property defines how many cores should be used to perform background +operations. The default is -1 (all cores).

+

The following settings relate to the TCP/IP parcelport.

+
[hpx.parcel.tcp]
+enable = ${HPX_HAVE_PARCELPORT_TCP:$[hpx.parcel.enabled]}
+array_optimization = ${HPX_PARCEL_TCP_ARRAY_OPTIMIZATION:$[hpx.parcel.array_optimization]}
+zero_copy_optimization = ${HPX_PARCEL_TCP_ZERO_COPY_OPTIMIZATION:$[hpx.parcel.zero_copy_optimization]}
+zero_copy_receive_optimization = ${HPX_PARCEL_TCP_ZERO_COPY_RECEIVE_OPTIMIZATION:$[hpx.parcel.zero_copy_receive_optimization]}
+zero_copy_serialization_threshold =  ${HPX_PARCEL_TCP_ZERO_COPY_SERIALIZATION_THRESHOLD:$[hpx.parcel.zero_copy_serialization_threshold]}
+async_serialization = ${HPX_PARCEL_TCP_ASYNC_SERIALIZATION:$[hpx.parcel.async_serialization]}
+parcel_pool_size = ${HPX_PARCEL_TCP_PARCEL_POOL_SIZE:$[hpx.threadpools.parcel_pool_size]}
+max_connections =  ${HPX_PARCEL_TCP_MAX_CONNECTIONS:$[hpx.parcel.max_connections]}
+max_connections_per_locality = ${HPX_PARCEL_TCP_MAX_CONNECTIONS_PER_LOCALITY:$[hpx.parcel.max_connections_per_locality]}
+max_message_size =  ${HPX_PARCEL_TCP_MAX_MESSAGE_SIZE:$[hpx.parcel.max_message_size]}
+max_outbound_message_size =  ${HPX_PARCEL_TCP_MAX_OUTBOUND_MESSAGE_SIZE:$[hpx.parcel.max_outbound_message_size]}
+max_background_threads =  ${HPX_PARCEL_TCP_MAX_BACKGROUND_THREADS:$[hpx.parcel.max_background_threads]}
+
+
+ ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +

Property

Description

hpx.parcel.tcp.enable

Enables the use of the default TCP parcelport. Note that the initial +bootstrap of the overall HPX application will be performed using the +default TCP connections. This parcelport is enabled by default. This will +be disabled only if MPI is enabled (see below).

hpx.parcel.tcp.array_optimization

This property defines whether this locality is allowed to utilize +array optimizations in the TCP/IP parcelport during serialization of +parcel data. The default is the same value as set for +hpx.parcel.array_optimization.

hpx.parcel.tcp.zero_copy_optimization

This property defines whether this locality is allowed to utilize +zero copy optimizations during serialization of +parcel data. The default is the same value as set for +hpx.parcel.zero_copy_optimization.

hpx.parcel.tcp.zero_copy_receive_optimization

This property defines whether this locality is allowed to utilize +zero copy optimizations on the receiving end in the TCP/IP parcelport during +de-serialization of parcel data. The default is the same value as set +for hpx.parcel.zero_copy_optimization.

hpx.parcel.tcp.zero_copy_serialization_threshold

This property defines the threshold value (in bytes) starting at which the +serialization layer will apply zero-copy optimizations for serialized +entities. The default is the same value as set for +hpx.parcel.zero_copy_serialization_threshold.

hpx.parcel.tcp.async_serialization

This property defines whether this locality is allowed to spawn a +new thread for serialization in the TCP/IP parcelport (this is both for +encoding and decoding parcels). The default is the same value as set for +hpx.parcel.async_serialization.

hpx.parcel.tcp.parcel_pool_size

The value of this property defines the number of OS threads created for +the internal parcel thread pool of the TCP parcel port. The default is +taken from hpx.threadpools.parcel_pool_size.

hpx.parcel.tcp.max_connections

This property defines how many network connections between different +localities are overall kept alive by each locality. The +default is taken from hpx.parcel.max_connections.

hpx.parcel.tcp.max_connections_per_locality

This property defines the maximum number of network connections that one +locality will open to another locality. The default is +taken from hpx.parcel.max_connections_per_locality.

hpx.parcel.tcp.max_message_size

This property defines the maximum allowed message size that will be +transferrable through the parcel layer. The default is taken from +hpx.parcel.max_message_size.

hpx.parcel.tcp.max_outbound_message_size

This property defines the maximum allowed outbound coalesced message size +that will be transferrable through the parcel layer. The default is +taken from hpx.parcel.max_outbound_connections.

hpx.parcel.tcp.max_background_threads

This property defines how many cores should be used to perform background +operations. The default is taken from hpx.parcel.max_background_threads.

+

The following settings relate to the MPI parcelport. These settings take effect +only if the compile time constant HPX_HAVE_PARCELPORT_MPI is set (the +equivalent CMake variable is HPX_WITH_PARCELPORT_MPI and has to be set to +ON).

+
[hpx.parcel.mpi]
+enable = ${HPX_HAVE_PARCELPORT_MPI:$[hpx.parcel.enabled]}
+env = ${HPX_HAVE_PARCELPORT_MPI_ENV:MV2_COMM_WORLD_RANK,PMI_RANK,OMPI_COMM_WORLD_SIZE,ALPS_APP_PE,PALS_NODEID}
+multithreaded = ${HPX_HAVE_PARCELPORT_MPI_MULTITHREADED:1}
+rank = <MPI_rank>
+processor_name = <MPI_processor_name>
+array_optimization = ${HPX_HAVE_PARCEL_MPI_ARRAY_OPTIMIZATION:$[hpx.parcel.array_optimization]}
+zero_copy_optimization = ${HPX_HAVE_PARCEL_MPI_ZERO_COPY_OPTIMIZATION:$[hpx.parcel.zero_copy_optimization]}
+zero_copy_receive_optimization = ${HPX_HAVE_PARCEL_MPI_ZERO_COPY_RECEIVE_OPTIMIZATION:$[hpx.parcel.zero_copy_receive_optimization]}
+zero_copy_serialization_threshold =  ${HPX_PARCEL_MPI_ZERO_COPY_SERIALIZATION_THRESHOLD:$[hpx.parcel.zero_copy_serialization_threshold]}
+use_io_pool = ${HPX_HAVE_PARCEL_MPI_USE_IO_POOL:$1}
+async_serialization = ${HPX_HAVE_PARCEL_MPI_ASYNC_SERIALIZATION:$[hpx.parcel.async_serialization]}
+parcel_pool_size = ${HPX_HAVE_PARCEL_MPI_PARCEL_POOL_SIZE:$[hpx.threadpools.parcel_pool_size]}
+max_connections =  ${HPX_HAVE_PARCEL_MPI_MAX_CONNECTIONS:$[hpx.parcel.max_connections]}
+max_connections_per_locality = ${HPX_HAVE_PARCEL_MPI_MAX_CONNECTIONS_PER_LOCALITY:$[hpx.parcel.max_connections_per_locality]}
+max_message_size =  ${HPX_HAVE_PARCEL_MPI_MAX_MESSAGE_SIZE:$[hpx.parcel.max_message_size]}
+max_outbound_message_size =  ${HPX_HAVE_PARCEL_MPI_MAX_OUTBOUND_MESSAGE_SIZE:$[hpx.parcel.max_outbound_message_size]}
+max_background_threads =  ${HPX_PARCEL_MPI_MAX_BACKGROUND_THREADS:$[hpx.parcel.max_background_threads]}
+
+
+ ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +

Property

Description

hpx.parcel.mpi.enable

Enables the use of the MPI parcelport. HPX tries to detect if the +application was started within a parallel MPI environment. If the +detection was successful, the MPI parcelport is enabled by default. To +explicitly disable the MPI parcelport, set to 0. Note that the initial +bootstrap of the overall HPX application will be performed using MPI as +well.

hpx.parcel.mpi.env

This property influences which environment variables (separated by commas) +will be analyzed to find out whether the application was invoked by MPI.

hpx.parcel.mpi.multithreaded

This property is used to determine what threading mode to use when +initializing MPI. If this setting is 0, HPX will initialize MPI with +MPI_THREAD_SINGLE. If the value is not equal to 0, HPX will +initialize MPI with MPI_THREAD_MULTI.

hpx.parcel.mpi.rank

This property will be initialized to the MPI rank of the +locality.

hpx.parcel.mpi.processor_name

This property will be initialized to the MPI processor name of the +locality.

hpx.parcel.mpi.array_optimization

This property defines whether this locality is allowed to utilize +array optimizations in the MPI parcelport during serialization of +parcel data. The default is the same value as set for +hpx.parcel.array_optimization.

hpx.parcel.mpi.zero_copy_optimization

This property defines whether this locality is allowed to utilize +zero copy optimizations in the MPI parcelport during serialization of +parcel data. The default is the same value as set for +hpx.parcel.zero_copy_optimization.

hpx.parcel.mpi.zero_copy_receive_optimization

This property defines whether this locality is allowed to utilize +zero copy optimizations on the receiving end in the MPI parcelport during +de-serialization of parcel data. The default is the same value as +set for hpx.parcel.zero_copy_optimization.

hpx.parcel.mpi.zero_copy_serialization_threshold

This property defines the threshold value (in bytes) starting at which the +serialization layer will apply zero-copy optimizations for serialized +entities. The default is the same value as set for +hpx.parcel.zero_copy_serialization_threshold.

hpx.parcel.mpi.use_io_pool

This property can be set to run the progress thread inside of HPX threads +instead of a separate thread pool. The default is 1.

hpx.parcel.mpi.async_serialization

This property defines whether this locality is allowed to spawn a +new thread for serialization in the MPI parcelport (this is both for +encoding and decoding parcels). The default is the same value as set for +hpx.parcel.async_serialization.

hpx.parcel.mpi.parcel_pool_size

The value of this property defines the number of OS threads created for +the internal parcel thread pool of the MPI parcel port. The default is +taken from hpx.threadpools.parcel_pool_size.

hpx.parcel.mpi.max_connections

This property defines how many network connections between different +localities are overall kept alive by each locality. The +default is taken from hpx.parcel.max_connections.

hpx.parcel.mpi.max_connections_per_locality

This property defines the maximum number of network connections that one +locality will open to another locality. The default is +taken from hpx.parcel.max_connections_per_locality.

hpx.parcel.mpi.max_message_size

This property defines the maximum allowed message size that will be +transferrable through the parcel layer. The default is taken from +hpx.parcel.max_message_size.

hpx.parcel.mpi.max_outbound_message_size

This property defines the maximum allowed outbound coalesced message size +that will be transferrable through the parcel layer. The default is +taken from hpx.parcel.max_outbound_connections.

hpx.parcel.mpi.max_background_threads

This property defines how many cores should be used to perform background +operations. The default is taken from hpx.parcel.max_background_threads.

+
+
+The hpx.agas configuration section# +
[hpx.agas]
+address = ${HPX_AGAS_SERVER_ADDRESS:<hpx_initial_ip_address>}
+port = ${HPX_AGAS_SERVER_PORT:<hpx_initial_ip_port>}
+service_mode = hosted
+dedicated_server = 0
+max_pending_refcnt_requests = ${HPX_AGAS_MAX_PENDING_REFCNT_REQUESTS:<hpx_initial_agas_max_pending_refcnt_requests>}
+use_caching = ${HPX_AGAS_USE_CACHING:1}
+use_range_caching = ${HPX_AGAS_USE_RANGE_CACHING:1}
+local_cache_size = ${HPX_AGAS_LOCAL_CACHE_SIZE:<hpx_agas_local_cache_size>}
+
+
+ ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +

Property

Description

hpx.agas.address

This property defines the default IP address to be used for the +AGAS root server. This IP address will be used as long as no +other values are specified (for instance, using the --hpx:agas +command line option). The expected format is any valid IP address or +domain name format that can be resolved into an IP address. The default +depends on the compile time preprocessor constant +HPX_INITIAL_IP_ADDRESS ("127.0.0.1").

hpx.agas.port

This property defines the default IP port to be used for the AGAS +root server. This IP port will be used as long as no other values are +specified (for instance, using the --hpx:agas command line +option). The default depends on the compile time preprocessor constant +HPX_INITIAL_IP_PORT (7009).

hpx.agas.service_mode

This property specifies what type of AGAS service is running on +this locality. Currently, two modes exist. The locality +that acts as the AGAS server runs in bootstrap mode. All other +localities are in hosted mode.

hpx.agas.dedicated_server

This property specifies whether the AGAS server is exclusively +running AGAS services and not hosting any application components. +It is a boolean value. Set to 1 if +--hpx:run-agas-server-only is present.

hpx.agas.max_pending_refcnt_requests

This property defines the number of reference counting requests +(increments or decrements) to buffer. The default depends on the compile +time preprocessor constant +HPX_INITIAL_AGAS_MAX_PENDING_REFCNT_REQUESTS (4096).

hpx.agas.use_caching

This property specifies whether a software address translation cache is +used. It is a boolean value. Defaults to 1.

hpx.agas.use_range_caching

This property specifies whether range-based caching is used by the +software address translation cache. This property is ignored if +hpx.agas.use_caching is false. It is a boolean value. Defaults to 1.

hpx.agas.local_cache_size

This property defines the size of the software address translation cache +for AGAS services. This property is ignored +if hpx.agas.use_caching is false. Note that if +hpx.agas.use_range_caching is true, this size will refer to the +maximum number of ranges stored in the cache, not the number of entries +spanned by the cache. The default depends on the compile time +preprocessor constant HPX_AGAS_LOCAL_CACHE_SIZE (4096).

+
+
+The hpx.commandline configuration section# +

The following table lists the definition of all pre-defined command line option +shortcuts. For more information about commandline options, see the section +HPX Command Line Options.

+
[hpx.commandline]
+aliasing = ${HPX_COMMANDLINE_ALIASING:1}
+allow_unknown = ${HPX_COMMANDLINE_ALLOW_UNKNOWN:0}
+
+[hpx.commandline.aliases]
+-a = --hpx:agas
+-c = --hpx:console
+-h = --hpx:help
+-I = --hpx:ini
+-l = --hpx:localities
+-p = --hpx:app-config
+-q = --hpx:queuing
+-r = --hpx:run-agas-server
+-t = --hpx:threads
+-v = --hpx:version
+-w = --hpx:worker
+-x = --hpx:hpx
+-0 = --hpx:node=0
+-1 = --hpx:node=1
+-2 = --hpx:node=2
+-3 = --hpx:node=3
+-4 = --hpx:node=4
+-5 = --hpx:node=5
+-6 = --hpx:node=6
+-7 = --hpx:node=7
+-8 = --hpx:node=8
+-9 = --hpx:node=9
+
+
+
+

Note

+

The short options listed above are disabled by default if the application +is built using #include <hpx/hpx_main.hpp>. See Re-use the main() function as the main HPX entry point for more +information. +The rationale behind this is that in this case the user’s application may +handle its own command line options, since HPX passes all unknown options +to main(). Short options like -t are prone to create ambiguities regarding +what the application will support. +Hence, the user should instead rely on the corresponding long options like +--hpx:threads in such a case.

+
+ ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +

Property

Description

hpx.commandline.aliasing

Enable command line aliases as defined in the section +hpx.commandline.aliases (see below). Defaults to 1.

hpx.commandline.allow_unknown

Allow for unknown command line options to be passed through to +hpx_main() Defaults to 0.

hpx.commandline.aliases.-a

On the commandline -a expands to: --hpx:agas.

hpx.commandline.aliases.-c

On the commandline -c expands to: --hpx:console.

hpx.commandline.aliases.-h

On the commandline -h expands to: --hpx:help.

hpx.commandline.aliases.--help

On the commandline --help expands to: --hpx:help.

hpx.commandline.aliases.-I

On the commandline -I expands to: --hpx:ini.

hpx.commandline.aliases.-l

On the commandline -l expands to: --hpx:localities.

hpx.commandline.aliases.-p

On the commandline -p expands to: --hpx:app-config.

hpx.commandline.aliases.-q

On the commandline -q expands to: --hpx:queuing.

hpx.commandline.aliases.-r

On the commandline -r expands to: --hpx:run-agas-server.

hpx.commandline.aliases.-t

On the commandline -t expands to: --hpx:threads.

hpx.commandline.aliases.-v

On the commandline -v expands to: --hpx:version.

hpx.commandline.aliases.--version

On the commandline --version expands to: --hpx:version.

hpx.commandline.aliases.-w

On the commandline -w expands to: --hpx:worker.

hpx.commandline.aliases.-x

On the commandline -x expands to: --hpx:hpx.

hpx.commandline.aliases.-0

On the commandline -0 expands to: --hpx:node=0.

hpx.commandline.aliases.-1

On the commandline -1 expands to: --hpx:node=1.

hpx.commandline.aliases.-2

On the commandline -2 expands to: --hpx:node=2.

hpx.commandline.aliases.-3

On the commandline -3 expands to: --hpx:node=3.

hpx.commandline.aliases.-4

On the commandline -4 expands to: --hpx:node=4.

hpx.commandline.aliases.-5

On the commandline -5 expands to: --hpx:node=5.

hpx.commandline.aliases.-6

On the commandline -6 expands to: --hpx:node=6.

hpx.commandline.aliases.-7

On the commandline -7 expands to: --hpx:node=7.

hpx.commandline.aliases.-8

On the commandline -8 expands to: --hpx:node=8.

hpx.commandline.aliases.-9

On the commandline -9 expands to: --hpx:node=9.

+
+
+
+
Loading INI files#
+

During startup and after the internal database has been initialized as +described in the section Built-in default configuration settings, HPX will try to locate and +load additional ini files to be used as a source for configuration properties. +This allows for a wide spectrum of additional customization possibilities by +the user and system administrators. The sequence of locations where HPX +will try loading the ini files is well defined and documented in this section. +All ini files found are merged into the internal configuration database. +The merge operation itself conforms to the rules as described in the section +The HPX ini file format.

+
    +
  1. Load all component shared libraries found in the directories specified by the +property hpx.component_path and retrieve their default configuration +information (see section Loading components for more details). This +property can refer to a list of directories separated by ':' (Linux, +Android, and MacOS) or by ';' (Windows).

  2. +
  3. Load all files named hpx.ini in the directories referenced by the property +hpx.master_ini_path This property can refer to a list of directories +separated by ':' (Linux, Android, and MacOS) or by ';' (Windows).

  4. +
  5. Load a file named .hpx.ini in the current working directory, e.g., the +directory the application was invoked from.

  6. +
  7. Load a file referenced by the environment variable HPX_INI. This variable +is expected to provide the full path name of the ini configuration file (if +any).

  8. +
  9. Load a file named /etc/hpx.ini. This lookup is done on non-Windows systems +only.

  10. +
  11. Load a file named .hpx.ini in the home directory of the current user, +e.g., the directory referenced by the environment variable HOME.

  12. +
  13. Load a file named .hpx.ini in the directory referenced by the environment +variable PWD.

  14. +
  15. Load the file specified on the command line using the option +--hpx:config.

  16. +
  17. Load all properties specified on the command line using the option +--hpx:ini. The properties will be added to the database in the +same sequence as they are specified on the command line. The format for those +options is, for instance, --hpx:ini=hpx.default_stack_size=0x4000. In +addition to the explicit command line options, this will set the following +properties as implied from other settings:

    + +
  18. +
  19. Load files based on the pattern *.ini in all directories listed by the +property hpx.ini_path. All files found during this search will be merged. +The property hpx.ini_path can hold a list of directories separated by +':' (on Linux or Mac) or ';' (on Windows).

  20. +
  21. Load the file specified on the command line using the option +--hpx:app-config. Note that this file will be merged as the content +for a top level section [application].

  22. +
+
+

Note

+

Any changes made to the configuration database caused by one of the steps +will influence the loading process for all subsequent steps. For instance, if +one of the ini files loaded changes the property hpx.ini_path, this will +influence the directories searched in step 9 as described above.

+
+
+

Important

+

The HPX core library will verify that all configuration settings specified +on the command line (using the --hpx:ini option) will be checked +for validity. That means that the library will accept only known +configuration settings. This is to protect the user from unintentional typos +while specifying those settings. This behavior can be overwritten by +appending a '!' to the configuration key, thus forcing the setting to be +entered into the configuration database. For instance: --hpx:ini=hpx.foo! = 1

+
+

If any of the environment variables or files listed above are not found, the +corresponding loading step will be silently skipped.

+
+
+
+
Loading components#
+

HPX relies on loading application specific components during the runtime of an +application. Moreover, HPX comes with a set of preinstalled components +supporting basic functionalities useful for almost every application. Any +component in HPX is loaded from a shared library, where any of the shared +libraries can contain more than one component type. During startup, HPX tries +to locate all available components (e.g., their corresponding shared libraries) +and creates an internal component registry for later use. This section describes +the algorithm used by HPX to locate all relevant shared libraries on a system. +As described, this algorithm is customizable by the configuration properties +loaded from the ini files (see section Loading INI files).

+

Loading components is a two-stage process. First HPX tries to locate all +component shared libraries, loads those, and generates a default configuration +section in the internal configuration database for each component found. For +each found component the following information is generated:

+
[hpx.components.<component_instance_name>]
+name = <name_of_shared_library>
+path = $[component_path]
+enabled = $[hpx.components.load_external]
+default = 1
+
+
+

The values in this section correspond to the expected configuration information +for a component as described in the section Built-in default configuration settings.

+

In order to locate component shared libraries, HPX will try loading all +shared libraries (files with the platform specific extension of a shared +library, Linux: *.so, Windows: *.dll, MacOS: *.dylib found in the +directory referenced by the ini property hpx.component_path).

+

This first step corresponds to step 1) during the process of filling the +internal configuration database with default information as described in section +Loading INI files.

+

After all of the configuration information has been loaded, HPX performs the +second step in terms of loading components. During this step, HPX scans all +existing configuration sections +[hpx.component.<some_component_instance_name>] and instantiates a special +factory object for each of the successfully located and loaded components. +During the application’s life time, these factory objects are responsible for +creating new and discarding old instances of the component they are associated with. +This step is performed after step 11) of the process of filling the internal +configuration database with default information as described in section +Loading INI files.

+
+
Application specific component example#
+

This section assumes there is a simple application component that exposes +one member function as a component action. The header file app_server.hpp +declares the C++ type to be exposed as a component. This type has a member +function print_greeting(), which is exposed as an action +print_greeting_action. We assume the source files for this example are +located in a directory referenced by $APP_ROOT:

+
// file: $APP_ROOT/app_server.hpp
+#include <hpx/hpx.hpp>
+#include <hpx/include/iostreams.hpp>
+
+namespace app
+{
+    // Define a simple component exposing one action 'print_greeting'
+    class HPX_COMPONENT_EXPORT server
+      : public hpx::components::component_base<server>
+    {
+        void print_greeting ()
+        {
+            hpx::cout << "Hey, how are you?\n" << std::flush;
+        }
+
+        // Component actions need to be declared, this also defines the
+        // type 'print_greeting_action' representing the action.
+        HPX_DEFINE_COMPONENT_ACTION(server, print_greeting, print_greeting_action);
+    };
+}
+
+// Declare boilerplate code required for each of the component actions.
+HPX_REGISTER_ACTION_DECLARATION(app::server::print_greeting_action);
+
+
+

The corresponding source file contains mainly macro invocations that define the +boilerplate code needed for HPX to function properly:

+
// file: $APP_ROOT/app_server.cpp
+#include "app_server.hpp"
+
+// Define boilerplate required once per component module.
+HPX_REGISTER_COMPONENT_MODULE();
+
+// Define factory object associated with our component of type 'app::server'.
+HPX_REGISTER_COMPONENT(app::server, app_server);
+
+// Define boilerplate code required for each of the component actions. Use the
+// same argument as used for HPX_REGISTER_ACTION_DECLARATION above.
+HPX_REGISTER_ACTION(app::server::print_greeting_action);
+
+
+

The following gives an example of how the component can be used. Here, one +instance of the app::server component is created on the current locality and +the exposed action print_greeting_action is invoked using the global id of the +newly created instance. Note that no special code is required to delete the +component instance after it is not needed anymore. It will be deleted +automatically when its last reference goes out of scope (shown in the example below at +the closing brace of the block surrounding the code):

+
// file: $APP_ROOT/use_app_server_example.cpp
+#include <hpx/hpx_init.hpp>
+#include "app_server.hpp"
+
+int hpx_main()
+{
+    {
+        // Create an instance of the app_server component on the current locality.
+        hpx::naming:id_type app_server_instance =
+            hpx::create_component<app::server>(hpx::find_here());
+
+        // Create an instance of the action 'print_greeting_action'.
+        app::server::print_greeting_action print_greeting;
+
+        // Invoke the action 'print_greeting' on the newly created component.
+        print_greeting(app_server_instance);
+    }
+    return hpx::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    return hpx::init(argc, argv);
+}
+
+
+

In order to make sure that the application will be able to use the component +app::server, special configuration information must be passed to HPX. The +simplest way to allow HPX to ‘find’ the component is to provide special ini +configuration files that add the necessary information to the internal +configuration database. The component should have a special ini file containing +the information specific to the component app_server.

+
# file: $APP_ROOT/app_server.ini
+[hpx.components.app_server]
+name = app_server
+path = $APP_LOCATION/
+
+
+

Here, $APP_LOCATION is the directory where the (binary) component shared +library is located. HPX will attempt to load the shared library from there. +The section name hpx.components.app_server reflects the instance name of the +component (app_server is an arbitrary, but unique name). The property value +for hpx.components.app_server.name should be the same as used for the second +argument to the macro HPX_REGISTER_COMPONENT above.

+

Additionally, a file .hpx.ini, which could be located in the current working +directory (see step 3 as described in the section Loading INI files), can +be used to add to the ini search path for components:

+
# file: $PWD/.hpx.ini
+[hpx]
+ini_path = $[hpx.ini_path]:$APP_ROOT/
+
+
+

This assumes that the above ini file specific to the component is located in +the directory $APP_ROOT.

+
+

Note

+

It is possible to reference the defined property from inside its value. HPX +will gracefully use the previous value of hpx.ini_path for the reference +on the right hand side and assign the overall (now expanded) value to the +property.

+
+
+
+
+
Logging#
+

HPX uses a sophisticated logging framework, allowing users to follow in detail +what operations have been performed inside the HPX library in what sequence. +This information proves to be very useful for diagnosing problems or just for +improving the understanding of what is happening in HPX as a consequence of +invoking HPX API functionality.

+
+
Default logging#
+

Enabling default logging is a simple process. The detailed description in the +remainder of this section explains different ways to customize the defaults. +Default logging can be enabled by using one of the following:

+
    +
  • A command line switch --hpx:debug-hpx-log, which will enable +logging to the console terminal.

  • +
  • The command line switch --hpx:debug-hpx-log=<filename>, which +enables logging to a given file <filename>.

  • +
  • Setting an environment variable HPX_LOGLEVEL=<loglevel> while running the +HPX application. In this case <loglevel> should be a number between (or +equal to) 1 and 5 where 1 means minimal logging and 5 causes +all available messages to be logged. When setting the environment variable, the logs +will be written to a file named hpx.<PID>.lo in the current working +directory, where <PID> is the process id of the console instance of the +application.

  • +
+
+
+
Customizing logging#
+

Generally, logging can be customized either using environment variable settings +or using by an ini configuration file. Logging is generated in several +categories, each of which can be customized independently. All customizable +configuration parameters have reasonable defaults, allowing for the use of logging +without any additional configuration effort. The following table lists the +available categories.

+ + ++++++ + + + + + + + + + + + + + + + + + + + + + + +
Table 5 Logging categories#

Category

Category shortcut

Information to be generated

Environment variable

General

None

Logging information generated by different subsystems of HPX, such as +thread-manager, parcel layer, LCOs, etc.

HPX_LOGLEVEL

AGAS

AGAS

Logging output generated by the AGAS subsystem

HPX_AGAS_LOGLEVEL

Application

APP

Logging generated by applications.

HPX_APP_LOGLEVEL

+

By default, all logging output is redirected to the console instance of an +application, where it is collected and written to a file, one file for each +logging category.

+

Each logging category can be customized at two levels. The parameters for each +are stored in the ini configuration sections hpx.logging.CATEGORY and +hpx.logging.console.CATEGORY (where CATEGORY is the category shortcut as +listed in the table above). The former influences logging at the source +locality and the latter modifies the logging behaviour for each of the +categories at the console instance of an application.

+
+
+
Levels#
+

All HPX logging output has seven different logging levels. These levels can +be set explicitly or through environment variables in the main HPX ini file +as shown below. The logging levels and their associated integral values are +shown in the table below, ordered from most verbose to least verbose. By +default, all HPX logs are set to 0, e.g., all logging output is disabled by +default.

+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 6 Logging levels#

Logging level

Integral value

<debug>

5

<info>

4

<warning>

3

<error>

2

<fatal>

1

No logging

0

+
+

Tip

+

The easiest way to enable logging output is to set the environment variable +corresponding to the logging category to an integral value as described in +the table above. For instance, setting HPX_LOGLEVEL=5 will enable full +logging output for the general category. Please note that the syntax and +means of setting environment variables varies between operating systems.

+
+
+
+
Configuration#
+

Logs will be saved to destinations as configured by the user. By default, +logging output is saved on the console instance of an application to +hpx.<CATEGORY>.<PID>.lo (where CATEGORY and PID> are placeholders +for the category shortcut and the OS process id). The output for the general +logging category is saved to hpx.<PID>.log. The default settings for the +general logging category are shown here (the syntax is described in the section +The HPX ini file format):

+
[hpx.logging]
+level = ${HPX_LOGLEVEL:0}
+destination = ${HPX_LOGDESTINATION:console}
+format = ${HPX_LOGFORMAT:(T%locality%/%hpxthread%.%hpxphase%/%hpxcomponent%) P%parentloc%/%hpxparent%.%hpxparentphase% %time%($hh:$mm.$ss.$mili) [%idx%]|\\n}
+
+
+

The logging level is taken from the environment variable HPX_LOGLEVEL and +defaults to zero, e.g., no logging. The default logging destination is read from +the environment variable HPX_LOGDESTINATION On any of the localities it +defaults to console, which redirects all generated logging output to the +console instance of an application. The following table lists the possible +destinations for any logging output. It is possible to specify more than one +destination separated by whitespace.

+ + ++++ + + + + + + + + + + + + + + + + + + + + +
Table 7 Logging destinations#

Logging destination

Description

file(<filename>)

Directs all output to a file with the given <filename>.

cout

Directs all output to the local standard output of the application +instance on this locality.

cerr

Directs all output to the local standard error output of the application +instance on this locality.

console

Directs all output to the console instance of the application. The console +instance has its logging destinations configured separately.

android_log

Directs all output to the (Android) system log (available on Android +systems only).

+

The logging format is read from the environment variable HPX_LOGFORMAT, and +it defaults to a complex format description. This format consists of several +placeholder fields (for instance %locality%), which will be replaced by +concrete values when the logging output is generated. All other information is +transferred verbatim to the output. The table below describes the available +field placeholders. The separator character | separates the logging message +prefix formatted as shown and the actual log message which will replace the +separator.

+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 8 Available field placeholders#

Name

Description

locality

The id of the locality on which the logging message was +generated.

hpxthread

The id of the HPX thread generating this logging output.

hpxphase

The phase 1 of the HPX thread generating this logging output.

hpxcomponent

The local virtual address of the component which the current HPX thread +is accessing.

parentloc

The id of the locality where the HPX thread was running that +initiated the current HPX thread. The current HPX thread is +generating this logging output.

hpxparent

The id of the HPX thread that initiated the current HPX thread. The +current HPX thread is generating this logging output.

hpxparentphase

The phase of the HPX thread when it initiated the current HPX thread. +The current HPX thread is generating this logging output.

time

The time stamp for this logging outputline as generated by the source +locality.

idx

The sequence number of the logging output line as generated on the source +locality.

osthread

The sequence number of the OS thread that executes the current +HPX thread.

+
+

Note

+

Not all of the field placeholder may be expanded for all generated logging +output. If no value is available for a particular field, it is replaced with a +sequence of '-' characters.

+
+

Here is an example line from a logging output generated by one of the HPX +examples (please note that this is generated on a single line, without a line +break):

+
(T00000000/0000000002d46f90.01/00000000009ebc10) P--------/0000000002d46f80.02 17:49.37.320 [000000000000004d]
+    <info>  [RT] successfully created component {0000000100ff0001, 0000000000030002} of type: component_barrier[7(3)]
+
+
+

The default settings for the general logging category on the console is shown +here:

+
[hpx.logging.console]
+level = ${HPX_LOGLEVEL:$[hpx.logging.level]}
+destination = ${HPX_CONSOLE_LOGDESTINATION:file(hpx.$[system.pid].log)}
+format = ${HPX_CONSOLE_LOGFORMAT:|}
+
+
+

These settings define how the logging is customized once the logging output is +received by the console instance of an application. The logging level is read +from the environment variable HPX_LOGLEVEL (as set for the console instance +of the application). The level defaults to the same values as the corresponding +settings in the general logging configuration shown before. The destination on +the console instance is set to be a file that’s name is generated based on its +OS process id. Setting the environment variable HPX_CONSOLE_LOGDESTINATION +allows customization of the naming scheme for the output file. The logging +format is set to leave the original logging output unchanged, as received from +one of the localities the application runs on.

+
+
+
+
HPX Command Line Options#
+

The predefined command line options for any application using +hpx::init are described in the following subsections.

+
+
HPX options (allowed on command line only)#
+
+
+--hpx:help#
+

Print out program usage (default: this message). Possible values: full +(additionally prints options from components).

+
+ +
+
+--hpx:version#
+

Print out HPX version and copyright information.

+
+ +
+
+--hpx:info#
+

Print out HPX configuration information.

+
+ +
+
+--hpx:options-file arg#
+

Specify a file containing command line options (alternatively: @filepath).

+
+ +
+
+
HPX options (additionally allowed in an options file)#
+
+
+--hpx:worker#
+

Run this instance in worker mode.

+
+ +
+
+--hpx:console#
+

Run this instance in console mode.

+
+ +
+
+--hpx:connect#
+

Run this instance in worker mode, but connecting late.

+
+ +
+
+--hpx:run-agas-server#
+

Run AGAS server as part of this runtime instance.

+
+ +
+
+--hpx:run-hpx-main#
+

Run the hpx_main function, regardless of locality mode.

+
+ +
+
+--hpx:hpx arg#
+

The IP address the HPX parcelport is listening on, expected format: +address:port (default: 127.0.0.1:7910).

+
+ +
+
+--hpx:agas arg#
+

The IP address the AGAS root server is running on, expected format: +address:port (default: 127.0.0.1:7910).

+
+ +
+
+--hpx:run-agas-server-only#
+

Run only the AGAS server.

+
+ +
+
+--hpx:nodefile arg#
+

The file name of a node file to use (list of nodes, one node name per line +and core).

+
+ +
+
+--hpx:nodes arg#
+

The (space separated) list of the nodes to use (usually this is extracted +from a node file).

+
+ +
+
+--hpx:endnodes#
+

This can be used to end the list of nodes specified using the option +--hpx:nodes.

+
+ +
+
+--hpx:ifsuffix arg#
+

Suffix to append to host names in order to resolve them to the proper network +interconnect.

+
+ +
+
+--hpx:ifprefix arg#
+

Prefix to prepend to host names in order to resolve them to the proper +network interconnect.

+
+ +
+
+--hpx:iftransform arg#
+

Sed-style search and replace (s/search/replace/) used to transform host +names to the proper network interconnect.

+
+ +
+
+--hpx:force_ipv4#
+

Network hostnames will be resolved to ipv4 addresses instead of using the +first resolved endpoint. This is especially useful on Windows where the +local hostname will resolve to an ipv6 address while remote network hostnames +are commonly resolved to ipv4 addresses.

+
+ +
+
+--hpx:localities arg#
+

The number of localities to wait for at application startup (default: 1).

+
+ +
+
+--hpx:node arg#
+

Number of the node this locality is run on (must be unique).

+
+ +
+
+--hpx:ignore-batch-env#
+

Ignore batch environment variables.

+
+ +
+
+--hpx:expect-connecting-localities#
+

This locality expects other localities to dynamically connect (this +is implied if the number of initial localities is larger than 1).

+
+ +
+
+--hpx:pu-offset#
+

The first processing unit this instance of HPX should be run on (default: +0).

+
+ +
+
+--hpx:pu-step#
+

The step between used processing unit numbers for this instance of HPX +(default: 1).

+
+ +
+
+--hpx:threads arg#
+

The number of operating system threads to spawn for this HPX +locality. Possible values are: numeric values 1, 2, 3 and +so on, all (which spawns one thread per processing unit, includes +hyperthreads), or cores (which spawns one thread per core) (default: +cores).

+
+ +
+
+--hpx:cores arg#
+

The number of cores to utilize for this HPX locality (default: +all, i.e., the number of cores is based on the number of threads +--hpx:threads assuming --hpx:bind=compact.

+
+ +
+
+--hpx:affinity arg#
+

The affinity domain the OS threads will be confined to, possible values: +pu, core, numa, machine (default: pu).

+
+ +
+
+--hpx:bind arg#
+

he detailed affinity description for the OS threads, see More details about HPX command line options for +a detailed description of possible values. Do not use with +--hpx:pu-step, --hpx:pu-offset or +--hpx:affinity options. Implies --hpx:numa-sensitive +(--hpx:bind=none) disables defining thread affinities).

+
+ +
+
+--hpx:use-process-mask#
+

Use the process mask to restrict available hardware resources (implies +--hpx:ignore-batch-env).

+
+ +
+
+--hpx:print-bind#
+

Print to the console the bit masks calculated from the arguments specified to +all --hpx:bind options.

+
+ +
+
+--hpx:queuing arg#
+

The queue scheduling policy to use. Options are local, +local-priority-fifo, local-priority-lifo, static, +static-priority, abp-priority-fifo, +local-workrequesting-fifo, local-workrequesting-lifo +local-workrequesting-mc, and abp-priority-lifo +(default: local-priority-fifo).

+
+ +
+
+--hpx:high-priority-threads arg#
+

The number of operating system threads maintaining a high priority queue +(default: number of OS threads), valid for --hpx:queuing=abp-priority, --hpx:queuingstatic-priority and +--hpx:queuinglocal-priority only.

+
+ +
+
+--hpx:numa-sensitive#
+

Makes the scheduler NUMA sensitive.

+
+ +
+
+
HPX configuration options#
+
+
+--hpx:app-config arg#
+

Load the specified application configuration (ini) file.

+
+ +
+
+--hpx:config arg#
+

Load the specified HPX configuration (ini) file.

+
+ +
+
+--hpx:ini arg#
+

Add a configuration definition to the default runtime configuration.

+
+ +
+
+--hpx:exit#
+

Exit after configuring the runtime.

+
+ +
+
+
HPX debugging options#
+
+
+--hpx:list-symbolic-names#
+

List all registered symbolic names after startup.

+
+ +
+
+--hpx:list-component-types#
+

List all dynamic component types after startup.

+
+ +
+
+--hpx:dump-config-initial#
+

Print the initial runtime configuration.

+
+ +
+
+--hpx:dump-config#
+

Print the final runtime configuration.

+
+ +
+
+--hpx:debug-hpx-log [arg]#
+

Enable all messages on the HPX log channel and send all HPX logs to the +target destination (default: cout).

+
+ +
+
+--hpx:debug-agas-log [arg]#
+

Enable all messages on the AGAS log channel and send all AGAS +logs to the target destination (default: cout).

+
+ +
+
+--hpx:debug-parcel-log [arg]#
+

Enable all messages on the parcel transport log channel and send all parcel +transport logs to the target destination (default: cout).

+
+ +
+
+--hpx:debug-timing-log [arg]#
+

Enable all messages on the timing log channel and send all timing logs to the +target destination (default: cout).

+
+ +
+
+--hpx:debug-app-log [arg]#
+

Enable all messages on the application log channel and send all application +logs to the target destination (default: cout).

+
+ +
+
+--hpx:debug-clp#
+

Debug command line processing.

+
+ +
+
+--hpx:attach-debugger arg#
+

Wait for a debugger to be attached, possible arg values: startup or +exception (default: startup)

+
+ +
+ +
+
Command line argument shortcuts#
+

Additionally, the following shortcuts are available from every HPX +application.

+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 9 Predefined command line option shortcuts#

Shortcut option

Equivalent long option

-a

--hpx:agas

-c

--hpx:console

-h

--hpx:help

-I

--hpx:ini

-l

--hpx:localities

-p

--hpx:app-config

-q

--hpx:queuing

-r

--hpx:run-agas-server

-t

--hpx:threads

-v

--hpx:version

-w

--hpx:worker

-x

--hpx:hpx

-0

--hpx:node=0

-1

--hpx:node=1

-2

--hpx:node=2

-3

--hpx:node=3

-4

--hpx:node=4

-5

--hpx:node=5

-6

--hpx:node=6

-7

--hpx:node=7

-8

--hpx:node=8

-9

--hpx:node=9

+
+

Note

+

The short options listed above are disabled by default if the application +is built using #include <hpx/hpx_main.hpp>. See Re-use the main() function as the main HPX entry point for more +information. +The rationale behind this is that in this case the user’s application may +handle its own command line options, since HPX passes all unknown options +to main(). Short options like -t are prone to create ambiguities regarding +what the application will support. +Hence, the user should instead rely on the corresponding long options like +--hpx:threads in such a case.

+
+

It is possible to define your own shortcut options. In fact, all of the +shortcuts listed above are pre-defined using the technique described here. Also, +it is possible to redefine any of the pre-defined shortcuts to expand +differently as well.

+

Shortcut options are obtained from the internal configuration database. They are +stored as key-value properties in a special properties section named +hpx.commandline. You can define your own shortcuts by adding the +corresponding definitions to one of the ini configuration files as described +in the section Configuring HPX applications. For instance, in order to define a command +line shortcut --p, which should expand to -hpx:print-counter, the +following configuration information needs to be added to one of the ini +configuration files:

+
[hpx.commandline.aliases]
+--pc = --hpx:print-counter
+
+
+
+

Note

+

Any arguments for shortcut options passed on the command line are retained +and passed as arguments to the corresponding expanded option. For instance, +given the definition above, the command line option:

+
--pc=/threads{locality#0/total}/count/cumulative
+
+
+

would be expanded to:

+
--hpx:print-counter=/threads{locality#0/total}/count/cumulative
+
+
+
+
+

Important

+

Any shortcut option should either start with a single '-' or with two +'--' characters. Shortcuts starting with a single '-' are interpreted +as short options (i.e., everything after the first character following the +'-' is treated as the argument). Shortcuts starting with '--' are +interpreted as long options. No other shortcut formats are supported.

+
+
+
+
Specifying options for single localities only#
+

For runs involving more than one locality, it is sometimes desirable to +supply specific command line options to single localities only. When the HPX +application is launched using a scheduler (like PBS; for more details see +section How to use HPX applications with PBS), specifying dedicated command line options for single +localities may be desirable. For this reason all of the command line options +that have the general format --hpx:<some_key> can be used in a more general +form: --hpx:<N>:<some_key>, where <N> is the number of the locality +this command line option will be applied to; all other localities will simply +ignore the option. For instance, the following PBS script passes the option +--hpx:pu-offset=4 to the locality '1' only.

+
#!/bin/bash
+#
+#PBS -l nodes=2:ppn=4
+
+APP_PATH=~/packages/hpx/bin/hello_world_distributed
+APP_OPTIONS=
+
+pbsdsh -u $APP_PATH $APP_OPTIONS --hpx:1:pu-offset=4 --hpx:nodes=`cat $PBS_NODEFILE`
+
+
+
+

Caution

+

If the first application specific argument (inside $APP_OPTIONS) is a +non-option (i.e., does not start with a - or a --), then it must be +placed before the option --hpx:nodes, which, in this case, +should be the last option on the command line.

+

Alternatively, use the option --hpx:endnodes to explicitly +mark the end of the list of node names:

+
$ pbsdsh -u $APP_PATH --hpx:1:pu-offset=4 --hpx:nodes=`cat $PBS_NODEFILE` --hpx:endnodes $APP_OPTIONS
+
+
+
+
+
+
More details about HPX command line options#
+

This section documents the following list of the command line options in more +detail:

+ +
+The command line option --hpx:bind# +

This command line option allows one to specify the required affinity of the +HPX worker threads to the underlying processing units. As a result the worker +threads will run only on the processing units identified by the corresponding +bind specification. The affinity settings are to be specified using +--hpx:bind=<BINDINGS>, where <BINDINGS> have to be formatted as +described below.

+

In addition to the syntax described below, one can use --hpx:bind=none to disable all binding of any threads to a particular core. This is +mostly supported for debugging purposes.

+

The specified affinities refer to specific regions within a machine hardware +topology. In order to understand the hardware topology of a particular machine, +it may be useful to run the lstopo tool, which is part of Portable Hardware Locality (HWLOC), to see the +reported topology tree. Seeing and understanding a topology tree will definitely +help in understanding the concepts that are discussed below.

+

Affinities can be specified using hwloc tuples. Tuples of hwloc objects and +associated indexes can be specified in the form object:index, +object:index-index or object:index,...,index. Hwloc objects +represent types of mapped items in a topology tree. Possible values for +objects are socket, numanode, core and pu (processing unit). +Indexes are non-negative integers that specify a unique physical object in a +topology tree using its logical sequence number.

+

Chaining multiple tuples together in the more general form +object1:index1[.object2:index2[...]] is permissible. While the first tuple’s +object may appear anywhere in the topology, the Nth tuple’s object must have a +shallower topology depth than the (N+1)th tuple’s object. Put simply: as you +move right in a tuple chain, objects must go deeper in the topology tree. +Indexes specified in chained tuples are relative to the scope of the parent +object. For example, socket:0.core:1 refers to the second core in the first +socket (all indices are zero based).

+

Multiple affinities can be specified using several --hpx:bind command +line options or by appending several affinities separated by a ';'. By +default, if multiple affinities are specified, they are added.

+

"all" is a special affinity consisting in the entire current topology.

+
+

Note

+

All “names” in an affinity specification, such as thread, socket, +numanode, pu or all, can be abbreviated. Thus, the affinity +specification threads:0-3=socket:0.core:1.pu:1 is fully equivalent to its +shortened form t:0-3=s:0.c:1.p:1.

+
+

Here is a full grammar describing the possible format of mappings:

+
+mappings     ::=  distribution | mapping (";" mapping)*
+distribution ::=  "compact" | "scatter" | "balanced" | "numa-balanced"
+mapping      ::=  thread_spec "=" pu_specs
+thread_spec  ::=  "thread:" range_specs
+pu_specs     ::=  pu_spec ("." pu_spec)*
+pu_spec      ::=  type ":" range_specs | "~" pu_spec
+range_specs  ::=  range_spec ("," range_spec)*
+range_spec   ::=  int | int "-" int | "all"
+type         ::=  "socket" | "numanode" | "core" | "pu"
+
+

The following example assumes a system with at least 4 cores, where each core +has more than 1 processing unit (hardware threads). Running +hello_world_distributed with 4 OS threads (on 4 processing units), where +each of those threads is bound to the first processing unit of each of the +cores, can be achieved by invoking:

+
$ hello_world_distributed -t4 --hpx:bind=thread:0-3=core:0-3.pu:0
+
+
+

Here, thread:0-3 specifies the OS threads used to define affinity +bindings, and core:0-3.pu: defines that for each of the cores (core:0-3) +only their first processing unit pu:0 should be used.

+
+

Note

+

The command line option --hpx:print-bind can be used to print the +bitmasks generated from the affinity mappings as specified with +--hpx:bind. For instance, on a system with hyperthreading enabled +(i.e. 2 processing units per core), the command line:

+
$ hello_world_distributed -t4 --hpx:bind=thread:0-3=core:0-3.pu:0 --hpx:print-bind
+
+
+

will cause this output to be printed:

+
0: PU L#0(P#0), Core L#0, Socket L#0, Node L#0(P#0)
+1: PU L#2(P#2), Core L#1, Socket L#0, Node L#0(P#0)
+2: PU L#4(P#4), Core L#2, Socket L#0, Node L#0(P#0)
+3: PU L#6(P#6), Core L#3, Socket L#0, Node L#0(P#0)
+
+
+

where each bit in the bitmasks corresponds to a processing unit the listed +worker thread will be bound to run on.

+
+

The difference between the four possible predefined distribution schemes +(compact, scatter, balanced and numa-balanced) is best explained +with an example. Imagine that we have a system with 4 cores and 4 hardware +threads per core on 2 sockets. If we place 8 threads the assignments produced by +the compact, scatter, balanced and numa-balanced types are shown +in the figure below. Notice that compact does not fully utilize all the +cores in the system. For this reason it is recommended that applications are run +using the scatter or balanced/numa-balanced options in most cases.

+
+_images/affinities.png +
+

Fig. 7 Schematic of thread affinity type distributions.#

+
+
+

In addition to the predefined distributions it is possible to restrict the +resources used by HPX to the process CPU mask. The CPU mask is typically set +by e.g. MPI and batch environments. Using the command line option +--hpx:use-process-mask makes HPX act as if only the processing units +in the CPU mask are available for use by HPX. The number of threads is +automatically determined from the CPU mask. The number of threads can still be +changed manually using this option, but only to a number less than or equal to +the number of processing units in the CPU mask. The option +--hpx:print-bind is useful in conjunction with +--hpx:use-process-mask to make sure threads are placed as expected.

+
+
1
+

The phase of a HPX-thread counts how often this thread has been +activated.

+
+
+
+
+
+
+
+

Writing single-node applications#

+

Being a C++ Standard Library for Concurrency and Parallelism, HPX implements all +of the corresponding facilities as defined by the C++ Standard but also those which +are proposed as part of the ongoing C++ standardization process. This section focuses +on the features available in HPX for parallel and concurrent computation on a single +node, although many of the features presented here are also implemented to work in the +distributed case.

+
+
Synchronization objects#
+

The following objects are providing synchronization for HPX applications:

+
    +
  1. Barrier

  2. +
  3. Condition variable

  4. +
  5. Latch

  6. +
  7. Mutex

  8. +
  9. Shared mutex

  10. +
  11. Semaphore

  12. +
  13. Composable guards

  14. +
+
+
Barrier#
+

Barriers are used for synchronizing multiple threads. +They provide a synchronization point, where all threads must wait until they have all reached +the barrier, before they can continue execution. This allows multiple threads to work together +to solve a common task, and ensures that no thread starts working on the next task until all +threads have completed the current task. This ensures that all threads are in the same state +before performing any further operations, leading to a more consistent and accurate computation.

+

Unlike latches, barriers are reusable: once the participating threads are released from a +barrier’s synchronization point, they can re-use the same barrier. It is thus useful for +managing repeated tasks, or phases of a larger task, that are handled by multiple threads. +The code below shows how barriers can be used to synchronize two threads:

+
#include <hpx/barrier.hpp>
+#include <hpx/future.hpp>
+#include <hpx/init.hpp>
+
+#include <iostream>
+
+int hpx_main()
+{
+    hpx::barrier b(2);
+
+    hpx::future<void> f1 = hpx::async([&b]() {
+        std::cout << "Thread 1 started." << std::endl;
+        // Do some computation
+        b.arrive_and_wait();
+        // Continue with next task
+        std::cout << "Thread 1 finished." << std::endl;
+    });
+
+    hpx::future<void> f2 = hpx::async([&b]() {
+        std::cout << "Thread 2 started." << std::endl;
+        // Do some computation
+        b.arrive_and_wait();
+        // Continue with next task
+        std::cout << "Thread 2 finished." << std::endl;
+    });
+
+    f1.get();
+    f2.get();
+
+    return hpx::local::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    return hpx::local::init(hpx_main, argc, argv);
+}
+
+
+

In this example, two hpx::future objects are created, each representing a separate thread of +execution. The wait function of the hpx::barrier object is called by each thread. The +threads will wait at the barrier until both have reached it. Once both threads have reached +the barrier, they can continue with their next task.

+
+
+
Condition variable#
+

A condition variable is a synchronization primitive +in HPX that allows a thread to wait for a specific condition to be satisfied before continuing +execution. It is typically used in conjunction with a mutex or a lock to protect shared data that is +being modified by multiple threads. Hence, it blocks one or more threads until another thread both +modifies a shared variable (the condition) and notifies the condition_variable. The code below +shows how two threads modifying the shared variable data can be synchronized using the +condition_variable:

+
#include <hpx/condition_variable.hpp>
+#include <hpx/init.hpp>
+#include <hpx/mutex.hpp>
+#include <hpx/thread.hpp>
+
+#include <iostream>
+#include <string>
+
+hpx::condition_variable cv;
+hpx::mutex m;
+std::string data;
+bool ready = false;
+bool processed = false;
+
+void worker_thread()
+{
+    // Wait until the main thread signals that data is ready
+    std::unique_lock<hpx::mutex> lk(m);
+    cv.wait(lk, [] { return ready; });
+
+    // Access the shared resource
+    std::cout << "Worker thread: Processing data...\n";
+    data = "Test data after";
+
+    // Send data back to the main thread
+    processed = true;
+    std::cout << "Worker thread: data processing is complete\n";
+
+    // Manual unlocking is done before notifying, to avoid waking up
+    // the waiting thread only to block again
+    lk.unlock();
+    cv.notify_one();
+}
+
+int hpx_main()
+{
+    hpx::thread worker(worker_thread);
+
+    // Do some work
+    std::cout << "Main thread: Preparing data...\n";
+    data = "Test data before";
+    hpx::this_thread::sleep_for(std::chrono::seconds(1));
+    std::cout << "Main thread: Data before processing = " << data << '\n';
+
+    // Signal that data is ready and send data to worker thread
+    {
+        std::lock_guard<hpx::mutex> lk(m);
+        ready = true;
+        std::cout << "Main thread: Data is ready...\n";
+    }
+    cv.notify_one();
+
+    // Wait for the worker thread to finish
+    {
+        std::unique_lock<hpx::mutex> lk(m);
+        cv.wait(lk, [] { return processed; });
+    }
+    std::cout << "Main thread: Data after processing = " << data << '\n';
+    worker.join();
+
+    return hpx::local::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    return hpx::local::init(hpx_main, argc, argv);
+}
+
+
+

The main thread of the code above starts by creating a worker thread and preparing the shared variable data. +Once the data is ready, the main thread acquires a lock on the mutex m using std::lock_guard<hpx::mutex> lk(m) +and sets the ready flag to true, then signals the worker thread to start processing by calling cv.notify_one(). +The cv.wait() call in the main thread then blocks until the worker thread signals that processing is +complete by setting the processed flag.

+

The worker thread starts by acquiring a lock on the mutex m to ensure exclusive access to the shared data. +The cv.wait() call blocks the thread until the ready flag is set by the main thread. Once this is +true, the worker thread accesses the shared data resource, processes it, and sets the processed flag +to indicate completion. The mutex is then unlocked using lk.unlock() and the cv.notify_one() call +signals the main thread to resume execution. Finally, the new data is printed by the main thread to the +console.

+
+
+
Latch#
+

A latch is a downward counter which can be used to synchronize threads. +The value of the counter is initialized on creation. Threads may block on the latch until the counter is +decremented to zero. There is no possibility to increase or reset the counter, which makes the latch a +single-use barrier.

+

In HPX, a latch is implemented as a counting semaphore, which can be initialized with a specific count +value and decremented each time a thread reaches the latch. When the count value reaches zero, all +waiting threads are unblocked and allowed to continue execution. The code below shows how latch can +be used to synchronize 16 threads:

+
std::ptrdiff_t num_threads = 16;
+
+///////////////////////////////////////////////////////////////////////////////
+void wait_for_latch(hpx::latch& l)
+{
+    l.arrive_and_wait();
+}
+
+///////////////////////////////////////////////////////////////////////////////
+int hpx_main(hpx::program_options::variables_map& vm)
+{
+    num_threads = vm["num-threads"].as<std::ptrdiff_t>();
+
+    hpx::latch l(num_threads + 1);
+
+    std::vector<hpx::future<void>> results;
+    for (std::ptrdiff_t i = 0; i != num_threads; ++i)
+        results.push_back(hpx::async(&wait_for_latch, std::ref(l)));
+
+    // Wait for all threads to reach this point.
+    l.arrive_and_wait();
+
+    hpx::wait_all(results);
+
+    return hpx::local::finalize();
+}
+
+
+

In the above code, the hpx_main function creates a latch object l with a count of num_threads + 1 +and num_threads number of threads using hpx::async. These threads call the wait_for_latch +function and pass the reference to the latch object. In the wait_for_latch function, the thread calls the +arrive_and_wait method on the latch, which decrements the count of the latch and causes the thread to wait +until the count reaches zero. Finally, the main thread waits for all the threads to arrive at the latch by +calling the arrive_and_wait method and then waits for all the threads to finish by calling the +hpx::wait_all method.

+
+
+
Mutex#
+

A mutex (short for “mutual exclusion”) is a synchronization primitive in +HPX used to control access to a shared resource, ensuring that only one thread can access it at a time. A +mutex is used to protect data structures from race conditions and other synchronization-related issues. When +a thread acquires a mutex, other threads that try to access the same resource will be blocked until the mutex +is released. The code below shows the basic use of mutexes:

+
#include <hpx/future.hpp>
+#include <hpx/init.hpp>
+#include <hpx/mutex.hpp>
+
+#include <iostream>
+
+int hpx_main()
+{
+    hpx::mutex m;
+
+    hpx::future<void> f1 = hpx::async([&m]() {
+        std::scoped_lock sl(m);
+        std::cout << "Thread 1 acquired the mutex" << std::endl;
+    });
+
+    hpx::future<void> f2 = hpx::async([&m]() {
+        std::scoped_lock sl(m);
+        std::cout << "Thread 2 acquired the mutex" << std::endl;
+    });
+
+    hpx::wait_all(f1, f2);
+
+    return hpx::local::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    return hpx::local::init(hpx_main, argc, argv);
+}
+
+
+

In this example, two HPX threads created using hpx::async are acquiring a hpx::mutex m. +std::scoped_lock sl(m) is used to take ownership of the given mutex m. When control leaves +the scope in which the scoped_lock object was created, the scoped_lock is destructed and +the mutex is released.

+
+

Attention

+

A common way to acquire and release mutexes is by using the function m.lock() before accessing +the shared resource, and m.unlock() called after the access is complete. However, these functions +may lead to deadlocks in case of exception(s). That is, if an exception happens when the mutex is locked +then the code that unlocks the mutex will never be executed, the lock will remain held by the thread +that acquired it, and other threads will be unable to access the shared resource. This can cause a +deadlock if the other threads are also waiting to acquire the same lock. For this reason, we suggest +you use std::scoped_lock, which prevents this issue by releasing the lock when control leaves the +scope in which the scoped_lock object was created.

+
+
+
+
Shared mutex#
+

A shared mutex is a synchronization primitive that can be used +to protect shared data from being simultaneously accessed by multiple threads. In contrast to other mutex +types which facilitate exclusive access, a shared_mutex has two levels of access:

+
    +
  • Exclusive access prevents any other thread from acquiring the mutex, just as with the normal mutex. +It does not matter if the other thread tries to acquire shared or exclusive access.

  • +
  • Shared access allows multiple threads to acquire the mutex, but all of them only in shared mode. +Exclusive access is not granted until all of the previous shared holders have returned the mutex +(typically, as long as an exclusive request is waiting, new shared ones are queued to be granted after +the exclusive access).

  • +
+

Shared mutexes are especially useful when shared data can be safely read by any number of threads +simultaneously, but a thread may only write the same data when no other thread is reading or writing +at the same time. A typical scenario is a database: The data can be read simultaneously by different +threads with no problem. However, modification of the database is critical: if some threads read data +while another one is writing, the threads reading may receive inconsistent data. Hence, while a thread +is writing, reading should not be allowed. After writing is complete, reads can occur simultaneously again. +The code below shows how shared_mutex can be used to synchronize reads and writes:

+
int const writers = 3;
+int const readers = 3;
+int const cycles = 10;
+
+using std::chrono::milliseconds;
+
+int hpx_main()
+{
+    std::vector<hpx::thread> threads;
+    std::atomic<bool> ready(false);
+    hpx::shared_mutex stm;
+
+    for (int i = 0; i < writers; ++i)
+    {
+        threads.emplace_back([&ready, &stm, i] {
+            std::mt19937 urng(static_cast<std::uint32_t>(std::time(nullptr)));
+            std::uniform_int_distribution<int> dist(1, 1000);
+
+            while (!ready)
+            { /*** wait... ***/
+            }
+
+            for (int j = 0; j < cycles; ++j)
+            {
+                // scope of unique_lock
+                {
+                    std::unique_lock<hpx::shared_mutex> ul(stm);
+
+                    std::cout << "^^^ Writer " << i << " starting..."
+                              << std::endl;
+                    hpx::this_thread::sleep_for(milliseconds(dist(urng)));
+                    std::cout << "vvv Writer " << i << " finished."
+                              << std::endl;
+                }
+
+                hpx::this_thread::sleep_for(milliseconds(dist(urng)));
+            }
+        });
+    }
+
+    for (int i = 0; i < readers; ++i)
+    {
+        int k = writers + i;
+        threads.emplace_back([&ready, &stm, k, i] {
+            HPX_UNUSED(k);
+            std::mt19937 urng(static_cast<std::uint32_t>(std::time(nullptr)));
+            std::uniform_int_distribution<int> dist(1, 1000);
+
+            while (!ready)
+            { /*** wait... ***/
+            }
+
+            for (int j = 0; j < cycles; ++j)
+            {
+                // scope of shared_lock
+                {
+                    std::shared_lock<hpx::shared_mutex> sl(stm);
+
+                    std::cout << "Reader " << i << " starting..." << std::endl;
+                    hpx::this_thread::sleep_for(milliseconds(dist(urng)));
+                    std::cout << "Reader " << i << " finished." << std::endl;
+                }
+                hpx::this_thread::sleep_for(milliseconds(dist(urng)));
+            }
+        });
+    }
+
+    ready = true;
+    for (auto& t : threads)
+        t.join();
+
+    return hpx::local::finalize();
+}
+
+
+

The above code creates writers and readers threads, each of which will perform cycles of operations. +Both the writer and reader threads use the hpx::shared_mutex object stm to synchronize access to a shared +resource.

+
    +
  • For the writer threads, a unique_lock on the shared mutex is acquired before each write operation and is released +after control leaves the scope in which the unique_lock object was created.

  • +
  • For the reader threads, a shared_lock on the shared mutex is acquired before each read operation and is released +after control leaves the scope in which the shared_lock object was created.

  • +
+

Before each operation, both the reader and writer threads sleep for a random time period, which is generated using +a random number generator. The random time period simulates the processing time of the operation.

+
+
+
Semaphore#
+

Semaphores are a synchronization mechanism used to control concurrent +access to a shared resource. The two types of semaphores are:

+
    +
  • counting semaphore: it has a counter that is bigger than zero. The counter is initialized in the constructor. +Acquiring the semaphore decreases the counter and releasing the semaphore increases the counter. If a thread +tries to acquire the semaphore when the counter is zero, the thread will block until another thread increments +the counter by releasing the semaphore. Unlike hpx::mutex, an hpx::counting_semaphore is not bound to a +thread, which means that the acquire and release call of a semaphore can happen on different threads.

  • +
  • binary semaphore: it is an alias for a hpx::counting_semaphore<1>. In this case, the least maximal value +is 1. hpx::binary_semaphore can be used to implement locks.

  • +
+
#include <hpx/init.hpp>
+#include <hpx/semaphore.hpp>
+#include <hpx/thread.hpp>
+
+#include <iostream>
+
+// initialize the semaphore with a count of 3
+hpx::counting_semaphore<> semaphore(3);
+
+void worker()
+{
+    semaphore.acquire();    // decrement the semaphore's count
+    std::cout << "Entering critical section" << std::endl;
+    hpx::this_thread::sleep_for(std::chrono::seconds(1));
+    semaphore.release();    // increment the semaphore's count
+    std::cout << "Exiting critical section" << std::endl;
+}
+
+int hpx_main()
+{
+    hpx::thread t1(worker);
+    hpx::thread t2(worker);
+    hpx::thread t3(worker);
+    hpx::thread t4(worker);
+    hpx::thread t5(worker);
+
+    t1.join();
+    t2.join();
+    t3.join();
+    t4.join();
+    t5.join();
+
+    return hpx::local::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    return hpx::local::init(hpx_main, argc, argv);
+}
+
+
+

In this example, the counting semaphore is initialized to the value of 3. This means that up to 3 threads can +access the critical section (the section of code inside the worker() function) at the same time. When a thread +enters the critical section, it acquires the semaphore, which decrements the count, while when it exits the +critical section, it releases the semaphore, incrementing thus the count. The worker() function simulates a +critical section by acquiring the semaphore, sleeping for 1 second and then releasing the semaphore.

+

In the main function, 5 worker threads are created and started, each trying to enter the critical section. +If the count of the semaphore is already 0, a worker will wait until another worker releases the semaphore +(increasing its value).

+
+
+
Composable guards#
+

Composable guards operate in a manner similar to locks, but are applied only to +asynchronous functions. The guard (or guards) is automatically locked at the +beginning of a specified task and automatically unlocked at the end. Because +guards are never added to an existing task’s execution context, the calling of +guards is freely composable and can never deadlock.

+

To call an application with a single guard, simply declare the guard and call +run_guarded() with a function (task):

+
hpx::lcos::local::guard gu;
+run_guarded(gu,task);
+
+
+

If a single method needs to run with multiple guards, use a guard set:

+
std::shared_ptr<hpx::lcos::local::guard> gu1(new hpx::lcos::local::guard());
+std::shared_ptr<hpx::lcos::local::guard> gu2(new hpx::lcos::local::guard());
+gs.add(*gu1);
+gs.add(*gu2);
+run_guarded(gs,task);
+
+
+

Guards use two atomic operations (which are not called repeatedly) to manage +what they do, so overhead should be extremely low.

+
+
+
+
Execution control#
+

The following objects are providing control of the execution in HPX applications:

+
    +
  1. Futures

  2. +
  3. Channels

  4. +
  5. Task blocks

  6. +
  7. Task groups

  8. +
  9. Threads

  10. +
+
+
Futures#
+

Futures are a mechanism to represent the result of a +potentially asynchronous operation. A future is a type that represents a value that will +become available at some point in the future, and it can be used to write asynchronous and +parallel code. Futures can be returned from functions that perform time-consuming operations, +allowing the calling code to continue executing while the function performs its work. The +value of the future is set when the operation completes and can be accessed later. Futures +are used in HPX to write asynchronous and parallel code. Below is an example demonstrating +different features of futures:

+
#include <hpx/assert.hpp>
+#include <hpx/future.hpp>
+#include <hpx/hpx_main.hpp>
+#include <hpx/tuple.hpp>
+
+#include <iostream>
+#include <utility>
+
+int main()
+{
+    // Asynchronous execution with futures
+    hpx::future<void> f1 = hpx::async(hpx::launch::async, []() {});
+    hpx::shared_future<int> f2 =
+        hpx::async(hpx::launch::async, []() { return 42; });
+    hpx::future<int> f3 =
+        f2.then([](hpx::shared_future<int>&& f) { return f.get() * 3; });
+
+    hpx::promise<double> p;
+    auto f4 = p.get_future();
+    HPX_ASSERT(!f4.is_ready());
+    p.set_value(123.45);
+    HPX_ASSERT(f4.is_ready());
+
+    hpx::packaged_task<int()> t([]() { return 43; });
+    hpx::future<int> f5 = t.get_future();
+    HPX_ASSERT(!f5.is_ready());
+    t();
+    HPX_ASSERT(f5.is_ready());
+
+    // Fire-and-forget
+    hpx::post([]() {
+        std::cout << "This will be printed later\n" << std::flush;
+    });
+
+    // Synchronous execution
+    hpx::sync([]() {
+        std::cout << "This will be printed immediately\n" << std::flush;
+    });
+
+    // Combinators
+    hpx::future<double> f6 = hpx::async([]() { return 3.14; });
+    hpx::future<double> f7 = hpx::async([]() { return 42.0; });
+    std::cout
+        << hpx::when_all(f6, f7)
+               .then([](hpx::future<
+                         hpx::tuple<hpx::future<double>, hpx::future<double>>>
+                             f) {
+                   hpx::tuple<hpx::future<double>, hpx::future<double>> t =
+                       f.get();
+                   double pi = hpx::get<0>(t).get();
+                   double r = hpx::get<1>(t).get();
+                   return pi * r * r;
+               })
+               .get()
+        << std::endl;
+
+    // Easier continuations with dataflow; it waits for all future or
+    // shared_future arguments before executing the continuation, and also
+    // accepts non-future arguments
+    hpx::future<double> f8 = hpx::async([]() { return 3.14; });
+    hpx::future<double> f9 = hpx::make_ready_future(42.0);
+    hpx::shared_future<double> f10 = hpx::async([]() { return 123.45; });
+    hpx::future<hpx::tuple<double, double>> f11 = hpx::dataflow(
+        [](hpx::future<double> a, hpx::future<double> b,
+            hpx::shared_future<double> c, double d) {
+            return hpx::make_tuple<>(a.get() + b.get(), c.get() / d);
+        },
+        f8, f9, f10, -3.9);
+
+    // split_future gives a tuple of futures from a future of tuple
+    hpx::tuple<hpx::future<double>, hpx::future<double>> f12 =
+        hpx::split_future(std::move(f11));
+    std::cout << hpx::get<1>(f12).get() << std::endl;
+
+    return 0;
+}
+
+
+

The first section of the main function demonstrates how to use futures for asynchronous execution. +The first two lines create two futures, one for void and another for an integer, using the +hpx::async() function. These futures are executed asynchronously in separate threads using +the hpx::launch::async launch policy. The third future is created by chaining the second +future using the then() member function. This future multiplies the result of the second future +by 3.

+

The next part of the code demonstrates how to use promises and packaged tasks, which are constructs +used for communicating data between threads. The promise class is used to store a value that can be +retrieved later using a future. The packaged_task class represents a task that can be executed +asynchronously, and its result can be obtained using a future. The last three lines create a +packaged task that returns an integer, obtain its future, execute the task, and check whether the +future is ready or not.

+

The code then demonstrates how to use the hpx::post() and hpx::sync() functions for +fire-and-forget and synchronous execution, respectively. The hpx::post() function executes a +given function asynchronously and returns immediately without waiting for the result. The +hpx::sync() function executes a given function synchronously and waits for the result before +returning.

+

Next the code demonstrates the use of combinators, which are higher-order functions that combine +two or more futures into a single future. The hpx::when_all() function is used to combine two futures, +which return double values, into a tuple of futures. The then() member function is then used to +compute the area of a circle using the values of the two futures. The get() member function is used to +retrieve the result of the computation.

+

The last section demonstrates the use of hpx::dataflow(), which is a higher-order function that waits +for all the future or shared_future arguments to be ready before executing the continuation. The +hpx::make_ready_future() function is used to create a future with a given value. The +hpx::split_future() function is used to split a future of a tuple into a tuple of futures. The last +line retrieves the value of the second future in the tuple using hpx::get() and prints it to the console.

+
+Extended facilities for futures# +

Concurrency is about both decomposing and composing the program from the parts +that work well individually and together. It is in the composition of connected +and multicore components where today’s C++ libraries are still lacking.

+

The functionality of std::future offers a partial solution. +It allows for the separation of the initiation of an operation and the act of waiting +for its result; however, the act of waiting is synchronous. In communication-intensive +code this act of waiting can be unpredictable, inefficient and simply +frustrating. The example below illustrates a possible synchronous wait using +futures:

+
#include <future>
+using namespace std;
+int main()
+{
+    future<int> f = async([]() { return 123; });
+    int result = f.get(); // might block
+}
+
+
+

For this reason, HPX implements a set of extensions to +std::future (as proposed by N4313). This +proposal introduces the following key asynchronous operations to +hpx::future, hpx::shared_future and hpx::async, +which enhance and enrich these facilities.

+ + ++++ + + + + + + + + + + + + + + + + + +
Table 10 Facilities extending std::future#

Facility

Description

hpx::future::then

In asynchronous programming, it is very common for one asynchronous +operation, on completion, to invoke a second operation and pass data to +it. The current C++ standard does not allow one to register a +continuation to a future. With then, instead of waiting for the result, +a continuation is “attached” to the asynchronous operation, which is +invoked when the result is ready. Continuations registered using then +function will help to avoid blocking waits or wasting threads on polling, +greatly improving the responsiveness and scalability of an application.

unwrapping constructor for hpx::future

In some scenarios, you might want to create a future that returns another +future, resulting in nested futures. Although it is possible to write +code to unwrap the outer future and retrieve the nested future and its +result, such code is not easy to write because users must handle exceptions +and it may cause a blocking call. Unwrapping can allow users to mitigate +this problem by doing an asynchronous call to unwrap the outermost +future.

hpx::future::is_ready

There are often situations where a get() call on a future may not be +a blocking call, or is only a blocking call under certain circumstances. +This function gives the ability to test for early completion and allows +us to avoid associating a continuation, which needs to be scheduled with +some non-trivial overhead and near-certain loss of cache efficiency.

hpx::make_ready_future

Some functions may know the value at the point of construction. In these +cases the value is immediately available, but needs to be returned as a +future. By using hpx::make_ready_future a future can be created that +holds a pre-computed result in its shared state. In the current standard +it is non-trivial to create a future directly from a value. First a +promise must be created, then the promise is set, and lastly the future +is retrieved from the promise. This can now be done with one operation.

+

The standard also omits the ability to compose multiple futures. This is a +common pattern that is ubiquitous in other asynchronous frameworks and is +absolutely necessary in order to make C++ a powerful asynchronous programming +language. Not including these functions is synonymous to Boolean algebra without +AND/OR.

+

In addition to the extensions proposed by N4313, HPX adds functions +allowing users to compose several futures in a more flexible way.

+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 11 Facilities for composing hpx::futures#

Facility

Description

hpx::when_any, hpx::when_any_n

Asynchronously wait for at least one of multiple future or shared_future +objects to finish.

hpx::wait_any, hpx::wait_any_n

Synchronously wait for at least one of multiple future or shared_future +objects to finish.

hpx::when_all, hpx::when_all_n

Asynchronously wait for all future and shared_future objects to finish.

hpx::wait_all, hpx::wait_all_n

Synchronously wait for all future and shared_future objects to finish.

hpx::when_some, hpx::when_some_n

Asynchronously wait for multiple future and shared_future objects to +finish.

hpx::wait_some, hpx::wait_some_n

Synchronously wait for multiple future and shared_future objects to +finish.

hpx::when_each

Asynchronously wait for multiple future and shared_future objects to +finish and call a function for each of the future objects as soon as it +becomes ready.

hpx::wait_each, hpx::wait_each_n

Synchronously wait for multiple future and shared_future objects to +finish and call a function for each of the future objects as soon as it +becomes ready.

+
+
+
+
Channels#
+

Channels combine communication (the exchange of a value) +with synchronization (guaranteeing that two calculations (tasks) are in a known state). A channel +can transport any number of values of a given type from a sender to a receiver:

+
    hpx::lcos::local::channel<int> c;
+    hpx::future<int> f = c.get();
+    HPX_ASSERT(!f.is_ready());
+    c.set(42);
+    HPX_ASSERT(f.is_ready());
+    std::cout << f.get() << std::endl;
+
+
+

Channels can be handed to another thread (or in case of channel components, to +other localities), thus establishing a communication channel between two +independent places in the program:

+
void do_something(hpx::lcos::local::receive_channel<int> c,
+    hpx::lcos::local::send_channel<> done)
+{
+    // prints 43
+    std::cout << c.get(hpx::launch::sync) << std::endl;
+    // signal back
+    done.set();
+}
+
+void send_receive_channel()
+{
+    hpx::lcos::local::channel<int> c;
+    hpx::lcos::local::channel<> done;
+
+    hpx::post(&do_something, c, done);
+
+    // send some value
+    c.set(43);
+    // wait for thread to be done
+    done.get().wait();
+}
+
+
+

Note how hpx::lcos::local::channel::get without any arguments +returns a future which is ready when a value has been set on the channel. The +launch policy hpx::launch::sync can be used to make +hpx::lcos::local::channel::get block until a value is set and +return the value directly.

+

A channel component is created on one locality and can be sent to +another locality using an action. This example also demonstrates how a +channel can be used as a range of values:

+
// channel components need to be registered for each used type (not needed
+// for hpx::lcos::local::channel)
+HPX_REGISTER_CHANNEL(double)
+
+void channel_sender(hpx::lcos::channel<double> c)
+{
+    for (double d : c)
+        hpx::cout << d << std::endl;
+}
+HPX_PLAIN_ACTION(channel_sender)
+
+void channel()
+{
+    // create the channel on this locality
+    hpx::lcos::channel<double> c(hpx::find_here());
+
+    // pass the channel to a (possibly remote invoked) action
+    hpx::post(channel_sender_action(), hpx::find_here(), c);
+
+    // send some values to the receiver
+    std::vector<double> v = {1.2, 3.4, 5.0};
+    for (double d : v)
+        c.set(d);
+
+    // explicitly close the communication channel (implicit at destruction)
+    c.close();
+}
+
+
+
+
+
Task blocks#
+

Task blocks in HPX provide a way to +structure and organize the execution of tasks in a parallel program, making it +easier to manage dependencies between tasks. A task block actually is a group of +tasks that can be executed in parallel. Tasks in a task block can depend on other +tasks in the same task block. The task block allows the runtime to optimize +the execution of tasks, by scheduling them in an optimal order based on the +dependencies between them.

+

The define_task_block, run and the wait functions implemented based +on N4755 are based on the task_block concept that is a part of the +common subset of the Microsoft Parallel Patterns Library (PPL) and the Intel Threading Building Blocks (TBB) libraries.

+

These implementations adopt a simpler syntax than exposed by those libraries— +one that is influenced by language-based concepts, such as spawn and sync from +Cilk++ and async and finish from X10. They improve on existing practice in +the following ways:

+
    +
  • The exception handling model is simplified and more consistent with normal C++ +exceptions.

  • +
  • Most violations of strict fork-join parallelism can be enforced at compile +time (with compiler assistance, in some cases).

  • +
  • The syntax allows scheduling approaches other than child stealing.

  • +
+

Consider an example of a parallel traversal of a tree, where a user-provided +function compute is applied to each node of the tree, returning the sum of the +results:

+
template <typename Func>
+int traverse(node& n, Func && compute)
+{
+    int left = 0, right = 0;
+    define_task_block(
+        [&](task_block<>& tr) {
+            if (n.left)
+                tr.run([&] { left = traverse(*n.left, compute); });
+            if (n.right)
+                tr.run([&] { right = traverse(*n.right, compute); });
+        });
+
+    return compute(n) + left + right;
+}
+
+
+

The example above demonstrates the use of two of the functions, +hpx::experimental::define_task_block and the +hpx::experimental::task_block::run member function of a +hpx::experimental::task_block.

+

The task_block function delineates a region in a program code potentially +containing invocations of threads spawned by the run member function of the +task_block class. The run function spawns an HPX thread, a unit of +work that is allowed to execute in parallel with respect to the caller. Any +parallel tasks spawned by run within the task block are joined back to a +single thread of execution at the end of the define_task_block. run +takes a user-provided function object f and starts it asynchronously—i.e., +it may return before the execution of f completes. The HPX scheduler may +choose to run f immediately or delay running f until compute resources +become available.

+

A task_block can be constructed only by define_task_block because it has +no public constructors. Thus, run can be invoked directly or indirectly +only from a user-provided function passed to define_task_block:

+
void g();
+
+void f(task_block<>& tr)
+{
+    tr.run(g);          // OK, invoked from within task_block in h
+}
+
+void h()
+{
+    define_task_block(f);
+}
+
+int main()
+{
+    task_block<> tr;    // Error: no public constructor
+    tr.run(g);          // No way to call run outside of a define_task_block
+    return 0;
+}
+
+
+
+Extensions for task blocks# +
+Using execution policies with task blocks# +

HPX implements some extensions for task_block beyond the actual +standards proposal N4755. The main addition is that a task_block +can be invoked with an execution policy as its first argument, very similar to +the parallel algorithms.

+

An execution policy is an object that expresses the requirements on the +ordering of functions invoked as a consequence of the invocation of a +task block. Enabling passing an execution policy to define_task_block +gives the user control over the amount of parallelism employed by the +created task_block. In the following example the use of an explicit +par execution policy makes the user’s intent explicit:

+
template <typename Func>
+int traverse(node *n, Func&& compute)
+{
+    int left = 0, right = 0;
+
+    define_task_block(
+        execution::par,                // execution::parallel_policy
+        [&](task_block<>& tb) {
+            if (n->left)
+                tb.run([&] { left = traverse(n->left, compute); });
+            if (n->right)
+                tb.run([&] { right = traverse(n->right, compute); });
+        });
+
+    return compute(n) + left + right;
+}
+
+
+

This also causes the hpx::experimental::task_block object to be a +template in our implementation. The template argument is the type of the +execution policy used to create the task block. The template argument defaults +to hpx::execution::parallel_policy.

+

HPX still supports calling hpx::experimental::define_task_block +without an explicit execution policy. In this case the task block will run using +the hpx::execution::parallel_policy.

+

HPX also adds the ability to access the execution policy that was used to +create a given task_block.

+
+
+Using executors to run tasks# +

Often, users want to be able to not only define an execution policy to use by +default for all spawned tasks inside the task block, but also to +customize the execution context for one of the tasks executed by +task_block::run. Adding an optionally passed executor instance to that +function enables this use case:

+
template <typename Func>
+int traverse(node *n, Func&& compute)
+{
+    int left = 0, right = 0;
+
+    define_task_block(
+        execution::par,                // execution::parallel_policy
+        [&](auto& tb) {
+            if (n->left)
+            {
+                // use explicitly specified executor to run this task
+                tb.run(my_executor(), [&] { left = traverse(n->left, compute); });
+            }
+            if (n->right)
+            {
+                // use the executor associated with the par execution policy
+                tb.run([&] { right = traverse(n->right, compute); });
+            }
+        });
+
+    return compute(n) + left + right;
+}
+
+
+

HPX still supports calling hpx::experimental::task_block::run +without an explicit executor object. In this case the task will be run using the +executor associated with the execution policy that was used to call +hpx::experimental::define_task_block.

+
+
+
+
+
Task groups#
+

A task group in HPX is a synchronization primitive +that allows you to execute a group of tasks concurrently and wait for their completion before +continuing. The tasks in an hpx::experimental::task_group can be added dynamically. This is the HPX +implementation of tbb::task_group of the Intel Threading Building Blocks (TBB) library.

+

The example below shows that to use a task group, you simply create an hpx::task_group object +and add tasks to it using the run() method. Once all the tasks have been added, you can call +the wait() method to synchronize the tasks and wait for them to complete.

+
#include <hpx/experimental/task_group.hpp>
+#include <hpx/init.hpp>
+
+#include <iostream>
+
+void task1()
+{
+    std::cout << "Task 1 executed." << std::endl;
+}
+
+void task2()
+{
+    std::cout << "Task 2 executed." << std::endl;
+}
+
+int hpx_main()
+{
+    hpx::experimental::task_group tg;
+
+    tg.run(task1);
+    tg.run(task2);
+
+    tg.wait();
+
+    std::cout << "All tasks finished!" << std::endl;
+
+    return hpx::local::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    return hpx::local::init(hpx_main, argc, argv);
+}
+
+
+
+

Note

+

task groups and task blocks are both ways to group and synchronize parallel tasks, but +task groups are used to group multiple tasks together as a single unit, while task blocks +are used to execute a loop in parallel, with each iteration of the loop executing in a separate +task. If the difference is not clear yet, continue reading.

+

A task group is a construct that allows multiple parallel tasks to be grouped together as a +single unit. The task group provides a way to synchronize all the tasks in the group before +continuing with the rest of the program.

+

A task block, on the other hand, is a parallel loop construct that allows you to execute a +loop in parallel, with each iteration of the loop executing in a separate task. The loop +iterations are executed in a block, meaning that the loop body is executed as a single task.

+
+
+
+
Threads#
+

A thread in HPX refers to a sequence of instructions +that can be executed concurrently with other such sequences in multithreading environments, while +sharing a same address space. These threads can communicate with each other through various means, +such as futures or shared data structures.

+

The example below demonstrates how to launch multiple threads and synchronize them using a hpx::latch +object. It also shows how to query the state of threads and wait for futures to complete.

+
#include <hpx/future.hpp>
+#include <hpx/init.hpp>
+#include <hpx/thread.hpp>
+
+#include <functional>
+#include <iostream>
+#include <vector>
+
+int const num_threads = 10;
+
+///////////////////////////////////////////////////////////////////////////////
+void wait_for_latch(hpx::latch& l)
+{
+    l.arrive_and_wait();
+}
+
+int hpx_main()
+{
+    // Spawn a couple of threads
+    hpx::latch l(num_threads + 1);
+
+    std::vector<hpx::future<void>> results;
+    results.reserve(num_threads);
+
+    for (int i = 0; i != num_threads; ++i)
+        results.push_back(hpx::async(&wait_for_latch, std::ref(l)));
+
+    // Allow spawned threads to reach latch
+    hpx::this_thread::yield();
+
+    // Enumerate all suspended threads
+    hpx::threads::enumerate_threads(
+        [](hpx::threads::thread_id_type id) -> bool {
+            std::cout << "thread " << hpx::thread::id(id) << " is "
+                      << hpx::threads::get_thread_state_name(
+                             hpx::threads::get_thread_state(id))
+                      << std::endl;
+            return true;    // always continue enumeration
+        },
+        hpx::threads::thread_schedule_state::suspended);
+
+    // Wait for all threads to reach this point.
+    l.arrive_and_wait();
+
+    hpx::wait_all(results);
+
+    return hpx::local::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    return hpx::local::init(hpx_main, argc, argv);
+}
+
+
+

In more detail, the wait_for_latch() function is a simple helper function that waits for a hpx::latch +object to be released. At this point we remind that hpx::latch is a synchronization primitive that +allows multiple threads to wait for a common event to occur.

+

In the hpx_main() function, an hpx::latch object is created with a count of num_threads + 1, +indicating that num_threads threads need to arrive at the latch before the latch is released. The loop +that follows launches num_threads asynchronous operations, each of which calls the wait_for_latch +function. The resulting futures are added to the vector.

+

After the threads have been launched, hpx::this_thread::yield() is called to give them a chance to +reach the latch before the program proceeds. Then, the hpx::threads::enumerate_threads function +prints the state of each suspended thread, while the next call of l.arrive_and_wait() waits for all +the threads to reach the latch. Finally, hpx::wait_all is called to wait for all the futures to complete.

+
+

Hint

+

An advantage of using hpx::thread over other threading libraries is that it is optimized for +high-performance parallelism, with support for lightweight threads and task scheduling to minimize +thread overhead and maximize parallelism. Additionally, hpx::thread integrates seamlessly with +other features of HPX such as futures, promises, and task groups, making it a powerful tool for +parallel programming.

+

Checkout the examples of Shared mutex, Condition variable, Semaphore +to see how HPX threads are used in combination with other features.

+
+
+
+
+
High level parallel facilities#
+

In preparation for the upcoming C++ Standards, there are currently several proposals +targeting different facilities supporting parallel programming. HPX implements +(and extends) some of those proposals. This is well aligned with our strategy to +align the APIs exposed from HPX with current and future C++ Standards.

+

At this point, HPX implements several of the C++ Standardization working +papers, most notably N4409 (Working Draft, Technical Specification for +C++ Extensions for Parallelism), N4755 (Task Blocks), and +N4406 (Parallel Algorithms Need Executors).

+
+
Using parallel algorithms#
+

A parallel algorithm is a function template declared in the namespace +hpx::parallel.

+

All parallel algorithms are very similar in semantics to their sequential +counterparts (as defined in the namespace std) with an additional formal +template parameter named ExecutionPolicy. The execution policy is generally +passed as the first argument to any of the parallel algorithms and describes the +manner in which the execution of these algorithms may be parallelized and the +manner in which they apply user-provided function objects.

+

The applications of function objects in parallel algorithms invoked with an +execution policy object of type hpx::execution::sequenced_policy or +hpx::execution::sequenced_task_policy execute in sequential order. For +hpx::execution::sequenced_policy the execution happens in the calling thread.

+

The applications of function objects in parallel algorithms invoked with an +execution policy object of type hpx::execution::parallel_policy or +hpx::execution::parallel_task_policy are permitted to execute in an unordered +fashion in unspecified threads, and are indeterminately sequenced within each +thread.

+
+

Important

+

It is the caller’s responsibility to ensure correctness, such as making sure that the +invocation does not introduce data races or deadlocks.

+
+

The example below demonstrates how to perform a sequential and parallel hpx::for_each loop on a vector of integers.

+
#include <hpx/algorithm.hpp>
+#include <hpx/execution.hpp>
+#include <hpx/init.hpp>
+
+#include <iostream>
+#include <vector>
+
+int hpx_main()
+{
+    std::vector<int> v{1, 2, 3, 4, 5};
+
+    auto print = [](const int& n) { std::cout << n << ' '; };
+
+    std::cout << "Print sequential: ";
+    hpx::for_each(v.begin(), v.end(), print);
+    std::cout << '\n';
+
+    std::cout << "Print parallel: ";
+    hpx::for_each(hpx::execution::par, v.begin(), v.end(), print);
+    std::cout << '\n';
+
+    return hpx::local::finalize();
+}
+
+int main(int argc, char* argv[])
+{
+    return hpx::local::init(hpx_main, argc, argv);
+}
+
+
+

The above code uses hpx::for_each to print the elements of the vector v{1, 2, 3, 4, 5}. +At first, hpx::for_each() is called without an execution policy, which means that it applies +the lambda function print to each element in the vector sequentially. Hence, the elements are +printed in order.

+

Next, hpx::for_each() is called with the hpx::execution::par execution policy, +which applies the lambda function print to each element in the vector in parallel. Therefore, +the output order of the elements in the vector is not deterministic and may vary from run to run.

+
+
+
Parallel exceptions#
+

During the execution of a standard parallel algorithm, if temporary memory +resources are required by any of the algorithms and no memory is available, the +algorithm throws a std::bad_alloc exception.

+

During the execution of any of the parallel algorithms, if the application of a +function object terminates with an uncaught exception, the behavior of the +program is determined by the type of execution policy used to invoke the +algorithm:

+ +

For example, the number of invocations of the user-provided function object in +for_each is unspecified. When hpx::for_each is executed sequentially, only one +exception will be contained in the hpx::exception_list object.

+

These guarantees imply that, unless the algorithm has failed to allocate memory +and terminated with std::bad_alloc, all exceptions thrown during the +execution of the algorithm are communicated to the caller. It is unspecified +whether an algorithm implementation will “forge ahead” after encountering and +capturing a user exception.

+

The algorithm may terminate with the std::bad_alloc exception even if one or +more user-provided function objects have terminated with an exception. For +example, this can happen when an algorithm fails to allocate memory while +creating or adding elements to the hpx::exception_list object.

+
+
+
Parallel algorithms#
+

HPX provides implementations of the following parallel algorithms:

+ + +++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 12 Non-modifying parallel algorithms of header hpx/algorithm.hpp#

Name

Description

C++ standard

hpx::adjacent_find

Computes the differences between adjacent elements in a range.

adjacent_find

hpx::all_of

Checks if a predicate is true for all of the elements in a range.

all_any_none_of

hpx::any_of

Checks if a predicate is true for any of the elements in a range.

all_any_none_of

hpx::count

Returns the number of elements equal to a given value.

count

hpx::count_if

Returns the number of elements satisfying a specific criteria.

count_if

hpx::equal

Determines if two sets of elements are the same.

equal

hpx::find

Finds the first element equal to a given value.

find

hpx::find_end

Finds the last sequence of elements in a certain range.

find_end

hpx::find_first_of

Searches for any one of a set of elements.

find_first_of

hpx::find_if

Finds the first element satisfying a specific criteria.

find_if

hpx::find_if_not

Finds the first element not satisfying a specific criteria.

find_if_not

hpx::for_each

Applies a function to a range of elements.

for_each

hpx::for_each_n

Applies a function to a number of elements.

for_each_n

hpx::lexicographical_compare

Checks if a range of values is lexicographically less than another range of values.

lexicographical_compare

hpx::mismatch

Finds the first position where two ranges differ.

mismatch

hpx::none_of

Checks if a predicate is true for none of the elements in a range.

all_any_none_of

hpx::search

Searches for a range of elements.

search

hpx::search_n

Searches for a number consecutive copies of an element in a range.

search_n

+
+

+
+ + +++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 13 Modifying parallel algorithms of header hpx/algorithm.hpp#

Name

Description

C++ standard

hpx::copy

Copies a range of elements to a new location.

exclusive_scan

hpx::copy_n

Copies a number of elements to a new location.

copy_n

hpx::copy_if

Copies the elements from a range to a new location for which the given predicate is true

copy

hpx::move

Moves a range of elements to a new location.

move

hpx::fill

Assigns a range of elements a certain value.

fill

hpx::fill_n

Assigns a value to a number of elements.

fill_n

hpx::generate

Saves the result of a function in a range.

generate

hpx::generate_n

Saves the result of N applications of a function.

generate_n

hpx::experimental::reduce_by_key

Performs an inclusive scan on consecutive elements with matching keys, +with a reduction to output only the final sum for each key. The key +sequence {1,1,1,2,3,3,3,3,1} and value sequence +{2,3,4,5,6,7,8,9,10} would be reduced to keys={1,2,3,1}, +values={9,5,30,10}.

hpx::remove

Removes the elements from a range that are equal to the given value.

remove

hpx::remove_if

Removes the elements from a range that are equal to the given predicate is false

remove

hpx::remove_copy

Copies the elements from a range to a new location that are not equal to the given value.

remove_copy

hpx::remove_copy_if

Copies the elements from a range to a new location for which the given predicate is false

remove_copy

hpx::replace

Replaces all values satisfying specific criteria with another value.

replace

hpx::replace_if

Replaces all values satisfying specific criteria with another value.

replace

hpx::replace_copy

Copies a range, replacing elements satisfying specific criteria with another value.

replace_copy

hpx::replace_copy_if

Copies a range, replacing elements satisfying specific criteria with another value.

replace_copy

hpx::reverse

Reverses the order elements in a range.

reverse

hpx::reverse_copy

Creates a copy of a range that is reversed.

reverse_copy

hpx::rotate

Rotates the order of elements in a range.

rotate

hpx::rotate_copy

Copies and rotates a range of elements.

rotate_copy

hpx::shift_left

Shifts the elements in the range left by n positions.

shift_left

hpx::shift_right

Shifts the elements in the range right by n positions.

shift_right

hpx::swap_ranges

Swaps two ranges of elements.

swap_ranges

hpx::transform

Applies a function to a range of elements.

transform

hpx::unique

Eliminates all but the first element from every consecutive group of equivalent elements from a range.

unique

hpx::unique_copy

Copies the elements from one range to another in such a way that there are no consecutive equal elements.

unique_copy

+
+

+
+ + +++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 14 Set operations on sorted sequences of header hpx/algorithm.hpp#

Name

Description

C++ standard

hpx::merge

Merges two sorted ranges.

merge

hpx::inplace_merge

Merges two ordered ranges in-place.

inplace_merge

hpx::includes

Returns true if one set is a subset of another.

includes

hpx::set_difference

Computes the difference between two sets.

set_difference

hpx::set_intersection

Computes the intersection of two sets.

set_intersection

hpx::set_symmetric_difference

Computes the symmetric difference between two sets.

set_symmetric_difference

hpx::set_union

Computes the union of two sets.

set_union

+
+

+
+ + +++++ + + + + + + + + + + + + + + + + + + +
Table 15 Heap operations of header hpx/algorithm.hpp#

Name

Description

C++ standard

hpx::is_heap

Returns true if the range is max heap.

is_heap

hpx::is_heap_until

Returns the first element that breaks a max heap.

is_heap_until

hpx::make_heap

Constructs a max heap in the range [first, last).

make_heap

+
+

+
+ + +++++ + + + + + + + + + + + + + + + + + + +
Table 16 Minimum/maximum operations of header hpx/algorithm.hpp#

Name

Description

C++ standard

hpx::max_element

Returns the largest element in a range.

max_element

hpx::min_element

Returns the smallest element in a range.

min_element

hpx::minmax_element

Returns the smallest and the largest element in a range.

minmax_element

+
+

+
+ + +++++ + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 17 Partitioning Operations of header hpx/algorithm.hpp#

Name

Description

C++ standard

hpx::nth_element

Partially sorts the given range making sure that it is partitioned by the given element

nth_element

hpx::is_partitioned

Returns true if each true element for a predicate precedes the false elements in a range.

is_partitioned

hpx::partition

Divides elements into two groups without preserving their relative order.

partition

hpx::partition_copy

Copies a range dividing the elements into two groups.

partition_copy

hpx::stable_partition

Divides elements into two groups while preserving their relative order.

stable_partition

+
+

+
+ + +++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 18 Sorting Operations of header hpx/algorithm.hpp#

Name

Description

C++ standard

hpx::is_sorted

Returns true if each element in a range is sorted.

is_sorted

hpx::is_sorted_until

Returns the first unsorted element.

is_sorted_until

hpx::sort

Sorts the elements in a range.

sort

hpx::stable_sort

Sorts the elements in a range, maintain sequence of equal elements.

stable_sort

hpx::partial_sort

Sorts the first elements in a range.

partial_sort

hpx::partial_sort_copy

Sorts the first elements in a range, storing the result in another range.

partial_sort_copy

hpx::experimental::sort_by_key

Sorts one range of data using keys supplied in another range.

+
+

+
+ + +++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 19 Numeric Parallel Algorithms of header hpx/numeric.hpp#

Name

Description

C++ standard

hpx::adjacent_difference

Calculates the difference between each element in an input range and the preceding element.

adjacent_difference

hpx::exclusive_scan

Does an exclusive parallel scan over a range of elements.

exclusive_scan

hpx::inclusive_scan

Does an inclusive parallel scan over a range of elements.

inclusive_scan

hpx::reduce

Sums up a range of elements.

reduce

hpx::transform_exclusive_scan

Does an exclusive parallel scan over a range of elements after applying a function.

transform_exclusive_scan

hpx::transform_inclusive_scan

Does an inclusive parallel scan over a range of elements after applying a function.

transform_inclusive_scan

hpx::transform_reduce

Sums up a range of elements after applying a function. Also, accumulates the inner products of two input ranges.

transform_reduce

+
+

+
+ + +++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 20 Dynamic Memory Management of header hpx/memory.hpp#

Name

Description

C++ standard

hpx::destroy

Destroys a range of objects.

destroy

hpx::destroy_n

Destroys a range of objects.

destroy_n

hpx::uninitialized_copy

Copies a range of objects to an uninitialized area of memory.

uninitialized_copy

hpx::uninitialized_copy_n

Copies a number of objects to an uninitialized area of memory.

uninitialized_copy_n

hpx::uninitialized_default_construct

Copies a range of objects to an uninitialized area of memory.

uninitialized_default_construct

hpx::uninitialized_default_construct_n

Copies a number of objects to an uninitialized area of memory.

uninitialized_default_construct_n

hpx::uninitialized_fill

Copies an object to an uninitialized area of memory.

uninitialized_fill

hpx::uninitialized_fill_n

Copies an object to an uninitialized area of memory.

uninitialized_fill_n

hpx::uninitialized_move

Moves a range of objects to an uninitialized area of memory.

uninitialized_move

hpx::uninitialized_move_n

Moves a number of objects to an uninitialized area of memory.

uninitialized_move_n

hpx::uninitialized_value_construct

Constructs objects in an uninitialized area of memory.

uninitialized_value_construct

hpx::uninitialized_value_construct_n

Constructs objects in an uninitialized area of memory.

uninitialized_value_construct_n

+
+

+
+ + ++++ + + + + + + + + + + + + + + + + + +
Table 21 Index-based for-loops of header hpx/algorithm.hpp#

Name

Description

hpx::experimental::for_loop

Implements loop functionality over a range specified by integral or iterator bounds.

hpx::experimental::for_loop_strided

Implements loop functionality over a range specified by integral or iterator bounds.

hpx::experimental::for_loop_n

Implements loop functionality over a range specified by integral or iterator bounds.

hpx::experimental::for_loop_n_strided

Implements loop functionality over a range specified by integral or iterator bounds.

+
+
+
Executor parameters and executor parameter traits#
+

HPX introduces the notion of execution parameters and execution parameter +traits. At this point, the only parameter that can be customized is the size of +the chunks of work executed on a single HPX thread (such as the number of loop +iterations combined to run as a single task).

+

An executor parameter object is responsible for exposing the calculation of the +size of the chunks scheduled. It abstracts the (potentially platform-specific) +algorithms of determining those chunk sizes.

+

The way executor parameters are implemented is aligned with the way executors +are implemented. All functionalities of concrete executor parameter types are +exposed and accessible through a corresponding customization point, e.g. +get_chunk_size().

+

With executor_parameter_traits, clients access all types of executor +parameters uniformly, e.g.:

+
std::size_t chunk_size =
+    hpx::execution::get_chunk_size(my_parameter, my_executor,
+        num_cores, num_tasks);
+
+
+

This call synchronously retrieves the size of a single chunk of loop iterations +(or similar) to combine for execution on a single HPX thread if the overall +number of cores num_cores and tasks to schedule is given by num_tasks. +The lambda function exposes a means of test-probing the execution of a single +iteration for performance measurement purposes. The execution parameter type +might dynamically determine the execution time of one or more tasks in order +to calculate the chunk size; see +hpx::execution::experimental::auto_chunk_size for an example of +this executor parameter type.

+

Other functions in the interface exist to discover whether an executor parameter +type should be invoked once (i.e., it returns a static chunk size; see +hpx::execution::experimental::static_chunk_size) or whether it +should be invoked +for each scheduled chunk of work (i.e., it returns a variable chunk size; for an +example, see hpx::execution::experimental::guided_chunk_size).

+

Although this interface appears to require executor parameter type authors to +implement all different basic operations, none are required. In +practice, all operations have sensible defaults. However, some executor +parameter types will naturally specialize all operations for maximum efficiency.

+

HPX implements the following executor parameter types:

+
    +
  • hpx::execution::experimental::auto_chunk_size: Loop iterations +are divided into pieces and then assigned to threads. The number of loop +iterations combined is +determined based on measurements of how long the execution of 1% of the +overall number of iterations takes. This executor parameter type makes sure +that as many loop iterations are combined as necessary to run for the amount +of time specified.

  • +
  • hpx::execution::experimental::static_chunk_size: Loop iterations +are divided +into pieces of a given size and then assigned to threads. If the size is not +specified, the iterations are, if possible, evenly divided contiguously among +the threads. This executor parameters type is equivalent to OpenMP’s STATIC +scheduling directive.

  • +
  • hpx::execution::experimental::dynamic_chunk_size: Loop iterations +are divided +into pieces of a given size and then dynamically scheduled among the cores; +when a core finishes one chunk, it is dynamically assigned another. If the +size is not specified, the default chunk size is 1. This executor parameter +type is equivalent to OpenMP’s DYNAMIC scheduling directive.

  • +
  • hpx::execution::experimental::guided_chunk_size: Iterations are +dynamically +assigned to cores in blocks as cores request them until no blocks remain to be +assigned. This is similar to dynamic_chunk_size except that the block size +decreases each time a number of loop iterations is given to a thread. The size +of the initial block is proportional to number_of_iterations / +number_of_cores. Subsequent blocks are proportional to +number_of_iterations_remaining / number_of_cores. The optional chunk size +parameter defines the minimum block size. The default minimal chunk size is 1. +This executor parameter type is equivalent to OpenMP’s GUIDED scheduling +directive.

  • +
+
+
+
+
+

Writing distributed applications#

+

This section focuses on the features of HPX needed to write distributed +applications, namely the Active Global Address Space (AGAS), +remotely executable functions (i.e., actions), and distributed +objects (i.e., components).

+
+
Global names#
+

HPX implements an Active Global Address Space (AGAS) which +exposes a single uniform address space spanning all localities an application +runs on. AGAS is a fundamental component of the ParalleX execution +model. Conceptually, there is no rigid demarcation of local or global memory in +AGAS; all available memory is a part of the same address space. +AGAS enables named objects to be moved (migrated) across localities +without having to change the object’s name; i.e., no references to migrated +objects have to be ever updated. This feature has significance for dynamic load +balancing and in applications where the workflow is highly dynamic, allowing +work to be migrated from heavily loaded nodes to less loaded nodes. In addition, +immutability of names ensures that AGAS does not have to keep extra +indirections (“bread crumbs”) when objects move, hence, minimizing complexity of +code management for system developers as well as minimizing overheads in +maintaining and managing aliases.

+

The AGAS implementation in HPX does not automatically expose every +local address to the global address space. It is the responsibility of the +programmer to explicitly define which of the objects have to be globally visible +and which of the objects are purely local.

+

In HPX global addresses (global names) are represented using the +hpx::id_type data type. This data type is conceptually very similar to +void* pointers as it does not expose any type information of the object it +is referring to.

+

The only predefined global addresses are assigned to all localities. The +following HPX API functions allow one to retrieve the global addresses of +localities:

+ +

Additionally, the global addresses of localities can be used to create new +instances of components using the following HPX API function:

+
    +
  • hpx::components::new_: Creates a new instance of the given +Component type on the specified locality.

  • +
+
+

Note

+

HPX does not expose any functionality to delete component instances. All +global addresses (as represented using hpx::id_type) are automatically +garbage collected. When the last (global) reference to a particular component +instance goes out of scope, the corresponding component instance is +automatically deleted.

+
+
+
+
Posting actions#
+
+
Action type definition#
+

Actions are special types used to describe possibly remote operations. For +every global function and every member function which has to be invoked +distantly, a special type must be defined. For any global function the special +macro HPX_PLAIN_ACTION can be used to define the +action type. Here is an example demonstrating this:

+
namespace app
+{
+    void some_global_function(double d)
+    {
+        cout << d;
+    }
+}
+
+// This will define the action type 'some_global_action' which represents
+// the function 'app::some_global_function'.
+HPX_PLAIN_ACTION(app::some_global_function, some_global_action);
+
+
+
+

Important

+

The macro HPX_PLAIN_ACTION has to be placed in +global namespace, even if the wrapped function is located in some other +namespace. The newly defined action type is placed in the global namespace as +well.

+
+

If the action type should be defined somewhere not in global namespace, the +action type definition has to be split into two macro invocations +(HPX_DEFINE_PLAIN_ACTION and HPX_REGISTER_ACTION) as shown +in the next example:

+
namespace app
+{
+    void some_global_function(double d)
+    {
+        cout << d;
+    }
+
+    // On conforming compilers the following macro expands to:
+    //
+    //    typedef hpx::actions::make_action<
+    //        decltype(&some_global_function), &some_global_function
+    //    >::type some_global_action;
+    //
+    // This will define the action type 'some_global_action' which represents
+    // the function 'some_global_function'.
+    HPX_DEFINE_PLAIN_ACTION(some_global_function, some_global_action);
+}
+
+// The following macro expands to a series of definitions of global objects
+// which are needed for proper serialization and initialization support
+// enabling the remote invocation of the function``some_global_function``
+HPX_REGISTER_ACTION(app::some_global_action, app_some_global_action);
+
+
+

The shown code defines an action type some_global_action inside the namespace +app.

+
+

Important

+

If the action type definition is split between two macros as shown above, the +name of the action type to create has to be the same for both macro +invocations (here some_global_action).

+
+
+

Important

+

The second argument passed to HPX_REGISTER_ACTION (app_some_global_action) has +to comprise a globally unique C++ identifier representing the action. This is +used for serialization purposes.

+
+

For member functions of objects which have been registered with AGAS +(e.g., ‘components’), a different registration macro +HPX_DEFINE_COMPONENT_ACTION has to be utilized. Any component needs +to be declared in a header file and have some special support macros defined in +a source file. Here is an example demonstrating this. The first snippet has to +go into the header file:

+
namespace app
+{
+    struct some_component
+      : hpx::components::component_base<some_component>
+    {
+        int some_member_function(std::string s)
+        {
+            return boost::lexical_cast<int>(s);
+        }
+
+        // This will define the action type 'some_member_action' which
+        // represents the member function 'some_member_function' of the
+        // object type 'some_component'.
+        HPX_DEFINE_COMPONENT_ACTION(some_component, some_member_function,
+            some_member_action);
+    };
+}
+
+// Note: The second argument to the macro below has to be systemwide-unique
+//       C++ identifiers
+HPX_REGISTER_ACTION_DECLARATION(app::some_component::some_member_action, some_component_some_action);
+
+
+

The next snippet belongs in a source file (e.g., the main application source +file) in the simplest case:

+
typedef hpx::components::component<app::some_component> component_type;
+typedef app::some_component some_component;
+
+HPX_REGISTER_COMPONENT(component_type, some_component);
+
+// The parameters for this macro have to be the same as used in the corresponding
+// HPX_REGISTER_ACTION_DECLARATION() macro invocation above
+typedef some_component::some_member_action some_component_some_action;
+HPX_REGISTER_ACTION(some_component_some_action);
+
+
+

While these macro invocations are a bit more complex than those for simple global +functions, they should still be manageable.

+

The most important macro invocation is the HPX_DEFINE_COMPONENT_ACTION in the header file +as this defines the action type we need to invoke the member function. For a +complete example of a simple component action see component_in_executable.cpp.

+
+
+
Action invocation#
+

The process of invoking a global function (or a member function of an object) +with the help of the associated action is called ‘posting the action’. Actions +can have arguments, which will be supplied while the action is applied. At the +minimum, one parameter is required to post any action - the id of the +locality the associated function should be invoked on (for global +functions), or the id of the component instance (for member functions). +Generally, HPX provides several ways to post an action, all of which are +described in the following sections.

+

Generally, HPX actions are very similar to ‘normal’ C++ functions except that +actions can be invoked remotely. Fig. 8 below shows an +overview of the main API exposed by HPX. This shows the function invocation +syntax as defined by the C++ language (dark gray), the additional invocation +syntax as provided through C++ Standard Library features (medium gray), and the +extensions added by HPX (light gray) where:

+
    +
  • f function to invoke,

  • +
  • p..: (optional) arguments,

  • +
  • R: return type of f,

  • +
  • action: action type defined by, HPX_DEFINE_PLAIN_ACTION or +HPX_DEFINE_COMPONENT_ACTION encapsulating f,

  • +
  • a: an instance of the type action,

  • +
  • id: the global address the action is applied to.

  • +
+
+_images/hpx_the_api.png +
+

Fig. 8 Overview of the main API exposed by HPX.#

+
+
+

This figure shows that HPX allows the user to post actions with a syntax +similar to the C++ standard. In fact, all action types have an overloaded +function operator allowing to synchronously post the action. Further, HPX +implements hpx::async which semantically works similar to the +way std::async works for plain C++ function.

+
+

Note

+

The similarity of posting an action to conventional function invocations +extends even further. HPX implements hpx::bind and hpx::function +two facilities which are semantically equivalent to the std::bind and +std::function types as defined by the C++11 Standard. While +hpx::async extends beyond the conventional semantics by supporting +actions and conventional C++ functions, the HPX facilities hpx::bind +and hpx::function extend beyond the conventional standard facilities too. +The HPX facilities not only support conventional functions, but can be used +for actions as well.

+
+

Additionally, HPX exposes hpx::post and hpx::async_continue both of +which refine and extend the standard C++ facilities.

+

The different ways to invoke a function in HPX will be explained in more +detail in the following sections.

+
+
+
Posting an action asynchronously without any synchronization#
+

This method (‘fire and forget’) will make sure the function associated with the +action is scheduled to run on the target locality. Posting the action +does not wait for the function to start running, instead it is a fully +asynchronous operation. The following example shows how to post the action as +defined in the previous section on the local +locality (the locality this code runs on):

+
some_global_action act;     // define an instance of some_global_action
+hpx::post(act, hpx::find_here(), 2.0);
+
+
+

(the function hpx::find_here() returns the id of the local locality, +i.e. the locality this code executes on).

+

Any component member function can be invoked using the same syntactic construct. +Given that id is the global address for a component instance created +earlier, this invocation looks like:

+
some_component_action act;     // define an instance of some_component_action
+hpx::post(act, id, "42");
+
+
+

In this case any value returned from this action (e.g. in this case the integer +42 is ignored. Please look at Action type definition for the code +defining the component action some_component_action used.

+
+
+
Posting an action asynchronously with synchronization#
+

This method will make sure the action is scheduled to run on the target +locality. Posting the action itself does not wait for the function to +start running or to complete, instead this is a fully asynchronous operation +similar to using hpx::post as described above. The difference is that this +method will return an instance of a hpx::future<> encapsulating the result +of the (possibly remote) execution. The future can be used to synchronize with +the asynchronous operation. The following example shows how to post the action +from above on the local locality:

+
some_global_action act;     // define an instance of some_global_action
+hpx::future<void> f = hpx::async(act, hpx::find_here(), 2.0);
+//
+// ... other code can be executed here
+//
+f.get();    // this will possibly wait for the asynchronous operation to 'return'
+
+
+

(as before, the function hpx::find_here() returns the id of the local +locality (the locality this code is executed on).

+
+

Note

+

The use of a hpx::future<void> allows the current thread to synchronize +with any remote operation not returning any value.

+
+
+

Note

+

Any std::future<> returned from std::async() is required to block in +its destructor if the value has not been set for this future yet. This is not +true for hpx::future<> which will never block in its destructor, even if +the value has not been returned to the future yet. We believe that +consistency in the behavior of futures is more important than standards +conformance in this case.

+
+

Any component member function can be invoked using the same syntactic construct. +Given that id is the global address for a component instance created +earlier, this invocation looks like:

+
some_component_action act;     // define an instance of some_component_action
+hpx::future<int> f = hpx::async(act, id, "42");
+//
+// ... other code can be executed here
+//
+cout << f.get();    // this will possibly wait for the asynchronous operation to 'return' 42
+
+
+
+

Note

+

The invocation of f.get() will return the result immediately (without +suspending the calling thread) if the result from the asynchronous operation +has already been returned. Otherwise, the invocation of f.get() will +suspend the execution of the calling thread until the asynchronous operation +returns its result.

+
+
+
+
Posting an action synchronously#
+

This method will schedule the function wrapped in the specified action on the +target locality. While the invocation appears to be synchronous (as we +will see), the calling thread will be suspended while waiting for the function +to return. Invoking a plain action (e.g. a global function) synchronously is +straightforward:

+
some_global_action act;     // define an instance of some_global_action
+act(hpx::find_here(), 2.0);
+
+
+

While this call looks just like a normal synchronous function invocation, the +function wrapped by the action will be scheduled to run on a new thread and the +calling thread will be suspended. After the new thread has executed the wrapped +global function, the waiting thread will resume and return from the synchronous +call.

+

Equivalently, any action wrapping a component member function can be invoked +synchronously as follows:

+
some_component_action act;     // define an instance of some_component_action
+int result = act(id, "42");
+
+
+

The action invocation will either schedule a new thread locally to execute the +wrapped member function (as before, id is the global address of the +component instance the member function should be invoked on), or it will send a +parcel to the remote locality of the component causing a new thread to +be scheduled there. The calling thread will be suspended until the function +returns its result. This result will be returned from the synchronous action +invocation.

+

It is very important to understand that this ‘synchronous’ invocation syntax in +fact conceals an asynchronous function call. This is beneficial as the calling +thread is suspended while waiting for the outcome of a potentially remote +operation. The HPX thread scheduler will schedule other work in the meantime, +allowing the application to make further progress while the remote result is +computed. This helps overlapping computation with communication and hiding +communication latencies.

+
+

Note

+

The syntax of posting an action is always the same, regardless whether the +target locality is remote to the invocation locality or not. +This is a very important feature of HPX as it frees the user from the task +of keeping track what actions have to be applied locally and which actions +are remote. If the target for posting an action is local, a new thread is +automatically created and scheduled. Once this thread is scheduled and run, +it will execute the function encapsulated by that action. If the target is +remote, HPX will send a parcel to the remote locality which +encapsulates the action and its parameters. Once the parcel is received on +the remote locality HPX will create and schedule a new thread +there. Once this thread runs on the remote locality, it will execute +the function encapsulated by the action.

+
+
+
+
Posting an action with a continuation but without any synchronization#
+

This method is very similar to the method described in section Posting an action asynchronously without any synchronization. The +difference is that it allows the user to chain a sequence of asynchronous +operations, while handing the (intermediate) results from one step to the next +step in the chain. Where hpx::post invokes a single function using ‘fire +and forget’ semantics, hpx::post_continue asynchronously triggers a chain +of functions without the need for the execution flow ‘to come back’ to the +invocation site. Each of the asynchronous functions can be executed on a +different locality.

+
+
+
Posting an action with a continuation and with synchronization#
+

This method is very similar to the method described in section Posting an action asynchronously with synchronization. In +addition to what hpx::async can do, the functions hpx::async_continue +takes an additional function argument. This function will be called as the +continuation of the executed action. It is expected to perform additional +operations and to make sure that a result is returned to the original invocation +site. This method chains operations asynchronously by providing a continuation +operation which is automatically executed once the first action has finished +executing.

+

As an example we chain two actions, where the result of the first action is +forwarded to the second action and the result of the second action is sent back +to the original invocation site:

+
// first action
+std::int32_t action1(std::int32_t i)
+{
+    return i+1;
+}
+HPX_PLAIN_ACTION(action1);    // defines action1_type
+
+// second action
+std::int32_t action2(std::int32_t i)
+{
+    return i*2;
+}
+HPX_PLAIN_ACTION(action2);    // defines action2_type
+
+// this code invokes 'action1' above and passes along a continuation
+// function which will forward the result returned from 'action1' to
+// 'action2'.
+action1_type act1;     // define an instance of 'action1_type'
+action2_type act2;     // define an instance of 'action2_type'
+hpx::future<int> f =
+    hpx::async_continue(act1, hpx::make_continuation(act2),
+        hpx::find_here(), 42);
+hpx::cout << f.get() << "\n";   // will print: 86 ((42 + 1) * 2)
+
+
+

By default, the continuation is executed on the same locality as +hpx::async_continue is invoked from. If you want to specify the +locality where the continuation should be executed, the code above has +to be written as:

+
// this code invokes 'action1' above and passes along a continuation
+// function which will forward the result returned from 'action1' to
+// 'action2'.
+action1_type act1;     // define an instance of 'action1_type'
+action2_type act2;     // define an instance of 'action2_type'
+hpx::future<int> f =
+    hpx::async_continue(act1, hpx::make_continuation(act2, hpx::find_here()),
+        hpx::find_here(), 42);
+hpx::cout << f.get() << "\n";   // will print: 86 ((42 + 1) * 2)
+
+
+

Similarly, it is possible to chain more than 2 operations:

+
action1_type act1;     // define an instance of 'action1_type'
+action2_type act2;     // define an instance of 'action2_type'
+hpx::future<int> f =
+    hpx::async_continue(act1,
+        hpx::make_continuation(act2, hpx::make_continuation(act1)),
+        hpx::find_here(), 42);
+hpx::cout << f.get() << "\n";   // will print: 87 ((42 + 1) * 2 + 1)
+
+
+

The function hpx::make_continuation creates a special function object +which exposes the following prototype:

+
struct continuation
+{
+    template <typename Result>
+    void operator()(hpx::id_type id, Result&& result) const
+    {
+        ...
+    }
+};
+
+
+

where the parameters passed to the overloaded function operator operator()() +are:

+
    +
  • the id is the global id where the final result of the asynchronous chain +of operations should be sent to (in most cases this is the id of the +hpx::future returned from the initial call to hpx::async_continue. Any +custom continuation function should make sure this id is forwarded to the +last operation in the chain.

  • +
  • the result is the result value of the current operation in the +asynchronous execution chain. This value needs to be forwarded to the next +operation.

  • +
+
+

Note

+

All of those operations are implemented by the predefined continuation +function object which is returned from hpx::make_continuation. Any (custom) +function object used as a continuation should conform to the same interface.

+
+
+
+
Action error handling#
+

Like in any other asynchronous invocation scheme it is important to be able to +handle error conditions occurring while the asynchronous (and possibly remote) +operation is executed. In HPX all error handling is based on standard C++ +exception handling. Any exception thrown during the execution of an asynchronous +operation will be transferred back to the original invocation locality, +where it is rethrown during synchronization with the calling thread.

+
+

Important

+

Exceptions thrown during asynchronous execution can be transferred back to +the invoking thread only for the synchronous and the asynchronous case with +synchronization. Like with any other unhandled exception, any exception +thrown during the execution of an asynchronous action without +synchronization will result in calling hpx::terminate causing the running +application to exit immediately.

+
+
+

Note

+

Even if error handling internally relies on exceptions, most of the API +functions exposed by HPX can be used without throwing an exception. Please +see Working with exceptions for more information.

+
+

As an example, we will assume that the following remote function will be +executed:

+
namespace app
+{
+    void some_function_with_error(int arg)
+    {
+        if (arg < 0) {
+            HPX_THROW_EXCEPTION(hpx::error::bad_parameter,
+                "some_function_with_error",
+                "some really bad error happened");
+        }
+        // do something else...
+    }
+}
+
+// This will define the action type 'some_error_action' which represents
+// the function 'app::some_function_with_error'.
+HPX_PLAIN_ACTION(app::some_function_with_error, some_error_action);
+
+
+

The use of HPX_THROW_EXCEPTION to report the error encapsulates the +creation of a hpx::exception which is initialized with the error +code hpx::error::bad_parameter. Additionally it carries the passed strings, the +information about the file name, line number, and call stack of the point the +exception was thrown from.

+

We invoke this action using the synchronous syntax as described before:

+
// note: wrapped function will throw hpx::exception
+some_error_action act;            // define an instance of some_error_action
+try {
+    act(hpx::find_here(), -3);    // exception will be rethrown from here
+}
+catch (hpx::exception const& e) {
+    // prints: 'some really bad error happened: HPX(bad parameter)'
+    cout << e.what();
+}
+
+
+

If this action is invoked asynchronously with synchronization, the exception is +propagated to the waiting thread as well and is re-thrown from the future’s +function get():

+
// note: wrapped function will throw hpx::exception
+some_error_action act;            // define an instance of some_error_action
+hpx::future<void> f = hpx::async(act, hpx::find_here(), -3);
+try {
+    f.get();                      // exception will be rethrown from here
+}
+catch (hpx::exception const& e) {
+    // prints: 'some really bad error happened: HPX(bad parameter)'
+    cout << e.what();
+}
+
+
+

For more information about error handling please refer to the section +Working with exceptions. There we also explain how to handle error conditions without +having to rely on exception.

+
+
+
+
Writing components#
+

A component in HPX is a C++ class which can be created remotely and for which +its member functions can be invoked remotely as well. The following sections +highlight how components can be defined, created, and used.

+
+
Defining components#
+

In order for a C++ class type to be managed remotely in HPX, the type must be +derived from the hpx::components::component_base template type. We +call such C++ class types ‘components’.

+

Note that the component type itself is passed as a template argument to the base +class:

+
// header file some_component.hpp
+
+#include <hpx/include/components.hpp>
+
+namespace app
+{
+    // Define a new component type 'some_component'
+    struct some_component
+      : hpx::components::component_base<some_component>
+    {
+        // This member function is has to be invoked remotely
+        int some_member_function(std::string const& s)
+        {
+            return boost::lexical_cast<int>(s);
+        }
+
+        // This will define the action type 'some_member_action' which
+        // represents the member function 'some_member_function' of the
+        // object type 'some_component'.
+        HPX_DEFINE_COMPONENT_ACTION(some_component, some_member_function, some_member_action);
+    };
+}
+
+// This will generate the necessary boiler-plate code for the action allowing
+// it to be invoked remotely. This declaration macro has to be placed in the
+// header file defining the component itself.
+//
+// Note: The second argument to the macro below has to be systemwide-unique
+//       C++ identifiers
+//
+HPX_REGISTER_ACTION_DECLARATION(app::some_component::some_member_action, some_component_some_action);
+
+
+

There is more boiler plate code which has to be placed into a source file in +order for the component to be usable. Every component type is required to have +macros placed into its source file, one for each component type and one macro +for each of the actions defined by the component type.

+

For instance:

+
// source file some_component.cpp
+
+#include "some_component.hpp"
+
+// The following code generates all necessary boiler plate to enable the
+// remote creation of 'app::some_component' instances with 'hpx::new_<>()'
+//
+using some_component = app::some_component;
+using some_component_type = hpx::components::component<some_component>;
+
+// Please note that the second argument to this macro must be a
+// (system-wide) unique C++-style identifier (without any namespaces)
+//
+HPX_REGISTER_COMPONENT(some_component_type, some_component);
+
+// The parameters for this macro have to be the same as used in the corresponding
+// HPX_REGISTER_ACTION_DECLARATION() macro invocation in the corresponding
+// header file.
+//
+// Please note that the second argument to this macro must be a
+// (system-wide) unique C++-style identifier (without any namespaces)
+//
+HPX_REGISTER_ACTION(app::some_component::some_member_action, some_component_some_action);
+
+
+
+
+
Defining client side representation classes#
+

Often it is very convenient to define a separate type for a component which can +be used on the client side (from where the component is instantiated and used). +This step might seem as unnecessary duplicating code, however it significantly +increases the type safety of the code.

+

A possible implementation of such a client side representation for the component +described in the previous section could look like:

+
#include <hpx/include/components.hpp>
+
+namespace app
+{
+    // Define a client side representation type for the component type
+    // 'some_component' defined in the previous section.
+    //
+    struct some_component_client
+      : hpx::components::client_base<some_component_client, some_component>
+    {
+        using base_type = hpx::components::client_base<
+                some_component_client, some_component>;
+
+        some_component_client(hpx::future<hpx::id_type> && id)
+          : base_type(std::move(id))
+        {}
+
+        hpx::future<int> some_member_function(std::string const& s)
+        {
+            some_component::some_member_action act;
+            return hpx::async(act, get_id(), s);
+        }
+    };
+}
+
+
+

A client side object stores the global id of the component instance it +represents. This global id is accessible by calling the function +client_base<>::get_id(). The special constructor which is provided in the +example allows to create this client side object directly using the API function +hpx::new_.

+
+
+
Creating component instances#
+

Instances of defined component types can be created in two different ways. If +the component to create has a defined client side representation type, then this +can be used, otherwise use the server type.

+

The following examples assume that some_component_type is the type of the +server side implementation of the component to create. All additional arguments +(see , ... notation below) are passed through to the corresponding +constructor calls of those objects:

+
// create one instance on the given locality
+hpx::id_type here = hpx::find_here();
+hpx::future<hpx::id_type> f =
+    hpx::new_<some_component_type>(here, ...);
+
+// create one instance using the given distribution
+// policy (here: hpx::colocating_distribution_policy)
+hpx::id_type here = hpx::find_here();
+hpx::future<hpx::id_type> f =
+    hpx::new_<some_component_type>(hpx::colocated(here), ...);
+
+// create multiple instances on the given locality
+hpx::id_type here = find_here();
+hpx::future<std::vector<hpx::id_type>> f =
+    hpx::new_<some_component_type[]>(here, num, ...);
+
+// create multiple instances using the given distribution
+// policy (here: hpx::binpacking_distribution_policy)
+hpx::future<std::vector<hpx::id_type>> f = hpx::new_<some_component_type[]>(
+    hpx::binpacking(hpx::find_all_localities()), num, ...);
+
+
+

The examples below demonstrate the use of the same API functions for creating +client side representation objects (instead of just plain ids). These examples +assume that client_type is the type of the client side representation of the +component type to create. As above, all additional arguments +(see , ... notation below) are passed through to the corresponding constructor +calls of the server side implementation objects corresponding to the +client_type:

+
// create one instance on the given locality
+hpx::id_type here = hpx::find_here();
+client_type c = hpx::new_<client_type>(here, ...);
+
+// create one instance using the given distribution
+// policy (here: hpx::colocating_distribution_policy)
+hpx::id_type here = hpx::find_here();
+client_type c = hpx::new_<client_type>(hpx::colocated(here), ...);
+
+// create multiple instances on the given locality
+hpx::id_type here = hpx::find_here();
+hpx::future<std::vector<client_type>> f =
+    hpx::new_<client_type[]>(here, num, ...);
+
+// create multiple instances using the given distribution
+// policy (here: hpx::binpacking_distribution_policy)
+hpx::future<std::vector<client_type>> f = hpx::new_<client_type[]>(
+    hpx::binpacking(hpx::find_all_localities()), num, ...);
+
+
+
+
+
Using component instances#
+

After having created the component instances as described above, we can simply +use them as indicated below:

+
#include <hpx/include/components.hpp>
+#include <iostream>
+#include <vector>
+
+// Define a simple component
+struct some_component : hpx::components::component_base<some_component>
+{
+    void print() const
+    {
+        std::cout << "Hello from component instance!" << std::endl;
+    }
+    HPX_DEFINE_COMPONENT_ACTION(some_component, print, print_action);
+};
+
+typedef some_component::print_action print_action;
+
+// Create one instance on the given locality
+hpx::id_type here = hpx::find_here();
+hpx::future<hpx::id_type> f1 =
+    hpx::new_<some_component>(here);
+
+// Get the future value
+hpx::id_type instance_id = f1.get();
+
+// Invoke action on the instance
+hpx::async<print_action>(instance_id).get();
+
+// Create multiple instances on the given locality
+int num = 3;
+hpx::future<std::vector<hpx::id_type>> f2 =
+    hpx::new_<some_component[]>(here, num);
+
+// Get the future value
+std::vector<hpx::id_type> instance_ids = f2.get();
+
+// Invoke action on each instance
+for (const auto& id : instance_ids)
+{
+    hpx::async<print_action>(id).get();
+}
+
+
+

We can use the component instances with distribution policies the same way.

+
+
+
+
Segmented containers#
+

In parallel programming, there is now a plethora of solutions aimed at +implementing “partially contiguous” or segmented data structures, whether on +shared memory systems or distributed memory systems. HPX implements such +structures by drawing inspiration from Standard C++ containers.

+
+
Using segmented containers#
+

A segmented container is a template class that is described in the namespace +hpx. All segmented containers are very similar semantically to their +sequential counterpart (defined in namespace std but with an additional +template parameter named DistPolicy). The distribution policy is an optional +parameter that is passed last to the segmented container constructor (after the +container size when no default value is given, after the default value if not). +The distribution policy describes the manner in which a container is segmented +and the placement of each segment among the available runtime localities.

+

However, only a part of the std container member functions were +reimplemented:

+
    +
  • (constructor), (destructor), operator=

  • +
  • operator[]

  • +
  • begin, cbegin, end, cend

  • +
  • size

  • +
+

An example of how to use the partitioned_vector container would be:

+
#include <hpx/include/partitioned_vector.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// remote creation of 'partitioned_vector' segments
+//
+HPX_REGISTER_PARTITIONED_VECTOR(double);
+
+// By default, the number of segments is equal to the current number of
+// localities
+//
+hpx::partitioned_vector<double> va(50);
+hpx::partitioned_vector<double> vb(50, 0.0);
+
+
+

An example of how to use the partitioned_vector container +with distribution policies would be:

+
#include <hpx/include/partitioned_vector.hpp>
+#include <hpx/runtime_distributed/find_localities.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// remote creation of 'partitioned_vector' segments
+//
+HPX_REGISTER_PARTITIONED_VECTOR(double);
+
+std::size_t num_segments = 10;
+std::vector<hpx::id_type> locs = hpx::find_all_localities()
+
+auto layout =
+        hpx::container_layout( num_segments, locs );
+
+// The number of segments is 10 and those segments are spread across the
+// localities collected in the variable locs in a Round-Robin manner
+//
+hpx::partitioned_vector<double> va(50, layout);
+hpx::partitioned_vector<double> vb(50, 0.0, layout);
+
+
+

By definition, a segmented container must be accessible from any thread although +its construction is synchronous only for the thread who has called its +constructor. To overcome this problem, it is possible to assign a symbolic name +to the segmented container:

+
#include <hpx/include/partitioned_vector.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// remote creation of 'partitioned_vector' segments
+//
+HPX_REGISTER_PARTITIONED_VECTOR(double);
+
+hpx::future<void> fserver = hpx::async(
+  [](){
+    hpx::partitioned_vector<double> v(50);
+
+    // Register the 'partitioned_vector' with the name "some_name"
+    //
+    v.register_as("some_name");
+
+    /* Do some code  */
+  });
+
+hpx::future<void> fclient =
+  hpx::async(
+    [](){
+      // Naked 'partitioned_vector'
+      //
+      hpx::partitioned_vector<double> v;
+
+      // Now the variable v points to the same 'partitioned_vector' that has
+      // been registered with the name "some_name"
+      //
+      v.connect_to("some_name");
+
+      /* Do some code  */
+    });
+
+
+
+Segmented containers# +

HPX provides the following segmented containers:

+ + ++++++ + + + + + + + + + + + + +
Table 22 Sequence containers#

Name

Description

In header

C++ standard

hpx::partitioned_vector

Dynamic segmented contiguous array.

<hpx/include/partitioned_vector.hpp>

vector

+ + ++++++ + + + + + + + + + + + + +
Table 23 Unordered associative containers#

Name

Description

In header

C++ standard

hpx::unordered_map

Segmented collection of key-value pairs, hashed by keys, keys are unique.

<hpx/include/unordered_map.hpp>

unordered_map

+
+
+
+
Segmented iterators and segmented iterator traits#
+

The basic iterator used in the STL library is only suitable for one-dimensional +structures. The iterators we use in HPX must adapt to the segmented format of +our containers. Our iterators are then able to know when incrementing themselves +if the next element of type T is in the same data segment or in another +segment. In this second case, the iterator will automatically point to the +beginning of the next segment.

+
+

Note

+

Note that the dereference operation operator * does not directly return a +reference of type T& but an intermediate object wrapping this reference. +When this object is used as an l-value, a remote write operation is +performed; When this object is used as an r-value, implicit conversion to +T type will take care of performing remote read operation.

+
+

It is sometimes useful not only to iterate element by element, but also segment +by segment, or simply get a local iterator in order to avoid additional +construction costs at each deferencing operations. To mitigate this need, the +hpx::traits::segmented_iterator_traits are used.

+

With segmented_iterator_traits users can uniformly get the iterators +which specifically iterates over segments (by providing a segmented iterator +as a parameter), or get the local begin/end iterators of the nearest +local segment (by providing a per-segment iterator as a parameter):

+
#include <hpx/include/partitioned_vector.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// remote creation of 'partitioned_vector' segments
+//
+HPX_REGISTER_PARTITIONED_VECTOR(double);
+
+using iterator = hpx::partitioned_vector<T>::iterator;
+using traits   = hpx::traits::segmented_iterator_traits<iterator>;
+
+hpx::partitioned_vector<T> v;
+std::size_t count = 0;
+
+auto seg_begin = traits::segment(v.begin());
+auto seg_end   = traits::segment(v.end());
+
+// Iterate over segments
+for (auto seg_it = seg_begin; seg_it != seg_end; ++seg_it)
+{
+    auto loc_begin = traits::begin(seg_it);
+    auto loc_end   = traits::end(seg_it);
+
+    // Iterate over elements inside segments
+    for (auto lit = loc_begin; lit != loc_end; ++lit, ++count)
+    {
+        *lit = count;
+    }
+}
+
+
+

Which is equivalent to:

+
hpx::partitioned_vector<T> v;
+std::size_t count = 0;
+
+auto begin = v.begin();
+auto end   = v.end();
+
+for (auto it = begin; it != end; ++it, ++count)
+{
+    *it = count;
+}
+
+
+
+
+
Using views#
+

The use of multidimensional arrays is quite common in the numerical field +whether to perform dense matrix operations or to process images. It exist many +libraries which implement such object classes overloading their basic operators +(e.g. +, -, *, (), etc.). However, such operation becomes more +delicate when the underlying data layout is segmented or when it is mandatory to +use optimized linear algebra subroutines (i.e. BLAS subroutines).

+

Our solution is thus to relax the level of abstraction by allowing the user to +work not directly on n-dimensionnal data, but on “n-dimensionnal collections of +1-D arrays”. The use of well-accepted techniques on contiguous data is thus +preserved at the segment level, and the composability of the segments is made +possible thanks to multidimensional array-inspired access mode.

+
+Preface: Why SPMD?# +

Although HPX refutes by design this programming model, the locality +plays a dominant role when it comes to implement vectorized code. To maximize +local computations and avoid unneeded data transfers, a parallel section (or +Single Programming Multiple Data section) is required. Because the use of global +variables is prohibited, this parallel section is created via the RAII idiom.

+

To define a parallel section, simply write an action taking a spmd_block +variable as a first parameter:

+
#include <hpx/collectives/spmd_block.hpp>
+
+void bulk_function(hpx::lcos::spmd_block block /* , arg0, arg1, ... */)
+{
+    // Parallel section
+
+    /* Do some code */
+}
+HPX_PLAIN_ACTION(bulk_function, bulk_action);
+
+
+
+

Note

+

In the following paragraphs, we will use the term “image” several times. An +image is defined as a lightweight process whose entry point is a function +provided by the user. It’s an “image of the function”.

+
+

The spmd_block class contains the following methods:

+
    +
  • Team information: get_num_images, this_image, images_per_locality

  • +
  • Control statements: sync_all, sync_images

  • +
+

Here is a sample code summarizing the features offered by the spmd_block +class:

+
#include <hpx/collectives/spmd_block.hpp>
+
+void bulk_function(hpx::lcos::spmd_block block /* , arg0, arg1, ... */)
+{
+    std::size_t num_images = block.get_num_images();
+    std::size_t this_image = block.this_image();
+    std::size_t images_per_locality = block.images_per_locality();
+
+    /* Do some code */
+
+    // Synchronize all images in the team
+    block.sync_all();
+
+    /* Do some code */
+
+    // Synchronize image 0 and image 1
+    block.sync_images(0,1);
+
+    /* Do some code */
+
+    std::vector<std::size_t> vec_images = {2,3,4};
+
+    // Synchronize images 2, 3 and 4
+    block.sync_images(vec_images);
+
+    // Alternative call to synchronize images 2, 3 and 4
+    block.sync_images(vec_images.begin(), vec_images.end());
+
+    /* Do some code */
+
+    // Non-blocking version of sync_all()
+    hpx::future<void> event =
+        block.sync_all(hpx::launch::async);
+
+    // Callback waiting for 'event' to be ready before being scheduled
+    hpx::future<void> cb =
+        event.then(
+          [](hpx::future<void>)
+          {
+
+            /* Do some code */
+
+          });
+
+    // Finally wait for the execution tree to be finished
+    cb.get();
+}
+HPX_PLAIN_ACTION(bulk_test_function, bulk_test_action);
+
+
+

Then, in order to invoke the parallel section, call the function +define_spmd_block specifying an arbitrary symbolic name and indicating the +number of images per locality to create:

+
void bulk_function(hpx::lcos::spmd_block block, /* , arg0, arg1, ... */)
+{
+
+}
+HPX_PLAIN_ACTION(bulk_test_function, bulk_test_action);
+
+int main()
+{
+    /* std::size_t arg0, arg1, ...; */
+
+    bulk_action act;
+    std::size_t images_per_locality = 4;
+
+    // Instantiate the parallel section
+    hpx::lcos::define_spmd_block(
+        "some_name", images_per_locality, std::move(act) /*, arg0, arg1, ... */);
+
+    return 0;
+}
+
+
+
+

Note

+

In principle, the user should never call the spmd_block constructor. The +define_spmd_block function is responsible of instantiating spmd_block +objects and broadcasting them to each created image.

+
+
+
+SPMD multidimensional views# +

Some classes are defined as “container views” when the purpose is to observe +and/or modify the values of a container using another perspective than the one +that characterizes the container. For example, the values of an std::vector +object can be accessed via the expression [i]. Container views can be used, +for example, when it is desired for those values to be “viewed” as a 2D matrix +that would have been flattened in a std::vector. The values would be +possibly accessible via the expression vv(i,j) which would call internally +the expression v[k].

+

By default, the partitioned_vector class integrates 1-D views of its segments:

+
#include <hpx/include/partitioned_vector.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// remote creation of 'partitioned_vector' segments
+//
+HPX_REGISTER_PARTITIONED_VECTOR(double);
+
+using iterator = hpx::partitioned_vector<double>::iterator;
+using traits   = hpx::traits::segmented_iterator_traits<iterator>;
+
+hpx::partitioned_vector<double> v;
+
+// Create a 1-D view of the vector of segments
+auto vv = traits::segment(v.begin());
+
+// Access segment i
+std::vector<double> v = vv[i];
+
+
+

Our views are called “multidimensional” in the sense that they generalize to N +dimensions the purpose of segmented_iterator_traits::segment() in the 1-D +case. Note that in a parallel section, the 2-D expression a(i,j) = b(i,j) is +quite confusing because without convention, each of the images invoked will race +to execute the statement. For this reason, our views are not only +multidimensional but also “spmd-aware”.

+
+

Note

+

SPMD-awareness: The convention is simple. If an assignment statement contains +a view subscript as an l-value, it is only and only the image holding the +r-value who is evaluating the statement. (In MPI sense, it is called a Put +operation).

+
+
+Subscript-based operations# +

Here are some examples of using subscripts in the 2-D view case:

+
#include <hpx/components/containers/partitioned_vector/partitioned_vector_view.hpp>
+#include <hpx/include/partitioned_vector.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// remote creation of 'partitioned_vector' segments
+//
+HPX_REGISTER_PARTITIONED_VECTOR(double);
+
+using Vec = hpx::partitioned_vector<double>;
+using View_2D = hpx::partitioned_vector_view<double,2>;
+
+/* Do some code */
+
+Vec v;
+
+// Parallel section (suppose 'block' an spmd_block instance)
+{
+    std::size_t height, width;
+
+    // Instantiate the view
+    View_2D vv(block, v.begin(), v.end(), {height,width});
+
+    // The l-value is a view subscript, the image that owns vv(1,0)
+    // evaluates the assignment.
+    vv(0,1) = vv(1,0);
+
+    // The l-value is a view subscript, the image that owns the r-value
+    // (result of expression 'std::vector<double>(4,1.0)') evaluates the
+    // assignment : oops! race between all participating images.
+    vv(2,3) = std::vector<double>(4,1.0);
+}
+
+
+
+
+Iterator-based operations# +

Here are some examples of using iterators in the 3-D view case:

+
#include <hpx/components/containers/partitioned_vector/partitioned_vector_view.hpp>
+#include <hpx/include/partitioned_vector.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// remote creation of 'partitioned_vector' segments
+//
+HPX_REGISTER_PARTITIONED_VECTOR(int);
+
+using Vec = hpx::partitioned_vector<int>;
+using View_3D = hpx::partitioned_vector_view<int,3>;
+
+/* Do some code */
+
+Vec v1, v2;
+
+// Parallel section (suppose 'block' an spmd_block instance)
+{
+    std::size_t sixe_x, size_y, size_z;
+
+    // Instantiate the views
+    View_3D vv1(block, v1.begin(), v1.end(), {sixe_x,size_y,size_z});
+    View_3D vv2(block, v2.begin(), v2.end(), {sixe_x,size_y,size_z});
+
+    // Save previous segments covered by vv1 into segments covered by vv2
+    auto vv2_it = vv2.begin();
+    auto vv1_it = vv1.cbegin();
+
+    for(; vv2_it != vv2.end(); vv2_it++, vv1_it++)
+    {
+        // It's a Put operation
+        *vv2_it = *vv1_it;
+    }
+
+    // Ensure that all images have performed their Put operations
+    block.sync_all();
+
+    // Ensure that only one image is putting updated data into the different
+    // segments covered by vv1
+    if(block.this_image() == 0)
+    {
+        int idx = 0;
+
+        // Update all the segments covered by vv1
+        for(auto i = vv1.begin(); i != vv1.end(); i++)
+        {
+            // It's a Put operation
+            *i = std::vector<float>(elt_size,idx++);
+        }
+    }
+}
+
+
+

Here is an example that shows how to iterate only over segments +owned by the current image:

+
#include <hpx/components/containers/partitioned_vector/partitioned_vector_view.hpp>
+#include <hpx/components/containers/partitioned_vector/partitioned_vector_local_view.hpp>
+#include <hpx/include/partitioned_vector.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// remote creation of 'partitioned_vector' segments
+//
+HPX_REGISTER_PARTITIONED_VECTOR(float);
+
+using Vec = hpx::partitioned_vector<float>;
+using View_1D = hpx::partitioned_vector_view<float,1>;
+
+/* Do some code */
+
+Vec v;
+
+// Parallel section (suppose 'block' an spmd_block instance)
+{
+    std::size_t num_segments;
+
+    // Instantiate the view
+    View_1D vv(block, v.begin(), v.end(), {num_segments});
+
+    // Instantiate the local view from the view
+    auto local_vv = hpx::local_view(vv);
+
+    for ( auto i = local_vv.begin(); i != local_vv.end(); i++ )
+    {
+        std::vector<float> & segment = *i;
+
+        /* Do some code */
+    }
+
+}
+
+
+
+
+Instantiating sub-views# +

It is possible to construct views from other views: we call it sub-views. The +constraint nevertheless for the subviews is to retain the dimension and the +value type of the input view. Here is an example showing how to create a +sub-view:

+
#include <hpx/components/containers/partitioned_vector/partitioned_vector_view.hpp>
+#include <hpx/include/partitioned_vector.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// remote creation of 'partitioned_vector' segments
+//
+HPX_REGISTER_PARTITIONED_VECTOR(float);
+
+using Vec = hpx::partitioned_vector<float>;
+using View_2D = hpx::partitioned_vector_view<float,2>;
+
+/* Do some code */
+
+Vec v;
+
+// Parallel section (suppose 'block' an spmd_block instance)
+{
+    std::size_t N = 20;
+    std::size_t tilesize = 5;
+
+    // Instantiate the view
+    View_2D vv(block, v.begin(), v.end(), {N,N});
+
+    // Instantiate the subview
+    View_2D svv(
+        block,&vv(tilesize,0),&vv(2*tilesize-1,tilesize-1),{tilesize,tilesize},{N,N});
+
+    if(block.this_image() == 0)
+    {
+        // Equivalent to 'vv(tilesize,0) = 2.0f'
+        svv(0,0) = 2.0f;
+
+        // Equivalent to 'vv(2*tilesize-1,tilesize-1) = 3.0f'
+        svv(tilesize-1,tilesize-1) = 3.0f;
+    }
+
+}
+
+
+
+

Note

+

The last parameter of the subview constructor is the size of the original +view. If one would like to create a subview of the subview and so on, this +parameter should stay unchanged. {N,N} for the above example).

+
+
+
+
+
+
C++ co-arrays#
+

Fortran has extended its scalar element indexing approach to reference each +segment of a distributed array. In this extension, a segment is attributed a +?co-index? and lives in a specific locality. A co-index provides the +application with enough information to retrieve the corresponding data +reference. In C++, containers present themselves as a ?smarter? alternative of +Fortran arrays but there are still no corresponding standardized features +similar to the Fortran co-indexing approach. We present here an implementation +of such features in HPX.

+
+Preface: co-array, a segmented container tied to a SPMD multidimensional views# +

As mentioned before, a co-array is a distributed array whose segments are +accessible through an array-inspired access mode. We have previously seen that +it is possible to reproduce such access mode using the concept of views. +Nevertheless, the user must pre-create a segmented container to instantiate this +view. We illustrate below how a single constructor call can perform those two +operations:

+
#include <hpx/components/containers/coarray/coarray.hpp>
+#include <hpx/collectives/spmd_block.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// co-creation of 'coarray'
+//
+HPX_REGISTER_COARRAY(double);
+
+// Parallel section (suppose 'block' an spmd_block instance)
+{
+    using hpx::container::placeholders::_;
+
+    std::size_t height=32, width=4, segment_size=10;
+
+    hpx::coarray<double,3> a(block, "a", {height,width,_}, segment_size);
+
+    /* Do some code */
+}
+
+
+

Unlike segmented containers, a co-array object can only be instantiated within a +parallel section. Here is the description of the parameters to provide to the +coarray constructor:

+ + ++++ + + + + + + + + + + + + + + + + + +
Table 24 Parameters of coarray constructor#

Parameter

Description

block

Reference to a spmd_block object

"a"

Symbolic name of type std::string

{height,width,_}

Dimensions of the coarray object

segment_size

Size of a co-indexed element (i.e. size of the object referenced by the +expression a(i,j,k))

+

Note that the “last dimension size” cannot be set by the user. It only accepts +the constexpr variable hpx::container::placeholders::_. This size, which is +considered private, is equal to the number of current images (value returned by +block.get_num_images()).

+
+

Note

+

An important constraint to remember about coarray objects is that all +segments sharing the same “last dimension index” are located in the same +image.

+
+
+
+Using co-arrays# +

The member functions owned by the coarray objects are exactly the same as +those of spmd multidimensional views. These are:

+
* Subscript-based operations
+* Iterator-based operations
+
+
+

However, one additional functionality is provided. Knowing that the element +a(i,j,k) is in the memory of the kth image, the use of local subscripts +is possible.

+
+

Note

+

For spmd multidimensional views, subscripts are only global as it still +involves potential remote data transfers.

+
+

Here is an example of using local subscripts:

+
#include <hpx/components/containers/coarray/coarray.hpp>
+#include <hpx/collectives/spmd_block.hpp>
+
+// The following code generates all necessary boiler plate to enable the
+// co-creation of 'coarray'
+//
+HPX_REGISTER_COARRAY(double);
+
+// Parallel section (suppose 'block' an spmd_block instance)
+{
+    using hpx::container::placeholders::_;
+
+    std::size_t height=32, width=4, segment_size=10;
+
+    hpx::coarray<double,3> a(block, "a", {height,width,_}, segment_size);
+
+    double idx = block.this_image()*height*width;
+
+    for (std::size_t j = 0; j<width; j++)
+    for (std::size_t i = 0; i<height; i++)
+    {
+        // Local write operation performed via the use of local subscript
+        a(i,j,_) = std::vector<double>(elt_size,idx);
+        idx++;
+    }
+
+    block.sync_all();
+}
+
+
+
+

Note

+

When the “last dimension index” of a subscript is equal to +hpx::container::placeholders::_, local subscript (and not global +subscript) is used. It is equivalent to a global subscript used with a “last +dimension index” equal to the value returned by block.this_image().

+
+
+
+
+
+
+

Running on batch systems#

+

This section walks you through launching HPX applications on various batch +systems.

+
+
How to use HPX applications with PBS#
+

Most HPX applications are executed on parallel computers. These platforms +typically provide integrated job management services that facilitate the +allocation of computing resources for each parallel program. HPX includes +support for one of the most common job management systems, the +Portable Batch System (PBS).

+

All PBS jobs require a script to specify the resource requirements and other +parameters associated with a parallel job. The PBS script is basically a shell +script with PBS directives placed within commented sections at the beginning of +the file. The remaining (not commented-out) portions of the file executes just +like any other regular shell script. While the description of all available PBS +options is outside the scope of this tutorial (the interested reader may refer +to in-depth documentation for +more information), below is a minimal example to illustrate the approach. The following +test application will use the multithreaded hello_world_distributed +program, explained in the section Remote execution with actions.

+
#!/bin/bash
+#
+#PBS -l nodes=2:ppn=4
+
+APP_PATH=~/packages/hpx/bin/hello_world_distributed
+APP_OPTIONS=
+
+pbsdsh -u $APP_PATH $APP_OPTIONS --hpx:nodes=`cat $PBS_NODEFILE`
+
+
+
+

Caution

+

If the first application specific argument (inside $APP_OPTIONS) is a +non-option (i.e., does not start with a - or a --), then the argument has to +be placed before the option --hpx:nodes, which, in this case, should +be the last option on the command line.

+

Alternatively, use the option --hpx:endnodes to explicitly mark the +end of the list of node names:

+
$ pbsdsh -u $APP_PATH --hpx:nodes`cat $PBS_NODEFILE` --hpx:endnodes $APP_OPTIONS
+
+
+
+

The #PBS -l nodes=2:ppn=4 directive will cause two compute nodes to be +allocated for the application, as specified in the option nodes. Each of the +nodes will dedicate four cores to the program, as per the option ppn, short +for “processors per node” (PBS does not distinguish between processors and +cores). Note that requesting more cores per node than physically available is +pointless and may prevent PBS from accepting the script.

+

On newer PBS versions the PBS command syntax might be different. For instance, +the PBS script above would look like:

+
#!/bin/bash
+#
+#PBS -l select=2:ncpus=4
+
+APP_PATH=~/packages/hpx/bin/hello_world_distributed
+APP_OPTIONS=
+
+pbsdsh -u $APP_PATH $APP_OPTIONS --hpx:nodes=`cat $PBS_NODEFILE`
+
+
+

APP_PATH and APP_OPTIONS are shell variables that respectively specify +the correct path to the executable (hello_world_distributed in this case) +and the command line options. Since the hello_world_distributed application +doesn’t need any command line options, APP_OPTIONS has been left empty. +Unlike in other execution environments, there is no need to use the +--hpx:threads option to indicate the required number of OS threads per +node; the HPX library will derive this parameter automatically from PBS.

+

Finally, pbsdsh is a PBS command that starts tasks to the resources allocated +to the current job. It is recommended to leave this line as shown and modify +only the PBS options and shell variables as needed for a specific application.

+
+

Important

+

A script invoked by pbsdsh starts in a very basic environment: the user’s +$HOME directory is defined and is the current directory, the LANG +variable is set to C and the PATH is set to the basic +/usr/local/bin:/usr/bin:/bin as defined in a system-wide file +pbs_environment. Nothing that would normally be set up by a system shell +profile or user shell profile is defined, unlike the environment for the main +job script.

+
+

Another choice is for the pbsdsh command in your main job script to invoke +your program via a shell, like sh or bash, so that it gives an initialized +environment for each instance. Users can create a small script runme.sh, which is used +to invoke the program:

+
#!/bin/bash
+# Small script which invokes the program based on what was passed on its
+# command line.
+#
+# This script is executed by the bash shell which will initialize all
+# environment variables as usual.
+$@
+
+
+

Now, the script is invoked using the pbsdsh tool:

+
#!/bin/bash
+#
+#PBS -l nodes=2:ppn=4
+
+APP_PATH=~/packages/hpx/bin/hello_world_distributed
+APP_OPTIONS=
+
+pbsdsh -u runme.sh $APP_PATH $APP_OPTIONS --hpx:nodes=`cat $PBS_NODEFILE`
+
+
+

All that remains now is submitting the job to the queuing system. Assuming that +the contents of the PBS script were saved in the file pbs_hello_world.sh in the +current directory, this is accomplished by typing:

+
$ qsub ./pbs_hello_world_pbs.sh
+
+
+

If the job is accepted, qsub will print out the assigned job ID, which may +look like:

+
$ 42.supercomputer.some.university.edu
+
+
+

To check the status of your job, issue the following command:

+
$ qstat 42.supercomputer.some.university.edu
+
+
+

and look for a single-letter job status symbol. The common cases include:

+
    +
  • Q - signifies that the job is queued and awaiting its turn to be executed.

  • +
  • R - indicates that the job is currently running.

  • +
  • C - means that the job has completed.

  • +
+

The example qstat output below shows a job waiting for execution resources +to become available:

+
Job id                    Name             User            Time Use S Queue
+------------------------- ---------------- --------------- -------- - -----
+42.supercomputer          ...ello_world.sh joe_user               0 Q batch
+
+
+

After the job completes, PBS will place two files, pbs_hello_world.sh.o42 and +pbs_hello_world.sh.e42, in the directory where the job was submitted. The +first contains the standard output and the second contains the standard error +from all the nodes on which the application executed. In our example, the error +output file should be empty and the standard output file should contain something +similar to:

+
hello world from OS-thread 3 on locality 0
+hello world from OS-thread 2 on locality 0
+hello world from OS-thread 1 on locality 1
+hello world from OS-thread 0 on locality 0
+hello world from OS-thread 3 on locality 1
+hello world from OS-thread 2 on locality 1
+hello world from OS-thread 1 on locality 0
+hello world from OS-thread 0 on locality 1
+
+
+

Congratulations! You have just run your first distributed HPX application!

+
+
+
How to use HPX applications with SLURM#
+

Just like PBS (described in section How to use HPX applications with PBS), SLURM is a job +management system which is widely used on large supercomputing systems. Any +HPX application can easily be run using SLURM. This section describes how this +can be done.

+

The easiest way to run an HPX application using SLURM is to utilize the +command line tool srun, which interacts with the SLURM batch scheduling system:

+
$ srun -p <partition> -N <number-of-nodes> hpx-application <application-arguments>
+
+
+

Here, <partition> is one of the node partitions existing on the target +machine (consult the machine’s documentation to get a list of existing +partitions) and <number-of-nodes> is the number of compute nodes that should +be used. By default, the HPX application is started with one locality per +node and uses all available cores on a node. You can change the number of +localities started per node (for example, to account for NUMA effects) by +specifying the -n option of srun. The number of cores per locality +can be set by -c. The <application-arguments> are any application +specific arguments that need to be passed on to the application.

+
+

Note

+

There is no need to use any of the HPX command line options related to the +number of localities, number of threads, or related to networking ports. All +of this information is automatically extracted from the SLURM environment by +the HPX startup code.

+
+
+

Important

+

The srun documentation explicitly states: “If -c is specified without +-n, as many tasks will be allocated per node as possible while satisfying +the -c restriction. For instance on a cluster with 8 CPUs per node, a job +request for 4 nodes and 3 CPUs per task may be allocated 3 or 6 CPUs per node +(1 or 2 tasks per node) depending upon resource consumption by other jobs.” +For this reason, it’s recommended to always specify -n <number-of-instances>, +even if <number-of-instances> is equal to one (1).

+
+
+
Interactive shells#
+

To get an interactive development shell on one of the nodes, users can issue the +following command:

+
$ srun -p <node-type> -N <number-of-nodes> --pty /bin/bash -l
+
+
+

After the shell has been opened, users can run their HPX application. By default, +it uses all available cores. Note that if you requested one node, you don’t need +to do srun again. However, if you requested more than one node, and want to +run your distributed application, you can use srun again to start up the +distributed HPX application. It will use the resources that have been requested +for the interactive shell.

+
+
+
Scheduling batch jobs#
+

The above mentioned method of running HPX applications is fine for development +purposes. The disadvantage that comes with srun is that it only returns once +the application is finished. This might not be appropriate for longer-running +applications (for example, benchmarks or larger scale simulations). In order to +cope with that limitation, users can use the sbatch command.

+

The sbatch command expects a script that it can run once the requested +resources are available. In order to request resources, users need to add +#SBATCH comments in their script or provide the necessary parameters to +sbatch directly. The parameters are the same as with run. The commands +you need to execute are the same you would need to start your application as if +you were in an interactive shell.

+
+
+
+
+

Debugging HPX applications#

+
+
Using a debugger with HPX applications#
+

Using a debugger such as gdb with HPX applications is no problem. However, +there are some things to keep in mind to make the experience somewhat more +productive.

+

Call stacks in HPX can often be quite unwieldy as the library is heavily +templated and the call stacks can be very deep. For this reason it is sometimes +a good idea compile HPX in RelWithDebInfo mode, which applies some +optimizations but keeps debugging symbols. This can often compress call stacks +significantly. On the other hand, stepping through the code can also be more +difficult because of statements being reordered and variables being optimized +away. Also, note that because HPX implements user-space threads and context +switching, call stacks may not always be complete in a debugger.

+

HPX launches not only worker threads but also a few helper threads. The first +thread is the main thread, which typically does no work in an HPX application, +except at startup and shutdown. If using the default settings, HPX will spawn +six additional threads (used for service thread pools). The first worker thread +is usually the eighth thread, and most user codes will be run on these worker +threads. The last thread is a helper thread used for HPX shutdown.

+

Finally, since HPX is a multi-threaded runtime, the following gdb options +can be helpful:

+
set pagination off
+set non-stop on
+
+
+

Non-stop mode allows users to have a single thread stop on a breakpoint without +stopping all other threads as well.

+
+
+
Using sanitizers with HPX applications#
+
+

Warning

+

Not all parts of HPX are sanitizer clean. This means that users may end up +with false positives from HPX itself when using sanitizers for their +applications.

+
+

To use sanitizers with HPX, turn on HPX_WITH_SANITIZERS and turn +off HPX_WITH_STACKOVERFLOW_DETECTION during CMake configuration. It’s +recommended to also build Boost with the same sanitizers that will be +used for HPX. The appropriate sanitizers can then be enabled using CMake by +appending -fsanitize=address -fno-omit-frame-pointer to CMAKE_CXX_FLAGS +and -fsanitize=address to CMAKE_EXE_LINKER_FLAGS. Replace address +with the sanitizer that you want to use.

+
+
+
Debugging applications using core files#
+

For HPX to generate useful core files, HPX has to be compiled without signal +and exception handlers +HPX_WITH_DISABLED_SIGNAL_EXCEPTION_HANDLERS:BOOL. If this option is +not specified, the signal handlers change the application state. For example, +after a segmentation fault the stack trace will show the signal handler. +Similarly, unhandled exceptions are also caught by these handlers and the +stack trace will not point to the location where the unhandled exception was +thrown.

+

In general, core files are a helpful tool to inspect the state of the +application at the moment of the crash (post-mortem debugging), without the need +of attaching a debugger beforehand. This approach to debugging is especially +useful if the error cannot be reliably reproduced, as only a single crashed +application run is required to gain potentially helpful information like a +stacktrace.

+

To debug with core files, the operating system first has to be told to actually +write them. On most Unix systems this can be done by calling:

+
$ ulimit -c unlimited
+
+
+

in the shell. Now the debugger can be started up with:

+
$ gdb <application> <core file name>
+
+
+

The debugger should now display the last state of the application. The default +file name for core files is core.

+
+
+
+

Optimizing HPX applications#

+
+
Performance counters#
+

Performance counters in HPX are used to provide information as to how well the +runtime system or an application is performing. The counter data can help +determine system bottlenecks, and fine-tune system and application performance. +The HPX runtime system, its networking, and other layers provide counter data +that an application can consume to provide users with information about how +well the application is performing.

+

Applications can also use counter data to determine how much system resources to +consume. For example, an application that transfers data over the network could +consume counter data from a network switch to determine how much data to +transfer without competing for network bandwidth with other network traffic. The +application could use the counter data to adjust its transfer rate as the +bandwidth usage from other network traffic increases or decreases.

+

Performance counters are HPX parallel processes that expose a predefined +interface. HPX exposes special API functions that allow one to create, manage, +and read the counter data, and release instances of performance counters. +Performance Counter instances are accessed by name, and these names have a +predefined structure which is described in the section +Performance counter names. The advantage of this is that any Performance +Counter can be accessed remotely (from a different locality) or locally +(from the same locality). Moreover, since all counters expose their data +using the same API, any code consuming counter data can be utilized to access +arbitrary system information with minimal effort.

+

Counter data may be accessed in real time. More information about how to consume +counter data can be found in the section Consuming performance counter data.

+

All HPX applications provide command line options related to performance +counters, such as the ability to list available counter types, or periodically +query specific counters to be printed to the screen or save them in a file. For +more information, please refer to the section HPX Command Line Options.

+
+
Performance counter names#
+

All Performance Counter instances have a name uniquely identifying each +instance. This name can be used to access the counter, retrieve all related meta +data, and to query the counter data (as described in the section +Consuming performance counter data). Counter names are strings with a predefined structure. The +general form of a countername is:

+
/objectname{full_instancename}/countername@parameters
+
+
+

where full_instancename could be either another (full) counter name or a +string formatted as:

+
parentinstancename#parentindex/instancename#instanceindex
+
+
+

Each separate part of a countername (e.g., objectname, countername +parentinstancename, instancename, and parameters) should start with +a letter ('a''z', 'A''Z') or an underscore +character ('_'), optionally followed by letters, digits ('0''9'), hyphen ('-'), or underscore characters. Whitespace is not allowed +inside a counter name. The characters '/', '{', '}', '#' and +'@' have a special meaning and are used to delimit the different parts of +the counter name.

+

The parts parentinstanceindex and instanceindex are integers. If an +index is not specified, HPX will assume a default of -1.

+
+
+
Two counter name examples#
+

This section gives examples of both simple counter names and aggregate +counter names. For more information on simple and aggregate counter +names, please see Performance counter instances.

+

An example of a well-formed (and meaningful) simple counter name would be:

+
/threads{locality#0/total}/count/cumulative
+
+
+

This counter returns the current cumulative number of executed (retired) +HPX threads for the locality 0. The counter type of this counter +is /threads/count/cumulative and the full instance name is +locality#0/total. This counter type does not require an instanceindex or +parameters to be specified.

+

In this case, the parentindex (the '0') designates the locality +for which the counter instance is created. The counter will return the number of +HPX threads retired on that particular locality.

+

Another example for a well formed (aggregate) counter name is:

+
/statistics{/threads{locality#0/total}/count/cumulative}/average@500
+
+
+

This counter takes the simple counter from the first example, samples its values +every 500 milliseconds, and returns the average of the value samples +whenever it is queried. The counter type of this counter is +/statistics/average and the instance name is the full name of the counter +for which the values have to be averaged. In this case, the parameters (the +'500') specify the sampling interval for the averaging to take place (in +milliseconds).

+
+
+
Performance counter types#
+

Every performance counter belongs to a specific performance counter type which +classifies the counters into groups of common semantics. The type of a counter +is identified by the objectname and the countername parts of the name.

+
/objectname/countername
+
+
+

When an application starts HPX will register all available counter types on each of +the localities. These counter types are held in a special performance counter +registration database, which can be used to retrieve the meta data related +to a counter type and to create counter instances based on a given counter +instance name.

+
+
+
Performance counter instances#
+

The full_instancename distinguishes different counter instances of the same +counter type. The formatting of the full_instancename depends on the counter +type. There are two types of counters: simple counters, which usually generate +the counter values based on direct measurements, and aggregate counters, which +take another counter and transform its values before generating their own +counter values. An example for a simple counter is given above: +counting retired HPX threads. An aggregate counter is shown as an example +above as well: calculating the average of the underlying +counter values sampled at constant time intervals.

+

While simple counters use instance names formatted as +parentinstancename#parentindex/instancename#instanceindex, most aggregate +counters have the full counter name of the embedded counter as their instance +name.

+

Not all simple counter types require specifying all four elements of a full counter +instance name; some of the parts (parentinstancename, parentindex, +instancename, and instanceindex) are optional for specific counters. +Please refer to the documentation of a particular counter for more information +about the formatting requirements for the name of this counter (see +Existing HPX performance counters).

+

The parameters are used to pass additional information to a counter at +creation time. They are optional, and they fully depend on the concrete counter. +Even if a specific counter type allows additional parameters to be given, those +usually are not required as sensible defaults will be chosen. Please refer to +the documentation of a particular counter for more information about what +parameters are supported, how to specify them, and what default values are +assumed (see also Existing HPX performance counters).

+

Every locality of an application exposes its own set of performance +counter types and performance counter instances. The set of exposed counters is +determined dynamically at application start based on the execution environment +of the application. For instance, this set is influenced by the current hardware +environment for the locality (such as whether the locality has +access to accelerators), and the software environment of the application (such +as the number of OS threads used to execute HPX threads).

+
+
+
Using wildcards in performance counter names#
+

It is possible to use wildcard characters when specifying performance counter +names. Performance counter names can contain two types of wildcard characters:

+
    +
  • Wildcard characters in the performance counter type

  • +
  • Wildcard characters in the performance counter instance name

  • +
+

A wildcard character has a meaning which is very close to usual file name +wildcard matching rules implemented by common shells (like bash).

+ + ++++ + + + + + + + + + + + + + + +
Table 25 Wildcard characters in the performance counter type#

Wildcard

Description

*

This wildcard character matches any number (zero or more) of arbitrary +characters.

?

This wildcard character matches any single arbitrary character.

[...]

This wildcard character matches any single character from the list of +specified within the square brackets.

+ + ++++ + + + + + + + + +
Table 26 Wildcard characters in the performance counter instance name#

Wildcard

Description

*

This wildcard character matches any locality or any thread, +depending on whether it is used for locality#* or +worker-thread#*. No other wildcards are allowed in counter instance +names.

+
+
+
Consuming performance counter data#
+

You can consume performance data using either the command line interface, +the HPX application or the HPX API. The command line interface is easier to +use, but it is less flexible and does not allow one to adjust the behaviour of +your application at runtime. The command line interface provides a convenience +abstraction but simplified abstraction for querying and logging performance +counter data for a set of performance counters.

+
+
+
Consuming performance counter data from the command line#
+

HPX provides a set of predefined command line options for every application +that uses hpx::init for its initialization. While there are many more +command line options available (see HPX Command Line Options), the set of options related +to performance counters allows one to list existing counters, and query existing +counters once at application termination or repeatedly after a constant time +interval.

+

The following table summarizes the available command line options:

+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 27 HPX Command Line Options Related to Performance Counters#

Command line option

Description

--hpx:print-counter

Prints the specified performance counter either repeatedly and/or at the +times specified by --hpx:print-counter-at (see also option +--hpx:print-counter-interval).

--hpx:print-counter-reset

Prints the specified performance counter either repeatedly and/or at the +times specified by --hpx:print-counter-at. Reset the counter after the +value is queried (see also option --hpx:print-counter-interval).

--hpx:print-counter-interval

Prints the performance counter(s) specified with --hpx:print-counter +repeatedly after the time interval (specified in milliseconds) +(default:0 which means print once at shutdown).

--hpx:print-counter-destination

Prints the performance counter(s) specified with --hpx:print-counter +to the given file (default: console).

--hpx:list-counters

Lists the names of all registered performance counters.

--hpx:list-counter-infos

Lists the description of all registered performance counters.

--hpx:print-counter-format

Prints the performance counter(s) specified with --hpx:print-counter. +Possible formats in CVS format with header or without any header (see +option --hpx:no-csv-header), possible values: csv (prints counter +values in CSV format with full names as header) csv-short (prints +counter values in CSV format with shortnames provided with +--hpx:print-counter as --hpx:print-counter +shortname,full-countername).

--hpx:no-csv-header

Prints the performance counter(s) specified with --hpx:print-counter +and csv or csv-short format specified with +--hpx:print-counter-format without header.

--hpx:print-counter-at arg

Prints the performance counter(s) specified with --hpx:print-counter +(or --hpx:print-counter-reset) at the given point in time. Possible +argument values: startup, shutdown (default), noshutdown.

--hpx:reset-counters

Resets all performance counter(s) specified with --hpx:print-counter +after they have been evaluated.

--hpx:print-counter-types

Appends counter type description to generated output.

--hpx:print-counters-locally

Each locality prints only its own local counters.

+

While the options --hpx:list-counters and --hpx:list-counter-infos give +a short list of all available counters, the full documentation for those can +be found in the section Existing HPX performance counters.

+
+
+
A simple example#
+

All of the commandline options mentioned above can be tested using +the hello_world_distributed example.

+

Listing all available counters hello_world_distributed --hpx:list-counters +yields:

+
List of available counter instances (replace * below with the appropriate
+sequence number)
+-------------------------------------------------------------------------
+/agas/count/allocate /agas/count/bind /agas/count/bind_gid
+/agas/count/bind_name ... /threads{locality#*/allocator#*}/count/objects
+/threads{locality#*/total}/count/stack-recycles
+/threads{locality#*/total}/idle-rate
+/threads{locality#*/worker-thread#*}/idle-rate
+
+
+

Providing more information about all available counters, +hello_world_distributed --hpx:list-counter-infos yields:

+
Information about available counter instances (replace * below with the
+appropriate sequence number)
+------------------------------------------------------------------------------
+fullname: /agas/count/allocate helptext: returns the number of invocations of
+the AGAS service 'allocate' type: counter_type::raw version: 1.0.0
+------------------------------------------------------------------------------
+
+------------------------------------------------------------------------------
+fullname: /agas/count/bind helptext: returns the number of invocations of the
+AGAS service 'bind' type: counter_type::raw version: 1.0.0
+------------------------------------------------------------------------------
+
+------------------------------------------------------------------------------
+fullname: /agas/count/bind_gid helptext: returns the number of invocations of
+the AGAS service 'bind_gid' type: counter_type::raw version: 1.0.0
+------------------------------------------------------------------------------
+
+...
+
+
+

This command will not only list the counter names but also a short description +of the data exposed by this counter.

+
+

Note

+

The list of available counters may differ depending on the concrete execution +environment (hardware or software) of your application.

+
+

Requesting the counter data for one or more performance counters can be achieved +by invoking hello_world_distributed with a list of counter names:

+
$ hello_world_distributed \
+    --hpx:print-counter=/threads{locality#0/total}/count/cumulative \
+    --hpx:print-counter=/agas{locality#0/total}/count/bind
+
+
+

which yields for instance:

+
hello world from OS-thread 0 on locality 0
+/threads{locality#0/total}/count/cumulative,1,0.212527,[s],33
+/agas{locality#0/total}/count/bind,1,0.212790,[s],11
+
+
+

The first line is the normal output generated by hello_world_distributed and +has no relation to the counter data listed. The last two lines contain the +counter data as gathered at application shutdown. These lines have six fields, the +counter name, the sequence number of the counter invocation, the time stamp at +which this information has been sampled, the unit of measure for the time stamp, +the actual counter value and an optional unit of measure for the counter value.

+
+

Note

+

The command line option --hpx:print-counter-types will append a seventh +field to the generated output. This field will hold an abbreviated counter +type.

+
+

The actual counter value can be represented by a single number (for counters +returning singular values) or a list of numbers separated by ':' (for +counters returning an array of values, like for instance a histogram).

+
+

Note

+

The name of the performance counter will be enclosed in double quotes '"' +if it contains one or more commas ','.

+
+

Requesting to query the counter data once after a constant time interval with +this command line:

+
$ hello_world_distributed \
+    --hpx:print-counter=/threads{locality#0/total}/count/cumulative \
+    --hpx:print-counter=/agas{locality#0/total}/count/bind \
+    --hpx:print-counter-interval=20
+
+
+

yields for instance (leaving off the actual console output of the +hello_world_distributed example for brevity):

+
threads{locality#0/total}/count/cumulative,1,0.002409,[s],22
+agas{locality#0/total}/count/bind,1,0.002542,[s],9
+threads{locality#0/total}/count/cumulative,2,0.023002,[s],41
+agas{locality#0/total}/count/bind,2,0.023557,[s],10
+threads{locality#0/total}/count/cumulative,3,0.037514,[s],46
+agas{locality#0/total}/count/bind,3,0.038679,[s],10
+
+
+

The command --hpx:print-counter-destination=<file> will redirect all counter +data gathered to the specified file name, which avoids cluttering the console +output of your application.

+

The command line option --hpx:print-counter supports using a limited set of +wildcards for a (very limited) set of use cases. In particular, all occurrences +of #* as in locality#* and in worker-thread#* will be automatically +expanded to the proper set of performance counter names representing the actual +environment for the executed program. For instance, if your program is utilizing +four worker threads for the execution of HPX threads (see command line option +--hpx:threads) the following command line

+
$ hello_world_distributed \
+    --hpx:threads=4 \
+    --hpx:print-counter=/threads{locality#0/worker-thread#*}/count/cumulative
+
+
+

will print the value of the performance counters monitoring each of the worker +threads:

+
hello world from OS-thread 1 on locality 0
+hello world from OS-thread 0 on locality 0
+hello world from OS-thread 3 on locality 0
+hello world from OS-thread 2 on locality 0
+/threads{locality#0/worker-thread#0}/count/cumulative,1,0.0025214,[s],27
+/threads{locality#0/worker-thread#1}/count/cumulative,1,0.0025453,[s],33
+/threads{locality#0/worker-thread#2}/count/cumulative,1,0.0025683,[s],29
+/threads{locality#0/worker-thread#3}/count/cumulative,1,0.0025904,[s],33
+
+
+

The command --hpx:print-counter-format takes values csv and +csv-short to generate CSV formatted counter values with a header.

+

With format as csv:

+
$ hello_world_distributed \
+    --hpx:threads=2 \
+    --hpx:print-counter-format csv \
+    --hpx:print-counter /threads{locality#*/total}/count/cumulative \
+    --hpx:print-counter /threads{locality#*/total}/count/cumulative-phases
+
+
+

will print the values of performance counters in CSV format with the full +countername as a header:

+
hello world from OS-thread 1 on locality 0
+hello world from OS-thread 0 on locality 0
+/threads{locality#*/total}/count/cumulative,/threads{locality#*/total}/count/cumulative-phases
+39,93
+
+
+

With format csv-short:

+
$ hello_world_distributed \
+    --hpx:threads 2 \
+    --hpx:print-counter-format csv-short \
+    --hpx:print-counter cumulative,/threads{locality#*/total}/count/cumulative \
+    --hpx:print-counter phases,/threads{locality#*/total}/count/cumulative-phases
+
+
+

will print the values of performance counters in CSV format with the short countername +as a header:

+
hello world from OS-thread 1 on locality 0
+hello world from OS-thread 0 on locality 0
+cumulative,phases
+39,93
+
+
+

With format csv and csv-short when used with --hpx:print-counter-interval:

+
$ hello_world_distributed \
+    --hpx:threads 2 \
+    --hpx:print-counter-format csv-short \
+    --hpx:print-counter cumulative,/threads{locality#*/total}/count/cumulative \
+    --hpx:print-counter phases,/threads{locality#*/total}/count/cumulative-phases \
+    --hpx:print-counter-interval 5
+
+
+

will print the header only once repeating the performance counter value(s) repeatedly:

+
cum,phases
+25,42
+hello world from OS-thread 1 on locality 0
+hello world from OS-thread 0 on locality 0
+44,95
+
+
+

The command --hpx:no-csv-header can be used with +--hpx:print-counter-format to print performance counter values in CSV format +without any header:

+
$ hello_world_distributed \
+--hpx:threads 2 \
+--hpx:print-counter-format csv-short \
+--hpx:print-counter cumulative,/threads{locality#*/total}/count/cumulative \
+--hpx:print-counter phases,/threads{locality#*/total}/count/cumulative-phases \
+--hpx:no-csv-header
+
+
+

will print:

+
hello world from OS-thread 1 on locality 0
+hello world from OS-thread 0 on locality 0
+37,91
+
+
+
+
+
Consuming performance counter data using the HPX API#
+

HPX provides an API that allows users to discover performance counters and +to retrieve the current value of any existing performance counter from any application.

+
+
+
Discover existing performance counters#
+
+
+
Retrieve the current value of any performance counter#
+

Performance counters are specialized HPX components. In order to retrieve a +counter value, the performance counter needs to be instantiated. HPX exposes a +client component object for this purpose:

+
hpx::performance_counters::performance_counter counter(std::string const& name);
+
+
+

Instantiating an instance of this type will create the performance counter +identified by the given name. Only the first invocation for any given counter +name will create a new instance of that counter. All following invocations for a +given counter name will reference the initially created instance. This ensures +that at any point in time there is never more than one active instance of +any of the existing performance counters.

+

In order to access the counter value (or to invoke any of the other functionality +related to a performance counter, like start, stop or reset) member +functions of the created client component instance should be called:

+
// print the current number of threads created on locality 0
+hpx::performance_counters::performance_counter count(
+    "/threads{locality#0/total}/count/cumulative");
+hpx::cout << count.get_value<int>().get() << std::endl;
+
+
+

For more information about the client component type, see +hpx::performance_counters::performance_counter

+
+

Note

+

In the above example count.get_value() returns a future. In order to print +the result we must append .get() to retrieve the value. You could write the +above example like this for more clarity:

+
// print the current number of threads created on locality 0
+hpx::performance_counters::performance_counter count(
+    "/threads{locality#0/total}/count/cumulative");
+hpx::future<int> result = count.get_value<int>();
+hpx::cout << result.get() << std::endl;
+
+
+
+
+
+
Providing performance counter data#
+

HPX offers several ways by which you may provide your own data as a +performance counter. This has the benefit of exposing additional, possibly +application-specific information using the existing Performance Counter +framework, unifying the process of gathering data about your application.

+

An application that wants to provide counter data can implement a performance +counter to provide the data. When a consumer queries performance data, the HPX +runtime system calls the provider to collect the data. The runtime system uses +an internal registry to determine which provider to call.

+

Generally, there are two ways of exposing your own performance counter data: a +simple, function-based way and a more complex, but more powerful way of +implementing a full performance counter. Both alternatives are described in the +following sections.

+
+
+
Exposing performance counter data using a simple function#
+

The simplest way to expose arbitrary numeric data is to write a function which +will then be called whenever a consumer queries this counter. Currently, this +type of performance counter can only be used to expose integer values. The +expected signature of this function is:

+
std::int64_t some_performance_data(bool reset);
+
+
+

The argument bool reset (which is supplied by the runtime system when the +function is invoked) specifies whether the counter value should be reset after +evaluating the current value (if applicable).

+

For instance, here is such a function returning how often it was invoked:

+
// The atomic variable 'counter' ensures the thread safety of the counter.
+boost::atomic<std::int64_t> counter(0);
+
+std::int64_t some_performance_data(bool reset)
+{
+    std::int64_t result = ++counter;
+    if (reset)
+        counter = 0;
+    return result;
+}
+
+
+

This example function exposes a linearly-increasing value as our performance +data. The value is incremented on each invocation, i.e., each time a consumer +requests the counter data of this performance counter.

+

The next step in exposing this counter to the runtime system is to register the +function as a new raw counter type using the HPX API function +hpx::performance_counters::install_counter_type. A counter type +represents certain common characteristics of counters, like their counter type +name and any associated description information. The following snippet shows an +example of how to register the function some_performance_data, which is shown +above, for a counter type named "/test/data". This registration has to be +executed before any consumer instantiates, and queries an instance of this +counter type:

+
#include <hpx/include/performance_counters.hpp>
+
+void register_counter_type()
+{
+    // Call the HPX API function to register the counter type.
+    hpx::performance_counters::install_counter_type(
+        "/test/data",                                   // counter type name
+        &some_performance_data,                         // function providing counter data
+        "returns a linearly increasing counter value"   // description text (optional)
+        ""                                              // unit of measure (optional)
+    );
+}
+
+
+

Now it is possible to instantiate a new counter instance based on the naming +scheme "/test{locality#*/total}/data" where * is a zero-based integer +index identifying the locality for which the counter instance should be +accessed. The function +hpx::performance_counters::install_counter_type enables users to +instantiate exactly one counter instance for each locality. Repeated +requests to instantiate such a counter will return the same instance, i.e., the +instance created for the first request.

+

If this counter needs to be accessed using the standard HPX command line +options, the registration has to be performed during application startup, before +hpx_main is executed. The best way to achieve this is to register an HPX +startup function using the API function +hpx::register_startup_function before calling hpx::init to +initialize the runtime system:

+
int main(int argc, char* argv[])
+{
+    // By registering the counter type we make it available to any consumer
+    // who creates and queries an instance of the type "/test/data".
+    //
+    // This registration should be performed during startup. The
+    // function 'register_counter_type' should be executed as an HPX thread right
+    // before hpx_main is executed.
+    hpx::register_startup_function(&register_counter_type);
+
+    // Initialize and run HPX.
+    return hpx::init(argc, argv);
+}
+
+
+

Please see the code in simplest_performance_counter.cpp +for a full example demonstrating this functionality.

+
+
+
Implementing a full performance counter#
+

Sometimes, the simple way of exposing a single value as a performance counter is +not sufficient. For that reason, HPX provides a means of implementing full +performance counters which support:

+
    +
  • Retrieving the descriptive information about the performance counter

  • +
  • Retrieving the current counter value

  • +
  • Resetting the performance counter (value)

  • +
  • Starting the performance counter

  • +
  • Stopping the performance counter

  • +
  • Setting the (initial) value of the performance counter

  • +
+

Every full performance counter will implement a predefined interface:

+
//  Copyright (c) 2007-2023 Hartmut Kaiser
+//
+//  SPDX-License-Identifier: BSL-1.0
+//  Distributed under the Boost Software License, Version 1.0. (See accompanying
+//  file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
+
+#pragma once
+
+#include <hpx/config.hpp>
+#include <hpx/async_base/launch_policy.hpp>
+#include <hpx/components/client_base.hpp>
+#include <hpx/functional/bind_front.hpp>
+#include <hpx/futures/future.hpp>
+#include <hpx/modules/execution.hpp>
+
+#include <hpx/performance_counters/counters_fwd.hpp>
+#include <hpx/performance_counters/server/base_performance_counter.hpp>
+
+#include <string>
+#include <utility>
+#include <vector>
+
+#include <hpx/config/warnings_prefix.hpp>
+
+///////////////////////////////////////////////////////////////////////////////
+namespace hpx::performance_counters {
+
+    ///////////////////////////////////////////////////////////////////////////
+    struct HPX_EXPORT performance_counter
+      : components::client_base<performance_counter,
+            server::base_performance_counter>
+    {
+        using base_type = components::client_base<performance_counter,
+            server::base_performance_counter>;
+
+        performance_counter() = default;
+
+        explicit performance_counter(std::string const& name);
+
+        performance_counter(
+            std::string const& name, hpx::id_type const& locality);
+
+        performance_counter(id_type const& id)
+          : base_type(id)
+        {
+        }
+
+        performance_counter(future<id_type>&& id)
+          : base_type(HPX_MOVE(id))
+        {
+        }
+
+        performance_counter(hpx::future<performance_counter>&& c)
+          : base_type(HPX_MOVE(c))
+        {
+        }
+
+        ///////////////////////////////////////////////////////////////////////
+        future<counter_info> get_info() const;
+        counter_info get_info(
+            launch::sync_policy, error_code& ec = throws) const;
+
+        future<counter_value> get_counter_value(bool reset) const;
+        counter_value get_counter_value(
+            launch::sync_policy, bool reset, error_code& ec = throws) const;
+
+        future<counter_value> get_counter_value() const;
+        counter_value get_counter_value(
+            launch::sync_policy, error_code& ec = throws) const;
+
+        future<counter_values_array> get_counter_values_array(bool reset) const;
+        counter_values_array get_counter_values_array(
+            launch::sync_policy, bool reset, error_code& ec = throws) const;
+
+        future<counter_values_array> get_counter_values_array() const;
+        counter_values_array get_counter_values_array(
+            launch::sync_policy, error_code& ec = throws) const;
+
+        ///////////////////////////////////////////////////////////////////////
+        future<bool> start() const;
+        bool start(launch::sync_policy, error_code& ec = throws) const;
+
+        future<bool> stop() const;
+        bool stop(launch::sync_policy, error_code& ec = throws) const;
+
+        future<void> reset() const;
+        void reset(launch::sync_policy, error_code& ec = throws) const;
+
+        future<void> reinit(bool reset = true) const;
+        void reinit(launch::sync_policy, bool reset = true,
+            error_code& ec = throws) const;
+
+        ///////////////////////////////////////////////////////////////////////
+        future<std::string> get_name() const;
+        std::string get_name(
+            launch::sync_policy, error_code& ec = throws) const;
+
+    private:
+        template <typename T>
+        static T extract_value(future<counter_value>&& value)
+        {
+            return value.get().get_value<T>();
+        }
+
+    public:
+        template <typename T>
+        future<T> get_value(bool reset = false)
+        {
+            return get_counter_value(reset).then(hpx::launch::sync,
+                hpx::bind_front(&performance_counter::extract_value<T>));
+        }
+        template <typename T>
+        T get_value(
+            launch::sync_policy, bool reset = false, error_code& ec = throws)
+        {
+            return get_counter_value(launch::sync, reset).get_value<T>(ec);
+        }
+
+        template <typename T>
+        future<T> get_value() const
+        {
+            return get_counter_value(false).then(hpx::launch::sync,
+                hpx::bind_front(&performance_counter::extract_value<T>));
+        }
+        template <typename T>
+        T get_value(launch::sync_policy, error_code& ec = throws) const
+        {
+            return get_counter_value(launch::sync, false).get_value<T>(ec);
+        }
+    };
+
+    // Return all counters matching the given name (with optional wild cards).
+    HPX_EXPORT std::vector<performance_counter> discover_counters(
+        std::string const& name, error_code& ec = throws);
+}    // namespace hpx::performance_counters
+
+#include <hpx/config/warnings_suffix.hpp>
+
+
+

In order to implement a full performance counter, you have to create an HPX +component exposing this interface. To simplify this task, HPX provides a +ready-made base class which handles all the boiler plate of creating +a component for you. The remainder of this section will explain the process of creating a full +performance counter based on the Sine example, which you can find in the +directory examples/performance_counters/sine/.

+

The base class is defined in the header file base_performance_counter.cpp +as:

+
//  Copyright (c) 2007-2023 Hartmut Kaiser
+//
+//  SPDX-License-Identifier: BSL-1.0
+//  Distributed under the Boost Software License, Version 1.0. (See accompanying
+//  file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
+
+#pragma once
+
+#include <hpx/config.hpp>
+#include <hpx/actions_base/component_action.hpp>
+#include <hpx/components_base/component_type.hpp>
+#include <hpx/components_base/server/component_base.hpp>
+#include <hpx/performance_counters/counters.hpp>
+#include <hpx/performance_counters/server/base_performance_counter.hpp>
+#include <hpx/runtime_local/get_locality_id.hpp>
+
+///////////////////////////////////////////////////////////////////////////////
+//[performance_counter_base_class
+namespace hpx::performance_counters {
+
+    template <typename Derived>
+    class base_performance_counter;
+}    // namespace hpx::performance_counters
+//]
+
+///////////////////////////////////////////////////////////////////////////////
+namespace hpx::performance_counters {
+
+    template <typename Derived>
+    class base_performance_counter
+      : public hpx::performance_counters::server::base_performance_counter
+      , public hpx::components::component_base<Derived>
+    {
+    private:
+        using base_type = hpx::components::component_base<Derived>;
+
+    public:
+        using type_holder = Derived;
+        using base_type_holder =
+            hpx::performance_counters::server::base_performance_counter;
+
+        base_performance_counter() = default;
+
+        explicit base_performance_counter(
+            hpx::performance_counters::counter_info const& info)
+          : base_type_holder(info)
+        {
+        }
+
+        // Disambiguate finalize() which is implemented in both base classes
+        void finalize()
+        {
+            base_type_holder::finalize();
+            base_type::finalize();
+        }
+
+        hpx::naming::address get_current_address() const
+        {
+            return hpx::naming::address(
+                hpx::naming::get_gid_from_locality_id(hpx::get_locality_id()),
+                hpx::components::get_component_type<Derived>(),
+                const_cast<Derived*>(static_cast<Derived const*>(this)));
+        }
+    };
+}    // namespace hpx::performance_counters
+
+
+

The single template parameter is expected to receive the type of the +derived class implementing the performance counter. In the Sine example +this looks like:

+
//  Copyright (c) 2007-2012 Hartmut Kaiser
+//
+//  SPDX-License-Identifier: BSL-1.0
+//  Distributed under the Boost Software License, Version 1.0. (See accompanying
+//  file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
+
+#pragma once
+
+#include <hpx/config.hpp>
+#if !defined(HPX_COMPUTE_DEVICE_CODE)
+#include <hpx/hpx.hpp>
+#include <hpx/include/lcos_local.hpp>
+#include <hpx/include/performance_counters.hpp>
+#include <hpx/include/util.hpp>
+
+#include <cstdint>
+
+namespace performance_counters { namespace sine { namespace server {
+    ///////////////////////////////////////////////////////////////////////////
+    //[sine_counter_definition
+    class sine_counter
+      : public hpx::performance_counters::base_performance_counter<sine_counter>
+    //]
+    {
+    public:
+        sine_counter()
+          : current_value_(0)
+          , evaluated_at_(0)
+        {
+        }
+        explicit sine_counter(
+            hpx::performance_counters::counter_info const& info);
+
+        /// This function will be called in order to query the current value of
+        /// this performance counter
+        hpx::performance_counters::counter_value get_counter_value(bool reset);
+
+        /// The functions below will be called to start and stop collecting
+        /// counter values from this counter.
+        bool start();
+        bool stop();
+
+        /// finalize() will be called just before the instance gets destructed
+        void finalize();
+
+    protected:
+        bool evaluate();
+
+    private:
+        typedef hpx::spinlock mutex_type;
+
+        mutable mutex_type mtx_;
+        double current_value_;
+        std::uint64_t evaluated_at_;
+
+        hpx::util::interval_timer timer_;
+    };
+}}}    // namespace performance_counters::sine::server
+#endif
+
+
+

i.e., the type sine_counter is derived from the base class passing the type +as a template argument (please see simplest_performance_counter.cpp +for the full source code of the counter definition). For more information about this +technique (called Curiously Recurring Template Pattern - CRTP), please see for +instance the corresponding Wikipedia article. This base +class itself is derived from the performance_counter interface described +above.

+

Additionally, a full performance counter implementation not only exposes the +actual value but also provides information about:

+
    +
  • The point in time a particular value was retrieved.

  • +
  • A (sequential) invocation count.

  • +
  • The actual counter value.

  • +
  • An optional scaling coefficient.

  • +
  • Information about the counter status.

  • +
+
+
+
Existing HPX performance counters#
+

The HPX runtime system exposes a wide variety of predefined performance +counters. These counters expose critical information about different modules of +the runtime system. They can help determine system bottlenecks and fine-tune +system and application performance.

+ + ++++ + + + + + + + + + + + +
Table 28 AGAS performance counter /agas/count/<agas_service>#

Counter type

/agas/count/<agas_service>

+

where <agas_service> is one of the following:

+

primary namespace services: route, bind_gid, resolve_gid, +unbind_gid, increment_credit, decrement_credit, allocate, +begin_migration, end_migration

+

component namespace services: bind_prefix, bind_name, +resolve_id, unbind_name, iterate_types, +get_component_typename, num_localities_type

+

locality namespace services: free, localities, +num_localities, num_threads, resolve_locality, +resolved_localities

+

symbol namespace services: bind, resolve, unbind, +iterate_names, on_symbol_namespace_event

+

Counter instance formatting

<agas_instance>/total

+

where <agas_instance> is the name of the AGAS service to query. +Currently, this value will be locality#0 where 0 is the root +locality (the id of the locality hosting the AGAS +service).

+

The value for * can be any locality id for the following +<agas_service>: route, bind_gid, resolve_gid, +unbind_gid, increment_credit, decrement_credit, bin, +resolve, unbind, and iterate_names (only the primary and +symbol AGAS service components live on all localities, whereas +all other AGAS services are available on locality#0 only).

+

Description

Returns the total number of invocations of the specified AGAS +service since its creation.

+ + ++++ + + + + + + + + + + + +
Table 29 AGAS performance counter /agas/<agas_service_category>/count#

Counter type

/agas/<agas_service_category>/count

+

where <agas_service_category> is one of the following: primary, +locality, component or symbol

+

Counter instance formatting

<agas_instance>/total

+

where <agas_instance> is the name of the AGAS service to query. +Currently, this value will be locality#0 where 0 is the root +locality (the id of the locality hosting the AGAS +service). Except for <agas_service_category>, primary or +symbol for which the value for * can be any locality id +(only the primary and symbol AGAS service components live on all +localities, whereas all other AGAS services are available on +locality#0 only).

+

Description

Returns the overall total number of invocations of all AGAS +services provided by the given AGAS service category since its +creation.

+ + ++++ + + + + + + + + + + + +
Table 30 AGAS performance counter /agas/<agas_service_category>/count#

Counter type

/agas/<agas_service_category>/count

+

where <agas_service_category> is one of the following: primary, +locality, component or symbol

+

Counter instance formatting

<agas_instance>/total

+

where <agas_instance> is the name of the AGAS service to query. +Currently, this value will be locality#0 where 0 is the root +locality (the id of the locality hosting the AGAS +service). Except for <agas_service_category>, primary or +symbol for which the value for * can be any locality id +(only the primary and symbol AGAS service components live on all +localities, whereas all other AGAS services are available on +locality#0 only).

+

Description

Returns the overall total number of invocations of all AGAS +services provided by the given AGAS service category since its +creation.

+ + ++++ + + + + + + + + + + + +
Table 31 AGAS performance counter agas/time/<agas_service>#

Counter type

agas/time/<agas_service>

+

where <agas_service> is one of the following:

+

primary namespace services: route, bind_gid, resolve_gid, +unbind_gid, increment_credit, decrement_credit, allocate +begin_migration, end_migration

+

component namespace services: bind_prefix, bind_name, +resolve_id, unbind_name, iterate_types, +get_component_typename, num_localities_type

+

locality namespace services: free, localities, +num_localities, num_threads, resolve_locality, +resolved_localities

+

symbol namespace services: bind, resolve, unbind, +iterate_names, on_symbol_namespace_event

+

Counter instance formatting

<agas_instance>/total

+

where <agas_instance> is the name of the AGAS service to query. +Currently, this value will be locality#0 where 0 is the root +locality (the id of the locality hosting the AGAS +service).

+

The value for * can be any locality id for the following +<agas_service>: route, bind_gid, resolve_gid, +unbind_gid, increment_credit, decrement_credit, bin, +resolve, unbind, and iterate_names (only the primary and +symbol AGAS service components live on all localities, whereas +all other AGAS services are available on locality#0 only).

+

Description

Returns the overall execution time of the specified AGAS service +since its creation (in nanoseconds).

+ + ++++ + + + + + + + + + + + +
Table 32 AGAS performance counter /agas/<agas_service_category>/time`#

Counter type

/agas/<agas_service_category>/time

+

where <agas_service_category> is one of the following: primary, +locality, component or symbol

+

Counter instance formatting

<agas_instance>/total

+

where <agas_instance> is the name of the AGAS service to query. +Currently, this value will be locality#0 where 0 is the root +locality (the id of the locality hosting the AGAS +service). Except for <agas_service_category primary or symbol +for which the value for * can be any locality id (only the +primary and symbol AGAS service components live on all +localities, whereas all other AGAS services are available on +locality#0 only).

+

Description

Returns the overall execution time of all AGAS services provided +by the given AGAS service category since its creation (in +nanoseconds).

+ + ++++ + + + + + + + + + + + +
Table 33 AGAS performance counter /agas/count/entries#

Counter type

/agas/count/entries

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the +AGAS cache should be queried. The locality id is a (zero based) +number identifying the locality.

+

Description

Returns the number of cache entries resident in the AGAS cache of +the specified locality (see <cache_statistics>).

+ + ++++ + + + + + + + + + + + +
Table 34 AGAS performance counter /agas/count/<cache_statistics>#

Counter type

/agas/count/<cache_statistics>

+

where <cache_statistics> is one of the +following: cache/evictions, cache/hits, cache/insertions, cache/misses

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the AGAS +cache should be queried. The locality id is a (zero based) number +identifying the locality

+

Description

Returns the number of cache events (evictions, hits, inserts, and misses) +in the AGAS cache of the specified locality (see +<cache_statistics>).

+ + ++++ + + + + + + + + + + + +
Table 35 AGAS performance counter /agas/count/<full_cache_statistics>#

Counter type

/agas/count/<full_cache_statistics>

+

where <full_cache_statistics> is one of the following: cache/get_entry, +cache/insert_entry, cache/update_entry, cache/erase_entry

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the AGAS +cache should be queried. The locality id is a (zero based) number +identifying the locality.

+

Description

Returns the number of invocations of the specified cache API function of +the AGAS cache.

+ + ++++ + + + + + + + + + + + +
Table 36 AGAS performance counter /agas/time/<full_cache_statistics>#

Counter type

/agas/time/<full_cache_statistics>

+

where <full_cache_statistics> is one of the following:

+

cache/get_entry, cache/insert_entry, cache/update_entry, +cache/erase_entry

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the AGAS +cache should be queried. The locality id is a (zero based) number +identifying the locality.

+

Description

Returns the overall time spent executing of the specified API function of +the AGAS cache.

+ + ++++ + + + + + + + + + + + +
Table 37 Parcel layer performance counter /data/count/<connection_type>/<operation>#

Counter type

/data/count/<connection_type>/<operation>

+

where: +<operation> is one of the following: sent, received

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the overall +number of transmitted bytes should be queried for. The locality +id is a (zero based) number identifying the locality.

+

Description

Returns the overall number of raw (uncompressed) bytes sent or received +(see <operation>, e.g. sent or received) for the specified +<connection_type>.

+

The performance counters are available only if the compile time constant +HPX_HAVE_PARCELPORT_COUNTERS was defined while compiling the HPX +core library (which is not defined by default). The corresponding cmake +configuration constant is HPX_WITH_PARCELPORT_COUNTERS.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+
+ + ++++ + + + + + + + + + + + +
Table 38 Parcel layer performance counter /data/time/<connection_type>/<operation>#

Counter type

/data/time/<connection_type>/<operation>

+

where:

+

<operation> is one of the following: sent, received

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the total +transmission time should be queried for. The locality id is a +(zero based) number identifying the locality.

+

Description

Returns the total time (in nanoseconds) between the start of each +asynchronous transmission operation and the end of the corresponding +operation for the specified <connection_type> the given +locality (see <operation>, e.g. sent or received).

+

The performance counters are available only if the compile time constant +HPX_HAVE_PARCELPORT_COUNTERS was defined while compiling the HPX +core library (which is not defined by default). The corresponding cmake +configuration constant is HPX_WITH_PARCELPORT_COUNTERS.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+
+ + ++++ + + + + + + + + + + + + + + +
Table 39 Parcel layer performance counter /serialize/count/<connection_type>/<operation>#

Counter type

/serialize/count/<connection_type>/<operation>

+

where:

+

<operation> is one of the following: sent, received

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the overall +number of transmitted bytes should be queried for. The locality +id is a (zero based) number identifying the locality.

+

Description

Returns the overall number of bytes transferred (see <operation>, +e.g. sent or received possibly compressed) for the specified +<connection_type> by the given locality.

+

The performance counters are available only if the compile time constant +HPX_HAVE_PARCELPORT_COUNTERS was defined while compiling the HPX +core library (which is not defined by default). The corresponding cmake +configuration constant is HPX_WITH_PARCELPORT_COUNTERS.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+

Description

If the configure-time option -DHPX_WITH_PARCELPORT_ACTION_COUNTERS=On +was specified, this counter allows one to specify an optional action name +as its parameter. In this case the counter will report the number of +bytes transmitted for the given action only.

+ + ++++ + + + + + + + + + + + + + + +
Table 40 Parcel layer performance counter /serialize/time/<connection_type>/<operation>#

Counter type

/serialize/time/<connection_type>/<operation>

+

where:

+

<operation> is one of the following: sent, received

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the +serialization time should be queried for. The locality id is a +(zero based) number identifying the locality.

+

Description

Returns the overall time spent performing outgoing data serialization for +the specified <connection_type> on the given locality (see +<operation>, e.g. sent or received).

+

The performance counters are available only if the compile time constant +HPX_HAVE_PARCELPORT_COUNTERS was defined while compiling the HPX +core library (which is not defined by default). The corresponding cmake +configuration constant is HPX_WITH_PARCELPORT_COUNTERS.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+

Parameters

If the configure-time option -DHPX_WITH_PARCELPORT_ACTION_COUNTERS=On +was specified, this counter allows one to specify an optional action name +as its parameter. In this case the counter will report the serialization +time for the given action only.

+ + ++++ + + + + + + + + + + + + + + +
Table 41 Parcel layer performance counter /parcels/count/routed#

Counter type

/parcels/count/routed

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the number of +routed parcels should be queried for. The locality id is a (zero +based) number identifying the locality.

+

Description

Returns the overall number of routed (outbound) parcels transferred by +the given locality.

+

Routed parcels are those which cannot directly be delivered to its +destination as the local AGAS is not able to resolve the +destination address. In this case a parcel is sent to the AGAS +service component which is responsible for creating the destination GID +(and is responsible for resolving the destination address). This +AGAS service component will deliver the parcel to its final +target.

+

Parameters

If the configure-time option -DHPX_WITH_PARCELPORT_ACTION_COUNTERS=On +was specified, this counter allows one to specify an optional action name +as its parameter. In this case the counter will report the number of +parcels for the given action only.

+ + ++++ + + + + + + + + + + + +
Table 42 Parcel layer performance counter /parcels/count/<connection_type>/<operation>#

Counter type

/parcels/count/<connection_type>/<operation>

+

where:

+

<operation> is one of the following: sent, received

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the number of +parcels should be queried for. The locality id is a (zero based) +number identifying the locality.

+

Description

Returns the overall number of parcels transferred using the specified +<connection_type> by the given locality (see operation>, +e.g. sent or received.

+

The performance counters are available only if the compile time constant +HPX_HAVE_PARCELPORT_COUNTERS was defined while compiling the HPX +core library (which is not defined by default). The corresponding cmake +configuration constant is HPX_WITH_PARCELPORT_COUNTERS.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+
+ + ++++ + + + + + + + + + + + +
Table 43 Parcel layer performance counter /messages/count/<connection_type>/<operation>#

Counter type

/messages/count/<connection_type>/<operation> +where:

+

<operation> is one of the following: sent, received

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the number of +messages should be queried for. The locality id is a (zero based) +number identifying the locality.

+

Description

Returns the overall number of messages 1 transferred using the +specified <connection_type> by the given locality (see +<operation>, e.g. sent or received)

+

The performance counters are available only if the compile time constant +HPX_HAVE_PARCELPORT_COUNTERS was defined while compiling the HPX +core library (which is not defined by default). The corresponding cmake +configuration constant is HPX_WITH_PARCELPORT_COUNTERS.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+
+ + ++++ + + + + + + + + + + + +
Table 44 Parcel layer performance counter /parcelport/count/<connection_type>/zero_copy_chunks/<operation>#

Counter type

/parcelport/count/<connection_type>/zero_copy_chunks/<operation>

+

where:

+

<operation> is one of the following: sent, received

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the overall +number of transmitted bytes should be queried for. The locality +id is a (zero based) number identifying the locality.

+

Description

Returns the overall number of zero-copy chunks sent or received +(see <operation>, e.g. sent or received) for the specified +<connection_type>.

+

The performance counters are available only if the compile time constant +HPX_HAVE_PARCELPORT_COUNTERS was defined while compiling the HPX +core library (which is not defined by default). The corresponding cmake +configuration constant is HPX_WITH_PARCELPORT_COUNTERS.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+
+ + ++++ + + + + + + + + + + + +
Table 45 Parcel layer performance counter /parcelport/count-max/<connection_type>/zero_copy_chunks/<operation>#

Counter type

/parcelport/count-max/<connection_type>/zero_copy_chunks/<operation>

+

where:

+

<operation> is one of the following: sent, received

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the overall +number of transmitted bytes should be queried for. The locality +id is a (zero based) number identifying the locality.

+

Description

Returns the maximum number of zero-copy chunks sent or received per message +(see <operation>, e.g. sent or received) for the specified +<connection_type>.

+

The performance counters are available only if the compile time constant +HPX_HAVE_PARCELPORT_COUNTERS was defined while compiling the HPX +core library (which is not defined by default). The corresponding cmake +configuration constant is HPX_WITH_PARCELPORT_COUNTERS.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+
+ + ++++ + + + + + + + + + + + +
Table 46 Parcel layer performance counter /parcelport/size/<connection_type>/zero_copy_chunks/<operation>#

Counter type

/parcelport/size/<connection_type>/zero_copy_chunks/<operation>

+

where:

+

<operation> is one of the following: sent, received

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the overall +number of transmitted bytes should be queried for. The locality +id is a (zero based) number identifying the locality.

+

Description

Returns the overall size of zero-copy chunks sent or received +(see <operation>, e.g. sent or received) for the specified +<connection_type>.

+

The performance counters are available only if the compile time constant +HPX_HAVE_PARCELPORT_COUNTERS was defined while compiling the HPX +core library (which is not defined by default). The corresponding cmake +configuration constant is HPX_WITH_PARCELPORT_COUNTERS.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+
+ + ++++ + + + + + + + + + + + +
Table 47 Parcel layer performance counter /parcelport/size-max/<connection_type>/zero_copy_chunks/<operation>#

Counter type

/parcelport/size-max/<connection_type>/zero_copy_chunks/<operation>

+

where:

+

<operation> is one of the following: sent, received

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the overall +number of transmitted bytes should be queried for. The locality +id is a (zero based) number identifying the locality.

+

Description

Returns the maximum size of zero-copy chunks sent or received +(see <operation>, e.g. sent or received) for the specified +<connection_type>.

+

The performance counters are available only if the compile time constant +HPX_HAVE_PARCELPORT_COUNTERS was defined while compiling the HPX +core library (which is not defined by default). The corresponding cmake +configuration constant is HPX_WITH_PARCELPORT_COUNTERS.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+
+ + ++++ + + + + + + + + + + + +
Table 48 Parcel layer performance counter /parcelport/count/<connection_type>/<cache_statistics>#

Counter type

/parcelport/count/<connection_type>/<cache_statistics>

+

where:

+

<cache_statistics> is one of the following: cache/insertions, +cache/evictions, cache/hits, cache/misses

+

<connection_type> is one of the following: tcp, mpi

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the number of +messages should be queried for. The locality id is a (zero based) +number identifying the locality.

+

Description

Returns the overall number cache events (evictions, hits, inserts, +misses, and reclaims) for the connection cache of the given connection +type on the given locality (see <cache_statistics, e.g. +ache/insertions, cache/evictions, cache/hits, +cache/misses or``cache/reclaims``.

+

The performance counters for the connection type mpi are available +only if the compile time constant HPX_HAVE_PARCELPORT_MPI was defined +while compiling the HPX core library (which is not defined by default). +The corresponding cmake configuration constant is +HPX_WITH_PARCELPORT_MPI.

+

Please see CMake options for more details.

+
+ + ++++ + + + + + + + + + + + +
Table 49 Parcel layer performance counter /parcelqueue/length/<operation>#

Counter type

/parcelqueue/length/<operation>

+

where <operation> is one of the following: sent, receive

+

Counter instance formatting

locality#*/total

+

where * is the locality id of the locality the parcel queue +should be queried. The locality id is a (zero based) number +identifying the locality.

+

Description

Returns the current number of parcels stored in the parcel queue (see +<operation> for which queue to query, e.g. sent or received).

+ + ++++ + + + + + + + + + + + +
Table 50 Thread manager performance counter /threads/count/cumulative#

Counter type

/threads/count/cumulative

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the overall +number of retired HPX-threads should be queried for. The +locality id (given by the *) is a (zero based) number identifying +the locality.

+
+
pool#* is defining the pool for which the current value of the

idle-loop counter should be queried for.

+
+
worker-thread#* is defining the worker thread for which the overall

number of retired HPX-threads should be queried for. The worker thread +number (given by the *) is a (zero based) number identifying the +worker thread. The number of available worker threads is usually +specified on the command line for the application using the option +--hpx:threads. If no pool-name is specified the counter refers +to the ‘default’ pool.

+
+
+

Description

Returns the overall number of executed (retired) HPX-threads on the +given locality since application start. If the instance name is +total the counter returns the accumulated number of retired +HPX-threads for all worker threads (cores) on that locality. If +the instance name is worker-thread#* the counter will return the +overall number of retired HPX-threads for all worker threads +separately. This counter is available only if the configuration time +constant HPX_WITH_THREAD_CUMULATIVE_COUNTS is set to ON (default: +ON).

+ + ++++ + + + + + + + + + + + +
Table 51 Thread manager performance counter /threads/time/average#

Counter type

/threads/time/average

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the average +time spent executing one HPX-thread should be queried for. The +locality id (given by the *) is a (zero based) number identifying +the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the average +time spent executing one HPX-thread should be queried for. The worker +thread number (given by the *) is a (zero based) number identifying +the worker thread. The number of available worker threads is usually +specified on the command line for the application using the option +--hpx:threads. If no pool-name is specified the counter refers +to the ‘default’ pool.

+

Description

Returns the average time spent executing one HPX-thread on the given +locality since application start. If the instance name is total +the counter returns the average time spent executing one HPX-thread for +all worker threads (cores) on that locality. If the instance name +is worker-thread#* the counter will return the average time spent +executing one HPX-thread for all worker threads separately. This counter +is available only if the configuration time constants +HPX_WITH_THREAD_CUMULATIVE_COUNTS (default: ON) and +HPX_WITH_THREAD_IDLE_RATES are set to ON (default: OFF). The unit +of measure for this counter is nanosecond [ns].

+ + ++++ + + + + + + + + + + + +
Table 52 Thread manager performance counter /threads/time/average-overhead#

Counter type

/threads/time/average-overhead

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the average +overhead spent executing one HPX-thread should be queried for. The +locality id (given by the *) is a (zero based) number identifying +the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the average +overhead spent executing one HPX-thread should be queried for. The +worker thread number (given by the *) is a (zero based) number +identifying the worker thread. The number of available worker threads is +usually specified on the command line for the application using the +option --hpx:threads. If no pool-name is specified the counter +refers to the ‘default’ pool.

+

Description

Returns the average time spent on overhead while executing one +HPX-thread on the given locality since application start. If +the instance name is total the counter returns the average time spent +on overhead while executing one HPX-thread for all worker threads +(cores) on that locality. If the instance name is +worker-thread#* the counter will return the average time spent on +overhead executing one HPX-thread for all worker threads separately. +This counter is available only if the configuration time constants +HPX_WITH_THREAD_CUMULATIVE_COUNTS (default: ON) and +HPX_WITH_THREAD_IDLE_RATES are set to ON (default: OFF). The +unit of measure for this counter is nanosecond [ns].

+ + ++++ + + + + + + + + + + + +
Table 53 Thread manager performance counter /threads/count/cumulative-phases#

Counter type

/threads/count/cumulative-phases

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the overall +number of executed HPX-thread phases (invocations) should be queried +for. The locality id (given by the *) is a (zero based) number +identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the overall +number of executed HPX-thread phases (invocations) should be queried +for. The worker thread number (given by the *) is a (zero based) +number identifying the worker thread. The number of available worker +threads is usually specified on the command line for the application +using the option --hpx:threads. If no pool-name is specified +the counter refers to the ‘default’ pool.

+

Description

Returns the overall number of executed HPX-thread phases (invocations) +on the given locality since application start. If the instance +name is total the counter returns the accumulated number of executed +HPX-thread phases (invocations) for all worker threads (cores) on that +locality. If the instance name is worker-thread#* the counter +will return the overall number of executed HPX-thread phases for all +worker threads separately. This counter is available only if the +configuration time constant HPX_WITH_THREAD_CUMULATIVE_COUNTS is set +to ON (default: ON). The unit of measure for this counter is +nanosecond [ns].

+ + ++++ + + + + + + + + + + + +
Table 54 Thread manager performance counter /threads/time/average-phase#

Counter type

/threads/time/average-phase

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the average +time spent executing one HPX-thread phase (invocation) should be +queried for. The locality id (given by the *) is a (zero based) +number identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the average +time executing one HPX-thread phase (invocation) should be queried for. +The worker thread number (given by the *) is a (zero based) number +identifying the worker thread. The number of available worker threads is +usually specified on the command line for the application using the +option --hpx:threads. If no pool-name is specified the counter +refers to the ‘default’ pool.

+

Description

Returns the average time spent executing one HPX-thread phase +(invocation) on the given locality since application start. If +the instance name is total the counter returns the average time spent +executing one HPX-thread phase (invocation) for all worker threads +(cores) on that locality. If the instance name is +worker-thread#* the counter will return the average time spent +executing one HPX-thread phase for all worker threads separately. This +counter is available only if the configuration time constants +HPX_WITH_THREAD_CUMULATIVE_COUNTS (default: ON) and +HPX_WITH_THREAD_IDLE_RATES are set to ON (default: OFF). The +unit of measure for this counter is nanosecond [ns].

+ + ++++ + + + + + + + + + + + +
Table 55 Thread manager performance counter /threads/time/average-phase-overhead#

Counter type

/threads/time/average-phase-overhead

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the average +time overhead executing one HPX-thread phase (invocation) should be +queried for. The locality id (given by the *) is a (zero based) +number identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the average +overhead executing one HPX-thread phase (invocation) should be queried +for. The worker thread number (given by the *) is a (zero based) +number identifying the worker thread. The number of available worker +threads is usually specified on the command line for the application +using the option --hpx:threads. If no pool-name is specified +the counter refers to the ‘default’ pool.

+

Description

Returns the average time spent on overhead executing one HPX-thread +phase (invocation) on the given locality since application start. +If the instance name is total the counter returns the average time +spent on overhead while executing one HPX-thread phase (invocation) for +all worker threads (cores) on that locality. If the instance name +is worker-thread#* the counter will return the average time spent on +overhead executing one HPX-thread phase for all worker threads +separately. This counter is available only if the configuration time +constants HPX_WITH_THREAD_CUMULATIVE_COUNTS (default: ON) and +HPX_WITH_THREAD_IDLE_RATES are set to ON (default: OFF). The +unit of measure for this counter is nanosecond [ns].

+ + ++++ + + + + + + + + + + + +
Table 56 Thread manager performance counter /threads/time/overall#

Counter type

/threads/time/overall

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the overall +time spent running the scheduler should be queried for. The +locality id (given by the *) is a (zero based) number identifying +the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the overall +time spent running the scheduler should be queried for. The worker thread +number (given by the *) is a (zero based) number identifying the +worker thread. The number of available worker threads is usually +specified on the command line for the application using the option +--hpx:threads. If no pool-name is specified the counter refers +to the ‘default’ pool.

+

Description

Returns the overall time spent running the scheduler on the given +locality since application start. If the instance name is total +the counter returns the overall time spent running the scheduler for all +worker threads (cores) on that locality. If the instance name is +worker-thread#* the counter will return the overall time spent running +the scheduler for all worker threads separately. This counter is available +only if the configuration time constant HPX_WITH_THREAD_IDLE_RATES is +set to ON (default: OFF). The unit of measure for this counter is +nanosecond [ns].

+ + ++++ + + + + + + + + + + + +
Table 57 Thread manager performance counter /threads/time/cumulative#

Counter type

/threads/time/cumulative

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the overall +time spent executing all HPX-threads should be queried for. The +locality id (given by the *) is a (zero based) number identifying +the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the overall +time spent executing all HPX-threads should be queried for. The worker +thread number (given by the *) is a (zero based) number identifying +the worker thread. The number of available worker threads is usually +specified on the command line for the application using the option +--hpx:threads. If no pool-name is specified the counter refers +to the ‘default’ pool.

+

Description

Returns the overall time spent executing all HPX-threads on the given +locality since application start. If the instance name is total +the counter returns the overall time spent executing all HPX-threads for +all worker threads (cores) on that locality. If the instance name +is worker-thread#* the counter will return the overall time spent +executing all HPX-threads for all worker threads separately. This counter +is available only if the configuration time constants +HPX_THREAD_MAINTAIN_CUMULATIVE_COUNTS (default: ON) and +HPX_THREAD_MAINTAIN_IDLE_RATES are set to ON (default: OFF).

+ + ++++ + + + + + + + + + + + +
Table 58 Thread manager performance counter /threads/time/cumulative-overheads#

Counter type

/threads/time/cumulative-overheads

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the overall +overhead time incurred by executing all HPX-threads should be queried +for. The locality id (given by the *) is a (zero based) number +identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the the +overall overhead time incurred by executing all HPX-threads should be +queried for. The worker thread number (given by the *) is a (zero +based) number identifying the worker thread. The number of available +worker threads is usually specified on the command line for the +application using the option --hpx:threads. If no pool-name is +specified the counter refers to the ‘default’ pool.

+

Description

Returns the overall overhead time incurred executing all HPX-threads on +the given locality since application start. If the instance name +is total the counter returns the overall overhead time incurred +executing all HPX-threads for all worker threads (cores) on that +locality. If the instance name is worker-thread#* the counter +will return the overall overhead time incurred executing all +HPX-threads for all worker threads separately. This counter is +available only if the configuration time constants +HPX_THREAD_MAINTAIN_CUMULATIVE_COUNTS (default: ON) and +HPX_THREAD_MAINTAIN_IDLE_RATES are set to ON (default: OFF). +The unit of measure for this counter is nanosecond [ns].

+ + ++++ + + + + + + + + + + + +
Table 59 Thread manager performance counter threads/count/instantaneous/<thread-state>#

Counter type

threads/count/instantaneous/<thread-state>

+

where:

+

<thread-state> is one of the following: all, active, +pending, suspended, terminated, staged

+

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the current +number of threads with the given state should be queried for. The +locality id (given by the *) is a (zero based) number identifying +the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the current +number of threads with the given state should be queried for. The worker +thread number (given by the *) is a (zero based) number identifying +the worker thread. The number of available worker threads is usually +specified on the command line for the application using the option +--hpx:threads. If no pool-name is specified the counter refers +to the ‘default’ pool.

+

The staged thread state refers to registered tasks before they are +converted to thread objects.

+

Description

Returns the current number of HPX-threads having the given thread state +on the given locality. If the instance name is total the +counter returns the current number of HPX-threads of the given state +for all worker threads (cores) on that locality. If the instance +name is worker-thread#* the counter will return the current number of +HPX-threads in the given state for all worker threads separately.

+ + ++++ + + + + + + + + + + + +
Table 60 Thread manager performance counter threads/wait-time/<thread-state>#

Counter type

threads/wait-time/<thread-state>

+

where:

+

<thread-state> is one of the following: pending staged

+

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the average +wait time of HPX-threads (pending) or thread descriptions (staged) with +the given state should be queried for. The locality id (given by +* is a (zero based) number identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the average +wait time for the given state should be queried for. The worker thread +number (given by the *) is a (zero based) number identifying the +worker thread. The number of available worker threads is usually +specified on the command line for the application using the option +--hpx:threads. If no pool-name is specified the counter refers +to the ‘default’ pool.

+

The staged thread state refers to the wait time of registered tasks +before they are converted into thread objects, while the pending +thread state refers to the wait time of threads in any of the scheduling +queues.

+

Description

Returns the average wait time of HPX-threads (if the thread state is +pending or of task descriptions (if the thread state is staged on +the given locality since application start. If the instance name +is total the counter returns the wait time of HPX-threads of the +given state for all worker threads (cores) on that locality. If +the instance name is worker-thread#* the counter will return the wait +time of HPX-threads in the given state for all worker threads +separately.

+

These counters are available only if the compile time constant +HPX_WITH_THREAD_QUEUE_WAITTIME was defined while compiling the HPX +core library (default: OFF). The unit of measure for this counter is +nanosecond [ns].

+
+ + ++++ + + + + + + + + + + + +
Table 61 Thread manager performance counter /threads/idle-rate#

Counter type

/threads/idle-rate

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the average +idle rate of all (or one) worker threads should be queried for. The +locality id (given by the *) is a (zero based) number identifying +the locality

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the averaged +idle rate should be queried for. The worker thread number (given by the +* is a (zero based) number identifying the worker thread. The number +of available worker threads is usually specified on the command line for +the application using the option --hpx:threads. If no pool-name +is specified the counter refers to the ‘default’ pool.

+

Description

Returns the average idle rate for the given worker thread(s) on the given +locality. The idle rate is defined as the ratio of the time spent +on scheduling and management tasks and the overall time spent executing +work since the application started. This counter is available only if the +configuration time constant HPX_WITH_THREAD_IDLE_RATES is set to ON +(default: OFF).

+ + ++++ + + + + + + + + + + + +
Table 62 Thread manager performance counter /threads/creation-idle-rate#

Counter type

/threads/creation-idle-rate

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the average +creation idle rate of all (or one) worker threads should be queried for. +The locality id (given by the *) is a (zero based) number +identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the averaged +idle rate should be queried for. The worker thread number (given by the +* is a (zero based) number identifying the worker thread. The number +of available worker threads is usually specified on the command line for +the application using the option --hpx:threads. If no pool-name +is specified the counter refers to the ‘default’ pool.

+

Description

Returns the average idle rate for the given worker thread(s) on the given +locality which is caused by creating new threads. The creation idle +rate is defined as the ratio of the time spent on creating new threads and +the overall time spent executing work since the application started. This +counter is available only if the configuration time constants +HPX_WITH_THREAD_IDLE_RATES (default: OFF) and +HPX_WITH_THREAD_CREATION_AND_CLEANUP_RATES are set to ON.

+ + ++++ + + + + + + + + + + + +
Table 63 Thread manager performance counter /threads/cleanup-idle-rate#

Counter type

/threads/cleanup-idle-rate

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the average +cleanup idle rate of all (or one) worker threads should be queried for. +The locality id (given by the *) is a (zero based) number +identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the averaged +cleanup idle rate should be queried for. The worker thread number (given +by the *) is a (zero based) number identifying the worker thread. The +number of available worker threads is usually specified on the command +line for the application using the option --hpx:threads. If no +pool-name is specified the counter refers to the ‘default’ pool.

+

Description

Returns the average idle rate for the given worker thread(s) on the given +locality which is caused by cleaning up terminated threads. The +cleanup idle rate is defined as the ratio of the time spent on cleaning up +terminated thread objects and the overall time spent executing work since +the application started. This counter is available only if the +configuration time constants HPX_WITH_THREAD_IDLE_RATES (default: +OFF) and HPX_WITH_THREAD_CREATION_AND_CLEANUP_RATES are set to +ON.

+ + ++++ + + + + + + + + + + + +
Table 64 Thread manager performance counter /threadqueue/length#

Counter type

/threadqueue/length

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the current +length of all thread queues in the scheduler for all (or one) worker +threads should be queried for. The locality id (given by the *) is +a (zero based) number identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the current +length of all thread queues in the scheduler should be queried for. The +worker thread number (given by the *) is a (zero based) number +identifying the worker thread. The number of available worker threads is +usually specified on the command line for the application using the +option --hpx:threads. If no pool-name is specified the counter +refers to the ‘default’ pool.

+

Description

Returns the overall length of all queues for the given worker thread(s) +on the given locality.

+ + ++++ + + + + + + + + + + + +
Table 65 Thread manager performance counter /threads/count/stack-unbinds#

Counter type

/threads/count/stack-unbinds

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the unbind +(madvise) operations should be queried for. The locality id is a +(zero based) number identifying the locality.

+

Description

Returns the total number of HPX-thread unbind (madvise) operations +performed for the referenced locality. Note that this counter is +not available on Windows based platforms.

+ + ++++ + + + + + + + + + + + +
Table 66 Thread manager performance counter /threads/count/stack-recycles#

Counter type

/threads/count/stack-recycles

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the recycling +operations should be queried for. The locality id is a (zero +based) number identifying the locality.

+

Description

Returns the total number of HPX-thread recycling operations performed.

+ + ++++ + + + + + + + + + + + +
Table 67 Thread manager performance counter /threads/count/stolen-from-pending#

Counter type

/threads/count/stolen-from-pending

Counter instance formatting

locality#*/total

+
+

where:

+
+

* is the locality id of the locality the number of +‘stole’ threads should be queried for. The locality id is a (zero +based) number identifying the locality.

+

Description

Returns the total number of HPX-threads ‘stolen’ from the pending +thread queue by a neighboring thread worker thread (these threads are +executed by a different worker thread than they were initially scheduled +on). This counter is available only if the configuration time constant +HPX_WITH_THREAD_STEALING_COUNTS is set to ON (default: ON).

+ + ++++ + + + + + + + + + + + +
Table 68 Thread manager performance counter /threads/count/pending-misses#

Counter type

/threads/count/pending-misses

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the number of +pending queue misses of all (or one) worker threads should be queried +for. The locality id (given by the *) is a (zero based) number +identifying the locality

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the number of +pending queue misses should be queried for. The worker thread number +(given by the *) is a (zero based) number identifying the worker +thread. The number of available worker threads is usually specified on +the command line for the application using the option +--hpx:threads. If no pool-name is specified the counter refers +to the ‘default’ pool.

+

Description

Returns the total number of times that the referenced worker-thread on +the referenced locality failed to find pending HPX-threads in +its associated queue. This counter is available only if the configuration +time constant HPX_WITH_THREAD_STEALING_COUNTS is set to ON +(default: ON).

+ + ++++ + + + + + + + + + + + +
Table 69 Thread manager performance counter /threads/count/pending-accesses#

Counter type

/threads/count/pending-accesses

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the number of +pending queue accesses of all (or one) worker threads should be queried +for. The locality id (given by the *) is a (zero based) number +identifying the locality

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the number of +pending queue accesses should be queried for. The worker thread number +(given by the *) is a (zero based) number identifying the worker +thread. The number of available worker threads is usually specified on +the command line for the application using the option +--hpx:threads. If no pool-name is specified the counter refers +to the ‘default’ pool.

+

Description

Returns the total number of times that the referenced worker-thread on +the referenced locality looked for pending HPX-threads in its +associated queue. This counter is available only if the configuration +time constant HPX_WITH_THREAD_STEALING_COUNTS is set to ON +(default: ON).

+ + ++++ + + + + + + + + + + + +
Table 70 Thread manager performance counter /threads/count/stolen-from-staged#

Counter type

/threads/count/stolen-from-staged

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the number of +HPX-threads stolen from the staged queue of all (or one) worker threads +should be queried for. The locality id (given by the *) is a (zero +based) number identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the number of +HPX-threads stolen from the staged queue should be queried for. The +worker thread number (given by the *) is a (zero based) number +identifying the worker thread. The number of available worker threads is +usually specified on the command line for the application using the +option --hpx:threads. If no pool-name is specified the counter +refers to the ‘default’ pool.

+

Description

Returns the total number of HPX-threads ‘stolen’ from the staged thread +queue by a neighboring worker thread (these threads are executed by a +different worker thread than they were initially scheduled on). This +counter is available only if the configuration time constant +HPX_WITH_THREAD_STEALING_COUNTS is set to ON (default: ON).

+ + ++++ + + + + + + + + + + + +
Table 71 Thread manager performance counter /threads/count/stolen-to-pending#

Counter type

/threads/count/stolen-to-pending

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the number of +HPX-threads stolen to the pending queue of all (or one) worker threads +should be queried for. The locality id (given by the *) is a (zero +based) number identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the number of +HPX-threads stolen to the pending queue should be queried for. The +worker thread number (given by the *) is a (zero based) number +identifying the worker thread. The number of available worker threads is +usually specified on the command line for the application using the +option --hpx:threads. If no pool-name is specified the counter +refers to the ‘default’ pool.

+

Description

Returns the total number of HPX-threads ‘stolen’ to the pending thread +queue of the worker thread (these threads are executed by a different +worker thread than they were initially scheduled on). This counter is +available only if the configuration time constant +HPX_WITH_THREAD_STEALING_COUNTS is set to ON (default: ON).

+ + ++++ + + + + + + + + + + + +
Table 72 Thread manager performance counter /threads/count/stolen-to-staged#

Counter type

/threads/count/stolen-to-staged

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the number of +HPX-threads stolen to the staged queue of all (or one) worker threads +should be queried for. The locality id (given by *) is a (zero +based) number identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the number of +HPX-threads stolen to the staged queue should be queried for. The +worker thread number (given by the *) is a (zero based) worker thread +number (given by the *) is a (zero based) number identifying the +worker thread. The number of available worker threads is usually +specified on the command line for the application using the option +--hpx:threads. If no pool-name is specified the counter refers +to the ‘default’ pool.

+

Description

Returns the total number of HPX-threads ‘stolen’ to the staged thread +queue of a neighboring worker thread (these threads are executed by a +different worker thread than they were initially scheduled on). This +counter is available only if the configuration time constant +HPX_WITH_THREAD_STEALING_COUNTS is set to ON (default: ON).

+ + ++++ + + + + + + + + + + + +
Table 73 Thread manager performance counter /threads/count/objects#

Counter type

/threads/count/objects

Counter instance formatting

locality#*/total or

+

locality#*/allocator#*

+

where:

+

locality#* is defining the locality for which the current +(cumulative) number of all created HPX-thread objects should be queried +for. The locality id (given by *) is a (zero based) number +identifying the locality.

+

allocator#* is defining the number of the allocator instance using +which the threads have been created. HPX uses a varying number of +allocators to create (and recycle) HPX-thread objects, most likely +these counters are of use for debugging purposes only. The allocator id +(given by *) is a (zero based) number identifying the allocator to +query.

+

Description

Returns the total number of HPX-thread objects created. Note that +thread objects are reused to improve system performance, thus this number +does not reflect the number of actually executed (retired) HPX-threads.

+ + ++++ + + + + + + + + + + + + + + +
Table 74 Thread manager performance counter /scheduler/utilization/instantaneous#

Counter type

/scheduler/utilization/instantaneous

Counter instance formatting

locality#*/total

+

where:

+

locality#* is defining the locality for which the current +(instantaneous) scheduler utilization queried for. The locality +id (given by *) is a (zero based) number identifying the +locality.

+

Description

+
Returns the total (instantaneous) scheduler utilization. This is the

current percentage of scheduler threads executing HPX threads.

+
+
+

Parameters

Percent

+ + ++++ + + + + + + + + + + + +
Table 75 Thread manager performance counter /threads/idle-loop-count/instantaneous#

Counter type

/threads/idle-loop-count/instantaneous

Counter instance formatting

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the current +current accumulated value of all idle-loop counters of all worker threads +should be queried. The locality id (given by the *) is a (zero +based) number identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the current +value of the idle-loop counter should be queried for. The worker thread +number (given by the *) is a (zero based) worker thread number (given +by the *) is a (zero based) number identifying the worker thread. The +number of available worker threads is usually specified on the command +line for the application using the option --hpx:threads. If no +pool-name is specified the counter refers to the ‘default’ pool.

+

Description

Returns the current (instantaneous) idle-loop count for the given +HPX- worker thread or the accumulated value for all worker threads.

+ + ++++ + + + + + + + + + + + +
Table 76 Thread manager performance counter /threads/busy-loop-count/instantaneous#

Counter type

/threads/busy-loop-count/instantaneous

Counter instance formatting

locality#*/worker-thread#* or

+

locality#*/pool#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the current +current accumulated value of all busy-loop counters of all worker threads +should be queried. The locality id (given by the *) is a (zero +based) number identifying the locality.

+

pool#* is defining the pool for which the current value of the +idle-loop counter should be queried for.

+

worker-thread#* is defining the worker thread for which the current +value of the busy-loop counter should be queried for. The worker thread +number (given by the *) is a (zero based) worker thread number (given +by the *) is a (zero based) number identifying the worker thread. The +number of available worker threads is usually specified on the command +line for the application using the option --hpx:threads. If no +pool-name is specified the counter refers to the ‘default’ pool.

+

Description

Returns the current (instantaneous) busy-loop count for the given HPX- +worker thread or the accumulated value for all worker threads.

+
+ + ++++ + + + + + + + + + + + +
Table 77 Thread manager performance counter /threads/time/background-work-duration#

Counter type

/threads/time/background-work-duration

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the overall time spent +performing background work should be queried for. The locality id (given +by *) is a (zero based) number identifying the locality.

+

worker-thread#* is defining the worker thread for which the overall +time spent performing background work should be queried for. The worker +thread number (given by the *) is a (zero based) number identifying +the worker thread. The number of available worker threads is usually +specified on the command line for the application using the option +--hpx:threads.

+

Description

Returns the overall time spent performing background work on the given +locality since application start. If the instance name is total the +counter returns the overall time spent performing background work for all +worker threads (cores) on that locality. If the instance name is +worker-thread#* the counter will return the overall time spent +performing background work for all worker threads separately. This +counter is available only if the configuration time constants +HPX_WITH_BACKGROUND_THREAD_COUNTERS (default: OFF) and +HPX_WITH_THREAD_IDLE_RATES are set to ON (default: OFF). The +unit of measure for this counter is nanosecond [ns].

+ + ++++ + + + + + + + + + + + +
Table 78 Thread manager performance counter /threads/background-overhead#

Counter type

/threads/background-overhead

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the background overhead +should be queried for. The locality id (given by *) is a (zero based) +number identifying the locality.

+

worker-thread#* is defining the worker thread for which the +background overhead should be queried for. The worker thread number +(given by the *) is a (zero based) number identifying the worker +thread. The number of available worker threads is usually specified on +the command line for the application using the option +--hpx:threads.

+

Description

Returns the background overhead on the given locality since application +start. If the instance name is total the counter returns the +background overhead for all worker threads (cores) on that locality. If +the instance name is worker-thread#* the counter will return +background overhead for all worker threads separately. This counter is +available only if the configuration time constants +HPX_WITH_BACKGROUND_THREAD_COUNTERS (default: OFF) and +HPX_WITH_THREAD_IDLE_RATES are set to ON (default: OFF). The +unit of measure displayed for this counter is 0.1%.

+ + ++++ + + + + + + + + + + + +
Table 79 Thread manager performance counter /threads/time/background-send-duration#

Counter type

/threads/time/background-send-duration

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the overall time spent +performing background work related to sending parcels should be queried +for. The locality id (given by *) is a (zero based) number +identifying the locality.

+

worker-thread#* is defining the worker thread for which the overall +time spent performing background work related to sending parcels should +be queried for. The worker thread number (given by the *) is a (zero +based) number identifying the worker thread. The number of available +worker threads is usually specified on the command line for the +application using the option --hpx:threads.

+

Description

Returns the overall time spent performing background work related to +sending parcels on the given locality since application start. If the +instance name is total the counter returns the overall time spent +performing background work for all worker threads (cores) on that +locality. If the instance name is worker-thread#* the counter will +return the overall time spent performing background work for all worker +threads separately. This counter is available only if the configuration +time constants HPX_WITH_BACKGROUND_THREAD_COUNTERS (default: OFF) +and HPX_WITH_THREAD_IDLE_RATES are set to ON (default: OFF). +The unit of measure for this counter is nanosecond [ns].

+

This counter will currently return meaningful values for the MPI +parcelport only.

+
+ + ++++ + + + + + + + + + + + +
Table 80 Thread manager performance counter /threads/background-send-overhead#

Counter type

/threads/background-send-overhead

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the background overhead +related to sending parcels should be queried for. The locality id (given +by *) is a (zero based) number identifying the locality.

+

worker-thread#* is defining the worker thread for which the +background overhead related to sending parcels should be queried for. +The worker thread number (given by the *) is a (zero based) number +identifying the worker thread. The number of available worker threads is +usually specified on the command line for the application using the option +--hpx:threads.

+

Description

Returns the background overhead related to sending parcels on the given +locality since application start. If the instance name is total the +counter returns the background overhead for all worker threads (cores) on +that locality. If the instance name is worker-thread#* the counter +will return background overhead for all worker threads separately. This +counter is available only if the configuration time constants +HPX_WITH_BACKGROUND_THREAD_COUNTERS (default: OFF) and +HPX_WITH_THREAD_IDLE_RATES are set to ON (default: OFF). The +unit of measure displayed for this counter is 0.1%.

+

This counter will currently return meaningful values for the MPI +parcelport only.

+
+ + ++++ + + + + + + + + + + + +
Table 81 Thread manager performance counter /threads/time/background-receive-duration#

Counter type

/threads/time/background-receive-duration

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the overall time spent +performing background work related to receiving parcels should be queried +for. The locality id (given by *) is a (zero based) number identifying +the locality.

+

worker-thread#* is defining the worker thread for which the overall +time spent performing background work related to receiving parcels should +be queried for. The worker thread number (given by the *) is a (zero +based) number identifying the worker thread. The number of available +worker threads is usually specified on the command line for the +application using the option --hpx:threads.

+

Description

Returns the overall time spent performing background work related to +receiving parcels on the given locality since application start. If the +instance name is total the counter returns the overall time spent +performing background work for all worker threads (cores) on that +locality. If the instance name is worker-thread#* the counter will +return the overall time spent performing background work for all worker +threads separately. This counter is available only if the configuration +time constants HPX_WITH_BACKGROUND_THREAD_COUNTERS (default: OFF) +and HPX_WITH_THREAD_IDLE_RATES are set to ON (default: OFF). +The unit of measure for this counter is nanosecond [ns].

+

This counter will currently return meaningful values for the MPI +parcelport only.

+
+ + ++++ + + + + + + + + + + + +
Table 82 Thread manager performance counter /threads/background-receive-overhead#

Counter type

/threads/background-receive-overhead

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the background overhead +related to receiving should be queried for. The locality id (given by +*) is a (zero based) number identifying the locality.

+

worker-thread#* is defining the worker thread for which the +background overhead related to receiving parcels should be queried for. +The worker thread number (given by the *) is a (zero based) number +identifying the worker thread. The number of available worker threads is +usually specified on the command line for the application using the option +--hpx:threads.

+

Description

Returns the background overhead related to receiving parcels on the given +locality since application start. If the instance name is total the +counter returns the background overhead for all worker threads (cores) on +that locality. If the instance name is worker-thread#* the counter +will return background overhead for all worker threads separately. This +counter is available only if the configuration time constants +HPX_WITH_BACKGROUND_THREAD_COUNTERS (default: OFF) and +HPX_WITH_THREAD_IDLE_RATES are set to ON (default: OFF). The +unit of measure displayed for this counter is 0.1%.

+

This counter will currently return meaningful values for the MPI +parcelport only.

+
+ + ++++ + + + + + + + + + + + + + + +
Table 83 General performance counter /runtime/count/component#

Counter type

/runtime/count/component

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +components should be queried. The locality id is a (zero based) +number identifying the locality.

+

Description

Returns the overall number of currently active components of the +specified type on the given locality.

Parameters

The type of the component. This is the string which has been used while +registering the component with HPX, e.g. which has been passed as the +second parameter to the macro HPX_REGISTER_COMPONENT.

+ + ++++ + + + + + + + + + + + + + + +
Table 84 General performance counter /runtime/count/action-invocation#

Counter type

/runtime/count/action-invocation

Counter instance formatting

locality#*/total

+
+

where:

+
+

* is the locality id of the locality the number of action +invocations should be queried. The locality id is a (zero based) +number identifying the locality.

+

Description

Returns the overall (local) invocation count of the specified action type +on the given locality.

Parameters

The action type. This is the string which has been used while registering +the action with HPX, e.g. which has been passed as the second parameter +to the macro HPX_REGISTER_ACTION or +HPX_REGISTER_ACTION_ID.

+ + ++++ + + + + + + + + + + + + + + +
Table 85 General performance counter /runtime/count/remote-action-invocation#

Counter type

/runtime/count/remote-action-invocation

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +action invocations should be queried. The locality id is a (zero +based) number identifying the locality.

+

Description

Returns the overall (remote) invocation count of the specified action +type on the given locality.

Parameters

The action type. This is the string which has been used while registering +the action with HPX, e.g. which has been passed as the second parameter +to the macro HPX_REGISTER_ACTION or +HPX_REGISTER_ACTION_ID.

+ + ++++ + + + + + + + + + + + +
Table 86 General performance counter /runtime/uptime#

Counter type

/runtime/uptime

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the system +uptime should be queried. The locality id is a (zero based) +number identifying the locality.

+

Description

Returns the overall time since application start on the given +locality in nanoseconds.

+ + ++++ + + + + + + + + + + + +
Table 87 General performance counter /runtime/memory/virtual#

Counter type

/runtime/memory/virtual

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the allocated +virtual memory should be queried. The locality id is a (zero +based) number identifying the locality.

+

Description

Returns the amount of virtual memory currently allocated by the +referenced locality (in bytes).

+ + ++++ + + + + + + + + + + + +
Table 88 General performance counter /runtime/memory/resident#

Counter type

/runtime/memory/resident

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the allocated +resident memory should be queried. The locality id is a (zero +based) number identifying the locality.

+

Description

Returns the amount of resident memory currently allocated by the +referenced locality (in bytes).

+ + ++++ + + + + + + + + + + + +
Table 89 General performance counter /runtime/memory/total#

Counter type

/runtime/memory/total

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the total +available memory should be queried. The locality id is a (zero +based) number identifying the locality. Note: only supported in +Linux.

+

Description

+
Returns the total available memory for use by the referenced

locality (in bytes). This counter is available on Linux and +Windows systems only.

+
+
+
+ + ++++ + + + + + + + + + + + +
Table 90 General performance counter /runtime/io/read_bytes_issued#

Counter type

/runtime/io/read_bytes_issued

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +bytes read should be queried. The locality id is a (zero based) +number identifying the locality.

+

Description

Returns the number of bytes read by the process (aggregate of count +arguments passed to read() call or its analogues). This performance +counter is available only on systems which expose the related data +through the /proc file system.

+ + ++++ + + + + + + + + + + + +
Table 91 General performance counter /runtime/io/write_bytes_issued#

Counter type

/runtime/io/write_bytes_issued

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +bytes written should be queried. The locality id is a (zero +based) number identifying the locality.

+

Description

Returns the number of bytes written by the process (aggregate of count +arguments passed to write() call or its analogues). This performance +counter is available only on systems which expose the related data +through the /proc file system.

+ + ++++ + + + + + + + + + + + +
Table 92 General performance counter /runtime/io/read_syscalls#

Counter type

/runtime/io/read_syscalls

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +system calls should be queried. The locality id is a (zero based) +number identifying the locality.

+

Description

Returns the number of system calls that perform I/O reads. This +performance counter is available only on systems which expose the +related data through the /proc file system.

+ + ++++ + + + + + + + + + + + +
Table 93 General performance counter /runtime/io/write_syscalls#

Counter type

/runtime/io/write_syscalls

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +system calls should be queried. The locality id is a (zero based) +number identifying the locality.

+

Description

Returns the number of system calls that perform I/O writes. This +performance counter is available only on systems which expose the +related data through the /proc file system.

+ + ++++ + + + + + + + + + + + +
Table 94 General performance counter /runtime/io/read_bytes_transferred#

Counter type

/runtime/io/read_bytes_transferred

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +bytes transferred should be queried. The locality id is a (zero +based) number identifying the locality.

+

Description

Returns the number of bytes retrieved from storage by I/O operations. +This performance counter is available only on systems which expose the +related data through the /proc file system.

+ + ++++ + + + + + + + + + + + +
Table 95 General performance counter /runtime/io/write_bytes_transferred#

Counter type

/runtime/io/write_bytes_transferred

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +bytes transferred should be queried. The locality id is a (zero +based) number identifying the locality.

+

Description

Returns the number of bytes retrieved from storage by I/O operations. +This performance counter is available only on systems which expose the +related data through the /proc file system.

+ + ++++ + + + + + + + + + + + +
Table 96 General performance counter /runtime/io/write_bytes_cancelled#

Counter type

/runtime/io/write_bytes_cancelled

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +bytes not being transferred should be queried. The locality id is +a (zero based) number identifying the locality.

+

Description

Returns the number of bytes accounted by write_bytes_transferred that +has not been ultimately stored due to truncation or deletion. This +performance counter is available only on systems which expose the +related data through the /proc file system.

+ + ++++ + + + + + + + + + + + +
Table 97 Performance counter /papi/<papi_event>#

Counter type

/papi/<papi_event>

+

where:

+

<papi_event> is the name of the PAPI event to expose as a performance +counter (such as PAPI_SR_INS). Note that the list of available PAPI +events changes depending on the used architecture.

+

For a full list of available PAPI events and their (short) description +use the --hpx:list-counters and --hpx:papi-event-info=all command +line options.

+

Counter instance formatting

locality#*/total or

+

locality#*/worker-thread#*

+

where:

+

locality#* is defining the locality for which the current +current accumulated value of all busy-loop counters of all worker threads +should be queried. The locality id (given by *) is a (zero +based) number identifying the locality.

+

worker-thread#* is defining the worker thread for which the current +value of the busy-loop counter should be queried for. The worker thread +number (given by the *) is a (zero based) worker thread number (given +by the *) is a (zero based) number identifying the worker thread. The +number of available worker threads is usually specified on the command +line for the application using the option --hpx:threads.

+

Description

Returns the current count of occurrences of the specified +PAPI event. This counter is available only if the configuration time +constant HPX_WITH_PAPI is set to ON (default: OFF).

+ + ++++ + + + + + + + + + + + + + + +
Table 98 Performance counter /statistics/average#

Counter type

/statistics/average

Counter instance formatting

Any full performance counter name. The referenced performance counter is +queried at fixed time intervals as specified by the first parameter.

Description

Returns the current average (mean) value calculated based on the values +queried from the underlying counter (the one specified as the instance +name).

Parameters

Any parameter will be interpreted as a list of up to two comma separated +(integer) values, where the first is the time interval (in milliseconds) +at which the underlying counter should be queried. If no value is +specified, the counter will assume 1000 [ms] as the default. The +second value can be either 0 or 1 and specifies whether the +underlying counter should be reset during evaluation 1 or not 0. +The default value is 0.

+ + ++++ + + + + + + + + + + + + + + +
Table 99 Performance counter /statistics/rolling_average#

Counter type

/statistics/rolling_average

Counter instance formatting

Any full performance counter name. The referenced performance counter is +queried at fixed time intervals as specified by the first parameter.

Description

Returns the current rolling average (mean) value calculated based on the +values queried from the underlying counter (the one specified as the +instance name).

Parameters

Any parameter will be interpreted as a list of up to three comma +separated (integer) values, where the first is the time interval (in +milliseconds) at which the underlying counter should be queried. If no +value is specified, the counter will assume 1000 [ms] as the default. +The second value will be interpreted as the size of the rolling window +(the number of latest values to use to calculate the rolling average). +The default value for this is 10. The third value can be +either 0 or 1 and specifies whether the underlying counter should +be reset during evaluation 1 or not 0. The default value is 0.

+ + ++++ + + + + + + + + + + + + + + +
Table 100 Performance counter /statistics/stddev#

Counter type

/statistics/stddev

Counter instance formatting

Any full performance counter name. The referenced performance counter is +queried at fixed time intervals as specified by the first parameter.

Description

Returns the current standard deviation (stddev) value calculated based on +the values queried from the underlying counter (the one specified as the +instance name).

Parameters

Any parameter will be interpreted as a list of up to two comma separated +(integer) values, where the first is the time interval (in milliseconds) +at which the underlying counter should be queried. If no value is +specified, the counter will assume 1000 [ms] as the default. The +second value can be either 0 or 1 and specifies whether the +underlying counter should be reset during evaluation 1 or not 0. +The default value is 0.

+ + ++++ + + + + + + + + + + + + + + +
Table 101 Performance counter /statistics/rolling_stddev#

Counter type

/statistics/rolling_stddev

Counter instance formatting

Any full performance counter name. The referenced performance counter is +queried at fixed time intervals as specified by the first parameter.

Description

Returns the current rolling variance (stddev) value calculated based on +the values queried from the underlying counter (the one specified as the +instance name).

Parameters

Any parameter will be interpreted as a list of up to three comma +separated (integer) values, where the first is the time interval (in +milliseconds) at which the underlying counter should be queried. If no +value is specified, the counter will assume 1000 [ms] as the default. +The second value will be interpreted as the size of the rolling window +(the number of latest values to use to calculate the rolling average). +The default value for this is 10. The third value can be either 0 +or 1 and specifies whether the underlying counter should be reset +during evaluation 1 or not 0. The default value is 0.

+ + ++++ + + + + + + + + + + + + + + +
Table 102 Performance counter /statistics/median#

Counter type

/statistics/median

Counter instance formatting

Any full performance counter name. The referenced performance counter is +queried at fixed time intervals as specified by the first parameter.

Description

Returns the current (statistically estimated) median value calculated +based on the values queried from the underlying counter (the one +specified as the instance name).

Parameters

Any parameter will be interpreted as a list of up to two comma separated +(integer) values, where the first is the time interval (in milliseconds) +at which the underlying counter should be queried. If no value is +specified, the counter will assume 1000 [ms] as the default. The +second value can be either 0 or 1 and specifies whether the +underlying counter should be reset during evaluation 1 or not 0. +The default value is 0.

+ + ++++ + + + + + + + + + + + + + + +
Table 103 Performance counter /statistics/max#

Counter type

/statistics/max

Counter instance formatting

Any full performance counter name. The referenced performance counter is +queried at fixed time intervals as specified by the first parameter.

Description

Returns the current maximum value calculated based on the values queried +from the underlying counter (the one specified as the instance name).

Parameters

Any parameter will be interpreted as a list of up to two comma separated +(integer) values, where the first is the time interval (in milliseconds) +at which the underlying counter should be queried. If no value is +specified, the counter will assume 1000 [ms] as the default. The +second value can be either 0 or 1 and specifies whether the +underlying counter should be reset during evaluation 1 or not 0. +The default value is 0.

+ + ++++ + + + + + + + + + + + + + + +
Table 104 Performance counter /statistics/rolling_max#

Counter type

/statistics/rolling_max

Counter instance formatting

Any full performance counter name. The referenced performance counter is +queried at fixed time intervals as specified by the first parameter.

Description

Returns the current rolling maximum value calculated based on the values +queried from the underlying counter (the one specified as the instance +name).

Parameters

Any parameter will be interpreted as a list of up to three comma +separated (integer) values, where the first is the time interval (in +milliseconds) at which the underlying counter should be queried. If no +value is specified, the counter will assume 1000 [ms] as the default. +The second value will be interpreted as the size of the rolling window +(the number of latest values to use to calculate the rolling average). +The default value for this is 10. The third value can be either 0 +or 1 and specifies whether the underlying counter should be reset +during evaluation 1 or not 0. The default value is 0.

+ + ++++ + + + + + + + + + + + + + + +
Table 105 Performance counter /statistics/min#

Counter type

/statistics/min

Counter instance formatting

Any full performance counter name. The referenced performance counter is +queried at fixed time intervals as specified by the first parameter.

Description

Returns the current minimum value calculated based on the values queried +from the underlying counter (the one specified as the instance name).

Parameters

Any parameter will be interpreted as a list of up to two comma separated +(integer) values, where the first is the time interval (in milliseconds) +at which the underlying counter should be queried. If no value is +specified, the counter will assume 1000 [ms] as the default. The +second value can be either 0 or 1 and specifies whether the +underlying counter should be reset during evaluation 1 or not 0. +The default value is 0.

+ + ++++ + + + + + + + + + + + + + + +
Table 106 Performance counter /statistics/rolling_min#

Counter type

/statistics/rolling_min

Counter instance formatting

Any full performance counter name. The referenced performance counter is +queried at fixed time intervals as specified by the first parameter.

Description

Returns the current rolling minimum value calculated based on the values +queried from the underlying counter (the one specified as the instance +name).

Parameters

Any parameter will be interpreted as a list of up to three comma +separated (integer) values, where the first is the time interval (in +milliseconds) at which the underlying counter should be queried. If no +value is specified, the counter will assume 1000 [ms] as the default. +The second value will be interpreted as the size of the rolling window +(the number of latest values to use to calculate the rolling average). +The default value for this is 10. The third value can be either 0 +or 1 and specifies whether the underlying counter should be reset +during evaluation 1 or not 0. The default value is 0.

+ + ++++ + + + + + + + + + + + +
Table 107 Performance counter /arithmetics/add#

Counter type

/arithmetics/add

Description

Returns the sum calculated based on the values queried from the +underlying counters (the ones specified as the parameters).

Parameters

The parameter will be interpreted as a comma separated list of full +performance counter names which are queried whenever this counter is +accessed. Any wildcards in the counter names will be expanded.

+ + ++++ + + + + + + + + + + + +
Table 108 Performance counter /arithmetics/subtract#

Counter type

/arithmetics/subtract

Description

Returns the difference calculated based on the values queried from the +underlying counters (the ones specified as the parameters).

Parameters

The parameter will be interpreted as a comma separated list of full +performance counter names which are queried whenever this counter is +accessed. Any wildcards in the counter names will be expanded.

+ + ++++ + + + + + + + + + + + +
Table 109 Performance counter /arithmetics/multiply#

Counter type

/arithmetics/multiply

Description

Returns the product calculated based on the values queried from the +underlying counters (the ones specified as the parameters).

Parameters

The parameter will be interpreted as a comma separated list of full +performance counter names which are queried whenever this counter is +accessed. Any wildcards in the counter names will be expanded.

+ + ++++ + + + + + + + + + + + +
Table 110 Performance counter /arithmetics/divide#

Counter type

/arithmetics/divide

Description

Returns the result of division of the values queried from the +underlying counters (the ones specified as the parameters).

Parameters

The parameter will be interpreted as a comma separated list of full +performance counter names which are queried whenever this counter is +accessed. Any wildcards in the counter names will be expanded.

+ + ++++ + + + + + + + + + + + +
Table 111 Performance counter /arithmetics/mean#

Counter type

/arithmetics/mean

Description

Returns the average value of all values queried from the +underlying counters (the ones specified as the parameters).

Parameters

The parameter will be interpreted as a comma separated list of full +performance counter names which are queried whenever this counter is +accessed. Any wildcards in the counter names will be expanded.

+ + ++++ + + + + + + + + + + + +
Table 112 Performance counter /arithmetics/variance#

Counter type

/arithmetics/variance

Description

Returns the standard deviation of all values queried from the underlying +counters (the ones specified as the parameters).

Parameters

The parameter will be interpreted as a comma separated list of full +performance counter names which are queried whenever this counter is +accessed. Any wildcards in the counter names will be expanded.

+ + ++++ + + + + + + + + + + + +
Table 113 Performance counter /arithmetics/median#

Counter type

/arithmetics/median

Description

Returns the median value of all values queried from the underlying +counters (the ones specified as the parameters).

Parameters

The parameter will be interpreted as a comma separated list of full +performance counter names which are queried whenever this counter is +accessed. Any wildcards in the counter names will be expanded.

+ + ++++ + + + + + + + + + + + +
Table 114 Performance counter /arithmetics/min#

Counter type

/arithmetics/min

Description

Returns the minimum value of all values queried from the underlying +counters (the ones specified as the parameters).

Parameters

The parameter will be interpreted as a comma separated list of full +performance counter names which are queried whenever this counter is +accessed. Any wildcards in the counter names will be expanded.

+ + ++++ + + + + + + + + + + + +
Table 115 Performance counter /arithmetics/max#

Counter type

/arithmetics/max

Description

Returns the maximum value of all values queried from the +underlying counters (the ones specified as the parameters).

Parameters

The parameter will be interpreted as a comma separated list of full +performance counter names which are queried whenever this counter is +accessed. Any wildcards in the counter names will be expanded.

+ + ++++ + + + + + + + + + + + +
Table 116 Performance counter /arithmetics/count#

Counter type

/arithmetics/count

Description

Returns the count value of all values queried from the underlying +counters (the ones specified as the parameters).

Parameters

The parameter will be interpreted as a comma separated list of full +performance counter names which are queried whenever this counter is +accessed. Any wildcards in the counter names will be expanded.

+
+

Note

+

The /arithmetics counters can consume an arbitrary number of other +counters. For this reason those have to be specified as parameters (a comma +separated list of counters appended after a '@'). For instance:

+
$ ./bin/hello_world_distributed -t2 \
+    --hpx:print-counter=/threads{locality#0/worker-thread#*}/count/cumulative \
+    --hpx:print-counter=/arithmetics/add@/threads{locality#0/worker-thread#*}/count/cumulative
+hello world from OS-thread 0 on locality 0
+hello world from OS-thread 1 on locality 0
+/threads{locality#0/worker-thread#0}/count/cumulative,1,0.515640,[s],25
+/threads{locality#0/worker-thread#1}/count/cumulative,1,0.515520,[s],36
+/arithmetics/add@/threads{locality#0/worker-thread#*}/count/cumulative,1,0.516445,[s],64
+
+
+

Since all wildcards in the parameters are expanded, this example is fully +equivalent to specifying both counters separately to /arithmetics/add:

+
$ ./bin/hello_world_distributed -t2 \
+    --hpx:print-counter=/threads{locality#0/worker-thread#*}/count/cumulative \
+    --hpx:print-counter=/arithmetics/add@\
+        /threads{locality#0/worker-thread#0}/count/cumulative,\
+        /threads{locality#0/worker-thread#1}/count/cumulative
+
+
+
+ + ++++ + + + + + + + + + + + + + + +
Table 117 Performance counter /coalescing/count/parcels#

Counter type

/coalescing/count/parcels

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +parcels for the given action should be queried for. The locality +id is a (zero based) number identifying the locality.

+

Description

Returns the number of parcels handled by the message handler +associated with the action which is given by the counter parameter.

Parameters

The action type. This is the string which has been used while registering +the action with HPX, e.g. which has been passed as the second parameter +to the macro HPX_REGISTER_ACTION or +HPX_REGISTER_ACTION_ID.

+ + ++++ + + + + + + + + + + + + + + +
Table 118 Performance counter /coalescing/count/messages#

Counter type

/coalescing/count/messages

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +messages for the given action should be queried for. The locality +id is a (zero based) number identifying the locality.

+

Description

Returns the number of messages generated by the message handler +associated with the action which is given by the counter parameter.

Parameters

The action type. This is the string which has been used while registering +the action with HPX, e.g. which has been passed as the second parameter +to the macro HPX_REGISTER_ACTION or +HPX_REGISTER_ACTION_ID.

+ + ++++ + + + + + + + + + + + + + + +
Table 119 Performance counter /coalescing/count/average-parcels-per-message#

Counter type

/coalescing/count/average-parcels-per-message

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the number of +messages for the given action should be queried for. The locality +id is a (zero based) number identifying the locality.

+

Description

Returns the average number of parcels sent in a message generated by the +message handler associated with the action which is given by the counter +parameter.

Parameters

The action type. This is the string which has been used while registering +the action with HPX, e.g. which has been passed as the second parameter +to the macro HPX_REGISTER_ACTION or +HPX_REGISTER_ACTION_ID

+ + ++++ + + + + + + + + + + + + + + +
Table 120 Performance counter /coalescing/time/average-parcel-arrival#

Counter type

/coalescing/time/average-parcel-arrival

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the average time +between parcels for the given action should be queried for. The +locality id is a (zero based) number identifying the +locality.

+

Description

Returns the average time between arriving parcels for the +action which is given by the counter parameter.

Parameters

The action type. This is the string which has been used while registering +the action with HPX, e.g. which has been passed as the second parameter +to the macro HPX_REGISTER_ACTION or +HPX_REGISTER_ACTION_ID

+ + ++++ + + + + + + + + + + + + + + +
Table 121 Performance counter /coalescing/time/parcel-arrival-histogram#

Counter type

/coalescing/time/parcel-arrival-histogram

Counter instance formatting

locality#*/total

+

where:

+

* is the locality id of the locality the average time +between parcels for the given action should be queried for. The +locality id is a (zero based) number identifying the +locality.

+

Description

Returns a histogram representing the times between arriving parcels for +the action which is given by the counter parameter.

+

This counter returns an array of values, where the first three values +represent the three parameters used for the histogram followed by one +value for each of the histogram buckets.

+

The first unit of measure displayed for this counter [ns] refers to +the lower and upper boundary values in the returned histogram data only. +The second unit of measure displayed [0.1%] refers to the actual +histogram data.

+

For each bucket the counter shows a value between 0 and 1000 +which corresponds to a percentage value between 0% and 100%.

+

Parameters

The action type and optional histogram parameters. The action type is +the string which has been used while registering the action with HPX, +e.g. which has been passed as the second parameter to the macro +HPX_REGISTER_ACTION or HPX_REGISTER_ACTION_ID.

+

The action type may be followed by a comma separated list of up-to three +numbers: the lower and upper boundaries for the collected histogram, and +the number of buckets for the histogram to generate. By default these +three numbers will be assumed to be 0 ([ns], lower +bound), 1000000 ([ns], upper bound), and 20 (number of +buckets to generate).

+
+
+

Note

+

The performance counters related to parcel coalescing are available only if +the configuration time constant HPX_WITH_PARCEL_COALESCING is set to +ON (default: ON). However, even in this case it will be available +only for actions that are enabled for parcel coalescing (see the +macros HPX_ACTION_USES_MESSAGE_COALESCING and +HPX_ACTION_USES_MESSAGE_COALESCING_NOTHROW).

+
+
+
1
+

A message can potentially consist of more than one parcel.

+
+
+
+
+
+
APEX integration#
+

HPX provides integration with APEX, which is a framework for application +profiling using task timers and various performance counters Huck et al.2. +It can be added as a git submodule by turning on the option HPX_WITH_APEX:BOOL +during CMake configuration. TAU is an optional dependency when using APEX.

+

To build HPX with APEX, add HPX_WITH_APEX=ON, and, +optionally, Tau_ROOT=$PATH_TO_TAU to your CMake configuration. In +addition, you can override the tag used for APEX with the +HPX_WITH_APEX_TAG option. Please see the APEX HPX documentation for detailed +instructions on using APEX with HPX.

+
+
+
References#
+
+
+
2
+

K. A. Huck, A. Porterfield, N Chaimov, H. Kaiser, A. D. Malony, T. Sterling, and R. Fowler. An autonomic performance environment for exascale. Supercomputing Frontiers and Innovations, 2015.

+
+
+
+
+
+
+

Using the LCI parcelport#

+
+
Basic information#
+

The Lightweight Communication Interface (LCI) is an ongoing research project +aiming to provide efficient support for applications with irregular and asynchronous +communication patterns such as +graph analysis, sparse linear algebra, and task-based runtime on +modern parallel architectures. Its features include (a) support for +more communication primitives such as two-sided send/recv and +one-sided (dynamic or direct) remote put/get (b) better multi-threaded +performance (c) explicit user control of communication resource +(d) flexible signaling mechanisms such as synchronizer, completion queue, +and active message handler. +It is designed to be a low-level communication library used by +high-level libraries and frameworks.

+

The LCI parcelport is an experimental parcelport. +It aims to provide the best possible communication performance +on high-performance computation platforms. +Compared to the MPI parcelport, it uses much fewer messages +and memory copies to transfer an HPX parcel over the network. +Its message transmission path involves minimum synchronization +points and is almost lock-free. It is expected to be much faster +than the MPI parcelport.

+
+
+
Build HPX with the LCI parcelport#
+

While building HPX, you can specify a set of CMake variables to enable +and configure the LCI parcelport. Below, there is a set of the most important +and frequently used CMake variables.

+
+
+HPX_WITH_PARCELPORT_LCI#
+

Enable the LCI parcelport. This enables the use of LCI for networking operations in the HPX runtime. +The default value is OFF because it’s not available on all systems and/or requires another dependency. However, +this experimental parcelport may provide better performance than the MPI parcelport. +You must set this variable to ON in order to use the LCI parcelport. All the following variables only +make sense when this variable is set to ON.

+
+ +
+
+HPX_WITH_FETCH_LCI#
+

Use FetchContent to fetch LCI. The default value is OFF. +If this option is set to OFF. You need to install your own LCI library and HPX will try +to find it using CMake find_package. You can specify the location of the LCI installation +by the environmental variable LCI_ROOT. Refer to the LCI README for how to install LCI. +If this option is set to ON. HPX will fetch and build LCI for you. You can use the following +CMake variables to configure this behavior for your platform.

+
+ +
+
+HPX_WITH_LCI_TAG#
+

This variable only takes effect when HPX_WITH_FETCH_LCI is set to ON +and FETCHCONTENT_SOURCE_DIR_LCI is not set. +HPX will fetch LCI from its github repository. This variable controls the branch/tag LCI +will be fetched.

+
+ +
+
+FETCHCONTENT_SOURCE_DIR_LCI#
+

This variable only takes effect when HPX_WITH_FETCH_LCI is set to ON. +When it is defined, HPX_WITH_LCI_TAG will be ignored. +It accepts a path to a local version of LCI source code and HPX will fetch and build LCI from there. +The default value is set conservatively for the stability of HPX, but users are welcome to set this +variable to master for potentially better performance.

+
+ +
+
+
Run HPX with the LCI parcelport#
+

We use the same mechanisms as MPI to launch LCI, so you can use the same way you run MPI parcelport to run LCI +parcelport. Typically, it would be hpxrun.py, mpirun, or srun.

+

hpxrun.py serves as a wrapper for mpirun and srun. +If you are using hpxrun.py, pass -p lci to the scripts. You also need to pass either -r mpi or +-r srun to select the correct run wrapper according to the platform.

+

If you are using mpirun or srun, you can just pass +--hpx:ini=hpx.parcel.lci.priority=1000, --hpx:ini=hpx.parcel.lci.enable=1, and +--hpx:ini=hpx.parcel.bootstrap=lci to the HPX applications.

+

The hpxrun.py argument -r none (the default option for the run wrapper) and its corresponding HPX arguments +--hpx:hpx and --hpx:agas do not work for the MPI or the LCI parcelport.

+
+
+
Performance tuning of the LCI parcelport#
+

We encourage users to set the following environmental variables +when using the LCI parcelport to get better performance.

+
$ export LCI_SERVER_MAX_SENDS=1024
+$ export LCI_SERVER_MAX_RECVS=4096
+$ export LCI_SERVER_NUM_PKTS=65536
+$ export LCI_SERVER_MAX_CQES=65536
+$ export LCI_PACKET_SIZE=12288
+
+
+

This setting needs roughly 800MB memory per process. The memory consumption mainly +comes from the packets, which can be calculated using LCI_SERVER_NUM_PKTS x LCI_PACKET_SIZE.

+
+
+
+

HPX runtime and resources#

+
+
HPX thread scheduling policies#
+

The HPX runtime has six thread scheduling policies: local-priority, +static-priority, local, static, local-workrequesting-fifo, and abp-priority. +These policies can be specified from the command line using the command line +option --hpx:queuing. In order to use a particular scheduling policy, +the runtime system must be built with the appropriate scheduler flag turned on +(e.g. cmake -DHPX_THREAD_SCHEDULERS=local, see CMake options for +more information).

+
+
Priority local scheduling policy (default policy)#
+

The priority local scheduling policy maintains one queue per operating system +(OS) thread. The OS thread pulls its work from this queue. By default the number +of high priority queues is equal to the number of OS threads; the number of high +priority queues can be specified on the command line using +--hpx:high-priority-threads. High priority threads are executed by any +of the OS threads before any other work is executed. When a queue is empty, work +will be taken from high priority queues first. There is one low priority queue +from which threads will be scheduled only when there is no other work.

+

For this scheduling policy there is an option to turn on NUMA sensitivity using +the command line option --hpx:numa-sensitive. When NUMA sensitivity is +turned on, work stealing is done from queues associated with the same NUMA domain +first, only after that work is stolen from other NUMA domains.

+

This scheduler is enabled at build time by default using the FIFO +(first-in-first-out) queueing policy. This policy can be invoked using +--hpx:queuinglocal-priority-fifo. The scheduler can also be +enabled using the LIFO (last-in-first-out) policy. This is not the default +policy and must be invoked using the command line option +--hpx:queuinglocal-priority-lifo.

+
+
+
Static priority scheduling policy#
+ +

The static scheduling policy maintains one queue per OS thread from which each +OS thread pulls its tasks (user threads). Threads are distributed in a round +robin fashion. There is no thread stealing in this policy.

+
+
+
Local scheduling policy#
+
    +
  • invoke using: --hpx:queuinglocal (or -ql)

  • +
  • flag to turn on for build: HPX_THREAD_SCHEDULERS=all or +HPX_THREAD_SCHEDULERS=local

  • +
+

The local scheduling policy maintains one queue per OS thread from which each OS +thread pulls its tasks (user threads).

+
+
+
Static scheduling policy#
+
    +
  • invoke using: --hpx:queuingstatic

  • +
  • flag to turn on for build: HPX_THREAD_SCHEDULERS=all or +HPX_THREAD_SCHEDULERS=static

  • +
+

The static scheduling policy maintains one queue per OS thread from which each +OS thread pulls its tasks (user threads). Threads are distributed in a round +robin fashion. There is no thread stealing in this policy.

+
+
+
Priority ABP scheduling policy#
+
    +
  • invoke using: --hpx:queuingabp-priority-fifo

  • +
  • flag to turn on for build: HPX_THREAD_SCHEDULERS=all or +HPX_THREAD_SCHEDULERS=abp-priority

  • +
+

Priority ABP policy maintains a double ended lock free queue for each OS thread. +By default the number of high priority queues is equal to the number of OS +threads; the number of high priority queues can be specified on the command line +using --hpx:high-priority-threads. High priority threads are executed +by the first OS threads before any other work is executed. When a queue is empty +work will be taken from high priority queues first. There is one low priority +queue from which threads will be scheduled only when there is no other work. For +this scheduling policy there is an option to turn on NUMA sensitivity using the +command line option --hpx:numa-sensitive. When NUMA sensitivity +is turned on work stealing is done from queues associated with the same NUMA +domain first, only after that work is stolen from other NUMA domains.

+

This scheduler can be used with two underlying queuing policies (FIFO: +first-in-first-out, and LIFO: last-in-first-out). In order to use the LIFO +policy use the command line option +--hpx:queuingabp-priority-lifo.

+
+
+
Work requesting scheduling policies#
+ +

The work-requesting policies rely on a different mechanism of balancing work +between cores (compared to the other policies listed above). Instead of actively +trying to steal work from other cores, requesting work relies on a less +disruptive mechanism. If a core runs out of work, instead of actively looking at +the queues of neighboring cores, in this case a request is posted to another +core. This core now (whenever it is not busy with other work) either responds to +the original core by sending back work or passes the request on to the next +possible core in the system. In general, this scheme avoids contention on the +work queues as those are always accessed by their own cores only.

+
+
+
+
The HPX resource partitioner#
+

The HPX resource partitioner lets you take the execution resources available +on a system—processing units, cores, and numa domains—and assign them to +thread pools. By default HPX creates a single thread pool name default. +While this is good for most use cases, the resource partitioner lets you create +multiple thread pools with custom resources and options.

+

Creating custom thread pools is useful for cases where you have tasks which +absolutely need to run without interference from other tasks. An example of this +is when using MPI for distribution instead of the built-in mechanisms in +HPX (useful in legacy applications). In this case one can create a thread pool +containing a single thread for MPI communication. MPI tasks will then +always run on the same thread, instead of potentially being stuck in a queue +behind other threads.

+

Note that HPX thread pools are completely independent from each other in the +sense that task stealing will never happen between different thread pools. +However, tasks running on a particular thread pool can schedule tasks on another +thread pool.

+
+

Note

+

It is simpler in some situations to schedule important tasks with high +priority instead of using a separate thread pool.

+
+
+
Using the resource partitioner#
+

The hpx::resource::partitioner is now created during HPX runtime +initialization without explicit action needed from the user. To specify some of +the initialization parameters you can use the hpx::init_params.

+

The resource partitioner callback is the interface to add thread pools to the +HPX runtime and to assign resources to the thread pools. In order to create +custom thread pools you can specify the resource partitioner callback +hpx::init_params::rp_callback which will be called once the +resource partitioner will be created , see the example below. You can also +specify other parameters, see hpx::init_params.

+

To add a thread pool use the +hpx::resource::partitioner::create_thread_pool method. If you +simply want to use the default scheduler and scheduler options, it is enough to +call rp.create_thread_pool("my-thread-pool").

+

Then, to add resources to the thread pool you can use the +hpx::resource::partitioner::add_resource method. The resource +partitioner exposes the hardware topology retrieved using Portable Hardware Locality (HWLOC) and lets you +iterate through the topology to add the wanted processing units to the thread +pool. Below is an example of adding all processing units from the first NUMA +domain to a custom thread pool, unless there is only one NUMA domain in which +case we leave the first processing unit for the default thread pool:

+
+

Note

+

Whatever processing units are not assigned to a thread pool by the time +hpx::init is called will be added to the default thread pool. It +is also possible to explicitly add processing units to the default thread +pool, and to create the default thread pool manually (in order to e.g. set +the scheduler type).

+
+
+

Tip

+

The command line option --hpx:print-bind is useful for checking +that the thread pools have been set up the way you expect.

+
+
+
+
Difference between the old and new version#
+

In the old version, you had to create an instance of the +resource_partitioner with argc and argv.

+
int main(int argc, char** argv)
+{
+    hpx::resource::partitioner rp(argc, argv);
+    hpx::init();
+}
+
+
+

From HPX 1.5.0 onwards, you just pass argc and argv to hpx::init() +or hpx::start() for the binding options to be parsed by the resource +partitioner.

+
int main(int argc, char** argv)
+{
+    hpx::init_params init_args;
+    hpx::init(argc, argv, init_args);
+}
+
+
+

In the old version, when creating a custom thread pool, you just called the +utilities on the resource partitioner instantiated previously.

+
int main(int argc, char** argv)
+{
+    hpx::resource::partitioner rp(argc, argv);
+
+    rp.create_thread_pool("my-thread-pool");
+
+    bool one_numa_domain = rp.numa_domains().size() == 1;
+    bool skipped_first_pu = false;
+
+    hpx::resource::numa_domain const& d = rp.numa_domains()[0];
+
+    for (const hpx::resource::core& c : d.cores())
+    {
+        for (const hpx::resource::pu& p : c.pus())
+        {
+            if (one_numa_domain && !skipped_first_pu)
+            {
+                skipped_first_pu = true;
+                continue;
+            }
+
+            rp.add_resource(p, "my-thread-pool");
+        }
+    }
+
+    hpx::init();
+}
+
+
+

You now specify the resource partitioner callback which will tie the resources +to the resource partitioner created during runtime initialization.

+
void init_resource_partitioner_handler(hpx::resource::partitioner& rp)
+{
+    rp.create_thread_pool("my-thread-pool");
+
+    bool one_numa_domain = rp.numa_domains().size() == 1;
+    bool skipped_first_pu = false;
+
+    hpx::resource::numa_domain const& d = rp.numa_domains()[0];
+
+    for (const hpx::resource::core& c : d.cores())
+    {
+        for (const hpx::resource::pu& p : c.pus())
+        {
+            if (one_numa_domain && !skipped_first_pu)
+            {
+                skipped_first_pu = true;
+                continue;
+            }
+
+            rp.add_resource(p, "my-thread-pool");
+        }
+    }
+}
+
+int main(int argc, char* argv[])
+{
+    hpx::init_params init_args;
+    init_args.rp_callback = &init_resource_partitioner_handler;
+
+    hpx::init(argc, argv, init_args);
+}
+
+
+
+
+
Advanced usage#
+

It is possible to customize the built in schedulers by passing scheduler options +to hpx::resource::partitioner::create_thread_pool. It is also possible +to create and use custom schedulers.

+
+

Note

+

It is not recommended to create your own scheduler. The HPX developers use +this to experiment with new scheduler designs before making them available to +users via the standard mechanisms of choosing a scheduler (command line +options). If you would like to experiment with a custom scheduler the +resource partitioner example shared_priority_queue_scheduler.cpp contains +a fully implemented scheduler with logging, etc. to make exploration easier.

+
+

To choose a scheduler and custom mode for a thread pool, pass additional options +when creating the thread pool like this:

+
rp.create_thread_pool("my-thread-pool",
+    hpx::resource::policies::local_priority_lifo,
+    hpx::policies::scheduler_mode(
+        hpx::policies::scheduler_mode::default |
+        hpx::policies::scheduler_mode::enable_elasticity));
+
+
+

The available schedulers are documented here: +hpx::resource::scheduling_policy, and the available scheduler modes +here: hpx::threads::policies::scheduler_mode. Also see the examples +folder for examples of advanced resource partitioner usage: +simple_resource_partitioner.cpp and +oversubscribing_resource_partitioner.cpp.

+
+
+
+
+

Miscellaneous#

+
+
Error handling#
+

Like in any other asynchronous invocation scheme, it is important to be able to +handle error conditions occurring while the asynchronous (and possibly remote) +operation is executed. In HPX all error handling is based on standard C++ +exception handling. Any exception thrown during the execution of an asynchronous +operation will be transferred back to the original invocation locality, +where it will be rethrown during synchronization with the calling thread.

+

The source code for this example can be found here: +error_handling.cpp.

+
+
Working with exceptions#
+

For the following description assume that the function raise_exception() +is executed by invoking the plain action raise_exception_type.

+
#include <hpx/iostream.hpp>
+#include <hpx/modules/runtime_local.hpp>
+
+//[error_handling_raise_exception
+void raise_exception()
+
+
+

The exception is thrown using the macro HPX_THROW_EXCEPTION. The type +of the thrown exception is hpx::exception. This associates +additional diagnostic information with the exception, such as file name and line +number, locality id and thread id, and stack backtrace from the point +where the exception was thrown.

+

Any exception thrown during the execution of an action is transferred back to +the (asynchronous) invocation site. It will be rethrown in this context when the +calling thread tries to wait for the result of the action by invoking either +future<>::get() or the synchronous action invocation wrapper as shown here:

+
{
+    {
+        ///////////////////////////////////////////////////////////////////////
+        // Error reporting using exceptions
+        //[exception_diagnostic_information
+        hpx::cout << "Error reporting using exceptions\n";
+        try
+        {
+            // invoke raise_exception() which throws an exception
+            raise_exception_action do_it;
+            do_it(hpx::find_here());
+        }
+        catch (hpx::exception const& e)
+        {
+            // Print just the essential error information.
+            hpx::cout << "caught exception: " << e.what() << "\n\n";
+
+
+
+

Note

+

The exception is transferred back to the invocation site even if it is +executed on a different locality.

+
+

Additionally, this example demonstrates how an exception thrown by an (possibly +remote) action can be handled. It shows the use of +hpx::diagnostic_information, which retrieves all available diagnostic +information from the exception as a formatted string. This includes, for +instance, the name of the source file and line number, the sequence number of +the OS thread and the HPX thread id, the locality id and the stack +backtrace of the point where the original exception was thrown.

+

Under certain circumstances it is desirable to output only some of the +diagnostics, or to output those using different formatting. For this case, HPX +exposes a set of lower-level functions as demonstrated in the following code +snippet:

+
                      << hpx::diagnostic_information(e) << "\n";
+        }
+        hpx::cout << std::flush;
+        //]
+
+        // Detailed error reporting using exceptions
+        //[exception_diagnostic_elements
+        hpx::cout << "Detailed error reporting using exceptions\n";
+        try
+        {
+            // Invoke raise_exception() which throws an exception.
+            raise_exception_action do_it;
+            do_it(hpx::find_here());
+        }
+        catch (hpx::exception const& e)
+        {
+            // Print the elements of the diagnostic information separately.
+            hpx::cout << "{what}: " << hpx::get_error_what(e) << "\n";
+            hpx::cout << "{locality-id}: " << hpx::get_error_locality_id(e)
+                      << "\n";
+            hpx::cout << "{hostname}: " << hpx::get_error_host_name(e) << "\n";
+            hpx::cout << "{pid}: " << hpx::get_error_process_id(e) << "\n";
+            hpx::cout << "{function}: " << hpx::get_error_function_name(e)
+                      << "\n";
+            hpx::cout << "{file}: " << hpx::get_error_file_name(e) << "\n";
+            hpx::cout << "{line}: " << hpx::get_error_line_number(e) << "\n";
+
+
+
+
+
Working with error codes#
+

Most of the API functions exposed by HPX can be invoked in two different +modes. By default those will throw an exception on error as described above. +However, sometimes it is desirable not to throw an exception in case of an error +condition. In this case an object instance of the hpx::error_code +type can be passed as the last argument to the API function. In case of an error, +the error condition will be returned in that hpx::error_code +instance. The following example demonstrates extracting the full diagnostic +information without exception handling:

+
                      << "\n";
+            hpx::cout << "{stack-trace}: " << hpx::get_error_backtrace(e)
+                      << "\n";
+            hpx::cout << "{env}: " << hpx::get_error_env(e) << "\n";
+        }
+        hpx::cout << std::flush;
+        //]
+
+        ///////////////////////////////////////////////////////////////////////
+        // Error reporting using error code
+        {
+            //[error_handling_diagnostic_information
+            hpx::cout << "Error reporting using error code\n";
+
+            // Create a new error_code instance.
+            hpx::error_code ec;
+
+            // If an instance of an error_code is passed as the last argument while
+            // invoking the action, the function will not throw in case of an error
+            // but store the error information in this error_code instance instead.
+            raise_exception_action do_it;
+            do_it(hpx::find_here(), ec);
+
+
+
+

Note

+

The error information is transferred back to the invocation site even if it +is executed on a different locality.

+
+

This example show how an error can be handled without having to resolve to +exceptions and that the returned hpx::error_code instance can be +used in a very similar way as the hpx::exception type above. Simply +pass it to the hpx::diagnostic_information, which retrieves all +available diagnostic information from the error code instance as a formatted +string.

+

As for handling exceptions, when working with error codes, under certain +circumstances it is desirable to output only some of the diagnostics, or to +output those using different formatting. For this case, HPX exposes a set of +lower-level functions usable with error codes as demonstrated in the following +code snippet:

+
                // Print all of the available diagnostic information as stored with
+                // the exception.
+                hpx::cout << "diagnostic information:"
+                          << hpx::diagnostic_information(ec) << "\n";
+            }
+
+            hpx::cout << std::flush;
+            //]
+        }
+
+        // Detailed error reporting using error code
+        {
+            //[error_handling_diagnostic_elements
+            hpx::cout << "Detailed error reporting using error code\n";
+
+            // Create a new error_code instance.
+            hpx::error_code ec;
+
+            // If an instance of an error_code is passed as the last argument while
+            // invoking the action, the function will not throw in case of an error
+            // but store the error information in this error_code instance instead.
+            raise_exception_action do_it;
+            do_it(hpx::find_here(), ec);
+
+            if (ec)
+            {
+                // Print the elements of the diagnostic information separately.
+                hpx::cout << "{what}: " << hpx::get_error_what(ec) << "\n";
+                hpx::cout << "{locality-id}: " << hpx::get_error_locality_id(ec)
+                          << "\n";
+                hpx::cout << "{hostname}: " << hpx::get_error_host_name(ec)
+                          << "\n";
+                hpx::cout << "{pid}: " << hpx::get_error_process_id(ec) << "\n";
+
+
+

For more information please refer to the documentation of +hpx::get_error_what, hpx::get_error_locality_id, +hpx::get_error_host_name, hpx::get_error_process_id, +hpx::get_error_function_name, hpx::get_error_file_name, +hpx::get_error_line_number, hpx::get_error_os_thread, +hpx::get_error_thread_id, +hpx::get_error_thread_description, +hpx::get_error_backtrace, hpx::get_error_env, and +hpx::get_error_state.

+
+
+
Lightweight error codes#
+

Sometimes it is not desirable to collect all the ambient information about the +error at the point where it happened as this might impose too much overhead for +simple scenarios. In this case, HPX provides a lightweight error code facility +that will hold the error code only. The following snippet demonstrates its use:

+
                          << "\n";
+                hpx::cout << "{thread-id}: " << std::hex
+                          << hpx::get_error_thread_id(ec) << "\n";
+                hpx::cout << "{thread-description}: "
+                          << hpx::get_error_thread_description(ec) << "\n\n";
+                hpx::cout << "{state}: " << std::hex << hpx::get_error_state(ec)
+                          << "\n";
+                hpx::cout << "{stack-trace}: " << hpx::get_error_backtrace(ec)
+                          << "\n";
+                hpx::cout << "{env}: " << hpx::get_error_env(ec) << "\n";
+            }
+
+            hpx::cout << std::flush;
+            //]
+        }
+
+        // Error reporting using lightweight error code
+        {
+            //[lightweight_error_handling_diagnostic_information
+            hpx::cout << "Error reporting using an lightweight error code\n";
+
+
+

All functions that retrieve other diagnostic elements from the +hpx::error_code will fail if called with a lightweight error_code +instance.

+
+
+
+
Utilities in HPX#
+

In order to ease the burden of programming, HPX provides several +utilities to users. The following section documents those facilies.

+
+
Checkpoint#
+

See checkpoint.

+
+
+
+
The HPX I/O-streams component#
+

The HPX I/O-streams subsystem extends the standard C++ output streams +std::cout and std::cerr to work in the distributed setting of an HPX +application. All of the output streamed to hpx::cout will be dispatched to +std::cout on the console locality. Likewise, all output generated +from hpx::cerr will be dispatched to std::cerr on the console +locality.

+
+

Note

+

All existing standard manipulators can be used in conjunction with +hpx::cout and hpx::cerr.

+
+

In order to use either hpx::cout or hpx::cerr, application codes need to +#include <hpx/include/iostreams.hpp>. For an example, please see the +following ‘Hello world’ program:

+
//  Copyright (c) 2007-2012 Hartmut Kaiser
+//
+//  SPDX-License-Identifier: BSL-1.0
+//  Distributed under the Boost Software License, Version 1.0. (See accompanying
+//  file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
+
+///////////////////////////////////////////////////////////////////////////////
+// The purpose of this example is to execute a HPX-thread printing
+// "Hello World!" once. That's all.
+
+//[hello_world_1_getting_started
+// Including 'hpx/hpx_main.hpp' instead of the usual 'hpx/hpx_init.hpp' enables
+// to use the plain C-main below as the direct main HPX entry point.
+#include <hpx/hpx_main.hpp>
+#include <hpx/iostream.hpp>
+
+int main()
+{
+    // Say hello to the world!
+    hpx::cout << "Hello World!\n" << std::flush;
+    return 0;
+}
+//]
+
+
+

Additionally, those applications need to link with the iostreams component. When +using CMake this can be achieved by using the COMPONENT_DEPENDENCIES +parameter; for instance:

+
include(HPX_AddExecutable)
+
+add_hpx_executable(
+    hello_world
+    SOURCES hello_world.cpp
+    COMPONENT_DEPENDENCIES iostreams
+)
+
+
+
+

Note

+

The hpx::cout and hpx::cerr streams buffer all output locally until a +std::endl or std::flush is encountered. That means that no output +will appear on the console as long as either of these is explicitly used.

+
+
+
+
+

Troubleshooting#

+
+
Common issues#
+

This section contains commonly encountered problems when compiling or using HPX.

+

See also the closed issues on GitHub to find out +how other people resolved a similar problem. If nothing of that works, you can +also open a new issue on GitHub or contact us using +one the options found in Support for deploying and using HPX.

+
+
HPX::iostreams_component" target not found#
+

You may see a CMake error message that looks a bit like this:

+
error: `HPX::iostreams_component`` target not found
+
+
+

Simply ensure that HPX is installed with HPX_WITH_DISTRIBUTED_RUNTIME=ON +to prevent encountering such error(s). This is required if you want to use +hpx::cout.

+
+
+
Undefined reference to hpx::cout#
+

You may see a linker error message that looks a bit like this:

+
hello_world.cpp:(.text+0x5aa): undefined reference to `hpx::cout'
+
+
+

This usually happens if you are trying to use HPX iostreams functionality such +as hpx::cout but are not linking against it. The iostreams functionality is +not part of the core HPX library, and must be linked to explicitly. Typically +this can be solved by adding COMPONENT_DEPENDENCIES iostreams to a call to +add_hpx_library/add_hpx_executable/hpx_setup_target if using CMake. See +Creating HPX projects for more details.

+
+
+
Fail compiling for examples with hpx::future and co_await#
+

You may see an error message that looks a bit like this:

+
error: coroutines require a traits template; cannot find 'std::coroutine_traits'
+
+
+

This can be resolved by using -DHPX_WITH_CXX_STANDARD=20 to the cmake command line. +Note that a compiler that supports C++20 is needed.

+

See also the corresponding closed Issue #5784.

+
+
+
Build fails with ASIO error#
+

You may see an error message that looks a bit like this:

+
Cannot open include file asio/io_context.hpp
+
+
+

This can be resolved by using -DHPX_WITH_FETCH_ASIO=ON to the cmake command line.

+

See also the corresponding closed Issue #5404 for more information.

+
+
+
Build fails with TCMalloc error#
+

You may see an error message that looks a bit like this:

+
Could NOT find TCMalloc (missing: Tcmalloc_LIBRARY Tcmalloc_INCLUDE_DIR)
+ERROR: HPX_WITH_MALLOC was set to tcmalloc, but tcmalloc could not be
+found.  Valid options for HPX_WITH_MALLOC are: system, tcmalloc, jemalloc,
+mimalloc, tbbmalloc, and custom
+
+
+

This can be resolved either by defining HPX_WITH_MALLOC=system or by installing TCMalloc. +This error occurs when users don’t specify an option for HPX_WITH_MALLOC; in that case, +HPX will be looking tcmalloc, which is the default value.

+
+
+
+
Useful suggestions#
+
+
Reducing compilation time#
+

If you want to significantly reduce compilation time, you can just use the local part of HPX +for parallelism by disabling the distributed functionality. Moreover, you can avoid compiling +examples. These can be done with the following flags:

+
-DHPX_WITH_NETWORKING=OFF
+-DHPX_WITH_DISTRIBUTED_RUNTIME=OFF
+-DHPX_WITH_EXAMPLES=OFF
+-DHPX_WITH_TESTS=OFF
+
+
+
+
+
Linking HPX to your application#
+

If you want to avoid installing and linking HPX, you can just build HPX and then use the +following flag on your HPX application CMake configuration:

+
-DHPX_DIR=<build_dir>/lib/cmake/HPX
+
+
+
+

Note

+

For this to work you need not to specify -DCMAKE_INSTALL_PREFIX when building HPX.

+
+
+
+
HPX-application build type conformance#
+

Your application’s build type should align with the HPX build type. For example, if you specified +-DCMAKE_BUILD_TYPE=Debug during the HPX compilation, then your application needs to be compiled +with the same flag. We recommend keeping a separate build folder for different build types and just +point accordingly to the type you want by using -DHPX_DIR=<build_dir>/lib/cmake/HPX.

+
+
+
+
+
+
+

Terminology#

+

This section gives definitions for some of the terms used throughout the +HPX documentation and source code.

+
+
Locality#

A locality in HPX describes a synchronous domain of execution, or the +domain of bounded upper response time. This normally is just a single node +in a cluster or a NUMA domain in a SMP machine.

+
+
Active Global Address Space#
AGAS#

HPX incorporates a global address space. Any executing thread can access +any object within the domain of the parallel application with the caveat +that it must have appropriate access privileges. The model does not assume +that global addresses are cache coherent; all loads and stores will deal +directly with the site of the target object. All global addresses within a +Synchronous Domain are assumed to be cache coherent for those processor +cores that incorporate transparent caches. The Active Global Address Space +used by HPX differs from research PGAS models. Partitioned Global +Address Space is passive in their means of address translation. Copy +semantics, distributed compound operations, and affinity relationships are +some of the global functionality supported by AGAS.

+
+
Process#

The concept of the “process” in HPX is extended beyond that of either +sequential execution or communicating sequential processes. While the +notion of process suggests action (as do “function” or “subroutine”) it +has a further responsibility of context, that is, the logical container of +program state. It is this aspect of operation that process is employed in +HPX. Furthermore, referring to “parallel processes” in HPX designates +the presence of parallelism within the context of a given process, as well +as the coarse grained parallelism achieved through concurrency of multiple +processes of an executing user job. HPX processes provide a hierarchical +name space within the framework of the active global address space and +support multiple means of internal state access from external sources.

+
+
Parcel#

The Parcel is a component in HPX that communicates data, invokes an +action at a distance, and distributes flow-control through the migration +of continuations. Parcels bridge the gap of asynchrony between synchronous +domains while maintaining symmetry of semantics between local and global +execution. Parcels enable message-driven computation and may be seen as a +form of “active messages”. Other important forms of message-driven +computation predating active messages include dataflow tokens, the J-machine’s support for remote +method instantiation, and at the coarse grained variations of Unix remote +procedure calls, among others. This enables work to be moved to the data +as well as performing the more common action of bringing data to the work. +A parcel can cause actions to occur remotely and asynchronously, among +which are the creation of threads at different system nodes or synchronous +domains.

+
+
Local Control Object#
Lightweight Control Object#
LCO#

A local control object (sometimes called a lightweight control object) is +a general term for the synchronization mechanisms used in HPX. Any +object implementing a certain concept can be seen as an LCO. This concepts +encapsulates the ability to be triggered by one or more events which when +taking the object into a predefined state will cause a thread to be +executed. This could either create a new thread or resume an existing +thread.

+

The LCO is a family of synchronization functions potentially representing +many classes of synchronization constructs, each with many possible +variations and multiple instances. The LCO is sufficiently general that it +can subsume the functionality of conventional synchronization primitives +such as spinlocks, mutexes, semaphores, and global barriers. However due +to the rich concept an LCO can represent powerful synchronization and +control functionality not widely employed, such as dataflow and futures +(among others), which open up enormous opportunities for rich diversity of +distributed control and operation.

+

See lcos for more details on how to use LCOs in HPX.

+
+
Action#

An action is a function that can be invoked remotely. In HPX a plain +function can be made into an action using a macro. See +applying_actions for details on how to use actions in HPX.

+
+
Component#

A component is a C++ object which can be accessed remotely. A component +can also contain member functions which can be invoked remotely. These are +referred to as component actions. See Writing components for details on how +to use components in HPX.

+
+
+
+
+

Why HPX?#

+

Current advances in high performance computing (HPC) continue to suffer from the +issues plaguing parallel computation. These issues include, but are not limited +to, ease of programming, inability to handle dynamically changing workloads, +scalability, and efficient utilization of system resources. Emerging +technological trends such as multi-core processors further highlight limitations +of existing parallel computation models. To mitigate the aforementioned +problems, it is necessary to rethink the approach to parallelization models. +ParalleX contains mechanisms such as multi-threading, parcels, +global name space support, percolation and local control +objects (LCO). By design, ParalleX overcomes limitations of current +models of parallelism by alleviating contention, latency, overhead and +starvation. With ParalleX, it is further possible to increase performance by at +least an order of magnitude on challenging parallel algorithms, e.g., dynamic +directed graph algorithms and adaptive mesh refinement methods for astrophysics. +An additional benefit of ParalleX is fine-grained control of power usage, +enabling reductions in power consumption.

+
+

ParalleX—a new execution model for future architectures#

+

ParalleX is a new parallel execution model that offers an alternative to +the conventional computation models, such as message passing. ParalleX +distinguishes itself by:

+
    +
  • Split-phase transaction model

  • +
  • Message-driven

  • +
  • Distributed shared memory (not cache coherent)

  • +
  • Multi-threaded

  • +
  • Futures synchronization

  • +
  • Local Control Objects (LCOs)

  • +
  • Synchronization for anonymous producer-consumer scenarios

  • +
  • Percolation (pre-staging of task data)

  • +
+

The ParalleX model is intrinsically latency hiding, delivering an abundance of +variable-grained parallelism within a hierarchical namespace environment. The +goal of this innovative strategy is to enable future systems delivering very +high efficiency, increased scalability and ease of programming. ParalleX can +contribute to significant improvements in the design of all levels of computing +systems and their usage from application algorithms and their programming +languages to system architecture and hardware design together with their +supporting compilers and operating system software.

+
+
+

What is HPX?#

+

High Performance ParalleX (HPX) is the first runtime system implementation of +the ParalleX execution model. The HPX runtime software package is a modular, +feature-complete, and performance-oriented representation of the ParalleX +execution model targeted at conventional parallel computing architectures, such +as SMP nodes and commodity clusters. It is academically developed and freely +available under an open source license. We provide HPX to the community for +experimentation and application to achieve high efficiency and scalability for +dynamic adaptive and irregular computational problems. HPX is a C++ library +that supports a set of critical mechanisms for dynamic adaptive resource +management and lightweight task scheduling within the context of a global +address space. It is solidly based on many years of experience in writing highly +parallel applications for HPC systems.

+

The two-decade success of the communicating sequential processes (CSP) execution +model and its message passing interface (MPI) programming model have been +seriously eroded by challenges of power, processor core complexity, multi-core +sockets, and heterogeneous structures of GPUs. Both efficiency and scalability +for some current (strong scaled) applications and future Exascale applications +demand new techniques to expose new sources of algorithm parallelism and exploit +unused resources through adaptive use of runtime information.

+

The ParalleX execution model replaces CSP to provide a new computing paradigm +embodying the governing principles for organizing and conducting highly +efficient scalable computations greatly exceeding the capabilities of today’s +problems. HPX is the first practical, reliable, and performance-oriented +runtime system incorporating the principal concepts of the ParalleX model +publicly provided in open source release form.

+

HPX is designed by the STE||AR Group (Systems Technology, +Emergent Parallelism, and Algorithm Research) at +Louisiana State University (LSU)’s Center for Computation and Technology (CCT) to enable developers to exploit the full processing power of +many-core systems with an unprecedented degree of parallelism. STE||AR is a +research group focusing on system software solutions and scientific application +development for hybrid and many-core hardware architectures.

+

For more information about the STE||AR Group, see People.

+
+
+

What makes our systems slow?#

+

Estimates say that we currently run our computers at well below 100% efficiency. +The theoretical peak performance (usually measured in +FLOPS—floating point operations per +second) is much higher than any practical peak performance reached by any +application. This is particularly true for highly parallel hardware. The more +hardware parallelism we provide to an application, the better the application +must scale in order to efficiently use all the resources of the machine. Roughly +speaking, we distinguish two forms of scalability: strong scaling (see +Amdahl’s Law) and weak scaling +(see Gustafson’s Law). Strong +scaling is defined as how the solution time varies with the number of processors +for a fixed total problem size. It gives an estimate of how much faster we +can solve a particular problem by throwing more resources at it. Weak scaling is +defined as how the solution time varies with the number of processors for a +fixed problem size per processor. In other words, it defines how much more +data can we process by using more hardware resources.

+

In order to utilize as much hardware parallelism as possible an application must +exhibit excellent strong and weak scaling characteristics, which requires a high +percentage of work executed in parallel, i.e., using multiple threads of +execution. Optimally, if you execute an application on a hardware resource with +N processors it either runs N times faster or it can handle N times more data. +Both cases imply 100% of the work is executed on all available processors in +parallel. However, this is just a theoretical limit. Unfortunately, there are +more things that limit scalability, mostly inherent to the hardware +architectures and the programming models we use. We break these limitations into +four fundamental factors that make our systems SLOW:

+
    +
  • Starvation occurs when there is insufficient concurrent work available to +maintain high utilization of all resources.

  • +
  • Latencies are imposed by the time-distance delay intrinsic to accessing +remote resources and services.

  • +
  • Overhead is work required for the management of parallel actions and +resources on the critical execution path, which is not necessary in a +sequential variant.

  • +
  • Waiting for contention resolution is the delay due to the lack of +availability of oversubscribed shared resources.

  • +
+

Each of those four factors manifests itself in multiple and different ways; each +of the hardware architectures and programming models expose specific forms. +However, the interesting part is that all of them are limiting the scalability of +applications no matter what part of the hardware jungle we look at. Hand-helds, +PCs, supercomputers, or the cloud, all suffer from the reign of the 4 horsemen: +Starvation, Latency, Overhead, and Contention. This +realization is very important as it allows us to derive the criteria for +solutions to the scalability problem from first principles, and it allows us to +focus our analysis on very concrete patterns and measurable metrics. Moreover, +any derived results will be applicable to a wide variety of targets.

+
+
+

Technology demands new response#

+

Today’s computer systems are designed based on the initial ideas of +John von Neumann, as +published back in 1945, and later extended by the +Harvard architecture. These +ideas form the foundation, the execution model, of computer systems we use +currently. However, a new response is required in the light of the demands +created by today’s technology.

+

So, what are the overarching objectives for designing systems allowing for +applications to scale as they should? In our opinion, the main objectives are:

+
    +
  • Performance: as previously mentioned, scalability and efficiency are the main criteria +people are interested in.

  • +
  • Fault tolerance: the low expected mean time between failures (MTBF) of future systems +requires embracing faults, not trying to avoid them.

  • +
  • Power: minimizing energy consumption is a must as it is one of the major cost +factors today, and will continue to rise in the future.

  • +
  • Generality: any system should be usable for a broad set of use cases.

  • +
  • Programmability: for programmer this is a very important objective, +ensuring long term platform stability and portability.

  • +
+

What needs to be done to meet those objectives, to make applications scale +better on tomorrow’s architectures? Well, the answer is almost obvious: we need +to devise a new execution model—a set of governing principles for the holistic +design of future systems—targeted at minimizing the effect of the outlined +SLOW factors. Everything we create for future systems, every design decision +we make, every criteria we apply, have to be validated against this single, +uniform metric. This includes changes in the hardware architecture we +prevalently use today, and it certainly involves new ways of writing software, +starting from the operating system, runtime system, compilers, and at the +application level. However, the key point is that all those layers have to be +co-designed; they are interdependent and cannot be seen as separate facets. The +systems we have today have been evolving for over 50 years now. All layers +function in a certain way, relying on the other layers to do so. But we do not +have the time to wait another 50 years for a new coherent system to evolve. +The new paradigms are needed now—therefore, co-design is the key.

+
+
+

Governing principles applied while developing HPX#

+

As it turn out, we do not have to start from scratch. Not everything has to be +invented and designed anew. Many of the ideas needed to combat the 4 horsemen +already exist, many for more than 30 years. All it takes is to gather +them into a coherent approach. We’ll highlight some of the derived principles we +think to be crucial for defeating SLOW. Some of those are focused on +high-performance computing, others are more general.

+
+
Focus on latency hiding instead of latency avoidance#
+

It is impossible to design a system exposing zero latencies. In an effort to +come as close as possible to this goal many optimizations are mainly targeted +towards minimizing latencies. Examples for this can be seen everywhere, such as +low latency network technologies like InfiniBand, caching memory hierarchies in all +modern processors, the constant optimization of existing MPI implementations +to reduce related latencies, or the data transfer latencies intrinsic to the way +we use GPGPUs today. It is important to +note that existing latencies are often tightly related to some resource having +to wait for the operation to be completed. At the same time it would be +perfectly fine to do some other, unrelated work in the meantime, allowing the +system to hide the latencies by filling the idle-time with useful work. Modern +systems already employ similar techniques (pipelined instruction execution in +the processor cores, asynchronous input/output operations, and many more). What +we propose is to go beyond anything we know today and to make latency hiding an +intrinsic concept of the operation of the whole system stack.

+
+
+
Embrace fine-grained parallelism instead of heavyweight threads#
+

If we plan to hide latencies even for very short operations, such as fetching +the contents of a memory cell from main memory (if it is not already cached), we +need to have very lightweight threads with extremely short context switching +times, optimally executable within one cycle. Granted, for mainstream +architectures, this is not possible today (even if we already have special +machines supporting this mode of operation, such as the Cray XMT). For conventional systems, however, +the smaller the overhead of a context switch and the finer the granularity of +the threading system, the better will be the overall system utilization and its +efficiency. For today’s architectures we already see a flurry of libraries +providing exactly this type of functionality: non-pre-emptive, task-queue based +parallelization solutions, such as Intel Threading Building Blocks (TBB), Microsoft Parallel Patterns Library (PPL), Cilk++, and many others. +The possibility to suspend a current task if some preconditions for its +execution are not met (such as waiting for I/O or the result of a different +task), seamlessly switching to any other task which can continue, and to +reschedule the initial task after the required result has been calculated, which +makes the implementation of latency hiding almost trivial.

+
+
+
Rediscover constraint-based synchronization to replace global barriers#
+

The code we write today is riddled with implicit (and explicit) global barriers. +By “global barriers,” we mean the synchronization of the control flow between +several (very often all) threads (when using OpenMP) or processes (MPI). +For instance, an implicit global barrier is inserted after each loop +parallelized using OpenMP as the system synchronizes the threads used to +execute the different iterations in parallel. In MPI each of the +communication steps imposes an explicit barrier onto the execution flow as +(often all) nodes have to be synchronized. Each of those barriers is like the eye +of a needle the overall execution is forced to be squeezed through. Even +minimal fluctuations in the execution times of the parallel threads (jobs) +causes them to wait. Additionally, it is often only one of the executing threads +that performs the actual reduce operation, which further impedes parallelism. A closer +analysis of a couple of key algorithms used in science applications reveals that +these global barriers are not always necessary. In many cases it is sufficient +to synchronize a small subset of the threads. Any operation should proceed +whenever the preconditions for its execution are met, and only those. Usually +there is no need to wait for iterations of a loop to finish before you can +continue calculating other things; all you need is to complete the iterations +that produce the required results for the next operation. Good +bye global barriers, hello constraint based synchronization! People have been +trying to build this type of computing (and even computers) since the 1970s. +The theory behind what they did is based on ideas around static and +dynamic dataflow. There are certain attempts today to get back to those ideas +and to incorporate them with modern architectures. For instance, a lot of work +is being done in the area of constructing dataflow-oriented execution trees. Our +results show that employing dataflow techniques in combination with the other +ideas, as outlined herein, considerably improves scalability for many problems.

+
+
+
Adaptive locality control instead of static data distribution#
+

While this principle seems to be a given for single desktop or laptop computers +(the operating system is your friend), it is everything but ubiquitous on modern +supercomputers, which are usually built from a large number of separate nodes +(i.e., Beowulf clusters), tightly interconnected by a high-bandwidth, low-latency +network. Today’s prevalent programming model for those is MPI, which does not +directly help with proper data distribution, leaving it to the programmer to +decompose the data to all of the nodes the application is running on. There are +a couple of specialized languages and programming environments based on PGAS +(Partitioned Global Address Space) designed to overcome this limitation, such as +Chapel, X10, UPC, or Fortress. However, all systems based on PGAS +rely on static data distribution. This works fine as long as this static data +distribution does not result in heterogeneous workload distributions or other +resource utilization imbalances. In a distributed system these imbalances can be +mitigated by migrating part of the application data to different localities +(nodes). The only framework supporting (limited) migration today is Charm++. +The first attempts towards solving related problem go back decades as well, a +good example is the Linda coordination language. Nevertheless, +none of the other mentioned systems support data migration today, which forces +the users to either rely on static data distribution and live with the related +performance hits or to implement everything themselves, which is very tedious +and difficult. We believe that the only viable way to flexibly support dynamic +and adaptive locality control is to provide a global, uniform address +space to the applications, even on distributed systems.

+
+
+
Prefer moving work to the data over moving data to the work#
+

For the best performance it seems obvious to minimize the amount of bytes +transferred from one part of the system to another. This is true on all levels. +At the lowest level we try to take advantage of processor memory caches, thus, +minimizing memory latencies. Similarly, we try to amortize the data transfer +time to and from GPGPUs as much as +possible. At high levels we try to minimize data transfer between different +nodes of a cluster or between different virtual machines on the cloud. Our +experience (well, it’s almost common wisdom) shows that the amount of bytes +necessary to encode a certain operation is very often much smaller than the +amount of bytes encoding the data the operation is performed upon. Nevertheless, +we still often transfer the data to a particular place where we execute the +operation just to bring the data back to where it came from afterwards. As an +example let’s look at the way we usually write our applications for clusters +using MPI. This programming model is all about data transfer between nodes. +MPI is the prevalent programming model for clusters, and it is fairly +straightforward to understand and to use. Therefore, we often write +applications in a way that accommodates this model, centered around data transfer. +These applications usually work well for smaller problem sizes and for regular +data structures. The larger the amount of data we have to churn and the more +irregular the problem domain becomes, the worse the overall machine +utilization and the (strong) scaling characteristics become. While it is not impossible +to implement more dynamic, data driven, and asynchronous applications using +MPI, it is somewhat difficult to do so. At the same time, if we look at +applications that prefer to execute the code close to the locality where the +data was placed, i.e., utilizing active messages (for instance based on +Charm++), we see better asynchrony, simpler application codes, and improved +scaling.

+
+
+
Favor message driven computation over message passing#
+

Today’s prevalently used programming model on parallel (multi-node) systems is +MPI. It is based on message passing, as the name implies, which means that +the receiver has to be aware of a message about to come in. Both codes, the +sender and the receiver, have to synchronize in order to perform the +communication step. Even the newer, asynchronous interfaces require explicitly +coding the algorithms around the required communication scheme. As a result, everything +but the most trivial MPI applications spends a considerable amount of time +waiting for incoming messages, thus, causing starvation and latencies to impede +full resource utilization. The more complex and more dynamic the data structures +and algorithms become, the larger the adverse effects. The community discovered +message-driven and data-driven methods of implementing algorithms a long +time ago, and systems such as Charm++ have already integrated active +messages demonstrating the validity of the concept. Message-driven computation +allows for sending messages without requiring the receiver to actively wait for +them. Any incoming message is handled asynchronously and triggers the encoded +action by passing along arguments and—possibly—continuations. HPX combines +this scheme with work-queue based scheduling as described above, which allows +the system to almost completely overlap any communication with useful work, +thereby minimizing latencies.

+
+
+
+
+

Additional material#

+ +
+
+
+
+

Overview#

+

HPX is organized into different sub-libraries and those in turn into modules. +The libraries and modules are independent, with clear dependencies and no +cycles. As an end-user, the use of these libraries is completely transparent. If +you use e.g. add_hpx_executable to create a target in your project you will +automatically get all modules as dependencies. See below for a list of the +available libraries and modules. Currently these are nothing more than an +internal grouping and do not affect usage. They cannot be consumed individually +at the moment.

+
+

Note

+

There is a dependency report that displays useful information about the +structure of the code. It is available for each commit at HPX Dependency report.

+
+
+
+

Core modules#

+
+
+
affinity#
+

The affinity module contains helper functionality for mapping worker threads to +hardware resources.

+

See the API reference of the module for more +details.

+
+
+
algorithms#
+

The algorithms module exposes the full set of algorithms defined by the C++ +standard. There is also partial support for C++ ranges.

+

See the API reference of the module for more +details.

+
+
+
allocator_support#
+

This module provides utilities for allocators. It contains +hpx::util::internal_allocator which directly forwards allocation +calls to jemalloc. This utility is is mainly useful on Windows.

+

See the API reference of the module for more +details.

+
+
+
asio#
+

The asio module is a thin wrapper around the Boost.Asio library, providing a +few additional helper functions.

+

See the API reference of the module for more +details.

+
+
+
assertion#
+

The assertion library implements the macros HPX_ASSERT and +HPX_ASSERT_MSG. Those two macros can be used to implement assertions +which are turned of during a release build.

+

By default, the location and function where the assert has been called from are +displayed when the assertion fires. This behavior can be modified by using +hpx::assertion::set_assertion_handler. When HPX initializes, it uses +this function to specify a more elaborate assertion handler. If your application +needs to customize this, it needs to do so before calling +hpx::init, hpx_main or using the C-main +wrappers.

+

See the API reference of the module for more +details.

+
+
+
async_base#
+

The async_base module defines the basic functionality for spawning tasks on +thread pools. This module does not implement any functionality on its own, but +is extended by async_local and async_distributed with +implementations for the local and distributed cases.

+

See the API reference of this module for more +details.

+
+
+
async_combinators#
+

This module contains combinators for futures. The when_* functions allow you +to turn multiple futures into a single future which is ready when all, any, +some, or each of the given futures are ready. The wait_* combinators are +equivalent to the when_* functions except that they do not return a future. +Those wait for all futures to become ready before returning to the user. Note +that the wait_* functions will rethrow one of the exceptions from +exceptional futures. +The wait_*_nothrow combinators are equivalent to the wait_* functions +exception that they do not throw if one of the futures has become exceptional.

+

The split_future combinator takes a single future of a container (e.g. +tuple) and turns it into a container of futures.

+

See lcos_local, synchronization, and +async_distributed for other synchronization facilities.

+

See the API reference of this module for more +details.

+
+
+
async_cuda#
+

This library adds a simple API that enables the user to retrieve a future from +a CUDA stream. Typically, a user may launch one or more kernels and then get a +future from the stream that will become ready when those kernels have completed. +It is important to note that multiple kernels may be launched without fetching a +future, and multiple futures may be obtained from the helper. Please refer to +the unit tests and examples for further examples.

+

See the API reference of this module for more +details.

+
+
+
async_local#
+

This module extends async_base to provide local implementations of +hpx::async, hpx::post, hpx::sync, and +hpx::dataflow. The async_distributed module extends the +functionality in this module to work with actions.

+

See the API reference of this module for more +details.

+
+
+
async_mpi#
+

The MPI library is intended to simplify the process of integrating MPI based +codes with the HPX runtime. Any MPI function that is asynchronous and uses an +MPI_Request may be converted into an hpx::future. +The syntax is designed to allow a simple replacement of the MPI call with a futurized +async version that accepts an executor instead of a communicator, +and returns a future instead of assigning a request. +Typically, an MPI call of the form

+
int MPI_Isend(buf, count, datatype, rank, tag, comm, request);
+
+
+

becomes

+
hpx::future<int> f = hpx::async(executor, MPI_Isend, buf, count, datatype, rank, tag);
+
+
+

When the MPI operation is complete, the future will become ready. +This allows communication to integrated cleanly with the rest of HPX, in particular +the continuation style of programming may be used to build up more +complex code. Consider the following example, that chains user processing, +sends and receives using continuations…

+
// create an executor for MPI dispatch
+hpx::mpi::experimental::executor exec(MPI_COMM_WORLD);
+
+// post an asynchronous receive using MPI_Irecv
+hpx::future<int> f_recv = hpx::async(
+    exec, MPI_Irecv, &data, rank, MPI_INT, rank_from, i);
+
+// attach a continuation to run when the recv completes,
+f_recv.then([=, &tokens, &counter](auto&&)
+{
+    // call an application specific function
+    msg_recv(rank, size, rank_to, rank_from, tokens[i], i);
+
+    // send a new message
+    hpx::future<int> f_send = hpx::async(
+        exec, MPI_Isend, &tokens[i], 1, MPI_INT, rank_to, i);
+
+    // when that send completes
+    f_send.then([=, &tokens, &counter](auto&&)
+    {
+        // call an application specific function
+        msg_send(rank, size, rank_to, rank_from, tokens[i], i);
+    });
+}
+
+
+

The example above makes use of MPI_Isend and MPI_Irecv, but any MPI function +that uses requests may be futurized in this manner. +The following is a (non exhaustive) list of MPI functions that should be supported, +though not all have been tested at the time of writing +(please report any problems to the issue tracker).

+
int MPI_Isend(...);
+int MPI_Ibsend(...);
+int MPI_Issend(...);
+int MPI_Irsend(...);
+int MPI_Irecv(...);
+int MPI_Imrecv(...);
+int MPI_Ibarrier(...);
+int MPI_Ibcast(...);
+int MPI_Igather(...);
+int MPI_Igatherv(...);
+int MPI_Iscatter(...);
+int MPI_Iscatterv(...);
+int MPI_Iallgather(...);
+int MPI_Iallgatherv(...);
+int MPI_Ialltoall(...);
+int MPI_Ialltoallv(...);
+int MPI_Ialltoallw(...);
+int MPI_Ireduce(...);
+int MPI_Iallreduce(...);
+int MPI_Ireduce_scatter(...);
+int MPI_Ireduce_scatter_block(...);
+int MPI_Iscan(...);
+int MPI_Iexscan(...);
+int MPI_Ineighbor_allgather(...);
+int MPI_Ineighbor_allgatherv(...);
+int MPI_Ineighbor_alltoall(...);
+int MPI_Ineighbor_alltoallv(...);
+int MPI_Ineighbor_alltoallw(...);
+
+
+

Note that the HPX mpi futurization wrapper should work with any asynchronous +MPI call, as long as the function signature has the last two arguments +MPI_xxx(..., MPI_Comm comm, MPI_Request *request) +- internally these two parameters will be substituted by the executor and future data +parameters that are supplied by template instantiations inside the hpx::mpi code.

+

See the API reference of this module for more +details.

+
+
+
async_sycl#
+

This module allows creating HPX futures using SYCL events, effectively integrating asynchronous SYCL kernels and +memory transfers with HPX. Building on this integration, this module also contains a SYCL executor. This executor +encapsulates a SYCL queue. When SYCL queue member functions are launched with this executor, the user can automatically +obtain the HPX futures associated with them.

+

The creation of the HPX futures using SYCL events is based on the same event polling mechanism that the CUDA HPX +integration uses. Each registered event gets an associated callback and gets inserted into a callback vector to +be polled by the scheduler in between tasks. Once the polling reveals the event is complete, the callback will be +called, which in turn sets the future to ready (see sycl_event_callback.cpp). +There are multiple adaptions for HipSYCL for this: To keep the runtime alive (avoiding the repeated on-the-fly creation of +the runtime during the polling), we keep a default queue. Furthermore, we flush the internal SYCL DAG to ensure +that the launched SYCL function is actually being executed.

+

The SYCL executor offers the usual post and async_execute functions. Additionally, it contains two get_future functions. +One expects a pre-existing SYCL event to return a future, the other one does not but will launch an empty SYCL kernel +instead, to obtain an event (causing higher overhead for the sake of being more convenient). +The post and async_execute implementations here are actually different for HipSYCL and OneAPI, since the sycl::queue +in OneAPI uses a different interface (using a code_location parameter) which requires some adaptations here.

+

To make this module compile, we use the -fno-sycl and -fsycl compiler parameters for the OneAPI use-case (requiring +HPX to be compiled with dpcpp). For HipSYCL we use its cmake integration instead (requiring HPX to be compiled with +clang++ and including HipSYCL as a library).

+

To build with OneAPI, use the CMake Variable HPX_WITH_SYCL=ON. +To build with HipSYCL, use HPX_WITH_SYCL=ON and HPX_WITH_HIPSYCL=ON (and make sure find_package will find HipSYCL).

+

Lastly, the module contains three tests/examples. All three implement a simple vector add example. The first one +obtains a future using the free method get_future, the second one uses a single SYCL executor and the last one +is using multiple executors called from multiple host threads.

+

To build the tests, use ” make tests.unit.modules.async_sycl ” +To run the tests, use “ctest -R sycl”.

+

NOTE: Theoretically, this module could work with other SYCL implementations, but was only tested using OneAPI and HipSYCL +so far.

+

See the API reference of this module for more +details.

+
+
+
batch_environments#
+

This module allows for the detection of execution as batch jobs, a series of +programs executed without user intervention. All data is preselected and will +be executed according to preset parameters, such as date or completion of +another task. Batch environments are especially useful for executing repetitive +tasks.

+

HPX supports the creation of batch jobs through the Portable Batch System +(PBS) and SLURM.

+

For more information on batch environments, see Running on batch systems +and the API reference for the module.

+
+
+
cache#
+

This module provides two cache data structures:

+ +

See the API reference of the module for more +details.

+
+
+
concepts#
+

This module provides helpers for emulating concepts. It provides the following +macros:

+
    +
  • HPX_CONCEPT_REQUIRES

  • +
  • HPX_HAS_MEMBER_XXX_TRAIT_DEF

  • +
  • HPX_HAS_XXX_TRAIT_DEF

  • +
+

See the API reference of the module for more details.

+
+
+
concurrency#
+

This module provides concurrency primitives useful for multi-threaded +programming such as:

+
    +
  • hpx::barrier

  • +
  • hpx::util::cache_line_data and +hpx::util::cache_aligned_data: wrappers for aligning and padding +data to cache lines.

  • +
  • various lockfree queue data structures

  • +
+

See the API reference of the module for more +details.

+
+
+
config#
+

The config module contains various configuration options, typically hidden +behind macros that choose the correct implementation based on the compiler and +other available options. It also contains platform independent macros to control +inlinining, export sets and more.

+

See the API reference of the module for more details.

+
+
+
config_registry#
+

The config_registry module is a low level module providing helper functionality +for registering configuration entries to a global registry from other modules. +The hpx::config_registry::add_module_config function is used to add +configuration options, and hpx::config_registry::get_module_configs +can be used to retrieve configuration entries registered so far. +add_module_config_helper can be used to register configuration +entries through static global options.

+

See the API reference of this module for more +details.

+
+
+
coroutines#
+

The coroutines module provides coroutine (user-space thread) implementations +for different platforms.

+

See the API reference of the module for more +details.

+
+
+
datastructures#
+

The datastructures module provides basic data structures (typically provided for +compatibility with older C++ standards):

+ +

See the API reference of the module for more +details.

+
+
+
debugging#
+

This module provides helpers for demangling symbol names.

+

See the API reference of the module for more +details.

+
+
+
errors#
+

This module provides support for exceptions and error codes:

+ +

See the API reference of the module for more details.

+
+
+
execution#
+

This library implements executors and execution policies for use with parallel +algorithms and other facilities related to managing the execution of tasks.

+

See the API reference of the module for more +details.

+
+
+
execution_base#
+

The basic execution module is the main entry point to implement parallel and +concurrent operations. It is modeled after P0443 +with some additions and implementations for the described concepts. Most +notably, it provides an abstraction for execution resources, execution contexts +and execution agents in such a way, that it provides customization points that +those aforementioned concepts can be replaced and combined with ease.

+

For that purpose, three virtual base classes are provided to be able to provide +implementations with different properties:

+
+
    +
  • +
    resource_base: This is the abstraction for execution resources, that is

    for example CPU cores or an accelerator.

    +
    +
    +
  • +
  • +
    context_base: An execution context uses execution resources and is able

    to spawn new execution agents, as new threads of executions on the available +resources.

    +
    +
    +
  • +
  • +
    agent_base: The execution agent represents the thread of execution, and

    can be used to yield, suspend, resume or abort a thread of execution.

    +
    +
    +
  • +
+
+
+
+
executors#
+

The executors module exposes executors and execution policies. Most importantly, +it exposes the following classes and constants:

+ +

See the API reference of this module for more +details.

+
+
+
filesystem#
+

This module provides a compatibility layer for the C++17 filesystem library. If +the filesystem library is available this module will simply forward its contents +into the hpx::filesystem namespace. If the library is not available it will +fall back to Boost.Filesystem instead.

+

See the API reference of the module for more +details.

+
+
+
format#
+

The format module exposes the format and format_to +functions for formatting strings.

+

See the API reference of the module for more details.

+
+
+
functional#
+

This module provides function wrappers and helpers for managing functions and +their arguments.

+ +

See the API reference of the module for more +details.

+
+
+
futures#
+

This module defines the hpx::future and +hpx::shared_future classes corresponding to the C++ standard +library classes std::future and +std::shared_future. Note that the +specializations of hpx::future::then for executors and +execution policies are defined in the execution module.

+

See the API reference of this module for more +details.

+
+
+
hardware#
+

The hardware module abstracts away hardware specific details of timestamps and +CPU features.

+

See the API reference of the module for more details.

+
+
+
hashing#
+

The hashing module provides two hashing implementations:

+
    +
  • hpx::util::fibhash

  • +
  • hpx::util::jenkins_hash

  • +
+

See the API reference of the module for more +details.

+
+
+
include_local#
+

This module provides no functionality in itself. Instead it provides headers +that group together other headers that often appear together. This module +provides local-only headers.

+

See the API reference of this module for +more details.

+
+
+
io_service#
+

This module provides an abstraction over Boost.ASIO, combining multiple +asio::io_contexts into a single pool. +hpx::util::io_service_pool provides a simple pool of +asio::io_contexts with an API similar to asio::io_context. +hpx::threads::detail::io_service_thread_pool wraps +hpx::util::io_service_pool into an interface derived from +hpx::threads::detail::thread_pool_base.

+

See the API reference of this module for more +details.

+
+
+
iterator_support#
+

This module provides helpers for iterators. It provides +hpx::util::iterator_facade and +hpx::util::iterator_adaptor for creating new iterators, and the +trait hpx::util::is_iterator along with more specific iterator +traits.

+

See the API reference of the module for more +details.

+
+
+
itt_notify#
+

This module provides support for profiling with Intel VTune.

+

See the API reference of this module for more +details.

+
+
+
lci_base#
+

This module provides helper functionality for detecting LCI environments.

+

See the API reference of this module for more +details.

+
+
+
lcos_local#
+

This module provides the following local LCOs:

+
    +
  • hpx::lcos::local::and_gate

  • +
  • hpx::lcos::local::channel

  • +
  • hpx::lcos::local::one_element_channel

  • +
  • hpx::lcos::local::receive_channel

  • +
  • hpx::lcos::local::send_channel

  • +
  • hpx::lcos::local::guard

  • +
  • hpx::lcos::local::guard_set

  • +
  • hpx::lcos::local::run_guarded

  • +
  • hpx::lcos::local::conditional_trigger

  • +
  • hpx::packaged_task

  • +
  • hpx::promise

  • +
  • hpx::lcos::local::receive_buffer

  • +
  • hpx::lcos::local::trigger

  • +
+

See lcos_distributed for distributed LCOs. Basic synchronization +primitives for use in HPX threads can be found in synchronization. +async_combinators contains useful utility functions for combining +futures.

+

See the API reference of this module for more +details.

+
+
+
lock_registration#
+

This module contains fucntionality for registering locks to detect when they are +locked and unlocked on different threads.

+

See the API reference of this module for more +details.

+
+
+
logging#
+

This module provides useful macros for logging information.

+

See the API reference of the module for more details.

+
+
+
memory#
+

Part of this module is a forked version of boost::intrusive_ptr from +Boost.SmartPtr.

+

See the API reference of the module for more details.

+
+
+
mpi_base#
+

This module provides helper functionality for detecting MPI environments.

+

See the API reference of this module for more +details.

+
+
+
pack_traversal#
+

This module exposes the basic functionality for traversing various packs, both +synchronously and asynchronously: hpx::util::traverse_pack and +hpx::util::traverse_pack_async. It also exposes the higher level +functionality of unwrapping nested futures: hpx::util::unwrap and +its function object form hpx::util::functional::unwrap.

+

See the API reference of this module for more +details.

+
+
+
plugin#
+

This module provides base utilities for creating plugins.

+

See the API reference of the module for more details.

+
+
+
prefix#
+

This module provides utilities for handling the prefix of an HPX application, +i.e. the paths used for searching components and plugins.

+

See the API reference of this module for more +details.

+
+
+
preprocessor#
+

This library contains useful preprocessor macros:

+ +

See the API reference of the module for more +details.

+
+
+
program_options#
+

The module program_options is a direct fork of the Boost.Program_options library +(Boost V1.70.0). +In order to be included as an HPX module, the Boost.Program_options library has +been moved to the namespace hpx::program_options. We have also replaced all +Boost facilities the library depends on with either the equivalent facilities +from the standard library or from HPX. As a result, the HPX program_options module +is fully interface compatible with Boost.Program_options (sans the hpx +namespace and the #include <hpx/modules/program_options.hpp> changes that need to be +applied to all code relying on this library).

+

All credit goes to Vladimir Prus, the author of the excellent Boost.Program_options +library. All bugs have been introduced by us.

+

See the API reference of the module for more +details.

+
+
+
properties#
+

This module implements the prefer customization point for properties in +terms of P2220. This differs from P1393 in that it relies fully on +tag_invoke overloads and fewer base customization points. Actual properties +are defined in modules. All functionality is experimental and can be accessed +through the hpx::experimental namespace.

+

See the API reference of this module for more +details.

+
+
+
resiliency#
+

In HPX, a program failure is a manifestation of a failing task. This module +exposes several APIs that allow users to manage failing tasks in a convenient way by +either replaying a failed task or by replicating a specific task.

+

Task replay is analogous to the Checkpoint/Restart mechanism found in conventional +execution models. The key difference being localized fault detection. When the +runtime detects an error, it replays the failing task as opposed to completely +rolling back the entire program to the previous checkpoint.

+

Task replication is designed to provide reliability enhancements by replicating +a set of tasks and evaluating their results to determine a consensus among them. +This technique is most effective in situations where there are few tasks in the +critical path of the DAG which leaves the system underutilized or where hardware +or software failures may result in an incorrect result instead of an error. +However, the drawback of this method is the additional computational cost incurred +by repeating a task multiple times.

+

The following API functions are exposed:

+
    +
  • hpx::resiliency::experimental::async_replay: This version of task replay will +catch user-defined exceptions and automatically reschedule the task N times +before throwing an hpx::resiliency::experimental::abort_replay_exception if no +task is able to complete execution without an exception.

  • +
  • hpx::resiliency::experimental::async_replay_validate: This version of replay +adds an argument to async replay which receives a user-provided validation +function to test the result of the task against. If the task’s output is +validated, the result is returned. If the output fails the check or an +exception is thrown, the task is replayed until no errors are encountered or +the number of specified retries has been exceeded.

  • +
  • hpx::resiliency::experimental::async_replicate: This is the most basic +implementation of the task replication. The API returns the first result that +runs without detecting any errors.

  • +
  • hpx::resiliency::experimental::async_replicate_validate: This API additionally +takes a validation function which evaluates the return values produced by the +threads. The first task to compute a valid result is returned.

  • +
  • hpx::resiliency::experimental::async_replicate_vote: This API adds a vote +function to the basic replicate function. Many hardware or software failures +are silent errors which do not interrupt program flow. In order to detect +errors of this kind, it is necessary to run the task several times and compare +the values returned by every version of the task. In order to determine which +return value is “correct”, the API allows the user to provide a custom +consensus function to properly form a consensus. This voting function then +returns the “correct”” answer.

  • +
  • hpx::resiliency::experimental::async_replicate_vote_validate: This combines the +features of the previously discussed replicate set. Replicate vote validate +allows a user to provide a validation function to filter results. +Additionally, as described in replicate vote, the user can provide a “voting +function” which returns the consensus formed by the voting logic.

  • +
  • hpx::resiliency::experimental::dataflow_replay: This version of dataflow replay +will catch user-defined exceptions and automatically reschedules the task N +times before throwing an hpx::resiliency::experimental::abort_replay_exception +if no task is able to complete execution without an exception. Any arguments +for the executed task that are futures will cause the task invocation to be +delayed until all of those futures have become ready.

  • +
  • hpx::resiliency::experimental::dataflow_replay_validate : This version of replay +adds an argument to dataflow replay which receives a user-provided validation +function to test the result of the task against. If the task’s output is +validated, the result is returned. If the output fails the check or an +exception is thrown, the task is replayed until no errors are encountered or +the number of specified retries have been exceeded. Any arguments for the +executed task that are futures will cause the task invocation to be delayed +until all of those futures have become ready.

  • +
  • hpx::resiliency::experimental::dataflow_replicate: This is the most basic +implementation of the task replication. The API returns the first result that +runs without detecting any errors. Any arguments for the executed task that +are futures will cause the task invocation to be delayed until all of those +futures have become ready.

  • +
  • hpx::resiliency::experimental::dataflow_replicate_validate: This API +additionally takes a validation function which evaluates the return values +produced by the threads. The first task to compute a valid result is returned. +Any arguments for the executed task that are futures will cause the task +invocation to be delayed until all of those futures have become ready.

  • +
  • hpx::resiliency::experimental::dataflow_replicate_vote: This API adds a vote +function to the basic replicate function. Many hardware or software failures +are silent errors which do not interrupt program flow. In order to detect +errors of this kind, it is necessary to run the task several times and compare +the values returned by every version of the task. In order to determine which +return value is “correct”, the API allows the user to provide a custom +consensus function to properly form a consensus. This voting function then +returns the “correct” answer. Any arguments for the executed task that are +futures will cause the task invocation to be delayed until all of those +futures have become ready.

  • +
  • hpx::resiliency::experimental::dataflow_replicate_vote_validate: This combines +the features of the previously discussed replicate set. Replicate vote +validate allows a user to provide a validation function to filter results. +Additionally, as described in replicate vote, the user can provide a “voting +function” which returns the consensus formed by the voting logic. Any +arguments for the executed task that are futures will cause the task +invocation to be delayed until all of those futures have become ready.

  • +
+

See the API reference of the module for more +details.

+
+
+
resource_partitioner#
+

The resource_partitioner module defines hpx::resource::partitioner, +the class used by the runtime and users to partition available hardware +resources into thread pools. See Using the resource partitioner for more +details on using the resource partitioner in applications.

+

See the API reference of this module for +more details.

+
+
+
runtime_configuration#
+

This module handles the configuration options required by the runtime.

+

See the API reference of this module +for more details.

+
+
+
schedulers#
+

This module provides schedulers used by thread pools in the +thread_pools module. There are currently three main schedulers:

+
    +
  • hpx::threads::policies::local_priority_queue_scheduler

  • +
  • hpx::threads::policies::static_priority_queue_scheduler

  • +
  • hpx::threads::policies::shared_priority_queue_scheduler

  • +
+

Other schedulers are specializations or variations of the above schedulers. See +the examples of the resource_partitioner module for examples of +specifying a custom scheduler for a thread pool.

+

See the API reference of this module for more +details.

+
+
+
serialization#
+

This module provides serialization primitives and support for all built-in +types as well as all C++ Standard Library collection and utility types. This +list is extended by HPX vocabulary types with proper support for global +reference counting. HPX’s mode of serialization is derived from Boost’s +serialization model +and, as such, is mostly interface compatible with +its Boost counterpart.

+

The purest form of serializing data is to copy the content of the payload bit +by bit; however, this method is impractical for generic C++ types, which might +be composed of more than just regular built-in types. Instead, HPX’s approach +to serialization is derived from the Boost Serialization library, and is geared +towards allowing the programmer of a given class explicit control and syntax of +what to serialize. It is based on operator overloading of two special archive +types that hold a buffer or stream to store the serialized data and is +responsible for dispatching the serialization mechanism to the intrusive or +non-intrusive version. The serialization process is recursive. Each member that +needs to be serialized must be specified explicitly. The advantage of this +approach is that the serialization code is written in C++ and leverages all +necessary programming techniques. The generic, user-facing interface allows +for effective application of the serialization process without obstructing the +algorithms that need special code for packing and unpacking. It also allows for +optimizations in the implementation of the archives.

+

See the API reference of the module for more +details.

+
+
+
static_reinit#
+

This module provides a simple wrapper around static variables that can be +reinitialized.

+

See the API reference of this module for more +details.

+
+
+
string_util#
+

This module contains string utilities inspired by the Boost String Algorithms Library.

+

See the API reference of this module for more +details.

+
+
+
synchronization#
+

This module provides synchronization primitives that should be used rather than +the C++ standard ones in HPX threads:

+ +

See lcos_local, async_combinators, and +async_distributed for higher level synchronization facilities.

+

See the API reference of this module for more +details.

+
+
+
testing#
+

The testing module contains useful macros for testing. The results of tests can +be printed with hpx::util::report_errors. The following macros are +provided:

+
    +
  • HPX_TEST

  • +
  • HPX_TEST_MSG

  • +
  • HPX_TEST_EQ

  • +
  • HPX_TEST_NEQ

  • +
  • HPX_TEST_LT

  • +
  • HPX_TEST_LTE

  • +
  • HPX_TEST_RANGE

  • +
  • HPX_TEST_EQ_MSG

  • +
  • HPX_TEST_NEQ_MSG

  • +
  • HPX_SANITY

  • +
  • HPX_SANITY_MSG

  • +
  • HPX_SANITY_EQ

  • +
  • HPX_SANITY_NEQ

  • +
  • HPX_SANITY_LT

  • +
  • HPX_SANITY_LTE

  • +
  • HPX_SANITY_RANGE

  • +
  • HPX_SANITY_EQ_MSG

  • +
+

See the API reference of the module for more details.

+
+
+
thread_pool_util#
+

This module contains helper functions for asynchronously suspending and resuming +thread pools and their worker threads.

+

See the API reference of this module for more +details.

+
+
+
thread_pools#
+

This module defines the thread pools and utilities used by the HPX runtime. +The only thread pool implementation provided by this module is +hpx::threads::detail::scheduled_thread_pool, which is derived from +hpx::threads::detail::thread_pool_base defined in the +threading_base module.

+

See the API reference of this module for more +details.

+
+
+
thread_support#
+

This module provides miscellaneous utilities for threading and concurrency.

+

See the API reference of the module for more +details.

+
+
+
threading#
+

This module provides the equivalents of std::thread and std::jthread +for lightweight HPX threads:

+ +

See the API reference of this module for more +details.

+
+
+
threading_base#
+

This module contains the base class definition required for threads. The base +class hpx::threads::thread_data is inherited by two specializations +for stackful and stackless threads: +hpx::threads::thread_data_stackful and +hpx::threads::thread_data_stackless. In addition, the module +defines the base classes for schedulers and thread pools: +hpx::threads::policies::scheduler_base and +hpx::threads::thread_pool_base.

+

See the API reference of this module for more +details.

+
+
+
thread_manager#
+

This module defines the hpx::threads::threadmanager class. This is +used by the runtime to manage the creation and destruction of thread pools. The +resource_partitioner module handles the partitioning of resources +into thread pools, but not the creation of thread pools.

+

See the API reference of this module for more +details.

+
+
+
timed_execution#
+

This module provides extensions to the executor interfaces defined in the +execution module that allow timed submission of tasks on thread +pools (at or after a specified time).

+

See the API reference of this module for more +details.

+
+
+
timing#
+

This module provides the timing utilities (clocks and timers).

+

See the API reference of the module for more details.

+
+
+
topology#
+

This module provides the class hpx::threads::topology which +represents the hardware resources available on a node. The class is a light +wrapper around the Portable Hardware Locality (HWLOC) library. The hpx::threads::cpu_mask is +a small companion class that represents a set of resources on a node.

+

See the API reference of the module for more details.

+
+
+
type_support#
+

This module provides helper facilities related to types.

+

See the API reference of the module for more +details.

+
+
+
util#
+

The util module provides miscellaneous standalone utilities.

+

See the API reference of the module for more details.

+
+
+
version#
+

This module macros and functions for accessing version information about HPX +and its dependencies.

+

See the API reference of this module for more +details.

+
+
+
+
+

Main HPX modules#

+
+
+
actions#
+

TODO: High-level description of the library.

+

See the API reference of this module for more +details.

+
+
+
actions_base#
+

TODO: High-level description of the library.

+

See the API reference of this module for more +details.

+
+
+
agas#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
agas_base#
+

This module holds the implementation of the four AGAS services: primary +namespace, locality namespace, component namespace, and symbol namespace.

+

See the API reference of this module for more +details.

+
+
+
async_colocated#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
async_distributed#
+

This module contains functionality for asynchronously launching work on remote +localities: hpx::async, hpx::post. This module extends +the local-only functions in libs_async_local.

+

See the API reference of this module for more +details.

+
+
+
checkpoint#
+

A common need of users is to periodically backup an application. This practice +provides resiliency and potential restart points in code. HPX utilizes the +concept of a checkpoint to support this use case.

+

Found in hpx/util/checkpoint.hpp, checkpoints are defined as objects +that hold a serialized version of an object or set of objects at a particular +moment in time. This representation can be stored in memory for later use or it +can be written to disk for storage and/or recovery at a later point. In order to +create and fill this object with data, users must use a function called +save_checkpoint. In code the function looks like this:

+
hpx::future<hpx::util::checkpoint> hpx::util::save_checkpoint(a, b, c, ...);
+
+
+

save_checkpoint takes arbitrary data containers, such as int, +double, float, vector, and future, and serializes them into a +newly created checkpoint object. This function returns a future to a +checkpoint containing the data. Here’s an example of a simple use case:

+
using hpx::util::checkpoint;
+using hpx::util::save_checkpoint;
+
+std::vector<int> vec{1,2,3,4,5};
+hpx::future<checkpoint> save_checkpoint(vec);
+
+
+

Once the future is ready, the checkpoint object will contain the vector +vec and its five elements.

+

prepare_checkpoint takes arbitrary data containers (same as for +save_checkpoint), , such as int, +double, float, vector, and future, and calculates the necessary +buffer space for the checkpoint that would be created if save_checkpoint +was called with the same arguments. This function returns a future to a +checkpoint that is appropriately initialized. Here’s an example of a +simple use case:

+
using hpx::util::checkpoint;
+using hpx::util::prepare_checkpoint;
+
+std::vector<int> vec{1,2,3,4,5};
+hpx::future<checkpoint> prepare_checkpoint(vec);
+
+
+

Once the future is ready, the checkpoint object will be initialized with an +appropriately sized internal buffer.

+

It is also possible to modify the launch policy used by save_checkpoint. +This is accomplished by passing a launch policy as the first argument. It is +important to note that passing hpx::launch::sync will cause +save_checkpoint to return a checkpoint instead of a future to a +checkpoint. All other policies passed to save_checkpoint will return a +future to a checkpoint.

+

Sometimes checkpoint s must be declared before they are used. +save_checkpoint allows users to move pre-created checkpoint s into the +function as long as they are the first container passing into the function (In +the case where a launch policy is used, the checkpoint will immediately +follow the launch policy). An example of these features can be found below:

+
    char character = 'd';
+    int integer = 10;
+    float flt = 10.01f;
+    bool boolean = true;
+    std::string str = "I am a string of characters";
+    std::vector<char> vec(str.begin(), str.end());
+    checkpoint archive;
+
+    // Test 1
+    //  test basic functionality
+    hpx::shared_future<checkpoint> f_archive = save_checkpoint(
+        std::move(archive), character, integer, flt, boolean, str, vec);
+
+
+

Once users can create checkpoints they must now be able to restore the +objects they contain into memory. This is accomplished by the function +restore_checkpoint. This function takes a checkpoint and fills its data +into the containers it is provided. It is important to remember that the +containers must be ordered in the same way they were placed into the +checkpoint. For clarity see the example below:

+
    char character2;
+    int integer2;
+    float flt2;
+    bool boolean2;
+    std::string str2;
+    std::vector<char> vec2;
+
+    restore_checkpoint(data, character2, integer2, flt2, boolean2, str2, vec2);
+
+
+

The core utility of checkpoint is in its ability to make certain data +persistent. Often, this means that the data needs to be stored in an object, +such as a file, for later use. HPX has two solutions for these issues: stream +operator overloads and access iterators.

+

HPX contains two stream overloads, operator<< and operator>>, to stream +data out of and into checkpoint. Here is an example of the overloads in +use below:

+
    double a9 = 1.0, b9 = 1.1, c9 = 1.2;
+    std::ofstream test_file_9("test_file_9.txt");
+    hpx::future<checkpoint> f_9 = save_checkpoint(a9, b9, c9);
+    test_file_9 << f_9.get();
+    test_file_9.close();
+
+    double a9_1, b9_1, c9_1;
+    std::ifstream test_file_9_1("test_file_9.txt");
+    checkpoint archive9;
+    test_file_9_1 >> archive9;
+    restore_checkpoint(archive9, a9_1, b9_1, c9_1);
+
+
+

This is the primary way to move data into and out of a checkpoint. It is +important to note, however, that users should be cautious when using a stream +operator to load data and another function to remove it (or vice versa). Both +operator<< and operator>> rely on a .write() and a .read() +function respectively. In order to know how much data to read from the +std::istream, the operator<< will write the size of the checkpoint +before writing the checkpoint data. Correspondingly, the operator>> will +read the size of the stored data before reading the data into a new instance of +checkpoint. As long as the user employs the operator<< and +operator>> to stream the data, this detail can be ignored.

+
+

Important

+

Be careful when mixing operator<< and operator>> with other +facilities to read and write to a checkpoint. operator<< writes an +extra variable, and operator>> reads this variable back separately. Used +together the user will not encounter any issues and can safely ignore this +detail.

+
+

Users may also move the data into and out of a checkpoint using the exposed +.begin() and .end() iterators. An example of this use case is +illustrated below.

+
    std::ofstream test_file_7("checkpoint_test_file.txt");
+    std::vector<float> vec7{1.02f, 1.03f, 1.04f, 1.05f};
+    hpx::future<checkpoint> fut_7 = save_checkpoint(vec7);
+    checkpoint archive7 = fut_7.get();
+    std::copy(archive7.begin(),    // Write data to ofstream
+        archive7.end(),            // ie. the file
+        std::ostream_iterator<char>(test_file_7));
+    test_file_7.close();
+
+    std::vector<float> vec7_1;
+    std::vector<char> char_vec;
+    std::ifstream test_file_7_1("checkpoint_test_file.txt");
+    if (test_file_7_1)
+    {
+        test_file_7_1.seekg(0, test_file_7_1.end);
+        auto length = test_file_7_1.tellg();
+        test_file_7_1.seekg(0, test_file_7_1.beg);
+        char_vec.resize(length);
+        test_file_7_1.read(char_vec.data(), length);
+    }
+    checkpoint archive7_1(std::move(char_vec));    // Write data to checkpoint
+    restore_checkpoint(archive7_1, vec7_1);
+
+
+
+
Checkpointing components#
+

save_checkpoint and restore_checkpoint are also able to store components +inside checkpoints. This can be done in one of two ways. First a client of +the component can be passed to save_checkpoint. When the user wishes to +resurrect the component she can pass a client instance to +restore_checkpoint.

+

This technique is demonstrated below:

+
    // Try to checkpoint and restore a component with a client
+    std::vector<int> vec3{10, 10, 10, 10, 10};
+
+    // Create a component instance through client constructor
+    data_client D(hpx::find_here(), std::move(vec3));
+    hpx::future<checkpoint> f3 = save_checkpoint(D);
+
+    // Create a new client
+    data_client E;
+
+    // Restore server inside client instance
+    restore_checkpoint(f3.get(), E);
+
+
+

The second way a user can save a component is by passing a shared_ptr to the +component to save_checkpoint. This component can be resurrected by creating +a new instance of the component type and passing a shared_ptr to the new +instance to restore_checkpoint.

+

This technique is demonstrated below:

+
    // test checkpoint a component using a shared_ptr
+    std::vector<int> vec{1, 2, 3, 4, 5};
+    data_client A(hpx::find_here(), std::move(vec));
+
+    // Checkpoint Server
+    hpx::id_type old_id = A.get_id();
+
+    hpx::future<std::shared_ptr<data_server>> f_a_ptr =
+        hpx::get_ptr<data_server>(A.get_id());
+    std::shared_ptr<data_server> a_ptr = f_a_ptr.get();
+    hpx::future<checkpoint> f = save_checkpoint(a_ptr);
+    auto&& data = f.get();
+
+    // test prepare_checkpoint API
+    checkpoint c = prepare_checkpoint(hpx::launch::sync, a_ptr);
+    HPX_TEST(c.size() == data.size());
+
+    // Restore Server
+    // Create a new server instance
+    std::shared_ptr<data_server> b_server;
+    restore_checkpoint(data, b_server);
+
+
+
+
+
+
checkpoint_base#
+

The checkpoint_base module contains lower level facilities that wrap simple +check-pointing capabilities. This module does not implement special handling +for futures or components, but simply serializes all arguments to or from +a given container.

+

This module exposes the hpx::util::save_checkpoint_data, +hpx::util::restore_checkpoint_data, and hpx::util::prepare_checkpoint_data +APIs. These functions encapsulate the basic serialization functionalities +necessary to save/restore a variadic list of arguments to/from a given data +container.

+

See the API reference of this module for more +details.

+
+
+
collectives#
+

The collectives module exposes a set of distributed collective operations. Those +can be used to exchange data between participating sites in a coordinated way. +At this point the module exposes the following collective primitives:

+ +

See the API reference of the module for more +details.

+
+
+
command_line_handling#
+

The command_line_handling module defines and handles the command-line options +required by the HPX runtime, combining them with configuration options +defined by the runtime_configuration module. The actual parsing of +command line options is handled by the program_options module.

+

See the API reference of the module for +more details.

+
+
+
components#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
components_base#
+

TODO: High-level description of the library.

+

See the API reference of this module for more +details.

+
+
+
compute#
+

The compute module provides utilities for handling task and memory affinity on +host systems.

+

See the API reference of the module for more details.

+
+
+
distribution_policies#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
executors_distributed#
+

This module provides the executor +hpx::parallel::execution::disribution_policy_executor. It allows +one to create work that is implicitly distributed over multiple localities.

+

See the API reference of this module for more +details.

+
+
+
include#
+

This module provides no functionality in itself. Instead it provides headers +that group together other headers that often appear together.

+

See the API reference of this module for more +details.

+
+
+
init_runtime#
+

TODO: High-level description of the library.

+

See the API reference of this module for more +details.

+
+
+
lcos_distributed#
+

This module contains distributed LCOs. Currently the only LCO provided +is :cpp:class::hpx::lcos::channel, a construct for sending values from one +locality to another. See libs_lcos_local for local LCOs.

+

See the API reference of this module for more details.

+
+
+
naming#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
naming_base#
+

This module provides a forward declaration of address_type, component_type +and invalid_locality_id.

+

See the API reference of this module for more +details.

+
+
+
parcelport_lci#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
parcelport_libfabric#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
parcelport_mpi#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
parcelport_tcp#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
parcelset#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
parcelset_base#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
performance_counters#
+

This module provides the basic functionality required for defining performance +counters. See Performance counters for more information about +performance counters.

+

See the API reference of this module for more +details.

+
+
+
plugin_factories#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
resiliency_distributed#
+

Software resiliency features of HPX were introduced in the +resiliency module. This module extends the APIs +to run on distributed-memory systems allowing the user to invoke the failing +task on other localities at runtime. This is useful in cases where a node is +identified to fail more often (e.g., for certain ALU computes) as the task can +now be replayed or replicated among different localities. The API exposed +allows for an easy integration with the local only resiliency APIs as well.

+

Distributed software resilience APIs have a similar function signature +and lives under the same namespace of hpx::resiliency::experimental. +The difference arises in the formal parameters where distributed APIs takes +the localities as the first argument, and an action as opposed to a function or +a function object. The localities signify the order in which the API will either +schedule (in case of Task Replay) tasks in a round robin fashion or replicate +the tasks onto the list of localities.

+

The list of APIs exposed by distributed resiliency modules is the same as those +defined in local resiliency module.

+

See the API reference of this module +for more details.

+
+
+
runtime_components#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
runtime_distributed#
+

TODO: High-level description of the module.

+

See the API reference of this module for more +details.

+
+
+
segmented_algorithms#
+

Segmented algorithms extend the usual parallel algorithms by +providing overloads that work with distributed containers, such as partitioned vectors.

+

See the API reference of the module for +more details.

+
+
+
statistics#
+

This module provide some statistics utilities like rolling min/max and +histogram.

+

See the API reference of the module for more +details.

+
+
+
+
+
+
+
+
+

API reference#

+

HPX follows a versioning scheme with three numbers: major.minor.patch. We +guarantee no breaking changes in the API for patch releases. Minor releases may +remove or break existing APIs, but only after a deprecation period of at least +two minor releases. In rare cases do we outright remove old and unused +functionality without a deprecation period.

+

We do not provide any ABI compatibility guarantees between any versions, debug +and release builds, and builds with different C++ standards.

+

The public API of HPX is presented below. Clicking on a name brings you to the +full documentation for the class or function. Including the header specified in +a heading brings in the features listed under that heading.

+
+

Note

+

Names listed here are guaranteed stable with respect to semantic versioning. +However, at the moment the list is incomplete and certain unlisted features +are intended to be in the public API. While we work on completing the list, +if you’re unsure about whether a particular unlisted name is part of the +public API you can get into contact with us or open an issue and we’ll +clarify the situation.

+
+
+
+

Public API#

+

Our API is semantically conforming; hence, the reader is highly encouraged to refer to the +corresponding facility in the C++ Standard if +needed. All names below are also available in the top-level hpx namespace unless +otherwise noted. The names in hpx should be preferred. The names in +sub-namespaces will eventually be removed.

+
+
hpx/algorithm.hpp#
+

The header hpx/algorithm.hpp corresponds to the +C++ standard library header algorithm. See Using parallel algorithms for +more information about the parallel algorithms.

+
+
Classes#
+ + ++++ + + + + + + + + + + + + + +
Table 122 Classes of header hpx/algorithm.hpp#

Class

C++ standard

hpx::experimental::reduction

N4808

hpx::experimental::induction

N4808

+
+
+
Functions#
+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 123 hpx functions of header hpx/algorithm.hpp#

hpx function

C++ standard

hpx::adjacent_find

std::adjacent_find

hpx::all_of

std::all_of

hpx::any_of

std::any_of

hpx::copy

std::copy

hpx::copy_if

std::copy_if

hpx::copy_n

std::copy_n

hpx::count

std::count

hpx::count_if

std::count_if

hpx::ends_with

std::ends_with

hpx::equal

std::equal

hpx::fill

std::fill

hpx::fill_n

std::fill_n

hpx::find

std::find

hpx::find_end

std::find_end

hpx::find_first_of

std::find_first_of

hpx::find_if

std::find_if

hpx::find_if_not

std::find_if_not

hpx::for_each

std::for_each

hpx::for_each_n

std::for_each_n

hpx::generate

std::generate

hpx::generate_n

std::generate_n

hpx::includes

std::includes

hpx::inplace_merge

std::inplace_merge

hpx::is_heap

std::is_heap

hpx::is_heap_until

std::is_heap_until

hpx::is_partitioned

std::is_partitioned

hpx::is_sorted

std::is_sorted

hpx::is_sorted_until

std::is_sorted_until

hpx::lexicographical_compare

std::lexicographical_compare

hpx::make_heap

std::make_heap

hpx::max_element

std::max_element

hpx::merge

std::merge

hpx::min_element

std::min_element

hpx::minmax_element

std::minmax_element

hpx::mismatch

std::mismatch

hpx::move

std::move

hpx::none_of

std::none_of

hpx::nth_element

std::nth_element

hpx::partial_sort

std::partial_sort

hpx::partial_sort_copy

std::partial_sort_copy

hpx::partition

std::partition

hpx::partition_copy

std::partition_copy

hpx::experimental::reduce_by_key

reduce_by_key

hpx::remove

std::remove

hpx::remove_copy

std::remove_copy

hpx::remove_copy_if

std::remove_copy_if

hpx::remove_if

std::remove_if

hpx::replace

std::replace

hpx::replace_copy

std::replace_copy

hpx::replace_copy_if

std::replace_copy_if

hpx::replace_if

std::replace_if

hpx::reverse

std::reverse

hpx::reverse_copy

std::reverse_copy

hpx::rotate

std::rotate

hpx::rotate_copy

std::rotate_copy

hpx::search

std::search

hpx::search_n

std::search_n

hpx::set_difference

std::set_difference

hpx::set_intersection

std::set_intersection

hpx::set_symmetric_difference

std::set_symmetric_difference

hpx::set_union

std::set_union

hpx::shift_left

std::shift_left

hpx::shift_right

std::shift_right

hpx::sort

std::sort

hpx::experimental::sort_by_key

sort_by_key

hpx::stable_partition

std::stable_partition

hpx::stable_sort

std::stable_sort

hpx::starts_with

std::starts_with

hpx::swap_ranges

std::swap_ranges

hpx::transform

std::transform

hpx::unique

std::unique

hpx::unique_copy

std::unique_copy

hpx::experimental::for_loop

N4808

hpx::experimental::for_loop_strided

N4808

hpx::experimental::for_loop_n

N4808

hpx::experimental::for_loop_n_strided

N4808

+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 124 hpx::ranges functions of header hpx/algorithm.hpp#

hpx::ranges function

C++ standard

hpx::ranges::adjacent_find

std::adjacent_find

hpx::ranges::all_of

std::all_of

hpx::ranges::any_of

std::any_of

hpx::ranges::copy

std::copy

hpx::ranges::copy_if

std::copy_if

hpx::ranges::copy_n

std::copy_n

hpx::ranges::count

std::count

hpx::ranges::count_if

std::count_if

hpx::ranges::ends_with

std::ends_with

hpx::ranges::equal

std::equal

hpx::ranges::fill

std::fill

hpx::ranges::fill_n

std::fill_n

hpx::ranges::find

std::find

hpx::ranges::find_end

std::find_end

hpx::ranges::find_first_of

std::find_first_of

hpx::ranges::find_if

std::find_if

hpx::ranges::find_if_not

std::find_if_not

hpx::ranges::for_each

std::for_each

hpx::ranges::for_each_n

std::for_each_n

hpx::ranges::generate

std::generate

hpx::ranges::generate_n

std::generate_n

hpx::ranges::includes

std::includes

hpx::ranges::inplace_merge

std::inplace_merge

hpx::ranges::is_heap

std::is_heap

hpx::ranges::is_heap_until

std::is_heap_until

hpx::ranges::is_partitioned

std::is_partitioned

hpx::ranges::is_sorted

std::is_sorted

hpx::ranges::is_sorted_until

std::is_sorted_until

hpx::ranges::make_heap

std::make_heap

hpx::ranges::max_element

std::max_element

hpx::ranges::merge

std::merge

hpx::ranges::min_element

std::min_element

hpx::ranges::minmax_element

std::minmax_element

hpx::ranges::mismatch

std::mismatch

hpx::ranges::move

std::move

hpx::ranges::none_of

std::none_of

hpx::ranges::nth_element

std::nth_element

hpx::ranges::partial_sort

std::partial_sort

hpx::ranges::partial_sort_copy

std::partial_sort_copy

hpx::ranges::partition

std::partition

hpx::ranges::partition_copy

std::partition_copy

hpx::ranges::set_difference

std::set_difference

hpx::ranges::set_intersection

std::set_intersection

hpx::ranges::set_symmetric_difference

std::set_symmetric_difference

hpx::ranges::set_union

std::set_union

hpx::ranges::shift_left

P2440

hpx::ranges::shift_right

P2440

hpx::ranges::sort

std::sort

hpx::ranges::stable_partition

std::stable_partition

hpx::ranges::stable_sort

std::stable_sort

hpx::ranges::starts_with

std::starts_with

hpx::ranges::swap_ranges

std::swap_ranges

hpx::ranges::transform

std::transform

hpx::ranges::unique

std::unique

hpx::ranges::unique_copy

std::unique_copy

hpx::ranges::experimental::for_loop

N4808

hpx::ranges::experimental::for_loop_strided

N4808

+
+
+
+
hpx/any.hpp#
+

The header hpx/any.hpp corresponds to the C++ +standard library header any.

+

hpx::any is compatible with std::any.

+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + + + + +
Table 125 Classes of header hpx/any.hpp#

Class

C++ standard

hpx::any

std::any

hpx::any_nonser

hpx::bad_any_cast

std::bad_any_cast

hpx::unique_any_nonser

+
+
+
Functions#
+ + ++++ + + + + + + + + + + + + + + + + + + + +
Table 126 Functions of header hpx/any.hpp#

Function

C++ standard

hpx::any_cast

std::any_cast

hpx::make_any

std::make_any

hpx::make_any_nonser

hpx::make_unique_any_nonser

+
+
+
+
hpx/assert.hpp#
+

The header hpx/assert.hpp corresponds to the C++ standard +library header cassert.

+

HPX_ASSERT is the HPX equivalent to assert in cassert. +HPX_ASSERT can also be used in CUDA device code.

+
+
Macros#
+ + +++ + + + + + + + + + + +
Table 127 Macros of header hpx/assert.hpp#

Macro

HPX_ASSERT

HPX_ASSERT_MSG

+
+
+
+
hpx/barrier.hpp#
+

The header hpx/barrier.hpp corresponds to the +C++ standard library header barrier and contains a distributed barrier implementation. This +functionality is also exposed through the hpx::distributed namespace. The name in +hpx::distributed should be preferred.

+
+
Classes#
+ + ++++ + + + + + + + + + + +
Table 128 Classes of header hpx/barrier.hpp#

Class

C++ standard

hpx::barrier

std::barrier

+ + +++ + + + + + + + + +
Table 129 Distributed implementation of classes of header hpx/barrier.hpp#

Class

hpx::distributed::barrier

+
+
+
+
hpx/channel.hpp#
+

The header hpx/channel.hpp contains a local and a +distributed channel implementation. This functionality is also exposed through the hpx::distributed +namespace. The name in hpx::distributed should be preferred.

+
+
Classes#
+ + +++ + + + + + + + + +
Table 130 Classes of header hpx/channel.hpp#

Class

hpx::channel

+ + +++ + + + + + + + + +
Table 131 Distributed implementation of classes of header hpx/channel.hpp#

Class

hpx::distributed::channel

+
+
+
+
hpx/chrono.hpp#
+

The header hpx/chrono.hpp corresponds to the +C++ standard library header chrono. The following replacements and +extensions are provided compared to chrono.

+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + +
Table 132 Classes of header hpx/chrono.hpp#

Class

C++ standard

hpx::chrono::high_resolution_clock

std::high_resolution_clock

hpx::chrono::high_resolution_timer

hpx::chrono::steady_time_point

std::time_point

+
+
+
+
hpx/condition_variable.hpp#
+

The header hpx/condition_variable.hpp corresponds to the C++ +standard library header condition_variable.

+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + +
Table 133 Classes of header hpx/condition_variable.hpp#

Class

C++ standard

hpx::condition_variable

std::condition_variable

hpx::condition_variable_any

std::condition_variable_any

hpx::cv_status

std::cv_status

+
+
+
+
hpx/exception.hpp#
+

The header hpx/exception.hpp corresponds to +the C++ standard library header exception. hpx::exception +extends std::exception and is the base class for all exceptions thrown in HPX. +HPX_THROW_EXCEPTION can be used to throw HPX exceptions with file and line information +attached to the exception.

+
+
Macros#
+ +
+
+
Classes#
+ + ++++ + + + + + + + + + + +
Table 134 Classes of header hpx/exception.hpp#

Class

C++ standard

hpx::exception

std::exception

+
+
+
+
hpx/execution.hpp#
+

The header hpx/execution.hpp corresponds to the +C++ standard library header execution. See High level parallel facilities, +Using parallel algorithms and Executor parameters and executor parameter traits for more information about execution +policies and executor parameters.

+
+

Note

+

These names are only available in the hpx::execution namespace, not in +the top-level hpx namespace.

+
+
+
Constants#
+ + ++++ + + + + + + + + + + + + + + + + + + + +
Table 135 Constants of header hpx/execution.hpp#

Constant

C++ standard

hpx::execution::seq

std::execution_policy_tag

hpx::execution::par

std::execution_policy_tag

hpx::execution::par_unseq

std::execution_policy_tag

hpx::execution::task

+
+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 136 Classes of header hpx/execution.hpp#

Class

C++ standard

hpx::execution::sequenced_policy

std::execution_policy_tag_t

hpx::execution::parallel_policy

std::execution_policy_tag_t

hpx::execution::parallel_unsequenced_policy

std::execution_policy_tag_t

hpx::execution::sequenced_task_policy

hpx::execution::parallel_task_policy

hpx::execution::experimental::auto_chunk_size

hpx::execution::experimental::dynamic_chunk_size

hpx::execution::experimental::guided_chunk_size

hpx::execution::experimental::persistent_auto_chunk_size

hpx::execution::experimental::static_chunk_size

hpx::execution::experimental::num_cores

+
+
+
+
hpx/functional.hpp#
+

The header hpx/functional.hpp corresponds to the +C++ standard library header functional. hpx::function is a more +efficient and serializable replacement for std::function.

+
+
Constants#
+

The following constants correspond to the C++ standard std::placeholders

+ + +++ + + + + + + + + + + + + + + +
Table 137 Constants of header hpx/functional.hpp#

Constant

hpx::placeholders::_1

hpx::placeholders::_2

hpx::placeholders::_9

+
+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 138 Classes of header hpx/functional.hpp#

Class

C++ standard

hpx::function

std::function

hpx::function_ref

P0792

hpx::move_only_function

std::move_only_function

hpx::is_bind_expression

std::is_bind_expression

hpx::is_placeholder

std::is_placeholder

hpx::scoped_annotation

+
+
+
Functions#
+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 139 Functions of header hpx/functional.hpp#

Function

C++ standard

hpx::annotated_function

hpx::bind

std::bind

hpx::bind_back

std::bind_front

hpx::bind_front

std::bind_front

hpx::invoke

std::invoke

hpx::invoke_fused

std::apply

hpx::invoke_fused_r

hpx::mem_fn

std::mem_fn

+
+
+
+
hpx/future.hpp#
+

The header hpx/future.hpp corresponds to the +C++ standard library header future. See Extended facilities for futures for more +information about extensions to futures compared to the C++ standard library.

+

This header file also contains overloads of hpx::async, +hpx::post, hpx::sync, and hpx::dataflow that can be used with +actions. See Action invocation for more information about invoking actions.

+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + + + + + + + +
Table 140 Classes of header hpx/future.hpp#

Class

C++ standard

hpx::future

std::future

hpx::shared_future

std::shared_future

hpx::promise

std::promise

hpx::launch

std::launch

hpx::packaged_task

std::packaged_task

+
+

Note

+

All names except hpx::promise are also available in +the top-level hpx namespace. hpx::promise refers to +hpx::distributed::promise, a distributed variant of +hpx::promise, but will eventually refer to +hpx::promise after a deprecation period.

+
+ + +++ + + + + + + + + +
Table 141 Distributed implementation of classes of header hpx/future.hpp#

Class

hpx::distributed::promise

+
+
+
Functions#
+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 142 Functions of header hpx/future.hpp#

Function

C++ standard

hpx::async

std::async

hpx::post

hpx::sync

hpx::dataflow

hpx::make_future

hpx::make_shared_future

hpx::make_ready_future

P0159

hpx::make_ready_future_alloc

hpx::make_ready_future_at

hpx::make_ready_future_after

hpx::make_exceptional_future

P0159

hpx::when_all

P0159

hpx::when_any

P0159

hpx::when_some

hpx::when_each

hpx::wait_all

hpx::wait_any

hpx::wait_some

hpx::wait_each

+
+
+
+
hpx/init.hpp#
+

The header hpx/init.hpp contains functionality for +starting, stopping, suspending, and resuming the HPX runtime. This is the main way to explicitly +start the HPX runtime. See Starting the HPX runtime for more details on starting the HPX runtime.

+
+
Classes#
+ + +++ + + + + + + + + + + +
Table 143 Classes of header hpx/init.hpp#

Class

hpx::init_params

hpx::runtime_mode

+
+
+
Functions#
+ + +++ + + + + + + + + + + + + + + + + + + +
Table 144 Functions of header hpx/init.hpp#

Function

hpx::init

hpx::start

hpx::finalize

hpx::disconnect

hpx::suspend

hpx::resume

+
+
+
+
hpx/latch.hpp#
+

The header hpx/latch.hpp corresponds to the C++ +standard library header latch. It contains a local and a distributed latch +implementation. This functionality is also exposed through the hpx::distributed namespace. +The name in hpx::distributed should be preferred.

+
+
Classes#
+ + ++++ + + + + + + + + + + +
Table 145 Classes of header hpx/latch.hpp#

Class

C++ standard

hpx::latch

std::latch

+ + +++ + + + + + + + + +
Table 146 Distributed implementation of classes of header hpx/latch.hpp#

Class

hpx::distributed::latch

+
+
+
+
hpx/mutex.hpp#
+

The header hpx/mutex.hpp corresponds to the +C++ standard library header mutex.

+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 147 Classes of header hpx/mutex.hpp#

Class

C++ standard

hpx::mutex

std::mutex

hpx::no_mutex

hpx::once_flag

std::once_flag

hpx::recursive_mutex

std::recursive_mutex

hpx::spinlock

hpx::timed_mutex

std::timed_mutex

hpx::unlock_guard

+
+
+
Functions#
+ + ++++ + + + + + + + + + + +
Table 148 Functions of header hpx/mutex.hpp#

Class

C++ standard

hpx::call_once

std::call_once

+
+
+
+
hpx/memory.hpp#
+

The header hpx/memory.hpp corresponds to the +C++ standard library header memory. It contains parallel versions of the +copy, fill, move, and construct helper functions in memory. See +Using parallel algorithms for more information about the parallel algorithms.

+
+
Functions#
+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 149 hpx functions of header hpx/memory.hpp#

hpx function

C++ standard

hpx::uninitialized_copy

std::uninitialized_copy

hpx::uninitialized_copy_n

std::uninitialized_copy_n

hpx::uninitialized_default_construct

std::uninitialized_default_construct

hpx::uninitialized_default_construct_n

std::uninitialized_default_construct_n

hpx::uninitialized_fill

std::uninitialized_fill

hpx::uninitialized_fill_n

std::uninitialized_fill_n

hpx::uninitialized_move

std::uninitialized_move

hpx::uninitialized_move_n

std::uninitialized_move_n

hpx::uninitialized_value_construct

std::uninitialized_value_construct

hpx::uninitialized_value_construct_n

std::uninitialized_value_construct_n

+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 150 hpx::ranges functions of header hpx/memory.hpp#

hpx::ranges function

C++ standard

hpx::ranges::uninitialized_copy

std::uninitialized_copy

hpx::ranges::uninitialized_copy_n

std::uninitialized_copy_n

hpx::ranges::uninitialized_default_construct

std::uninitialized_default_construct

hpx::ranges::uninitialized_default_construct_n

std::uninitialized_default_construct_n

hpx::ranges::uninitialized_fill

std::uninitialized_fill

hpx::ranges::uninitialized_fill_n

std::uninitialized_fill_n

hpx::ranges::uninitialized_move

std::uninitialized_move

hpx::ranges::uninitialized_move_n

std::uninitialized_move_n

hpx::ranges::uninitialized_value_construct

std::uninitialized_value_construct

hpx::ranges::uninitialized_value_construct_n

std::uninitialized_value_construct_n

+
+
+
+
hpx/numeric.hpp#
+

The header hpx/numeric.hpp corresponds to the +C++ standard library header numeric. See Using parallel algorithms for more +information about the parallel algorithms.

+
+
Functions#
+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 151 hpx functions of header hpx/numeric.hpp#

hpx function

C++ standard

hpx::adjacent_difference

std::adjacent_difference

hpx::exclusive_scan

std::exclusive_scan

hpx::inclusive_scan

std::inclusive_scan

hpx::reduce

std::reduce

hpx::transform_exclusive_scan

std::transform_exclusive_scan

hpx::transform_inclusive_scan

std::transform_inclusive_scan

hpx::transform_reduce

std::transform_reduce

+ + +++ + + + + + + + + + + + + + + + + + + + + +
Table 152 hpx::ranges functions of header hpx/numeric.hpp#

hpx::ranges function

hpx::ranges::adjacent_difference

hpx::ranges::exclusive_scan

hpx::ranges::inclusive_scan

hpx::ranges::reduce

hpx::ranges::transform_exclusive_scan

hpx::ranges::transform_inclusive_scan

hpx::ranges::transform_reduce

+
+
+
+
hpx/optional.hpp#
+

The header hpx/optional.hpp corresponds to the +C++ standard library header optional. hpx::optional is compatible +with std::optional.

+
+
Constants#
+
    +
  • hpx::nullopt

  • +
+
+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + +
Table 153 Classes of header hpx/optional.hpp#

Class

C++ standard

hpx::optional

std::optional

hpx::nullopt_t

std::nullopt_t

hpx::bad_optional_access

std::bad_optional_access

+
+
+
+
hpx/runtime.hpp#
+

The header hpx/runtime.hpp contains functions for accessing +local and distributed runtime information.

+
+
Typedefs#
+ + +++ + + + + + + + + + + +
Table 154 Typedefs of header hpx/runtime.hpp#

Typedef

hpx::startup_function_type

hpx::shutdown_function_type

+
+
+
Functions#
+ + +++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 155 Functions of header hpx/runtime.hpp#

Function

hpx::find_root_locality

hpx::find_all_localities

hpx::find_remote_localities

hpx::find_locality

hpx::get_colocation_id

hpx::get_locality_id

hpx::get_num_worker_threads

hpx::get_worker_thread_num

hpx::get_thread_name

hpx::register_pre_startup_function

hpx::register_startup_function

hpx::register_pre_shutdown_function

hpx::register_shutdown_function

hpx::get_num_localities

hpx::get_locality_name

+
+
+
+
hpx/experimental/scope.hpp#
+

The header hpx/experimental/scope.hpp corresponds to the +C++ standard library header experimental/scope.

+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + +
Table 156 Classes of header hpx/scope.hpp#

Class

C++ standard

hpx::experimental::scope_exit

std::scope_exit

hpx::experimental::scope_fail

std::scope_fail

hpx::experimental::scope_success

std::scope_success

+
+
+
+
hpx/semaphore.hpp#
+

The header hpx/semaphore.hpp corresponds to the +C++ standard library header semaphore.

+
+
Classes#
+ + ++++ + + + + + + + + + + + + + +
Table 157 Classes of header hpx/semaphore.hpp#

Class

C++ standard

hpx::binary_semaphore

std::counting_semaphore

hpx::counting_semaphore

std::counting_semaphore

+
+
+
+
hpx/shared_mutex.hpp#
+

The header hpx/shared_mutex.hpp corresponds to the +C++ standard library header shared_mutex.

+
+
Classes#
+ + ++++ + + + + + + + + + + +
Table 158 Classes of header hpx/shared_mutex.hpp#

Class

C++ standard

hpx::shared_mutex

std::shared_mutex

+
+
+
+
hpx/source_location.hpp#
+

The header hpx/source_location.hpp corresponds to the +C++ standard library header source_location.

+
+
Classes#
+ + ++++ + + + + + + + + + + +
Table 159 Classes of header hpx/system_error.hpp#

Class

C++ standard

hpx::source_location

std::source_location

+
+
+
+
hpx/stop_token.hpp#
+

The header hpx/stop_token.hpp corresponds to the +C++ standard library header stop_token.

+
+
Constants#
+ + ++++ + + + + + + + + + + +
Table 160 Constants of header hpx/stop_token.hpp#

Constant

C++ standard

hpx::nostopstate

std::nostopstate

+
+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + + + + +
Table 161 Classes of header hpx/stop_token.hpp#

Class

C++ standard

hpx::stop_callback

std::stop_callback

hpx::stop_source

std::stop_source

hpx::stop_token

std::stop_token

hpx::nostopstate_t

std::nostopstate_t

+
+
+
+
hpx/system_error.hpp#
+

The header hpx/system_error.hpp corresponds to the +C++ standard library header system_error.

+
+
Classes#
+ + ++++ + + + + + + + + + + +
Table 162 Classes of header hpx/system_error.hpp#

Class

C++ standard

hpx::error_code

std::error_code

+
+
+
+
hpx/task_block.hpp#
+

The header hpx/task_block.hpp corresponds to the +task_block feature in N4755. See using_task_block for more details on using task +blocks.

+
+
Classes#
+ + +++ + + + + + + + + + + +
Table 163 Classes of header hpx/task_block.hpp#

Class

hpx::experimental::task_canceled_exception

hpx::experimental::task_block

+
+
+
Functions#
+ + +++ + + + + + + + + + + +
Table 164 Functions of header hpx/task_block.hpp#

Function

hpx::experimental::define_task_block

hpx::experimental::define_task_block_restore_thread

+
+
+
+
hpx/experimental/task_group.hpp#
+

The header hpx/experimental/task_group.hpp +corresponds to the task_group feature in oneAPI Threading Building Blocks (oneTBB).

+
+
Classes#
+ + +++ + + + + + + + + +
Table 165 Classes of header hpx/experimental/task_group.hpp#

Class

hpx::experimental::task_group

+
+
+
+
hpx/thread.hpp#
+

The header hpx/thread.hpp corresponds to the +C++ standard library header thread. The functionality in this header is +equivalent to the standard library thread functionality, with the exception that the HPX +equivalents are implemented on top of lightweight threads and the HPX runtime.

+
+
Classes#
+ + ++++ + + + + + + + + + + + + + +
Table 166 Classes of header hpx/thread.hpp#

Class

C++ standard

hpx::thread

std::thread

hpx::jthread

std::jthread

+
+
+
Functions#
+ + ++++ + + + + + + + + + + + + + + + + + + + +
Table 167 Functions of header hpx/thread.hpp#

Function

C++ standard

hpx::this_thread::yield

std::yield

hpx::this_thread::get_id

std::get_id

hpx::this_thread::sleep_for

std::sleep_for

hpx::this_thread::sleep_until

std::sleep_until

+
+
+
+
hpx/tuple.hpp#
+

The header hpx/tuple.hpp corresponds to the +C++ standard library header tuple. hpx::tuple can be used in +CUDA device code, unlike std::tuple.

+
+
Constants#
+ + ++++ + + + + + + + + + + +
Table 168 Constants of header hpx/tuple.hpp#

Constant

C++ standard

hpx::ignore

std::ignore

+
+
+
Classes#
+ + ++++ + + + + + + + + + + + + + + + + +
Table 169 Classes of header hpx/tuple.hpp#

Class

C++ standard

hpx::tuple

std::tuple

hpx::tuple_size

std::tuple_size

hpx::tuple_element

std::tuple_element

+
+
+
Functions#
+ + ++++ + + + + + + + + + + + + + + + + + + + + + + +
Table 170 Functions of header hpx/tuple.hpp#

Function

C++ standard

hpx::make_tuple

std::tuple_element

hpx::tie

std::tie

hpx::forward_as_tuple

std::forward_as_tuple

hpx::tuple_cat

std::tuple_cat

hpx::get

std::get

+
+
+
+
hpx/type_traits.hpp#
+

The header hpx/type_traits.hpp corresponds to the +C++ standard library header type_traits.

+
+
Classes#
+ + ++++ + + + + + + + + + + + + + +
Table 171 Classes of header hpx/type_traits.hpp#

Class

C++ standard

hpx::is_invocable

std::is_invocable

hpx::is_invocable_r

std::is_invocable

+
+
+
+
hpx/unwrap.hpp#
+

The header hpx/unwrap.hpp contains utilities for +unwrapping futures.

+
+
Classes#
+ + +++ + + + + + + + + + + + + +
Table 172 Classes of header hpx/unwrap.hpp#

Class

hpx::functional::unwrap

hpx::functional::unwrap_n

hpx::functional::unwrap_all

+
+
+
Functions#
+ + +++ + + + + + + + + + + + + + + + + + + +
Table 173 Functions of header hpx/unwrap.hpp#

Function

hpx::unwrap

hpx::unwrap_n

hpx::unwrap_all

hpx::unwrapping

hpx::unwrapping_n

hpx::unwrapping_all

+
+
+
+
hpx/version.hpp#
+

The header hpx/version.hpp provides version information +about HPX.

+
+
Macros#
+ + +++ + + + + + + + + + + + + + + + + + + + + +
Table 174 Macros of header hpx/version.hpp#

Macro

HPX_VERSION_MAJOR

HPX_VERSION_MINOR

HPX_VERSION_SUBMINOR

HPX_VERSION_FULL

HPX_VERSION_DATE

HPX_VERSION_TAG

HPX_AGAS_VERSION

+
+
+
Functions#
+ + +++ + + + + + + + + + + + + + + + + + + + + + + + + +
Table 175 Functions of header hpx/version.hpp#

Function

hpx::major_version

hpx::minor_version

hpx::subminor_version

hpx::full_version

hpx::full_version_as_string

hpx::tag

hpx::agas_version

hpx::build_type

hpx::build_date_time

+
+
+
+
hpx/wrap_main.hpp#
+

The header hpx/wrap_main.hpp does not provide any direct functionality +but is used for implicitly using main as the runtime entry point. See Re-use the main() function as the main HPX entry point for more +details on implicitly starting the HPX runtime.

+
+
+
+
+
+

Public distributed API#

+

Our Public Distributed API offers a rich set of tools and functions that enable developers +to harness the full potential of distributed computing. Here, you’ll find a comprehensive +list of header files, classes and functions for various distributed computing features +provided by HPX.

+
+
hpx/barrier.hpp#
+

The header hpx/barrier.hpp includes +a distributed barrier implementation. For information regarding the C++ standard +library header barrier, see Public API.

+
+
Classes#
+ + +++ + + + + + + + + +
Table 176 Distributed implementation of classes of header hpx/barrier.hpp#

Class

hpx::distributed::barrier

+
+
+
Functions#
+ + +++ + + + + + + + + + + +
Table 177 hpx functions of header hpx/barrier.hpp#

Function

hpx::distributed::wait

hpx::distributed::synchronize

+
+
+
+
hpx/collectives.hpp#
+

The header hpx/collectives.hpp +contains definitions and implementations related to the collectives operations.

+
+
Classes#
+ + +++ + + + + + + + + + + + + + + + + + + + + + + + + +
Table 178 hpx classes of header hpx/collectives.hpp#

Class

hpx::collectives::num_sites_arg

hpx::collectives::this_site_arg

hpx::collectives::that_site_arg

hpx::collectives::generation_arg

hpx::collectives::root_site_arg

hpx::collectives::tag_arg

hpx::collectives::arity_arg

hpx::collectives::communicator

hpx::collectives::channel_communicator

+
+
+
Functions#
+ + +++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 179 hpx functions of header hpx/collectives.hpp#

Function

hpx::collectives::all_gather

hpx::collectives::all_reduce

hpx::collectives::all_to_all

hpx::collectives::broadcast_to

hpx::collectives::broadcast_from

hpx::collectives::create_channel_communicator

hpx::collectives::set

hpx::collectives::get

hpx::collectives::create_communication_set

hpx::collectives::create_communicator

hpx::collectives::create_local_communicator

hpx::collectives::communicator::set_info

hpx::collectives::communicator::get_info

hpx::collectives::communicator::is_root

hpx::collectives::exclusive_scan

hpx::collectives::gather_here

hpx::collectives::gather_there

hpx::collectives::inclusive_scan

hpx::collectives::reduce_here

hpx::collectives::reduce_there

hpx::collectives::scatter_from

hpx::collectives::scatter_to

+
+
+
+
hpx/latch.hpp#
+

The header hpx/latch.hpp includes +a distributed latch implementation. For information regarding the C++ standard +library header latch, see Public API.

+
+
Classes#
+ + +++ + + + + + + + + +
Table 180 Distributed implementation of classes of header hpx/latch.hpp#

Class

hpx::distributed::latch

+
+Member functions# + + +++ + + + + + + + + + + + + + + + + + + +
Table 181 hpx functions of class hpx::distributed::latch from header hpx/latch.hpp#

Function

hpx::distributed::latch::count_down_and_wait

hpx::distributed::latch::arrive_and_wait

hpx::distributed::latch::count_down

hpx::distributed::latch::is_ready

hpx::distributed::latch::try_wait

hpx::distributed::latch::wait

+
+
+
+
+
hpx/async.hpp#
+

The header hpx/async.hpp +includes distributed implementations of hpx::async, +hpx::post, hpx::sync, and hpx::dataflow. +For information regarding the C++ standard library header, see Public API.

+
+
Functions#
+ + +++ + + + + + + + + + + + + + + +
Table 182 Distributed implementation of functions of header hpx/async.hpp#

Functions

hpx::async (distributed)

hpx::sync (distributed)

hpx::post (distributed)

hpx::dataflow (distributed)

+
+
+
+
hpx/components.hpp#
+

The header hpx/include/components.hpp +includes the components implementation. A component in hpx is a C++ class +which can be created remotely and for which its member functions can be invoked +remotely as well. More information about how components can be defined, +created, and used can be found in Writing components. Components and actions +includes examples on the accumulator, template accumulator and template function +accumulator.

+
+
Macros#
+ + +++ + + + + + + + + + + + + + + + + + + + + +
Table 183 hpx macros of header hpx/components.hpp#

Macro

HPX_DEFINE_COMPONENT_ACTION

HPX_REGISTER_ACTION_DECLARATION

HPX_REGISTER_ACTION

HPX_REGISTER_COMMANDLINE_MODULE

HPX_REGISTER_COMPONENT

HPX_REGISTER_COMPONENT_MODULE

HPX_REGISTER_STARTUP_MODULE

+
+
+
Classes#
+ + +++ + + + + + + + + + + + + + + + + +
Table 184 hpx classes of header hpx/components.hpp#

Class

hpx::components::client

hpx::components::client_base

hpx::components::component

hpx::components::component_base

hpx::components::component_commandline_base

+
+
+
Functions#
+ + +++ + + + + + + + + +
Table 185 hpx functions of header hpx/components.hpp#

Function

hpx::new_

+
+
+
+
+
+
+

Full API#

+

The full API of HPX is presented below. The listings for the public API above +refer to the full documentation below.

+
+

Note

+

Most names listed in the full API reference are implementation details or +considered unstable. They are listed mostly for completeness. If there is a +particular feature you think deserves being in the public API we may consider +promoting it. In general we prioritize making sure features corresponding to +C++ standard library features are stable and complete.

+
+
+
+
algorithms#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::experimental::task_canceled_exception, hpx::experimental::task_block, hpx::experimental::define_task_block, hpx::experimental::define_task_block_restore_thread#
+

Defined in header hpx/task_block.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace experimental
+

Top-level namespace.

+
+

Functions

+
+
+template<typename ExPolicy, typename F>
decltype(auto) define_task_block(ExPolicy &&policy, F &&f)#
+

Constructs a task_block, tr, using the given execution policy policy,and invokes the expression f(tr) on the user-provided object, f.

+

+Postcondition: All tasks spawned from f have finished execution. A call to define_task_block may return on a different thread than that on which it was called.

+
+

Note

+

It is expected (but not mandated) that f will (directly or indirectly) call tr.run(callable_object).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the task block may be parallelized.

  • +
  • F – The type of the user defined function to invoke inside the define_task_block (deduced). F shall be MoveConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • f – The user defined function to invoke inside the task block. Given an lvalue tr of type task_block, the expression, (void)f(tr), shall be well-formed.

  • +
+
+
Throws
+

exception_list – specified in Exception Handling.

+
+
+
+ +
+
+template<typename F>
void define_task_block(F &&f)#
+

Constructs a task_block, tr, and invokes the expression f(tr) on the user-provided object, f. This version uses parallel_policy for task scheduling.

+

+Postcondition: All tasks spawned from f have finished execution. A call to define_task_block may return on a different thread than that on which it was called.

+
+

Note

+

It is expected (but not mandated) that f will (directly or indirectly) call tr.run(callable_object).

+
+
+
Template Parameters
+

F – The type of the user defined function to invoke inside the define_task_block (deduced). F shall be MoveConstructible.

+
+
Parameters
+

f – The user defined function to invoke inside the task block. Given an lvalue tr of type task_block, the expression, (void)f(tr), shall be well-formed.

+
+
Throws
+

exception_list – specified in Exception Handling.

+
+
+
+ +
+
+template<typename ExPolicy, typename F>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> define_task_block_restore_thread(ExPolicy &&policy, F &&f)#
+

Constructs a task_block, tr, and invokes the expression f(tr) on the user-provided object, f.

+

+Postcondition: All tasks spawned from f have finished execution. A call to define_task_block_restore_thread always returns on the same thread as that on which it was called.

+
+

Note

+

It is expected (but not mandated) that f will (directly or indirectly) call tr.run(callable_object).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the task block may be parallelized.

  • +
  • F – The type of the user defined function to invoke inside the define_task_block (deduced). F shall be MoveConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • f – The user defined function to invoke inside the define_task_block. Given an lvalue tr of type task_block, the expression, (void)f(tr), shall be well-formed.

  • +
+
+
Throws
+

exception_list – specified in Exception Handling.

+
+
+
+ +
+
+template<typename F>
void define_task_block_restore_thread(F &&f)#
+

Constructs a task_block, tr, and invokes the expression f(tr) on the user-provided object, f. This version uses parallel_policy for task scheduling.

+

+Postcondition: All tasks spawned from f have finished execution. A call to define_task_block_restore_thread always returns on the same thread as that on which it was called.

+
+

Note

+

It is expected (but not mandated) that f will (directly or indirectly) call tr.run(callable_object).

+
+
+
Template Parameters
+

F – The type of the user defined function to invoke inside the define_task_block (deduced). F shall be MoveConstructible.

+
+
Parameters
+

f – The user defined function to invoke inside the define_task_block. Given an lvalue tr of type task_block, the expression, (void)f(tr), shall be well-formed.

+
+
Throws
+

exception_list – specified in Exception Handling.

+
+
+
+ +
+
+
+template<typename ExPolicy = hpx::execution::parallel_policy>
class task_block#
+
+#include <task_block.hpp>
+

The class task_block defines an interface for forking and joining parallel tasks. The define_task_block and define_task_block_restore_thread function templates create an object of type task_block and pass a reference to that object to a user-provided callable object.

+

An object of class task_block cannot be constructed, destroyed, copied, or moved except by the implementation of the task region library. Taking the address of a task_block object via operator& or addressof is ill formed. The result of obtaining its address by any other means is unspecified.

+

A task_block

is active if it was created by the nearest enclosing task block, where “task block” refers to an invocation of define_task_block or define_task_block_restore_thread and “nearest

+

enclosing” means the most recent invocation that has not yet completed. Code designated for execution in another thread by means other than the facilities in this section (e.g., using thread or async) are not enclosed in the task region and a

+task_block passed to (or captured by) such code is not active within that code. Performing any operation on a task_block that is not active results in undefined behavior.

+

The task_block that is active before a specific call to the run member function is not active within the asynchronous function that invoked run. (The invoked function should not, therefore, capture the task_block from the surrounding block.)

+

Example:
+   define_task_block([&](auto& tr) {
+       tr.run([&] {
+           tr.run([] { f(); });              // Error: tr is not active
+           define_task_block([&](auto& tr) { // Nested task block
+               tr.run(f);                    // OK: inner tr is active
+               /// ...
+           });
+       }); /// ...
+   });
+
+
+

+
+
Template Parameters
+

ExPolicy – The execution policy an instance of a task_block was created with. This defaults to parallel_policy.

+
+
+
+

Public Types

+
+
+using execution_policy = ExPolicy#
+

Refers to the type of the execution policy used to create the task_block.

+
+ +
+
+

Public Functions

+
+
+inline constexpr execution_policy const &get_execution_policy() const noexcept#
+

Return the execution policy instance used to create this task_block

+
+ +
+
+template<typename F, typename ...Ts>
inline void run(F &&f, Ts&&... ts)#
+

Causes the expression f() to be invoked asynchronously. The invocation of f is permitted to run on an unspecified thread in an unordered fashion relative to the sequence of operations following the call to run(f) (the continuation), or indeterminately sequenced within the same thread as the continuation.

+

The call to run synchronizes with the invocation of f. The completion of f() synchronizes with the next invocation of wait on the same task_block or completion of the nearest enclosing task block (i.e., the define_task_block or define_task_block_restore_thread that created this task block).

+

Requires: F shall be MoveConstructible. The expression, (void)f(), shall be well-formed.

+

Precondition: this shall be the active task_block.

+

Postconditions: A call to run may return on a different thread than that on which it was called.

+
+

Note

+

The call to run is sequenced before the continuation as if run returns on the same thread. The invocation of the user-supplied callable object f may be immediate or may be delayed until compute resources are available. run might or might not return before invocation of f completes.

+
+
+
Throws
+

task_canceled_exception – described in Exception Handling.

+
+
+
+ +
+
+template<typename Executor, typename F, typename ...Ts>
inline void run(Executor &&exec, F &&f, Ts&&... ts)#
+

Causes the expression f() to be invoked asynchronously using the given executor. The invocation of f is permitted to run on an unspecified thread associated with the given executor and in an unordered fashion relative to the sequence of operations following the call to run(exec, f) (the continuation), or indeterminately sequenced within the same thread as the continuation.

+

The call to run synchronizes with the invocation of f. The completion of f() synchronizes with the next invocation of wait on the same task_block or completion of the nearest enclosing task block (i.e., the define_task_block or define_task_block_restore_thread that created this task block).

+

Requires: Executor shall be a type modeling the Executor concept. F shall be MoveConstructible. The expression, (void)f(), shall be well-formed.

+

Precondition: this shall be the active task_block.

+

Postconditions: A call to run may return on a different thread than that on which it was called.

+
+

Note

+

The call to run is sequenced before the continuation as if run returns on the same thread. The invocation of the user-supplied callable object f may be immediate or may be delayed until compute resources are available. run might or might not return before invocation of f completes.

+
+
+
Throws
+

task_canceled_exception – described in Exception Handling. The function will also throw an exception_list holding all exceptions that were caught while executing the tasks.

+
+
+
+ +
+
+inline void wait()#
+

Blocks until the tasks spawned using this task_block have finished.

+

Precondition: this shall be the active task_block.

+

Postcondition: All tasks spawned by the nearest enclosing task region have finished. A call to wait may return on a different thread than that on which it was called.

+

Example:
+   define_task_block([&](auto& tr) {
+       tr.run([&]{ process(a, w, x); }); // Process a[w] through a[x]
+       if (y < x) tr.wait();   // Wait if overlap between [w, x) and [y, z)
+       process(a, y, z);       // Process a[y] through a[z]
+   });
+
+
+

+
+

Note

+

The call to wait is sequenced before the continuation as if wait returns on the same thread.

+
+
+
Throws
+

This – function may throw task_canceled_exception, as described in Exception Handling. The function will also throw a exception_list holding all exceptions that were caught while executing the tasks.

+
+
+
+ +
+
+inline ExPolicy &policy() noexcept#
+

Returns a reference to the execution policy used to construct this object.

+

Precondition: this shall be the active task_block.

+
+ +
+
+inline constexpr ExPolicy const &policy() const noexcept#
+

Returns a reference to the execution policy used to construct this object.

+

Precondition: this shall be the active task_block.

+
+ +
+
+

Private Members

+
+
+hpx::experimental::task_group tasks_#
+
+ +
+
+threads::thread_id_type id_#
+
+ +
+
+ExPolicy policy_#
+
+ +
+
+ +
+
+class task_canceled_exception : public exception#
+
+#include <task_block.hpp>
+

The class task_canceled_exception defines the type of objects thrown by task_block::run or task_block::wait if they detect that an exception is pending within the current parallel region.

+
+

Public Functions

+
+
+inline task_canceled_exception() noexcept#
+
+ +
+
+ +
+ +
+
+namespace parallel
+
+

Typedefs

+
+
+typedef hpx::experimental::task_canceled_exception instead#
+
+ +
+
+

Functions

+
+
+template<typename ExPolicy, typename F>  HPX_DEPRECATED_V (1, 9, "hpx::parallel:v2::define_task_block is deprecated, use " "hpx::experimental::define_task_block instead") hpx
+
+ +
+
+template<typename ExPolicy, typename F>  HPX_DEPRECATED_V (1, 9, "hpx::parallel:v2::define_task_block is deprecated, use " "hpx::experimental::define_task_block instead") void define_task_block(ExPolicy &&policy
+
+ +
+
+template<typename F>  HPX_DEPRECATED_V (1, 9, "hpx::parallel:v2::define_task_block is deprecated, use " "hpx::experimental::define_task_block instead") void define_task_block(F &&f)
+
+ +
+
+

Variables

+
+
+F && f  {returnhpx::experimental::define_task_block(policy, f)
+
+ +
+
+ +
+ +
+
+
hpx::experimental::task_group#
+

Defined in header hpx/experimental/task_group.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution#
+
+
+namespace experimental#
+
+

Typedefs

+
+
+using instead = hpx::experimental::task_group#
+
+ +
+
+ +
+ +
+
+namespace experimental
+

Top-level namespace.

+
+
+class task_group#
+
+#include <task_group.hpp>
+

A task_group represents concurrent execution of a group of tasks. Tasks can be dynamically added to the group while it is executing.

+
+

Public Functions

+
+
+task_group()#
+
+ +
+
+~task_group()#
+
+ +
+
+task_group(task_group const&) = delete#
+
+ +
+
+task_group(task_group&&) = delete#
+
+ +
+
+task_group &operator=(task_group const&) = delete#
+
+ +
+
+task_group &operator=(task_group&&) = delete#
+
+ +
+
+template<typename Executor, typename F, typename ...Ts>
inline void run(Executor &&exec, F &&f, Ts&&... ts)#
+

Adds a task to compute f() and returns immediately.

+
+
Template Parameters
+
    +
  • Executor – The type of the executor to associate with this execution policy.

  • +
  • F – The type of the user defined function to invoke.

  • +
  • Ts – The type of additional arguments used to invoke f().

  • +
+
+
Parameters
+
    +
  • exec – The executor to use for the execution of the parallel algorithm the returned execution policy is used with.

  • +
  • f – The user defined function to invoke inside the task group.

  • +
  • ts – Additional arguments to use to invoke f().

  • +
+
+
+
+ +
+
+template<typename F, typename ...Ts>
inline void run(F &&f, Ts&&... ts)#
+

Adds a task to compute f() and returns immediately.

+
+
Template Parameters
+
    +
  • F – The type of the user defined function to invoke.

  • +
  • Ts – The type of additional arguments used to invoke f().

  • +
+
+
Parameters
+
    +
  • f – The user defined function to invoke inside the task group.

  • +
  • ts – Additional arguments to use to invoke f().

  • +
+
+
+
+ +
+
+void wait()#
+

Waits for all tasks in the group to complete or be cancelled.

+
+ +
+
+void add_exception(std::exception_ptr p)#
+

Adds an exception to this task_group.

+
+ +
+
+

Private Types

+
+
+using shared_state_type = lcos::detail::future_data<void>#
+
+ +
+
+

Private Functions

+
+
+void serialize(serialization::output_archive&, unsigned const)#
+
+ +
+
+

Private Members

+
+
+hpx::lcos::local::latch latch_#
+
+ +
+
+hpx::intrusive_ptr<shared_state_type> state_#
+
+ +
+
+hpx::exception_list errors_#
+
+ +
+
+std::atomic<bool> has_arrived_#
+
+ +
+
+

Private Static Functions

+
+
+static inline constexpr void serialize(serialization::input_archive&, unsigned const) noexcept#
+
+ +
+
+

Friends

+
+
+friend class serialization::access
+
+ +
+
+ +
+ +
+ +
+
+
hpx::adjacent_difference#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx#
+
+

Functions

+
+
+template<typename FwdIter1, typename FwdIter2>
FwdIter2 adjacent_difference(FwdIter1 first, FwdIter1 last, FwdIter2 dest)#
+

Assigns each value in the range given by result its corresponding element in the range [first, last] and the one preceding it except *result, which is assigned *first.

+
+

Note

+

Complexity: Exactly (last - first) - 1 application of the binary operator and (last - first) assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the input range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the output range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the sequence of elements the results will be assigned to.

  • +
+
+
Returns
+

The adjacent_difference algorithm returns a FwdIter2. The adjacent_difference algorithm returns an iterator to the element past the last element written.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> adjacent_difference(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest)#
+

Assigns each value in the range given by result its corresponding element in the range [first, last] and the one preceding it except *result, which is assigned *first. Executed according to the policy.

+

+The difference operations in the parallel adjacent_difference invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The difference operations in the parallel adjacent_difference invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly (last - first) - 1 application of the binary operator and (last - first) assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the input range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the output range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the sequence of elements the results will be assigned to.

  • +
+
+
Returns
+

The adjacent_difference algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The adjacent_difference algorithm returns an iterator to the element past the last element written.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename Op>
FwdIter2 adjacent_difference(FwdIter1 first, FwdIter1 last, FwdIter2 dest, Op &&op)#
+

Assigns each value in the range given by result its corresponding element in the range [first, last] and the one preceding it except *result, which is assigned *first

+
+

Note

+

Complexity: Exactly (last - first) - 1 application of the binary operator and (last - first) assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the input range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the output range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Op – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of adjacent_difference requires Op to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the sequence of elements the results will be assigned to.

  • +
  • op – The binary operator which returns the difference of elements. The signature should be equivalent to the following:

    bool op(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter1 can be dereferenced and then implicitly converted to the dereferenced type of dest.

  • +
+
+
Returns
+

The adjacent_difference algorithm returns FwdIter2. The adjacent_difference algorithm returns an iterator to the element past the last element written.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Op>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> adjacent_difference(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Op &&op)#
+

Assigns each value in the range given by result its corresponding element in the range [first, last] and the one preceding it except *result, which is assigned *first

+

+The difference operations in the parallel adjacent_difference invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The difference operations in the parallel adjacent_difference invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly (last - first) - 1 application of the binary operator and (last - first) assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the input range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the output range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Op – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of adjacent_difference requires Op to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the sequence of elements the results will be assigned to.

  • +
  • op – The binary operator which returns the difference of elements. The signature should be equivalent to the following:

    bool op(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter1 can be dereferenced and then implicitly converted to the dereferenced type of dest.

  • +
+
+
Returns
+

The adjacent_difference algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The adjacent_difference algorithm returns an iterator to the element past the last element written.

+
+
+
+ +
+
+ +
+
+
hpx::adjacent_find#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename Pred = hpx::parallel::detail::equal_to>
InIter adjacent_find(InIter first, InIter last, Pred &&pred = Pred())#
+

Searches the range [first, last) for two consecutive identical elements.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Pred – The type of an optional function/function object to use.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • pred – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1 .

  • +
+
+
Returns
+

The adjacent_find algorithm returns an iterator to the first of the identical elements. If no such elements are found, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Pred = hpx::parallel::detail::equal_to>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> adjacent_find(ExPolicy &&policy, FwdIter first, FwdIter last, Pred &&pred = Pred())#
+

Searches the range [first, last) for two consecutive identical elements. This version uses the given binary predicate pred

+

+The comparison operations in the parallel adjacent_find invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel adjacent_find invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+This overload of adjacent_find is available if the user decides to provide their algorithm their own binary predicate pred.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • pred – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1 .

  • +
+
+
Returns
+

The adjacent_find algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The adjacent_find algorithm returns an iterator to the first of the identical elements. If no such elements are found, last is returned.

+
+
+
+ +
+
+ +
+
+
hpx::all_of, hpx::any_of, hpx::none_of#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter, typename F>
util::detail::algorithm_result_t<ExPolicy, bool> none_of(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Checks if unary predicate f returns true for no elements in the range [first, last).

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the predicate f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The none_of algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The none_of algorithm returns true if the unary predicate f returns true for no elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+template<typename InIter, typename F>
bool none_of(InIter first, InIter last, F &&f)#
+

Checks if unary predicate f returns true for no elements in the range [first, last).

+
+

Note

+

Complexity: At most last - first applications of the predicate f

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The none_of algorithm returns a bool . The none_of algorithm returns true if the unary predicate f returns true for no elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename F>
util::detail::algorithm_result_t<ExPolicy, bool> any_of(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Checks if unary predicate f returns true for at least one element in the range [first, last).

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the predicate f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of any_of requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The any_of algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The any_of algorithm returns true if the unary predicate f returns true for at least one element in the range, false otherwise. It returns false if the range is empty.

+
+
+
+ +
+
+template<typename InIter, typename F>
bool any_of(InIter first, InIter last, F &&f)#
+

Checks if unary predicate f returns true for at least one element in the range [first, last).

+
+

Note

+

Complexity: At most last - first applications of the predicate f

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of any_of requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The any_of algorithm returns a bool . The any_of algorithm returns true if the unary predicate f returns true for at least one element in the range, false otherwise. It returns false if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename F>
util::detail::algorithm_result_t<ExPolicy, bool> all_of(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Checks if unary predicate f returns true for all elements in the range [first, last).

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the predicate f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of all_of requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The all_of algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The all_of algorithm returns true if the unary predicate f returns true for all elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename InIter, typename F>
bool all_of(InIter first, InIter last, F &&f)#
+

Checks if unary predicate f returns true for all elements in the range [first, last).

+
+

Note

+

Complexity: At most last - first applications of the predicate f

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of all_of requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The all_of algorithm returns a bool . The all_of algorithm returns true if the unary predicate f returns true for all elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+ +
+
+
hpx::copy, hpx::copy_n, hpx::copy_if#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> copy(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest)#
+

Copies the elements in the range, defined by [first, last), to another range beginning at dest. Executed according to the policy.

+

+The assignments in the parallel copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The copy algorithm returns a hpx::future<FwdIter2> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2> otherwise. The copy algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2>
FwdIter2 copy(FwdIter1 first, FwdIter1 last, FwdIter2 dest)#
+

Copies the elements in the range, defined by [first, last), to another range beginning at dest.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The copy algorithm returns a FwdIter2 . The copy algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Size, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> copy_n(ExPolicy &&policy, FwdIter1 first, Size count, FwdIter2 dest)#
+

Copies the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest. Executed according to the policy.

+

+The assignments in the parallel copy_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel copy_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The copy_n algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The copy_n algorithm returns Iterator in the destination range, pointing past the last element copied if count>0 or result otherwise.

+
+
+
+ +
+
+template<typename FwdIter1, typename Size, typename FwdIter2>
FwdIter2 copy_n(FwdIter1 first, Size count, FwdIter2 dest)#
+

Copies the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The copy_n algorithm returns a FwdIter2 . The copy_n algorithm returns Iterator in the destination range, pointing past the last element copied if count>0 or result otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> copy_if(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Pred &&pred)#
+

Copies the elements in the range, defined by [first, last), to another range beginning at dest. Copies only the elements for which the predicate f returns true. The order of the elements that are not removed is preserved. Executed according to the policy.

+

+The assignments in the parallel copy_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate f.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of copy_if requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The copy_if algorithm returns a hpx::future<FwdIter2> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The copy_if algorithm returns output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename Pred>
FwdIter2 copy_if(FwdIter1 first, FwdIter1 last, FwdIter2 dest, Pred &&pred)#
+

Copies the elements in the range, defined by [first, last), to another range beginning at dest. Copies only the elements for which the predicate f returns true. The order of the elements that are not removed is preserved.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate f.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of copy_if requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The copy_if algorithm returns a FwdIter2 . The copy_if algorithm returns output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::count, hpx::count_if#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter, typename T>
util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<FwdIter>::difference_type>::type count(ExPolicy &&policy, FwdIter first, FwdIter last, T const &value)#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts the elements that are equal to the given value. Executed according to the policy.

+

+The comparisons in the parallel count algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first comparisons.

+
+
+

Note

+

The comparisons in the parallel count algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the comparisons.

  • +
  • FwdIter – The type of the source iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to search for (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to search for.

  • +
+
+
Returns
+

The count algorithm returns a hpx::future<difference_type> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by std::iterator_traits<FwdIterB>::difference_type. The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+template<typename InIter, typename T>
std::iterator_traits<InIter>::difference_type count(InIter first, InIter last, T const &value)#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts the elements that are equal to the given value.

+
+

Note

+

Complexity: Performs exactly last - first comparisons.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterator used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to search for (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to search for.

  • +
+
+
Returns
+

The count algorithm returns a difference_type (where difference_type is defined by std::iterator_traits<InIter>::difference_type. The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename F>
util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<FwdIter>::difference_type>::type count_if(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts elements for which predicate f returns true. Executed according to the policy.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+

Note

+

The assignments in the parallel count_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+
+
+

Note

+

The assignments in the parallel count_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the comparisons.

  • +
  • FwdIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of count_if requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The count_if algorithm returns hpx::future<difference_type> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by std::iterator_traits<FwdIter>::difference_type. The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+template<typename InIter, typename F>
std::iterator_traits<InIter>::difference_type count_if(InIter first, InIter last, F &&f)#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts elements for which predicate f returns true.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of count_if requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The count_if algorithm returns difference_type (where a difference_type is defined by std::iterator_traits<InIter>::difference_type. The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+ +
+
+
hpx::destroy, hpx::destroy_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter>
util::detail::algorithm_result_t<ExPolicy> destroy(ExPolicy &&policy, FwdIter first, FwdIter last)#
+

Destroys objects of type typename iterator_traits<ForwardIt>::value_type in the range [first, last). Executed according to the policy.

+

+The operations in the parallel destroy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The operations in the parallel destroy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first operations.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The destroy algorithm returns a hpx::future<void>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename FwdIter>
void destroy(FwdIter first, FwdIter last)#
+

Destroys objects of type typename iterator_traits<ForwardIt>::value_type in the range [first, last).

+
+

Note

+

Complexity: Performs exactly last - first operations.

+
+
+
Template Parameters
+

FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The destroy algorithm returns a void

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size>
util::detail::algorithm_result_t<ExPolicy, FwdIter> destroy_n(ExPolicy &&policy, FwdIter first, Size count)#
+

Destroys objects of type typename iterator_traits<ForwardIt>::value_type in the range [first, first + count). Executed according to the policy.

+

+The operations in the parallel destroy_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The operations in the parallel destroy_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count operations, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply this algorithm to.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The destroy_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The destroy_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+template<typename FwdIter, typename Size>
FwdIter destroy_n(FwdIter first, Size count)#
+

Destroys objects of type typename iterator_traits<ForwardIt>::value_type in the range [first, first + count).

+
+

Note

+

Complexity: Performs exactly count operations, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply this algorithm to.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The destroy_n algorithm returns a FwdIter . The destroy_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+ +
+
+
hpx::ends_with#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter1, typename InIter2, typename Pred>
bool ends_with(InIter1 first1, InIter1 last1, InIter2 first2, InIter2 last2, Pred &&pred)#
+

Checks whether the second range defined by [first1, last1) matches the suffix of the first range defined by [first2, last2)

+

+The assignments in the parallel ends_with algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • InIter1 – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • InIter2 – The type of the begin destination iterators used deduced). This iterator type must meet the requirements of a input iterator.

  • +
  • Pred – The binary predicate that compares the projected elements.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the source range.

  • +
  • last1 – Refers to the end of the source range.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Refers to the end of the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
+
+
Returns
+

The ends_with algorithm returns bool. The ends_with algorithm returns a boolean with the value true if the second range matches the suffix of the first range, false otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred>
hpx::parallel::util::detail::algorithm_result<ExPolicy, bool>::type ends_with(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, Pred &&pred)#
+

Checks whether the second range defined by [first1, last1) matches the suffix of the first range defined by [first2, last2). Executed according to the policy.

+

+The assignments in the parallel ends_with algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel ends_with algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the begin destination iterators used deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The binary predicate that compares the projected elements.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the source range.

  • +
  • last1 – Refers to the end of the source range.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Refers to the end of the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for

  • +
+
+
Returns
+

The ends_with algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The ends_with algorithm returns a boolean with the value true if the second range matches the suffix of the first range, false otherwise.

+
+
+
+ +
+
+ +
+
+
hpx::equal#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred = detail::equal_to>
util::detail::algorithm_result_t<ExPolicy, bool> equal(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, Pred &&op = Pred())#
+

Returns true if the range [first1, last1) is equal to the range [first2, last2), and false otherwise. Executed according to the policy.

+

+The comparison operations in the parallel equal algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel equal algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(min(last1 - first1, last2 - first2)) applications of the predicate op.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The equal algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false. If the length of the range [first1, last1) does not equal the length of the range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
util::detail::algorithm_result_t<ExPolicy, bool> equal(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2)#
+

Returns true if the range [first1, last1) is equal to the range [first2, last2), and false otherwise. Executed according to policy.

+

+The comparison operations in the parallel equal algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel equal algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(min(last1 - first1, last2 - first2)) applications of the predicate std::equal_to.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The equal algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false. If the length of the range [first1, last1) does not equal the length of the range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred = detail::equal_to>
util::detail::algorithm_result_t<ExPolicy, bool> equal(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, Pred &&op = Pred())#
+

Returns true if the range [first1, last1) is equal to the range starting at first2, and false otherwise. Executed according to policy.

+

+The comparison operations in the parallel equal algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel equal algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(min(last1 - first1, last2 - first2)) applications of the predicate op.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The equal algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
util::detail::algorithm_result_t<ExPolicy, bool> equal(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2)#
+

Returns true if the range [first1, last1) is equal to the range [first2, last2), and false otherwise. Executed according to policy.

+

+The comparison operations in the parallel equal algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel equal algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last1 - first1 applications of the predicate op.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The equal algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false. If the length of the range [first1, last1) does not equal the length of the range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename Pred = detail::equal_to>
bool equal(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, Pred &&op = Pred())#
+

Returns true if the range [first1, last1) is equal to the range [first2, last2), and false otherwise.

+
+

Note

+

Complexity: At most min(last1 - first1, last2 - first2) applications of the predicate op.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The equal algorithm returns a bool . The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false. If the length of the range [first1, last1) does not equal the length of the range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2>
bool equal(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2)#
+

Returns true if the range [first1, last1) is equal to the range [first2, last2), and false otherwise.

+
+

Note

+

Complexity: At most min(last1 - first1, last2 - first2) applications of the predicate std::equal_to.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The equal algorithm returns a bool . The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false. If the length of the range [first1, last1) does not equal the length of the range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename Pred = detail::equal_to>
bool equal(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, Pred &&op = Pred())#
+

Returns true if the range [first1, last1) is equal to the range [first2, first2 + (last1 - first1)), and false otherwise.

+
+

Note

+

Complexity: At most last1 - first1 applications of the predicate op.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The equal algorithm returns a bool . The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false. If the length of the range [first1, last1) does not equal the length of the range [first2, last2), it returns false.

+
+
+
+ +
+
+ +
+
+
hpx::exclusive_scan#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename OutIter, typename T>
OutIter exclusive_scan(InIter first, InIter last, OutIter dest, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(+, init, *first, …, *(first + (i - result) - 1))

+

+The reduce operations in the parallel exclusive_scan algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate std::plus<T>.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The exclusive_scan algorithm returns OutIter. The exclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename T>
util::detail::algorithm_result_t<ExPolicy, FwdIter2> exclusive_scan(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(+, init, *first, …, *(first + (i - result) - 1))

+

+The reduce operations in the parallel exclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel exclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate std::plus<T>.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The exclusive_scan algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The exclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename InIter, typename OutIter, typename T, typename Op>
OutIter exclusive_scan(InIter first, InIter last, OutIter dest, T init, Op &&op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, *first, …, *(first + (i - result) - 1)).

+

+The reduce operations in the parallel exclusive_scan algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum. If op is not mathematically associative, the behavior of inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The exclusive_scan algorithm returns OutIter. The exclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Op, typename T>
util::detail::algorithm_result_t<ExPolicy, FwdIter2> exclusive_scan(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, T init, Op &&op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, *first, …, *(first + (i - result) - 1)).

+

+The reduce operations in the parallel exclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel exclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum. If op is not mathematically associative, the behavior of inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The exclusive_scan algorithm returns a hpx::future<OutIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns OutIter otherwise. The exclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::fill, hpx::fill_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter, typename T>
util::detail::algorithm_result_t<ExPolicy> fill(ExPolicy &&policy, FwdIter first, FwdIter last, T value)#
+

Assigns the given value to the elements in the range [first, last). Executed according to the policy.

+

+The comparisons in the parallel fill algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel fill algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by void.

+
+
+
+ +
+
+template<typename FwdIter, typename T>
void fill(FwdIter first, FwdIter last, T value)#
+

Assigns the given value to the elements in the range [first, last).

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill algorithm returns a void.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size, typename T>
util::detail::algorithm_result_t<ExPolicy, FwdIter> fill_n(ExPolicy &&policy, FwdIter first, Size count, T value)#
+

Assigns the given value value to the first count elements in the range beginning at first if count > 0. Does nothing otherwise. Executed according to the policy.

+

+The comparisons in the parallel fill_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel fill_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, for count > 0.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill_n algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by void.

+
+
+
+ +
+
+template<typename FwdIter, typename Size, typename T>
FwdIter fill_n(FwdIter first, Size count, T value)#
+

Assigns the given value value to the first count elements in the range beginning at first if count > 0. Does nothing otherwise.

+
+

Note

+

Complexity: Performs exactly count assignments, for count > 0.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill_n algorithm returns a FwdIter.

+
+
+
+ +
+
+ +
+
+
hpx::find, hpx::find_if, hpx::find_if_not, hpx::find_end, hpx::find_first_of#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter, typename T>
util::detail::algorithm_result_t<ExPolicy, FwdIter> find(ExPolicy &&policy, FwdIter first, FwdIter last, T const &val)#
+

Returns the first element in the range [first, last) that is equal to value. Executed according to the policy.

+

+The comparison operations in the parallel find algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the operator==().

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to find (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • val – the value to compare the elements to

  • +
+
+
Returns
+

The find algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find algorithm returns the first element in the range [first,last) that is equal to val. If no such element in the range of [first,last) is equal to val, then the algorithm returns last.

+
+
+
+ +
+
+template<typename InIter, typename T>
InIter find(InIter first, InIter last, T const &val)#
+

Returns the first element in the range [first, last) that is equal to value. Executed according to the policy.

+
+

Note

+

Complexity: At most last - first applications of the operator==().

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to find (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • val – the value to compare the elements to

  • +
+
+
Returns
+

The find algorithm returns a InIter. The find algorithm returns the first element in the range [first,last) that is equal to val. If no such element in the range of [first,last) is equal to val, then the algorithm returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename F>
util::detail::algorithm_result_t<ExPolicy, FwdIter> find_if(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Returns the first element in the range [first, last) for which predicate f returns true. Executed according to the policy.

+

+The comparison operations in the parallel find_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • f – The unary predicate which returns true for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The find_if algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find_if algorithm returns the first element in the range [first,last) that satisfies the predicate f. If no such element exists that satisfies the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename InIter, typename F>
InIter find_if(InIter first, InIter last, F &&f)#
+

Returns the first element in the range [first, last) for which predicate f returns true.

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • f – The unary predicate which returns true for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type InIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The find_if algorithm returns a InIter. The find_if algorithm returns the first element in the range [first,last) that satisfies the predicate f. If no such element exists that satisfies the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename F>
util::detail::algorithm_result_t<ExPolicy, FwdIter> find_if_not(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Returns the first element in the range [first, last) for which predicate f returns false. Executed according to the policy.

+

+The comparison operations in the parallel find_if_not algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_if_not algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • f – The unary predicate which returns false for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The find_if_not algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find_if_not algorithm returns the first element in the range [first, last) that does not satisfy the predicate f. If no such element exists that does not satisfy the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename FwdIter, typename F>
FwdIter find_if_not(FwdIter first, FwdIter last, F &&f)#
+

Returns the first element in the range [first, last) for which predicate f returns false.

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • f – The unary predicate which returns false for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The find_if_not algorithm returns a FwdIter. The find_if_not algorithm returns the first element in the range [first, last) that does not satisfy the predicate f. If no such element exists that does not satisfy the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred = detail::equal_to>
util::detail::algorithm_result_t<ExPolicy, FwdIter1> find_end(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, Pred &&op = Pred())#
+

Returns the last subsequence of elements [first2, last2) found in the range [first, last) using the given predicate op to compare elements. Executed according to the policy.

+

+The comparison operations in the parallel find_end algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_end algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+This overload of find_end is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most S*(N-S+1) comparisons where S = distance(first2, last2) and N = distance(first1, last1).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of replace requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • last2 – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
+
+
Returns
+

The find_end algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find_end algorithm returns an iterator to the beginning of the last subsequence [first2, last2) in range [first, last). If the length of the subsequence [first2, last2) is greater than the length of the range [first1, last1), last1 is returned. Additionally if the size of the subsequence is empty or no subsequence is found, last1 is also returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
util::detail::algorithm_result_t<ExPolicy, FwdIter1> find_end(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2)#
+

Returns the last subsequence of elements [first2, last2) found in the range [first, last). Elements are compared using operator==. Executed according to the policy.

+

+The comparison operations in the parallel find_end algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_end algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most S*(N-S+1) comparisons where S = distance(first2, last2) and N = distance(first1, last1).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • last2 – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
+
+
Returns
+

The find_end algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find_end algorithm returns an iterator to the beginning of the last subsequence [first2, last2) in range [first, last). If the length of the subsequence [first2, last2) is greater than the length of the range [first1, last1), last1 is returned. Additionally if the size of the subsequence is empty or no subsequence is found, last1 is also returned.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename Pred = detail::equal_to>
FwdIter1 find_end(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, Pred &&op = Pred())#
+

Returns the last subsequence of elements [first2, last2) found in the range [first, last) using the given predicate op to compare elements.

+

+This overload of find_end is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most S*(N-S+1) comparisons where S = distance(first2, last2) and N = distance(first1, last1).

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of replace requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • last2 – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
+
+
Returns
+

The find_end algorithm returns a FwdIter1. The find_end algorithm returns an iterator to the beginning of the last subsequence [first2, last2) in range [first, last). If the length of the subsequence [first2, last2) is greater than the length of the range [first1, last1), last1 is returned. Additionally if the size of the subsequence is empty or no subsequence is found, last1 is also returned.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2>
FwdIter1 find_end(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2)#
+

Returns the last subsequence of elements [first2, last2) found in the range [first, last). Elements are compared using operator==.

+
+

Note

+

Complexity: at most S*(N-S+1) comparisons where S = distance(first2, last2) and N = distance(first1, last1).

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • last2 – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
+
+
Returns
+

The find_end algorithm returns a FwdIter1. The find_end algorithm returns an iterator to the beginning of the last subsequence [first2, last2) in range [first, last). If the length of the subsequence [first2, last2) is greater than the length of the range [first1, last1), last1 is returned. Additionally if the size of the subsequence is empty or no subsequence is found, last1 is also returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred = detail::equal_to>
util::detail::algorithm_result_t<ExPolicy, FwdIter1> find_first_of(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 s_first, FwdIter2 s_last, Pred &&op = Pred())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses binary predicate op to compare elements. Executed according to the policy.

+

+The comparison operations in the parallel find_first_of algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_first_of algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+This overload of find_first_of is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
+
+
Returns
+

The find_first_of algorithm returns a hpx::future<FwdIter1> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter1 otherwise. The find_first_of algorithm returns an iterator to the first element in the range [first, last) that is equal to an element from the range [s_first, s_last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty or no subsequence is found, last is also returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
util::detail::algorithm_result_t<ExPolicy, FwdIter1> find_first_of(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 s_first, FwdIter2 s_last)#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Elements are compared using operator==. Executed according to the policy.

+

+The comparison operations in the parallel find_first_of algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_first_of algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
+
+
Returns
+

The find_first_of algorithm returns a hpx::future<FwdIter1> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter1 otherwise. The find_first_of algorithm returns an iterator to the first element in the range [first, last) that is equal to an element from the range [s_first, s_last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty or no subsequence is found, last is also returned.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename Pred = detail::equal_to>
FwdIter1 find_first_of(FwdIter1 first, FwdIter1 last, FwdIter2 s_first, FwdIter2 s_last, Pred &&op = Pred())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses binary predicate op to compare elements.

+

+This overload of find_first_of is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
+
+
Returns
+

The find_first_of algorithm returns a FwdIter1. The find_first_of algorithm returns an iterator to the first element in the range [first, last) that is equal to an element from the range [s_first, s_last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty or no subsequence is found, last is also returned.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2>
FwdIter1 find_first_of(FwdIter1 first, FwdIter1 last, FwdIter2 s_first, FwdIter2 s_last)#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Elements are compared using operator==.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
+
+
Returns
+

The find_first_of algorithm returns a FwdIter1. The find_first_of algorithm returns an iterator to the first element in the range [first, last) that is equal to an element from the range [s_first, s_last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty or no subsequence is found, last is also returned.

+
+
+
+ +
+
+ +
+
+
hpx::for_each, hpx::for_each_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename F>
F for_each(InIter first, InIter last, F &&f)#
+

Applies f to the result of dereferencing every iterator in the range [first, last).

+

+If f returns a result, the result is ignored.

+

If the type of first satisfies the requirements of a mutable iterator, f may apply non-constant functions through the dereferenced iterator.

+
+

Note

+

Complexity: Applies f exactly last - first times.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source begin and end iterator used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). F must meet requirements of MoveConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    <ignored> pred(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

f.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename F>
util::detail::algorithm_result_t<ExPolicy, void> for_each(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Applies f to the result of dereferencing every iterator in the range [first, last). Executed according to the policy.

+

+If f returns a result, the result is ignored.

+

If the type of first satisfies the requirements of a mutable iterator, f may apply non-constant functions through the dereferenced iterator.

+

Unlike its sequential form, the parallel overload of for_each does not return a copy of its Function parameter, since parallelization may not permit efficient state accumulation.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Applies f exactly last - first times.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter – The type of the source begin and end iterator used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of for_each requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    <ignored> pred(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The for_each algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename InIter, typename Size, typename F>
InIter for_each_n(InIter first, Size count, F &&f)#
+

Applies f to the result of dereferencing every iterator in the range [first, first + count), starting from first and proceeding to first + count - 1.

+

+If f returns a result, the result is ignored.

+

If the type of first satisfies the requirements of a mutable iterator, f may apply non-constant functions through the dereferenced iterator.

+
+

Note

+

Complexity: Applies f exactly count times.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source begin and end iterator used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • F – The type of the function/function object to use (deduced). F must meet requirements of MoveConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    <ignored> pred(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

first + count for non-negative values of count and first for negative values.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size, typename F>
util::detail::algorithm_result_t<ExPolicy, FwdIter> for_each_n(ExPolicy &&policy, FwdIter first, Size count, F &&f)#
+

Applies f to the result of dereferencing every iterator in the range [first, first + count), starting from first and proceeding to first + count - 1. Executed according to the policy.

+

+If f returns a result, the result is ignored.

+

If the type of first satisfies the requirements of a mutable iterator, f may apply non-constant functions through the dereferenced iterator.

+

Unlike its sequential form, the parallel overload of for_each_n does not return a copy of its Function parameter, since parallelization may not permit efficient state accumulation.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Applies f exactly count times.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of for_each_n requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    <ignored> pred(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The for_each_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. It returns first + count for non-negative values of count and first for negative values.

+
+
+
+ +
+
+ +
+
+
hpx::experimental::for_loop, hpx::experimental::for_loop_strided, hpx::experimental::for_loop_n, hpx::experimental::for_loop_n_strided#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace experimental#
+

Top-level namespace.

+
+

Functions

+
+
+template<typename I, typename ...Args>
void for_loop(std::decay_t<I> first, I last, Args&&... args)#
+

The for_loop implements loop functionality over a range specified by integral or iterator bounds. For the iterator case, these algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

The execution of for_loop without specifying an execution policy is equivalent to specifying hpx::execution::seq as the execution policy.

+

+Requires: I shall be an integral type or meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • I – The type of the iteration variable. This could be an (forward) iterator type or an integral type.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(I const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
+
+ +
+
+template<typename ExPolicy, typename I, typename ...Args>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> for_loop(ExPolicy &&policy, std::decay_t<I> first, I last, Args&&... args)#
+

The for_loop implements loop functionality over a range specified by integral or iterator bounds. For the iterator case, these algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator. Executed according to the policy.

+

+Requires: I shall be an integral type or meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • I – The type of the iteration variable. This could be an (forward) iterator type or an integral type.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(I const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
Returns
+

The for_loop algorithm returns a hpx::future<void> if the execution policy is of type hpx::execution::sequenced_task_policy or hpx::execution::parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename I, typename S, typename ...Args>
void for_loop_strided(std::decay_t<I> first, I last, S stride, Args&&... args)#
+

The for_loop_strided implements loop functionality over a range specified by integral or iterator bounds. For the iterator case, these algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

The execution of for_loop without specifying an execution policy is equivalent to specifying hpx::execution::seq as the execution policy.

+

+Requires: I shall be an integral type or meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • I – The type of the iteration variable. This could be an (forward) iterator type or an integral type.

  • +
  • S – The type of the stride variable. This should be an integral type.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • stride – Refers to the stride of the iteration steps. This shall have non-zero value and shall be negative only if I has integral type or meets the requirements of a bidirectional iterator.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(I const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
+
+ +
+
+template<typename ExPolicy, typename I, typename S, typename ...Args>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> for_loop_strided(ExPolicy &&policy, std::decay_t<I> first, I last, S stride, Args&&... args)#
+

The for_loop_strided implements loop functionality over a range specified by integral or iterator bounds. For the iterator case, these algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator. Executed according to the policy.

+

+Requires: I shall be an integral type or meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • I – The type of the iteration variable. This could be an (forward) iterator type or an integral type.

  • +
  • S – The type of the stride variable. This should be an integral type.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • stride – Refers to the stride of the iteration steps. This shall have non-zero value and shall be negative only if I has integral type or meets the requirements of a bidirectional iterator.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(I const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
Returns
+

The for_loop_strided algorithm returns a hpx::future<void> if the execution policy is of type hpx::execution::sequenced_task_policy or hpx::execution::parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename I, typename Size, typename ...Args>
void for_loop_n(I first, Size size, Args&&... args)#
+

The for_loop_n implements loop functionality over a range specified by integral or iterator bounds. For the iterator case, these algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

The execution of for_loop_n without specifying an execution policy is equivalent to specifying hpx::execution::seq as the execution policy.

+

+Requires: I shall be an integral type or meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • I – The type of the iteration variable. This could be an (forward) iterator type or an integral type.

  • +
  • Size – The type of a non-negative integral value specifying the number of items to iterate over.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • size – Refers to the number of items the algorithm will be applied to.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(I const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
+
+ +
+
+template<typename ExPolicy, typename I, typename Size, typename ...Args>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> for_loop_n(ExPolicy &&policy, I first, Size size, Args&&... args)#
+

The for_loop_n implements loop functionality over a range specified by integral or iterator bounds. For the iterator case, these algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator. Executed according to the policy.

+

+Requires: I shall be an integral type or meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • I – The type of the iteration variable. This could be an (forward) iterator type or an integral type.

  • +
  • Size – The type of a non-negative integral value specifying the number of items to iterate over.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • size – Refers to the number of items the algorithm will be applied to.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(I const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
Returns
+

The for_loop_n algorithm returns a hpx::future<void> if the execution policy is of type hpx::execution::sequenced_task_policy or hpx::execution::parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename I, typename Size, typename S, typename ...Args>
void for_loop_n_strided(I first, Size size, S stride, Args&&... args)#
+

The for_loop_n_strided implements loop functionality over a range specified by integral or iterator bounds. For the iterator case, these algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

The execution of for_loop without specifying an execution policy is equivalent to specifying hpx::execution::seq as the execution policy.

+

+Requires: I shall be an integral type or meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • I – The type of the iteration variable. This could be an (forward) iterator type or an integral type.

  • +
  • Size – The type of a non-negative integral value specifying the number of items to iterate over.

  • +
  • S – The type of the stride variable. This should be an integral type.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • size – Refers to the number of items the algorithm will be applied to.

  • +
  • stride – Refers to the stride of the iteration steps. This shall have non-zero value and shall be negative only if I has integral type or meets the requirements of a bidirectional iterator.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(I const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
+
+ +
+
+template<typename ExPolicy, typename I, typename Size, typename S, typename ...Args>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> for_loop_n_strided(ExPolicy &&policy, I first, Size size, S stride, Args&&... args)#
+

The for_loop_n_strided implements loop functionality over a range specified by integral or iterator bounds. For the iterator case, these algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator. Executed according to the policy.

+

+Requires: I shall be an integral type or meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • I – The type of the iteration variable. This could be an (forward) iterator type or an integral type.

  • +
  • Size – The type of a non-negative integral value specifying the number of items to iterate over.

  • +
  • S – The type of the stride variable. This should be an integral type.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • size – Refers to the number of items the algorithm will be applied to.

  • +
  • stride – Refers to the stride of the iteration steps. This shall have non-zero value and shall be negative only if I has integral type or meets the requirements of a bidirectional iterator.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(I const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
Returns
+

The for_loop_n_strided algorithm returns a hpx::future<void> if the execution policy is of type hpx::execution::sequenced_task_policy or hpx::execution::parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::experimental::induction#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace experimental
+

Top-level namespace.

+
+

Functions

+
+
+template<typename T>
constexpr hpx::parallel::detail::induction_stride_helper<T> induction(T &&value, std::size_t stride)#
+

The function template returns an induction object of unspecified type having a value type and encapsulating an initial value value of that type and, optionally, a stride.

+

For each element in the input range, a looping algorithm over input sequence S computes an induction value from an induction variable and ordinal position p within S by the formula i + p * stride if a stride was specified or i + p otherwise. This induction value is passed to the element access function.

+

If the value argument to induction is a non-const lvalue, then that lvalue becomes the live-out object for the returned induction object. For each induction object that has a live-out object, the looping algorithm assigns the value of i + n * stride to the live-out object upon return, where n is the number of elements in the input range.

+
+
Template Parameters
+

T – The value type to be used by the induction object.

+
+
Parameters
+
    +
  • value – [in] The initial value to use for the induction object

  • +
  • stride – [in] The (optional) stride to use for the induction object (default: 1)

  • +
+
+
Returns
+

This returns an induction object with value type T, initial value value, and (if specified) stride stride. If T is an lvalue of non-const type, value is used as the live-out object for the induction object; otherwise there is no live-out object.

+
+
+
+ +
+
+ +
+
+namespace parallel#
+
+ +
+ +
+
+
hpx::experimental::reduction#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace experimental
+

Top-level namespace.

+
+

Functions

+
+
+template<typename T, typename Op>
constexpr hpx::parallel::detail::reduction_helper<T, std::decay_t<Op>> reduction(T &var, T const &identity, Op &&combiner)#
+

The function template returns a reduction object of unspecified type having a value type and encapsulating an identity value for the reduction, a combiner function object, and a live-out object from which the initial value is obtained and into which the final value is stored.

+

A parallel algorithm uses reduction objects by allocating an unspecified number of instances, called views, of the reduction’s value type. Each view is initialized with the reduction object’s identity value, except that the live-out object (which was initialized by the caller) comprises one of the views. The algorithm passes a reference to a view to each application of an element-access function, ensuring that no two concurrently-executing invocations share the same view. A view can be shared between two applications that do not execute concurrently, but initialization is performed only once per view.

+

Modifications to the view by the application of element access functions accumulate as partial results. At some point before the algorithm returns, the partial results are combined, two at a time, using the reduction object’s combiner operation until a single value remains, which is then assigned back to the live-out object.

+

+T shall meet the requirements of CopyConstructible and MoveAssignable. The expression

var = combiner(var, var) 
+
+
+ shall be well formed.

+
+

Note

+

In order to produce useful results, modifications to the view should be limited to commutative operations closely related to the combiner operation. For example if the combiner is plus<T>, incrementing the view would be consistent with the combiner but doubling it or assigning to it would not.

+
+
+
Template Parameters
+
    +
  • T – The value type to be used by the induction object.

  • +
  • Op – The type of the binary function (object) used to perform the reduction operation.

  • +
+
+
Parameters
+
    +
  • var – [in,out] The life-out value to use for the reduction object. This will hold the reduced value after the algorithm is finished executing.

  • +
  • identity – [in] The identity value to use for the reduction operation.

  • +
  • combiner – [in] The binary function (object) used to perform a pairwise reduction on the elements.

  • +
+
+
Returns
+

This returns a reduction object of unspecified type having a value type of T. When the return value is used by an algorithm, the reference to var is used as the live-out object, new views are initialized to a copy of identity, and views are combined by invoking the copy of combiner, passing it the two views to be combined.

+
+
+
+ +
+
+ +
+
+namespace parallel
+
+ +
+ +
+
+
hpx::generate, hpx::generate_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter, typename F>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> generate(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Assign each element in range [first, last) a value generated by the given function object f. Executed according to the policy.

+

+The assignments in the parallel generate algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel generate algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly distance(first, last) invocations of f and assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – generator function that will be called. signature of function should be equivalent to the following:

    Ret fun();
    +
    +
    + + The type Ret must be such that an object of type FwdIter can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The generate algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise.

+
+
+
+ +
+
+template<typename FwdIter, typename F>
FwdIter generate(FwdIter first, FwdIter last, F &&f)#
+

Assign each element in range [first, last) a value generated by the given function object f.

+
+

Note

+

Complexity: Exactly distance(first, last) invocations of f and assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – generator function that will be called. signature of function should be equivalent to the following:

    Ret fun();
    +
    +
    + + The type Ret must be such that an object of type FwdIter can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The generate algorithm returns a FwdIter.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size, typename F>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> generate_n(ExPolicy &&policy, FwdIter first, Size count, F &&f)#
+

Assigns each element in range [first, first+) a value generated by the given function object f. Executed according to the policy.

+

+The assignments in the parallel generate_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel generate_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly count invocations of f and assignments, for count > 0.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Size – The type of a non-negative integral value specifying the number of items to iterate over.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements in the sequence the algorithm will be applied to.

  • +
  • f – Refers to the generator function object that will be called. The signature of the function should be equivalent to

    Ret fun();
    +
    +
    + + The type Ret must be such that an object of type OutputIt can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The generate_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. generate_n algorithm returns iterator one past the last element assigned if count>0, first otherwise.

+
+
+
+ +
+
+template<typename FwdIter, typename Size, typename F>
FwdIter generate_n(FwdIter first, Size count, F &&f)#
+

Assigns each element in range [first, first+) a value generated by the given function object f.

+
+

Note

+

Complexity: Exactly count invocations of f and assignments, for count > 0.

+
+
+
Template Parameters
+
    +
  • Size – The type of a non-negative integral value specifying the number of items to iterate over.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements in the sequence the algorithm will be applied to.

  • +
  • f – Refers to the generator function object that will be called. The signature of the function should be equivalent to

    Ret fun();
    +
    +
    + + The type Ret must be such that an object of type OutputIt can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The generate_n algorithm returns a FwdIter. generate_n algorithm returns iterator one past the last element assigned if count>0, first otherwise.

+
+
+
+ +
+
+ +
+
+
hpx::includes#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool>::type includes(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, Pred &&op = Pred())#
+

Returns true if every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty. The version expects both ranges to be sorted with the user supplied binary predicate f. Executed according to the policy.

+

+The comparison operations in the parallel includes algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel includes algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

At most 2*(N1+N2-1) comparisons, where N1 = std::distance(first1, last1) and N2 = std::distance(first2, last2).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of includes requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as includes. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The includes algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The includes algorithm returns true every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename Pred = hpx::parallel::detail::less>
bool includes(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, Pred &&op = Pred())#
+

Returns true if every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty. The version expects both ranges to be sorted with the user supplied binary predicate f.

+
+

Note

+

At most 2*(N1+N2-1) comparisons, where N1 = std::distance(first1, last1) and N2 = std::distance(first2, last2).

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of includes requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as includes. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The includes algorithm returns a bool. The includes algorithm returns true every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty.

+
+
+
+ +
+
+ +
+
+
hpx::inclusive_scan#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename OutIter>
OutIter inclusive_scan(InIter first, InIter last, OutIter dest)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(+, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op, here std::plus<>().

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns OutIter. The inclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> inclusive_scan(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(+, *first, …, *(first + (i - result))). Executed according to the policy.

+

+The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op, here std::plus<>().

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The inclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename InIter, typename OutIter, typename Op>
OutIter inclusive_scan(InIter first, InIter last, OutIter dest, Op &&op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns OutIter. The inclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Op>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> inclusive_scan(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Op &&op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, *first, …, *(first + (i - result))). Executed according to the policy.

+

+The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The inclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename InIter, typename OutIter, typename Op, typename T>
OutIter inclusive_scan(InIter first, InIter last, OutIter dest, Op &&op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, init, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum. If op is not mathematically associative, the behavior of inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns OutIter. The inclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Op, typename T>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> inclusive_scan(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Op &&op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, init, *first, …, *(first + (i - result))). Executed according to the policy.

+

+The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum. If op is not mathematically associative, the behavior of inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The inclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::is_heap, hpx::is_heap_until#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename RandIter, typename Comp = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> is_heap(ExPolicy &&policy, RandIter first, RandIter last, Comp &&comp = Comp())#
+

Returns whether the range is max heap. That is, true if the range is max heap, false otherwise. The function uses the given comparison function object comp (defaults to using operator<()). Executed according to the policy.

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RandIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
+
+
Returns
+

The is_heap algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The is_heap algorithm returns whether the range is max heap. That is, true if the range is max heap, false otherwise.

+
+
+
+ +
+
+template<typename RandIter, typename Comp = hpx::parallel::detail::less>
bool is_heap(RandIter first, RandIter last, Comp &&comp = Comp())#
+

Returns whether the range is max heap. That is, true if the range is max heap, false otherwise. The function uses the given comparison function object comp (defaults to using operator<()).

+

comp has to induce a strict weak ordering on the values.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+
Template Parameters
+
    +
  • RandIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
+
+
Returns
+

The is_heap a bool. The is_heap algorithm returns whether the range is max heap. That is, true if the range is max heap, false otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename RandIter, typename Comp = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, RandIter> is_heap_until(ExPolicy &&policy, RandIter first, RandIter last, Comp &&comp = Comp())#
+

Returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap. The function uses the given comparison function object comp (defaults to using operator<()). Executed according to the policy.

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RandIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
+
+
Returns
+

The is_heap_until algorithm returns a hpx::future<RandIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns RandIter otherwise. The is_heap_until algorithm returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap.

+
+
+
+ +
+
+template<typename RandIter, typename Comp = hpx::parallel::detail::less>
RandIter is_heap_until(RandIter first, RandIter last, Comp &&comp = Comp())#
+

Returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap. The function uses the given comparison function object comp (defaults to using operator<()).

+

comp has to induce a strict weak ordering on the values.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+
Template Parameters
+
    +
  • RandIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
+
+
Returns
+

The is_heap_until algorithm returns a RandIter. The is_heap_until algorithm returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap.

+
+
+
+ +
+
+ +
+
+
hpx::is_partitioned#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter, typename Pred>
bool is_partitioned(FwdIter first, FwdIter last, Pred &&pred)#
+

Determines if the range [first, last) is partitioned.

+
+

Note

+

Complexity: at most (N) predicate evaluations where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the unary predicate which returns true for elements expected to be found in the beginning of the range. The signature of the function should be equivalent to

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The is_partitioned algorithm returns bool. The is_partitioned algorithm returns true if each element in the sequence for which pred returns true precedes those for which pred returns false. Otherwise is_partitioned returns false. If the range [first, last) contains less than two elements, the function is always true.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Pred>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> is_partitioned(ExPolicy &&policy, FwdIter first, FwdIter last, Pred &&pred)#
+

Determines if the range [first, last) is partitioned. Executed according to the policy.

+

+The predicate operations in the parallel is_partitioned algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel is_partitioned algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (N) predicate evaluations where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Pred must be CopyConstructible when using a parallel policy.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the unary predicate which returns true for elements expected to be found in the beginning of the range. The signature of the function should be equivalent to

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The is_partitioned algorithm returns a hpx::future<bool> if the execution policy is of type task_execution_policy and returns bool otherwise. The is_partitioned algorithm returns true if each element in the sequence for which pred returns true precedes those for which pred returns false. Otherwise is_partitioned returns false. If the range [first, last) contains less than two elements, the function is always true.

+
+
+
+ +
+
+ +
+
+
hpx::is_sorted, hpx::is_sorted_until#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter, typename Pred = hpx::parallel::detail::less>
bool is_sorted(FwdIter first, FwdIter last, Pred &&pred = Pred())#
+

Determines if the range [first, last) is sorted. Uses pred to compare elements.

+

+The comparison operations in the parallel is_sorted algorithm executes in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = distance(first, last). S = number of partitions

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The is_sorted algorithm returns a bool. The is_sorted algorithm returns true if each element in the sequence [first, last) satisfies the predicate passed. If the range [first, last) contains less than two elements, the function always returns true.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Pred = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> is_sorted(ExPolicy &&policy, FwdIter first, FwdIter last, Pred &&pred = Pred())#
+

Determines if the range [first, last) is sorted. Uses pred to compare elements. Executed according to the policy.

+

+The comparison operations in the parallel is_sorted algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel is_sorted algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = distance(first, last). S = number of partitions

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of is_sorted requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The is_sorted algorithm returns a hpx::future<bool> if the execution policy is of type task_execution_policy and returns bool otherwise. The is_sorted algorithm returns a bool if each element in the sequence [first, last) satisfies the predicate passed. If the range [first, last) contains less than two elements, the function always returns true.

+
+
+
+ +
+
+template<typename FwdIter, typename Pred = hpx::parallel::detail::less>
FwdIter is_sorted_until(FwdIter first, FwdIter last, Pred &&pred = Pred())#
+

Returns the first element in the range [first, last) that is not sorted. Uses a predicate to compare elements or the less than operator.

+

+The comparison operations in the parallel is_sorted_until algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = distance(first, last). S = number of partitions

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The is_sorted_until algorithm returns a FwdIter. The is_sorted_until algorithm returns the first unsorted element. If the sequence has less than two elements or the sequence is sorted, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Pred = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type is_sorted_until(ExPolicy &&policy, FwdIter first, FwdIter last, Pred &&pred = Pred())#
+

Returns the first element in the range [first, last) that is not sorted. Uses a predicate to compare elements or the less than operator. Executed according to the policy.

+

+The comparison operations in the parallel is_sorted_until algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel is_sorted_until algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = distance(first, last). S = number of partitions

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of is_sorted_until requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The is_sorted_until algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The is_sorted_until algorithm returns the first unsorted element. If the sequence has less than two elements or the sequence is sorted, last is returned.

+
+
+
+ +
+
+ +
+
+
hpx::lexicographical_compare#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter1, typename InIter2, typename Pred = hpx::parallel::detail::less>
bool lexicographical_compare(InIter1 first1, InIter1 last1, InIter2 first2, InIter2 last2, Pred &&pred)#
+

Checks if the first range [first1, last1) is lexicographically less than the second range [first2, last2). uses a provided predicate to compare elements.

+

+The comparison operations in the parallel lexicographical_compare algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most 2 * min(N1, N2) applications of the comparison operation, where N1 = std::distance(first1, last) and N2 = std::distance(first2, last2).

+
+
+

Note

+

Lexicographical comparison is an operation with the following properties

    +
  • Two ranges are compared element by element

  • +
  • The first mismatching element defines which range is lexicographically less or greater than the other

  • +
  • If one range is a prefix of another, the shorter range is lexicographically less than the other

  • +
  • If two ranges have equivalent elements and are of the same length, then the ranges are lexicographically equal

  • +
  • An empty range is lexicographically less than any non-empty range

  • +
  • Two empty ranges are lexicographically equal

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • InIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of lexicographical_compare requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • pred – Refers to the comparison function that the first and second ranges will be applied to

  • +
+
+
Returns
+

The lexicographically_compare algorithm returns a returns bool if the execution policy object is not passed in. The lexicographically_compare algorithm returns true if the first range is lexicographically less, otherwise it returns false. range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> lexicographical_compare(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, Pred &&pred)#
+

Checks if the first range [first1, last1) is lexicographically less than the second range [first2, last2). uses a provided predicate to compare elements.

+

+The comparison operations in the parallel lexicographical_compare algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel lexicographical_compare algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2 * min(N1, N2) applications of the comparison operation, where N1 = std::distance(first1, last) and N2 = std::distance(first2, last2).

+
+
+

Note

+

Lexicographical comparison is an operation with the following properties

    +
  • Two ranges are compared element by element

  • +
  • The first mismatching element defines which range is lexicographically less or greater than the other

  • +
  • If one range is a prefix of another, the shorter range is lexicographically less than the other

  • +
  • If two ranges have equivalent elements and are of the same length, then the ranges are lexicographically equal

  • +
  • An empty range is lexicographically less than any non-empty range

  • +
  • Two empty ranges are lexicographically equal

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of lexicographical_compare requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • pred – Refers to the comparison function that the first and second ranges will be applied to

  • +
+
+
Returns
+

The lexicographically_compare algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The lexicographically_compare algorithm returns true if the first range is lexicographically less, otherwise it returns false. range [first2, last2), it returns false.

+
+
+
+ +
+
+ +
+
+
hpx::make_heap#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename RndIter, typename Comp>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> make_heap(ExPolicy &&policy, RndIter first, RndIter last, Comp &&comp)#
+

Constructs a max heap in the range [first, last). Executed according to the policy.

+

+The predicate operations in the parallel make_heap algorithm invoked with an execution policy object of type sequential_execution_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel make_heap algorithm invoked with an execution policy object of type parallel_execution_policy or parallel_task_execution_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RndIter – The type of the source iterators used for algorithm. This iterator must meet the requirements for a random access iterator.

  • +
  • Comp – Comparison function object (i.e. an object that satisfies the requirements of Compare) which returns true if the first argument is less than the second. The signature of the comparison function should be equivalent to the following:

    bool cmp(const Type1 &a, const Type2 &b);
    +
    +
    + While the signature does not need to have const &, the function must not modify the objects passed to it and must be able to accept all values of type (possibly const) Type1 and Type2 regardless of value category (thus, Type1 & is not allowed, nor is Type1 unless for Type1 a move is equivalent to a copy. The types Type1 and Type2 must be such that an object of type RandomIt can be dereferenced and then implicitly converted to both of them.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • comp – Refers to the binary predicate which returns true if the first argument should be treated as less than the second. The signature of the function should be equivalent to

    bool comp(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types RndIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The make_heap algorithm returns a hpx::future<void> if the execution policy is of type task_execution_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename RndIter>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> make_heap(ExPolicy &&policy, RndIter first, RndIter last)#
+

Constructs a max heap in the range [first, last). Uses the operator < for comparisons. Executed according to the policy.

+

+The predicate operations in the parallel make_heap algorithm invoked with an execution policy object of type sequential_execution_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel make_heap algorithm invoked with an execution policy object of type parallel_execution_policy or parallel_task_execution_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RndIter – The type of the source iterators used for algorithm. This iterator must meet the requirements for a random access iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
+
+
Returns
+

The make_heap algorithm returns a hpx::future<void> if the execution policy is of type task_execution_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename RndIter, typename Comp>
void make_heap(RndIter first, RndIter last, Comp &&comp)#
+

Constructs a max heap in the range [first, last).

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • RndIter – The type of the source iterators used for algorithm. This iterator must meet the requirements for a random access iterator.

  • +
  • Comp – Comparison function object (i.e. an object that satisfies the requirements of Compare) which returns true if the first argument is less than the second. The signature of the comparison function should be equivalent to the following:

    bool cmp(const Type1 &a, const Type2 &b);
    +
    +
    + While the signature does not need to have const &, the function must not modify the objects passed to it and must be able to accept all values of type (possibly const) Type1 and Type2 regardless of value category (thus, Type1 & is not allowed, nor is Type1 unless for Type1 a move is equivalent to a copy. The types Type1 and Type2 must be such that an object of type RandomIt can be dereferenced and then implicitly converted to both of them.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • comp – Refers to the binary predicate which returns true if the first argument should be treated as less than the second. The signature of the function should be equivalent to

    bool comp(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types RndIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The make_heap algorithm returns a void.

+
+
+
+ +
+
+template<typename RndIter>
void make_heap(RndIter first, RndIter last)#
+

Constructs a max heap in the range [first, last).

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+

RndIter – The type of the source iterators used for algorithm. This iterator must meet the requirements for a random access iterator.

+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
+
+
Returns
+

The make_heap algorithm returns a void.

+
+
+
+ +
+
+ +
+
+
hpx::merge, hpx::inplace_merge#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename RandIter1, typename RandIter2, typename RandIter3, typename Comp = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, RandIter3> merge(ExPolicy &&policy, RandIter1 first1, RandIter1 last1, RandIter2 first2, RandIter2 last2, RandIter3 dest, Comp &&comp = Comp())#
+

Merges two sorted ranges [first1, last1) and [first2, last2) into one sorted range beginning at dest. The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range. The destination range cannot overlap with either of the input ranges. Executed according to the policy.

+

+The assignments in the parallel merge algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel merge algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs O(std::distance(first1, last1) + std::distance(first2, last2)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RandIter1 – The type of the source iterators used (deduced) representing the first sorted range. This iterator type must meet the requirements of an random access iterator.

  • +
  • RandIter2 – The type of the source iterators used (deduced) representing the second sorted range. This iterator type must meet the requirements of an random access iterator.

  • +
  • RandIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the first range of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first range of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second range of elements the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the second range of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types RandIter1 and RandIter2 can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
+
+
Returns
+

The merge algorithm returns a hpx::future<RandIter3> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns RandIter3 otherwise. The merge algorithm returns the destination iterator to the end of the dest range.

+
+
+
+ +
+
+template<typename RandIter1, typename RandIter2, typename RandIter3, typename Comp = hpx::parallel::detail::less>
RandIter3 merge(RandIter1 first1, RandIter1 last1, RandIter2 first2, RandIter2 last2, RandIter3 dest, Comp &&comp = Comp())#
+

Merges two sorted ranges [first1, last1) and [first2, last2) into one sorted range beginning at dest. The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range. The destination range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: Performs O(std::distance(first1, last1) + std::distance(first2, last2)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • RandIter1 – The type of the source iterators used (deduced) representing the first sorted range. This iterator type must meet the requirements of an random access iterator.

  • +
  • RandIter2 – The type of the source iterators used (deduced) representing the second sorted range. This iterator type must meet the requirements of an random access iterator.

  • +
  • RandIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the first range of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first range of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second range of elements the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the second range of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types RandIter1 and RandIter2 can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
+
+
Returns
+

The merge algorithm returns a RandIter3. The merge algorithm returns the destination iterator to the end of the dest range.

+
+
+
+ +
+
+template<typename ExPolicy, typename RandIter, typename Comp = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> inplace_merge(ExPolicy &&policy, RandIter first, RandIter middle, RandIter last, Comp &&comp = Comp())#
+

Merges two consecutive sorted ranges [first, middle) and [middle, last) into one sorted range [first, last). The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range. Executed according to the policy.

+

+The assignments in the parallel inplace_merge algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel inplace_merge algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs O(std::distance(first, last)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RandIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of inplace_merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the first sorted range the algorithm will be applied to.

  • +
  • middle – Refers to the end of the first sorted range and the beginning of the second sorted range the algorithm will be applied to.

  • +
  • last – Refers to the end of the second sorted range the algorithm will be applied to.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types RandIter can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
+
+
Returns
+

The inplace_merge algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns void otherwise. The inplace_merge algorithm returns the source iterator last.

+
+
+
+ +
+
+template<typename RandIter, typename Comp = hpx::parallel::detail::less>
void inplace_merge(RandIter first, RandIter middle, RandIter last, Comp &&comp = Comp())#
+

Merges two consecutive sorted ranges [first, middle) and [middle, last) into one sorted range [first, last). The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range.

+
+

Note

+

Complexity: Performs O(std::distance(first, last)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • RandIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of inplace_merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the first sorted range the algorithm will be applied to.

  • +
  • middle – Refers to the end of the first sorted range and the beginning of the second sorted range the algorithm will be applied to.

  • +
  • last – Refers to the end of the second sorted range the algorithm will be applied to.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types RandIter can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
+
+
Returns
+

The inplace_merge algorithm returns a void. The inplace_merge algorithm returns the source iterator last.

+
+
+
+ +
+
+ +
+
+
hpx::min_element, hpx::max_element, hpx::minmax_element#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter, typename F = hpx::parallel::detail::less>
FwdIter min_element(FwdIter first, FwdIter last, F &&f)#
+

Finds the smallest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel min_element algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
+
+
Returns
+

The min_element algorithm returns FwdIter. The min_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename F = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> min_element(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Finds the smallest element in the range [first, last) using the given comparison function f. Executed according to the policy.

+

+The comparisons in the parallel min_element algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel min_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of min_element requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
+
+
Returns
+

The min_element algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The min_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename FwdIter, typename F = hpx::parallel::detail::less>
FwdIter max_element(FwdIter first, FwdIter last, F &&f)#
+

Finds the largest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel min_element algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the This argument is optional and defaults to std::less. the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
+
+
Returns
+

The max_element algorithm returns FwdIter. The max_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename F = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type max_element(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Removes all elements satisfying specific criteria from the range Finds the largest element in the range [first, last) using the given comparison function f. Executed according to the policy.

+

+The comparisons in the parallel max_element algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel max_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of max_element requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the This argument is optional and defaults to std::less. the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
+
+
Returns
+

The max_element algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The max_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename FwdIter, typename F = hpx::parallel::detail::less>
minmax_element_result<FwdIter> minmax_element(FwdIter first, FwdIter last, F &&f)#
+

Finds the largest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel minmax_element algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most max(floor(3/2*(N-1)), 0) applications of the predicate, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. This argument is optional and defaults to std::less. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
+
+
Returns
+

The minmax_element algorithm returns a minmax_element_result<FwdIter> The minmax_element algorithm returns a pair consisting of an iterator to the smallest element as the min element and an iterator to the largest element as the max element. Returns minmax_element_result<FwdIter>{first,first} if the range is empty. If several elements are equivalent to the smallest element, the iterator to the first such element is returned. If several elements are equivalent to the largest element, the iterator to the last such element is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename F = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, minmax_element_result<FwdIter>> minmax_element(ExPolicy &&policy, FwdIter first, FwdIter last, F &&f)#
+

Finds the largest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel minmax_element algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel minmax_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most max(floor(3/2*(N-1)), 0) applications of the predicate, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of minmax_element requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. This argument is optional and defaults to std::less. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
+
+
Returns
+

The minmax_element algorithm returns a hpx::future<minmax_element_result<FwdIter>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns minmax_element_result<FwdIter> otherwise. The minmax_element algorithm returns a pair consisting of an iterator to the smallest element as the min element and an iterator to the largest element as the max element. Returns std::make_pair(first,first) if the range is empty. If several elements are equivalent to the smallest element, the iterator to the first such element is returned. If several elements are equivalent to the largest element, the iterator to the last such element is returned.

+
+
+
+ +
+
+ +
+
+
hpx::mismatch#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, std::pair<FwdIter1, FwdIter2>> mismatch(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, Pred &&op)#
+

Returns the first mismatching pair of elements from two ranges: one defined by [first1, last1) and another defined by [first2,last2). If last2 is not provided, it denotes first2 + (last1 - first1). Executed according to the policy.

+

+The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most min(last1 - first1, last2 - first2) applications of the predicate op or operator==. If FwdIter1 and FwdIter2 meet the requirements of RandomAccessIterator and (last1 - first1) != (last2 - first2) then no applications of the predicate op or operator== are made.

+
+
+

Note

+

The two ranges are considered mismatch if, for every iterator i in the range [first1,last1), *i mismatches *(first2 + (i - first1)). This overload of mismatch uses operator== to determine if two elements are mismatch.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of mismatch requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as mismatch. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The mismatch algorithm returns a hpx::future<std::pair<FwdIter1,FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns std::pair<FwdIter1,FwdIter2> otherwise. If no mismatches are found when the comparison reaches last1 or last2, whichever happens first, the pair holds the end iterator and the corresponding iterator from the other range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, std::pair<FwdIter1, FwdIter2>> mismatch(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2)#
+

Returns the first mismatching pair of elements from two ranges: one defined by [first1, last1) and another defined by [first2,last2). If last2 is not provided, it denotes first2 + (last1 - first1). Executed according to the policy.

+

+The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most min(last1 - first1, last2 - first2) applications of operator==. If FwdIter1 and FwdIter2 meet the requirements of RandomAccessIterator and (last1 - first1) != (last2 - first2) then no applications of operator== are made.

+
+
+

Note

+

The two ranges are considered mismatch if, for every iterator i in the range [first1,last1), *i mismatches *(first2 + (i - first1)). This overload of mismatch uses operator== to determine if two elements are mismatch.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The mismatch algorithm returns a hpx::future<std::pair<FwdIter1,FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns std::pair<FwdIter1,FwdIter2> otherwise. If no mismatches are found when the comparison reaches last1 or last2, whichever happens first, the pair holds the end iterator and the corresponding iterator from the other range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, std::pair<FwdIter1, FwdIter2>> mismatch(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, Pred &&op)#
+

Returns the first mismatching pair of elements from two ranges: one defined by [first1, last1) and another defined by [first2,last2). If last2 is not provided, it denotes first2 + (last1 - first1). Executed according to the policy.

+

+The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last1 - first1 applications of the predicate op or operator==. If FwdIter1 and FwdIter2 meet the requirements of RandomAccessIterator and (last1 - first1) != (last2 - first2) then no applications of the predicate op or operator== are made.

+
+
+

Note

+

The two ranges are considered mismatch if, for every iterator i in the range [first1,last1), *i mismatches *(first2 + (i - first1)). This overload of mismatch uses operator== to determine if two elements are mismatch.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of mismatch requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as mismatch. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The mismatch algorithm returns a hpx::future<std::pair<FwdIter1,FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns std::pair<FwdIter1,FwdIter2> otherwise. If no mismatches are found when the comparison reaches last1 or last2, whichever happens first, the pair holds the end iterator and the corresponding iterator from the other range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, std::pair<FwdIter1, FwdIter2>> mismatch(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2)#
+

Returns the first mismatching pair of elements from two ranges: one defined by [first1, last1) and another defined by [first2,last2). If last2 is not provided, it denotes first2 + (last1 - first1). Executed according to the policy.

+

+The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last1 - first1 applications of operator==. If FwdIter1 and FwdIter2 meet the requirements of RandomAccessIterator and (last1 - first1) != (last2 - first2) then no applications of operator== are made.

+
+
+

Note

+

The two ranges are considered mismatch if, for every iterator i in the range [first1,last1), *i mismatches *(first2 + (i - first1)). This overload of mismatch uses operator== to determine if two elements are mismatch.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of mismatch requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The mismatch algorithm returns a hpx::future<std::pair<FwdIter1,FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns std::pair<FwdIter1,FwdIter2> otherwise. If no mismatches are found when the comparison reaches last1 or last2, whichever happens first, the pair holds the end iterator and the corresponding iterator from the other range.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename Pred>
std::pair<FwdIter1, FwdIter2> mismatch(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, Pred &&op)#
+

Returns the first mismatching pair of elements from two ranges: one defined by [first1, last1) and another defined by [first2,last2). If last2 is not provided, it denotes first2 + (last1 - first1).

+
+

Note

+

Complexity: At most min(last1 - first1, last2 - first2) applications of the predicate op or operator==. If FwdIter1 and FwdIter2 meet the requirements of RandomAccessIterator and (last1 - first1) != (last2 - first2) then no applications of the predicate op or operator== are made.

+
+
+

Note

+

The two ranges are considered mismatch if, for every iterator i in the range [first1,last1), *i mismatches *(first2 + (i - first1)). This overload of mismatch uses operator== to determine if two elements are mismatch.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of mismatch requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as mismatch. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The mismatch algorithm returns a std::pair<FwdIter1,FwdIter2>. If no mismatches are found when the comparison reaches last1 or last2, whichever happens first, the pair holds the end iterator and the corresponding iterator from the other range.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2>
std::pair<FwdIter1, FwdIter2> mismatch(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2)#
+

Returns the first mismatching pair of elements from two ranges: one defined by [first1, last1) and another defined by [first2,last2). If last2 is not provided, it denotes first2 + (last1 - first1).

+
+

Note

+

Complexity: At most min(last1 - first1, last2 - first2) applications of operator==. If FwdIter1 and FwdIter2 meet the requirements of RandomAccessIterator and (last1 - first1) != (last2 - first2) then no applications of operator== are made.

+
+
+

Note

+

The two ranges are considered mismatch if, for every iterator i in the range [first1,last1), *i mismatches *(first2 + (i - first1)). This overload of mismatch uses operator== to determine if two elements are mismatch.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The mismatch algorithm returns a std::pair<FwdIter1,FwdIter2>. If no mismatches are found when the comparison reaches last1 or last2, whichever happens first, the pair holds the end iterator and the corresponding iterator from the other range.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename Pred>
std::pair<FwdIter1, FwdIter2> mismatch(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, Pred &&op)#
+

Returns the first mismatching pair of elements from two ranges: one defined by [first1, last1) and another defined by [first2,last2). If last2 is not provided, it denotes first2 + (last1 - first1).

+
+

Note

+

Complexity: At most last1 - first1 applications of the predicate op or operator==. If FwdIter1 and FwdIter2 meet the requirements of RandomAccessIterator and (last1 - first1) != (last2 - first2) then no applications of the predicate op or operator== are made.

+
+
+

Note

+

The two ranges are considered mismatch if, for every iterator i in the range [first1,last1), *i mismatches *(first2 + (i - first1)). This overload of mismatch uses operator== to determine if two elements are mismatch.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of mismatch requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as mismatch. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The mismatch algorithm returns a std::pair<FwdIter1,FwdIter2>. If no mismatches are found when the comparison reaches last1 or last2, whichever happens first, the pair holds the end iterator and the corresponding iterator from the other range.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2>
std::pair<FwdIter1, FwdIter2> mismatch(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2)#
+

Returns the first mismatching pair of elements from two ranges: one defined by [first1, last1) and another defined by [first2,last2). If last2 is not provided, it denotes first2 + (last1 - first1).

+
+

Note

+

Complexity: At most last1 - first1 applications of operator==. If FwdIter1 and FwdIter2 meet the requirements of RandomAccessIterator and (last1 - first1) != (last2 - first2) then no applications of operator== are made.

+
+
+

Note

+

The two ranges are considered mismatch if, for every iterator i in the range [first1,last1), *i mismatches *(first2 + (i - first1)). This overload of mismatch uses operator== to determine if two elements are mismatch.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of mismatch requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The mismatch algorithm returns a std::pair<FwdIter1,FwdIter2>. If no mismatches are found when the comparison reaches last1 or last2, whichever happens first, the pair holds the end iterator and the corresponding iterator from the other range.

+
+
+
+ +
+
+ +
+
+
hpx::move#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> move(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest)#
+

Moves the elements in the range [first, last), to another range beginning at dest. After this operation the elements in the moved-from range will still contain valid values of the appropriate type, but not necessarily the same values as before the move. Executed according to the policy.

+

+The move assignments in the parallel move algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The move assignments in the parallel move algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first move assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the move assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The move algorithm returns a hpx::future<FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The move algorithm returns the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2>
FwdIter2 move(FwdIter1 first, FwdIter1 last, FwdIter2 dest)#
+

Moves the elements in the range [first, last), to another range beginning at dest. After this operation the elements in the moved-from range will still contain valid values of the appropriate type, but not necessarily the same values as before the move.

+
+

Note

+

Complexity: Performs exactly last - first move assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The move algorithm returns a FwdIter2. The move algorithm returns the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+ +
+
+
hpx::nth_element#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename RandomIt, typename Pred = hpx::parallel::detail::less>
void nth_element(RandomIt first, RandomIt nth, RandomIt last, Pred &&pred = Pred())#
+

nth_element is a partial sorting algorithm that rearranges elements in [first, last) such that the element pointed at by nth is changed to whatever element would occur in that position if [first, last) were sorted and all of the elements before this new nth element are less than or equal to the elements after the new nth element. Executed according to the policy.

+

+The comparison operations in the parallel nth_element algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in std::distance(first, last) on average. O(N) applications of the predicate, and O(N log N) swaps, where N = last - first.

+
+
+
Template Parameters
+
    +
  • RandomIt – The type of the source begin, nth, and end iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Pred – Comparison function object which returns true if the first argument is less than the second. This defaults to std::less<>.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • nth – Refers to the iterator defining the sort partition point

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the comparison function object which returns true if the first argument is less than (i.e. is ordered before) the second. The signature of this comparison function should be equivalent to:

    bool cmp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type must be such that an object of type randomIt can be dereferenced and then implicitly converted to Type. This defaults to std::less<>.

  • +
+
+
Returns
+

The nth_element algorithms returns nothing.

+
+
+
+ +
+
+template<typename ExPolicy, typename RandomIt, typename Pred = hpx::parallel::detail::less>
void nth_element(ExPolicy &&policy, RandomIt first, RandomIt nth, RandomIt last, Pred &&pred = Pred())#
+

nth_element is a partial sorting algorithm that rearranges elements in [first, last) such that the element pointed at by nth is changed to whatever element would occur in that position if [first, last) were sorted and all of the elements before this new nth element are less than or equal to the elements after the new nth element.

+

+The comparison operations in the parallel nth_element invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel nth_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in std::distance(first, last) on average. O(N) applications of the predicate, and O(N log N) swaps, where N = last - first.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RandomIt – The type of the source begin, nth, and end iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Pred – Comparison function object which returns true if the first argument is less than the second. This defaults to std::less<>.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • nth – Refers to the iterator defining the sort partition point

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the comparison function object which returns true if the first argument is less than (i.e. is ordered before) the second. The signature of this comparison function should be equivalent to:

    bool cmp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type must be such that an object of type randomIt can be dereferenced and then implicitly converted to Type. This defaults to std::less<>.

  • +
+
+
Returns
+

The nth_element algorithms returns nothing.

+
+
+
+ +
+
+ +
+
+
hpx::partial_sort#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename RandIter, typename Comp = hpx::parallel::detail::less>
RandIter partial_sort(RandIter first, RandIter middle, RandIter last, Comp &&comp = Comp())#
+

Places the first middle - first elements from the range [first, last) as sorted with respect to comp into the range [first, middle). The rest of the elements in the range [middle, last) are placed in an unspecified order.

+
+

Note

+

Complexity: Approximately (last - first) * log(middle - first) comparisons.

+
+
+
Template Parameters
+
    +
  • RandIter – The type of the source begin, middle, and end iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the middle of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. It defaults to detail::less.

  • +
+
+
Returns
+

The partial_sort algorithm returns a RandIter that refers to last.

+
+
+
+ +
+
+template<typename ExPolicy, typename RandIter, typename Comp = hpx::parallel::detail::less>
parallel::util::detail::algorithm_result_t<ExPolicy, RandIter> partial_sort(ExPolicy &&policy, RandIter first, RandIter middle, RandIter last, Comp &&comp = Comp())#
+

Places the first middle - first elements from the range [first, last) as sorted with respect to comp into the range [first, middle). The rest of the elements in the range [middle, last) are placed in an unspecified order.

+
+

Note

+

Complexity: Approximately (last - first) * log(middle - first) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • RandIter – The type of the source begin, middle, and end iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the middle of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. It defaults to detail::less.

  • +
+
+
Returns
+

The partial_sort algorithm returns a hpx::future<RandIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns RandIter otherwise. The iterator returned refers to last.

+
+
+
+ +
+
+ +
+
+
hpx::partial_sort_copy#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename RandIter, typename Comp = hpx::parallel::detail::less>
RandIter partial_sort_copy(InIter first, InIter last, RandIter d_first, RandIter d_last, Comp &&comp = Comp())#
+

Sorts some of the elements in the range [first, last) in ascending order, storing the result in the range [d_first, d_last). At most d_last - d_first of the elements are placed sorted to the range [d_first, d_first + n) where n is the number of elements to sort (n = min(last - first, d_last - d_first)).

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(min(D,N))), where N = std::distance(first, last) and D = std::distance(d_first, d_last) comparisons.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • RandIter – The type of the destination iterators used(deduced) This iterator type must meet the requirements of an random iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • d_first – Refers to the beginning of the destination range.

  • +
  • d_last – Refers to the end of the destination range.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. This defaults to detail::less.

  • +
+
+
Returns
+

The partial_sort_copy algorithm returns a RandomIt. The algorithm returns an iterator to the element defining the upper boundary of the sorted range i.e. d_first + min(last - first, d_last - d_first)

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename RandIter, typename Comp = hpx::parallel::detail::less>
parallel::util::detail::algorithm_result_t<ExPolicy, RandIter> partial_sort_copy(ExPolicy &&policy, FwdIter first, FwdIter last, RandIter d_first, RandIter d_last, Comp &&comp = Comp())#
+

Sorts some of the elements in the range [first, last) in ascending order, storing the result in the range [d_first, d_last). At most d_last - d_first of the elements are placed sorted to the range [d_first, d_first + n) where n is the number of elements to sort (n = min(last - first, d_last - d_first)). Executed according to the policy.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(min(D,N))), where N = std::distance(first, last) and D = std::distance(d_first, d_last) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • RandIter – The type of the destination iterators used(deduced) This iterator type must meet the requirements of an random iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • d_first – Refers to the beginning of the destination range.

  • +
  • d_last – Refers to the end of the destination range.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. This defaults to detail::less.

  • +
+
+
Returns
+

The partial_sort_copy algorithm returns a hpx::future<RandomIt> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns RandomIt otherwise. The algorithm returns an iterator to the element defining the upper boundary of the sorted range i.e. d_first + min(last - first, d_last - d_first)

+
+
+
+ +
+
+ +
+
+
hpx::partition, hpx::stable_partition, hpx::partition_copy#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter, typename Pred, typename Proj = hpx::identity>
FwdIter partition(FwdIter first, FwdIter last, Pred &&pred, Proj &&proj = Proj())#
+

Reorders the elements in the range [first, last) in such a way that all elements for which the predicate pred returns true precede the elements for which the predicate pred returns false. Relative order of the elements is not preserved.

+

+The assignments in the parallel partition algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most 2 * (last - first) swaps. Exactly last - first applications of the predicate and projection.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition algorithm returns returns FwdIter. The partition algorithm returns the iterator to the first element of the second group.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Pred, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> partition(ExPolicy &&policy, FwdIter first, FwdIter last, Pred &&pred, Proj &&proj = Proj())#
+

Reorders the elements in the range [first, last) in such a way that all elements for which the predicate pred returns true precede the elements for which the predicate pred returns false. Relative order of the elements is not preserved.

+

+The assignments in the parallel partition algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel partition algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2 * (last - first) swaps. Exactly last - first applications of the predicate and projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition algorithm returns a hpx::future<FwdIter> if the execution policy is of type parallel_task_policy and returns FwdIter otherwise. The partition algorithm returns the iterator to the first element of the second group.

+
+
+
+ +
+
+template<typename BidirIter, typename F, typename Proj = hpx::identity>
BidirIter stable_partition(BidirIter first, BidirIter last, F &&f, Proj &&proj = Proj())#
+

Permutes the elements in the range [first, last) such that there exists an iterator i such that for every iterator j in the range [first, i) INVOKE(f, INVOKE (proj, *j)) != false, and for every iterator k in the range [i, last), INVOKE(f, INVOKE (proj, *k)) == false

+

+The invocations of f in the parallel stable_partition algorithm invoked without an execution policy object executes in sequential order in the calling thread.

+
+

Note

+

Complexity: At most (last - first) * log(last - first) swaps, but only linear number of swaps if there is enough extra memory. Exactly last - first applications of the predicate and projection.

+
+
+
Template Parameters
+
    +
  • BidirIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a bidirectional iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Unary predicate which returns true if the element should be ordered before other elements. Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type BidirIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The stable_partition algorithm returns an iterator i such that for every iterator j in the range [first, i), f(*j) != false INVOKE(f, INVOKE(proj, *j)) != false, and for every iterator k in the range [i, last), f(*k) == false INVOKE(f, INVOKE (proj, *k)) == false. The relative order of the elements in both groups is preserved.

+
+
+
+ +
+
+template<typename ExPolicy, typename BidirIter, typename F, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result_t<ExPolicy, BidirIter> stable_partition(ExPolicy &&policy, BidirIter first, BidirIter last, F &&f, Proj &&proj = Proj())#
+

Permutes the elements in the range [first, last) such that there exists an iterator i such that for every iterator j in the range [first, i) INVOKE(f, INVOKE (proj, *j)) != false, and for every iterator k in the range [i, last), INVOKE(f, INVOKE (proj, *k)) == false

+

+The invocations of f in the parallel stable_partition algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The invocations of f in the parallel stable_partition algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most (last - first) * log(last - first) swaps, but only linear number of swaps if there is enough extra memory. Exactly last - first applications of the predicate and projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the invocations of f.

  • +
  • BidirIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a bidirectional iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Unary predicate which returns true if the element should be ordered before other elements. Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type BidirIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The stable_partition algorithm returns an iterator i such that for every iterator j in the range [first, i), f(*j) != false INVOKE(f, INVOKE(proj, *j)) != false, and for every iterator k in the range [i, last), f(*k) == false INVOKE(f, INVOKE (proj, *k)) == false. The relative order of the elements in both groups is preserved. If the execution policy is of type parallel_task_policy the algorithm returns a future<> referring to this iterator.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename FwdIter3, typename Pred, typename Proj = hpx::identity>
std::pair<FwdIter2, FwdIter3> partition_copy(FwdIter1 first, FwdIter1 last, FwdIter2 dest_true, FwdIter3 dest_false, Pred &&pred, Proj &&proj = Proj())#
+

Copies the elements in the range, defined by [first, last), to two different ranges depending on the value returned by the predicate pred. The elements, that satisfy the predicate pred are copied to the range beginning at dest_true. The rest of the elements are copied to the range beginning at dest_false. The order of the elements is preserved.

+

+The assignments in the parallel partition_copy algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate pred.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range for the elements that satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range for the elements that don’t satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition_copy requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest_true – Refers to the beginning of the destination range for the elements that satisfy the predicate pred

  • +
  • dest_false – Refers to the beginning of the destination range for the elements that don’t satisfy the predicate pred.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition_copy algorithm returns std::pair<OutIter1, OutIter2>. The partition_copy algorithm returns the pair of the destination iterator to the end of the dest_true range, and the destination iterator to the end of the dest_false range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename FwdIter3, typename Pred, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result_t<ExPolicy, std::pair<FwdIter2, FwdIter3>> partition_copy(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest_true, FwdIter3 dest_false, Pred &&pred, Proj &&proj = Proj())#
+

Copies the elements in the range, defined by [first, last), to two different ranges depending on the value returned by the predicate pred. The elements, that satisfy the predicate pred, are copied to the range beginning at dest_true. The rest of the elements are copied to the range beginning at dest_false. The order of the elements is preserved.

+

+The assignments in the parallel partition_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel partition_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate pred.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range for the elements that satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range for the elements that don’t satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition_copy requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest_true – Refers to the beginning of the destination range for the elements that satisfy the predicate pred

  • +
  • dest_false – Refers to the beginning of the destination range for the elements that don’t satisfy the predicate pred.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition_copy algorithm returns a hpx::future<std::pair<OutIter1, OutIter2>> if the execution policy is of type parallel_task_policy and returns std::pair<OutIter1, OutIter2> otherwise. The partition_copy algorithm returns the pair of the destination iterator to the end of the dest_true range, and the destination iterator to the end of the dest_false range.

+
+
+
+ +
+
+ +
+
+
hpx::reduce#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter, typename F, typename T = typename std::iterator_traits<FwdIter>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> reduce(ExPolicy &&policy, FwdIter first, FwdIter last, T init, F &&f)#
+

Returns GENERALIZED_SUM(f, init, *first, …, *(first + (last - first) - 1)). Executed according to the policy.

+

+The reduce operations in the parallel reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicate f.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source begin and end iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of reduce requires F to meet the requirements of CopyConstructible.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 Ret must be such that an object of type FwdIter can be dereferenced and then implicitly converted to any of those types.

  • +
+
+
Returns
+

The reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise. The reduce algorithm returns the result of the generalized sum over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename T = typename std::iterator_traits<FwdIter>::value_type>
util::detail::algorithm_result_t<ExPolicy, T> reduce(ExPolicy &&policy, FwdIter first, FwdIter last, T init)#
+

Returns GENERALIZED_SUM(+, init, *first, …, *(first + (last - first) - 1)). Executed according to the policy.

+

+The reduce operations in the parallel reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source begin and end iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise. The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter>
hpx::parallel::util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<FwdIter>::value_type>::type reduce(ExPolicy &&policy, FwdIter first, FwdIter last)#
+

Returns GENERALIZED_SUM(+, T(), *first, …, *(first + (last - first) - 1)). Executed according to the policy.

+

+The reduce operations in the parallel reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel reduce algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

The type of the initial value (and the result type) T is determined from the value_type of the used FwdIter.

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source begin and end iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise (where T is the value_type of FwdIter). The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename FwdIter, typename F, typename T = typename std::iterator_traits<FwdIter>::value_type>
T reduce(FwdIter first, FwdIter last, T init, F &&f)#
+

Returns GENERALIZED_SUM(f, init, *first, …, *(first + (last - first) - 1)). Executed according to the policy.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicate f.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source begin and end iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of reduce requires F to meet the requirements of CopyConstructible.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 Ret must be such that an object of type InIter can be dereferenced and then implicitly converted to any of those types.

  • +
+
+
Returns
+

The reduce algorithm returns T. The reduce algorithm returns the result of the generalized sum over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename FwdIter, typename T = typename std::iterator_traits<FwdIter>::value_type>
T reduce(FwdIter first, FwdIter last, T init)#
+

Returns GENERALIZED_SUM(+, init, *first, …, *(first + (last - first) - 1)). Executed according to the policy.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source begin and end iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The reduce algorithm returns a T. The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename FwdIter>
std::iterator_traits<FwdIter>::value_type reduce(FwdIter first, FwdIter last)#
+

Returns GENERALIZED_SUM(+, T(), *first, …, *(first + (last - first) - 1)). Executed according to the policy.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

The type of the initial value (and the result type) T is determined from the value_type of the used FwdIter.

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+

FwdIter – The type of the source begin and end iterators used (deduced). This iterator type must meet the requirements of an input iterator.

+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The reduce algorithm returns T (where T is the value_type of FwdIter). The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+ +
+
+
hpx::reduce_by_key#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace experimental
+

Top-level namespace.

+
+

Functions

+
+
+template<typename ExPolicy, typename RanIter, typename RanIter2, typename FwdIter1, typename FwdIter2, typename Compare = std::equal_to<typename std::iterator_traits<RanIter>::value_type>, typename Func = std::plus<typename std::iterator_traits<RanIter2>::value_type>>
util::detail::algorithm_result<ExPolicy, util::in_out_result<FwdIter1, FwdIter2>>::type reduce_by_key(ExPolicy &&policy, RanIter key_first, RanIter key_last, RanIter2 values_first, FwdIter1 keys_output, FwdIter2 values_output, Compare &&comp = Compare(), Func &&func = Func())#
+

Reduce by Key performs an inclusive scan reduction operation on elements supplied in key/value pairs. The algorithm produces a single output value for each set of equal consecutive keys in [key_first, key_last). the value being the GENERALIZED_NONCOMMUTATIVE_SUM(op, init, *first, …, *(first + (i - result))). for the run of consecutive matching keys. The number of keys supplied must match the number of values.

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • RanIter – The type of the key iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • RanIter2 – The type of the value iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • FwdIter1 – The type of the iterator representing the destination key range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination value range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Compare – The type of the optional function/function object to use to compare keys (deduced). Assumed to be std::equal_to otherwise.

  • +
  • Func – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of reduce_by_key requires Func to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • key_first – Refers to the beginning of the sequence of key elements the algorithm will be applied to.

  • +
  • key_last – Refers to the end of the sequence of key elements the algorithm will be applied to.

  • +
  • values_first – Refers to the beginning of the sequence of value elements the algorithm will be applied to.

  • +
  • keys_output – Refers to the start output location for the keys produced by the algorithm.

  • +
  • values_output – Refers to the start output location for the values produced by the algorithm.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • func – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 Ret must be such that an object of type FwdIter can be dereferenced and then implicitly converted to any of those types.

  • +
+
+
Returns
+

The reduce_by_key algorithm returns a hpx::future<pair<Iter1,Iter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns pair<Iter1,Iter2> otherwise.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::remove, hpx::remove_if#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter, typename T = typename std::iterator_traits<FwdIter>::value_type>
FwdIter remove(FwdIter first, FwdIter last, T const &value)#
+

Removes all elements satisfying specific criteria from the range [first, last) and returns a past-the-end iterator for the new end of the range. This version removes all elements that are equal to value.

+

+The assignments in the parallel remove algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the operator==().

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to remove (deduced). This value type must meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – Specifies the value of elements to remove.

  • +
+
+
Returns
+

The remove algorithm returns a FwdIter. The remove algorithm returns the iterator to the new end of the range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename T = typename std::iterator_traits<FwdIter>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> remove(ExPolicy &&policy, FwdIter first, FwdIter last, T const &value)#
+

Removes all elements satisfying specific criteria from the range [first, last) and returns a past-the-end iterator for the new end of the range. This version removes all elements that are equal to value. Executed according to the policy.

+

+The assignments in the parallel remove algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel remove algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the operator==().

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to remove (deduced). This value type must meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – Specifies the value of elements to remove.

  • +
+
+
Returns
+

The remove algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The remove algorithm returns the iterator to the new end of the range.

+
+
+
+ +
+
+template<typename FwdIter, typename Pred>
FwdIter remove_if(FwdIter first, FwdIter last, Pred &&pred)#
+

Removes all elements satisfying specific criteria from the range [first, last) and returns a past-the-end iterator for the new end of the range. This version removes all elements for which predicate pred returns true.

+

+The assignments in the parallel remove_if algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate pred.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of remove_if requires Pred to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The remove_if algorithm returns a FwdIter. The remove_if algorithm returns the iterator to the new end of the range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Pred>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> remove_if(ExPolicy &&policy, FwdIter first, FwdIter last, Pred &&pred)#
+

Removes all elements satisfying specific criteria from the range [first, last) and returns a past-the-end iterator for the new end of the range. This version removes all elements for which predicate pred returns true. Executed according to the policy.

+

+The assignments in the parallel remove_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel remove_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate pred.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of remove_if requires Pred to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The remove_if algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The remove_if algorithm returns the iterator to the new end of the range.

+
+
+
+ +
+
+ +
+
+
hpx::remove_copy, hpx::remove_copy_if#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename OutIter, typename T = typename std::iterator_traits<InIter>::value_type>
OutIter remove_copy(InIter first, InIter last, OutIter dest, T const &value)#
+

Copies the elements in the range, defined by [first, last), to another range beginning at dest. Copies only the elements for which the comparison operator returns false when compare to value. The order of the elements that are not removed is preserved.

+

Effects: Copies all the elements referred to by the iterator it in the range [first,last) for which the following corresponding conditions do not hold: *it == value

+

+The assignments in the parallel remove_copy algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate pred, here comparison operator.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • T – The type that the result of dereferencing FwdIter1 is compared to.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • value – Value to be removed.

  • +
+
+
Returns
+

The remove_copy algorithm returns an OutIter. The remove_copy algorithm returns the iterator to the element past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename T = typename std::iterator_traits<InIter>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> remove_copy(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, T const &value)#
+

Copies the elements in the range, defined by [first, last), to another range beginning at dest. Copies only the elements for which the comparison operator returns false when compare to value. The order of the elements that are not removed is preserved. Executed according to the policy.

+

Effects: Copies all the elements referred to by the iterator it in the range [first,last) for which the following corresponding conditions do not hold: *it == value

+

+The assignments in the parallel remove_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel remove_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate pred, here comparison operator.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type that the result of dereferencing FwdIter1 is compared to.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • value – Value to be removed.

  • +
+
+
Returns
+

The remove_copy algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The remove_copy algorithm returns the iterator to the element past the last element copied.

+
+
+
+ +
+
+template<typename InIter, typename OutIter, typename Pred>
OutIter remove_copy_if(InIter first, InIter last, OutIter dest, Pred &&pred)#
+

Copies the elements in the range, defined by [first, last), to another range beginning at dest. Copies only the elements for which the predicate pred returns false. The order of the elements that are not removed is preserved.

+

Effects: Copies all the elements referred to by the iterator it in the range [first,last) for which the following corresponding conditions do not hold: INVOKE(pred, *it) != false.

+

+The assignments in the parallel remove_copy_if algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate pred.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of the function/function object to use (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements to be removed. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The remove_copy_if algorithm returns an OutIter The remove_copy_if algorithm returns the iterator to the element past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> remove_copy_if(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Pred &&pred)#
+

Copies the elements in the range, defined by [first, last), to another range beginning at dest. Copies only the elements for which the predicate pred returns false. The order of the elements that are not removed is preserved. Executed according to the policy.

+

Effects: Copies all the elements referred to by the iterator it in the range [first,last) for which the following corresponding conditions do not hold: INVOKE(pred, *it) != false.

+

+The assignments in the parallel remove_copy_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel remove_copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate pred.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of remove_copy_if requires Pred to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements to be removed. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
+
+
Returns
+

The remove_copy_if algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The remove_copy_if algorithm returns the iterator to the element past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::replace, hpx::replace_if, hpx::replace_copy, hpx::replace_copy_if#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename T = typename std::iterator_traits<InIter>::value_type>
void replace(InIter first, InIter last, T const &old_value, T const &new_value)#
+

Replaces all elements satisfying specific criteria with new_value in the range [first, last).

+

Effects: Substitutes elements referred by the iterator it in the range [first, last) with new_value, when the following corresponding conditions hold: *it == old_value

+

+The assignments in the parallel replace algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • T – The type of the old and new values to replace (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
+
+
Returns
+

The replace algorithm returns a void.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename T = typename std::iterator_traits<FwdIter>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, void> replace(ExPolicy &&policy, FwdIter first, FwdIter last, T const &old_value, T const &new_value)#
+

Replaces all elements satisfying specific criteria with new_value in the range [first, last). Executed according to the policy.

+

Effects: Substitutes elements referred by the iterator it in the range [first, last) with new_value, when the following corresponding conditions hold: *it == old_value

+

+The assignments in the parallel replace algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • T – The type of the old and new values to replace (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
+
+
Returns
+

The replace algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename Iter, typename Pred, typename T = typename std::iterator_traits<Iter>::value_type>
void replace_if(Iter first, Iter last, Pred &&pred, T const &new_value)#
+

Replaces all elements satisfying specific criteria (for which predicate pred returns true) with new_value in the range [first, last).

+

Effects: Substitutes elements referred by the iterator it in the range [first, last) with new_value, when the following corresponding conditions hold: INVOKE(f, *it) != false

+

+The assignments in the parallel replace_if algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
+
+
Returns
+

The replace_if algorithm returns void.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Pred, typename T = typename std::iterator_traits<FwdIter>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, void> replace_if(ExPolicy &&policy, FwdIter first, FwdIter last, Pred &&pred, T const &new_value)#
+

Replaces all elements satisfying specific criteria (for which predicate f returns true) with new_value in the range [first, last). Executed according to the policy.

+

Effects: Substitutes elements referred by the iterator it in the range [first, last) with new_value, when the following corresponding conditions hold: INVOKE(f, *it) != false

+

+The assignments in the parallel replace_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
+
+
Returns
+

The replace_if algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename InIter, typename OutIter, typename T = typename std::iterator_traits<OutIter>::value_type>
OutIter replace_copy(InIter first, InIter last, OutIter dest, T const &old_value, T const &new_value)#
+

Copies the all elements from the range [first, last) to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (last - first)) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: *(first + (i - result)) == old_value

+

+The assignments in the parallel replace_copy algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • T – The type of the old and new values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
+
+
Returns
+

The replace_copy algorithm returns an OutIter The replace_copy algorithm returns the Iterator to the element past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename T = typename std::iterator_traits<FwdIter2>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> replace_copy(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, T const &old_value, T const &new_value)#
+

Copies the all elements from the range [first, last) to another range beginning at dest replacing all elements satisfying a specific criteria with new_value. Executed according to the policy.

+

Effects: Assigns to every iterator it in the range [result, result + (last - first)) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: *(first + (i - result)) == old_value

+

+The assignments in the parallel replace_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the old and new values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
+
+
Returns
+

The replace_copy algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The replace_copy algorithm returns the Iterator to the element past the last element copied.

+
+
+
+ +
+
+template<typename InIter, typename OutIter, typename Pred, typename T = typename std::iterator_traits<OutIter>::value_type>
OutIter replace_copy_if(InIter first, InIter last, OutIter dest, Pred &&pred, T const &new_value)#
+

Copies the all elements from the range [first, last) to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (last - first)) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: INVOKE(f, *(first + (i - result))) != false

+

+The assignments in the parallel replace_copy_if algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
+
+
Returns
+

The replace_copy_if algorithm returns an OutIter. The replace_copy_if algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred, typename T = typename std::iterator_traits<FwdIter2>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> replace_copy_if(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Pred &&pred, T const &new_value)#
+

Copies the all elements from the range [first, last) to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (last - first)) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: INVOKE(f, *(first + (i - result))) != false

+

+The assignments in the parallel replace_copy_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace_copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of replace_copy_if requires Pred to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
+
+
Returns
+

The replace_copy_if algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The replace_copy_if algorithm returns the iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::reverse, hpx::reverse_copy#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename BidirIter>
void reverse(BidirIter first, BidirIter last)#
+

Reverses the order of the elements in the range [first, last). Behaves as if applying std::iter_swap to every pair of iterators first+i, (last-i) - 1 for each non-negative i < (last-first)/2.

+

+The assignments in the parallel reverse algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+
Template Parameters
+

BidirIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a bidirectional iterator.

+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The reverse algorithm returns void.

+
+
+
+ +
+
+template<typename ExPolicy, typename BidirIter>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, void> reverse(ExPolicy &&policy, BidirIter first, BidirIter last)#
+

Reverses the order of the elements in the range [first, last). Behaves as if applying std::iter_swap to every pair of iterators first+i, (last-i) - 1 for each non-negative i < (last-first)/2. Executed according to the policy.

+

+The assignments in the parallel reverse algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel reverse algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • BidirIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a bidirectional iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The reverse algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename BidirIter, typename OutIter>
OutIter reverse_copy(BidirIter first, BidirIter last, OutIter dest)#
+

Copies the elements from the range [first, last) to another range beginning at dest in such a way that the elements in the new range are in reverse order. Behaves as if by executing the assignment *(dest + (last - first) - 1 - i) = *(first + i) once for each non-negative i < (last - first) If the source and destination ranges (that is, [first, last) and [dest, dest+(last-first)) respectively) overlap, the behavior is undefined.

+

+The assignments in the parallel reverse_copy algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • BidirIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a bidirectional iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the begin of the destination range.

  • +
+
+
Returns
+

The reverse_copy algorithm returns an OutIter. The reverse_copy algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename BidirIter, typename FwdIter>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> reverse_copy(ExPolicy &&policy, BidirIter first, BidirIter last, FwdIter dest)#
+

Copies the elements from the range [first, last) to another range beginning at dest in such a way that the elements in the new range are in reverse order. Behaves as if by executing the assignment *(dest + (last - first) - 1 - i) = *(first + i) once for each non-negative i < (last - first) If the source and destination ranges (that is, [first, last) and [dest, dest+(last-first)) respectively) overlap, the behavior is undefined. Executed according to the policy.

+

+The assignments in the parallel reverse_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel reverse_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • BidirIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a bidirectional iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the begin of the destination range.

  • +
+
+
Returns
+

The reverse_copy algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The reverse_copy algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::rotate, hpx::rotate_copy#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter>
FwdIter rotate(FwdIter first, FwdIter new_first, FwdIter last)#
+

Performs a left rotation on a range of elements. Specifically, rotate swaps the elements in the range [first, last) in such a way that the element new_first becomes the first element of the new range and new_first - 1 becomes the last element.

+

+The assignments in the parallel rotate algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable and MoveConstructible.

+
+
+
Template Parameters
+

FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • new_first – Refers to the element that should appear at the beginning of the rotated range.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The rotate algorithm returns a FwdIter. The rotate algorithm returns the iterator to the new location of the element pointed by first,equal to first + (last - new_first).

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> rotate(ExPolicy &&policy, FwdIter first, FwdIter new_first, FwdIter last)#
+

Performs a left rotation on a range of elements. Specifically, rotate swaps the elements in the range [first, last) in such a way that the element new_first becomes the first element of the new range and new_first - 1 becomes the last element. Executed according to the policy.

+

+The assignments in the parallel rotate algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel rotate algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable and MoveConstructible.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • new_first – Refers to the element that should appear at the beginning of the rotated range.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The rotate algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The rotate algorithm returns the iterator equal to first + (last - new_first).

+
+
+
+ +
+
+template<typename FwdIter, typename OutIter>
OutIter rotate_copy(FwdIter first, FwdIter new_first, FwdIter last, OutIter dest_first)#
+

Copies the elements from the range [first, last), to another range beginning at dest_first in such a way, that the element new_first becomes the first element of the new range and new_first - 1 becomes the last element.

+

+The assignments in the parallel rotate_copy algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • OutIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a output iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • new_first – Refers to the element that should appear at the beginning of the rotated range.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest_first – Refers to the begin of the destination range.

  • +
+
+
Returns
+

The rotate_copy algorithm returns a output iterator, The rotate_copy algorithm returns the output iterator to the element past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> rotate_copy(ExPolicy &&policy, FwdIter1 first, FwdIter1 new_first, FwdIter1 last, FwdIter2 dest_first)#
+

Copies the elements from the range [first, last), to another range beginning at dest_first in such a way, that the element new_first becomes the first element of the new range and new_first - 1 becomes the last element. Executed according to the policy.

+

+The assignments in the parallel rotate_copy algorithm execute in sequential order in the calling thread.

+

The assignments in the parallel rotate_copy algorithm execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • new_first – Refers to the element that should appear at the beginning of the rotated range.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest_first – Refers to the begin of the destination range.

  • +
+
+
Returns
+

The rotate_copy algorithm returns a hpx::future<FwdIter2> if the execution policy is of type parallel_task_policy and returns FwdIter2 otherwise. The rotate_copy algorithm returns the output iterator to the element past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::search, hpx::search_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter, typename FwdIter2, typename Pred = parallel::detail::equal_to>
FwdIter search(FwdIter first, FwdIter last, FwdIter2 s_first, FwdIter2 s_last, Pred &&op = Pred())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements.

+

+The comparison operations in the parallel search algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of search requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The search algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The search algorithm returns an iterator to the beginning of the first subsequence [s_first, s_last) in range [first, last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty first is returned. If no subsequence is found, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename FwdIter2, typename Pred = parallel::detail::equal_to>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> search(ExPolicy &&policy, FwdIter first, FwdIter last, FwdIter2 s_first, FwdIter2 s_last, Pred &&op = Pred())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements. Executed according to the policy.

+

+The comparison operations in the parallel search algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel search algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of search requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The search algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The search algorithm returns an iterator to the beginning of the first subsequence [s_first, s_last) in range [first, last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty first is returned. If no subsequence is found, last is returned.

+
+
+
+ +
+
+template<typename FwdIter, typename FwdIter2, typename Pred = parallel::detail::equal_to>
FwdIter search_n(FwdIter first, std::size_t count, FwdIter2 s_first, FwdIter2 s_last, Pred &&op = Pred())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements.

+

+The comparison operations in the parallel search_n algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = count.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of search_n requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • count – Refers to the range of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The search_n algorithm returns FwdIter. The search_n algorithm returns an iterator to the beginning of the last subsequence [s_first, s_last) in range [first, first+count). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, first+count), first is returned. Additionally if the size of the subsequence is empty or no subsequence is found, first is also returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename FwdIter2, typename Pred = parallel::detail::equal_to>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> search_n(ExPolicy &&policy, FwdIter first, std::size_t count, FwdIter2 s_first, FwdIter2 s_last, Pred &&op = Pred())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements. Executed according to the policy.

+

+The comparison operations in the parallel search_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel search_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = count.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of search_n requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • count – Refers to the range of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
+
+
Returns
+

The search_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The search_n algorithm returns an iterator to the beginning of the last subsequence [s_first, s_last) in range [first, first+count). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, first+count), first is returned. Additionally if the size of the subsequence is empty or no subsequence is found, first is also returned.

+
+
+
+ +
+
+ +
+
+
hpx::set_difference#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename FwdIter3, typename Pred = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter3> set_difference(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, FwdIter3 dest, Pred &&op = Pred())#
+

Constructs a sorted range beginning at dest consisting of all elements present in the range [first1, last1) and not present in the range [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate pred. Executed according to the policy.

+

+Equivalent elements are treated individually, that is, if some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::max(m-n, 0) times. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1

  • +
+
+
Returns
+

The set_difference algorithm returns a hpx::future<FwdIter3> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter3 otherwise. The set_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename FwdIter3, typename Pred = hpx::parallel::detail::less>
FwdIter3 set_difference(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, FwdIter3 dest, Pred &&op = Pred())#
+

Constructs a sorted range beginning at dest consisting of all elements present in the range [first1, last1) and not present in the range [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate pred.

+

+Equivalent elements are treated individually, that is, if some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::max(m-n, 0) times. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1

  • +
+
+
Returns
+

The set_difference algorithm returns a FwdIter3. The set_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::set_intersection#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename FwdIter3, typename Pred = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter3> set_intersection(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, FwdIter3 dest, Pred &&op = Pred())#
+

Constructs a sorted range beginning at dest consisting of all elements present in both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate pred. Executed according to the policy.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), the first std::min(m, n) elements will be copied from the first range to the destination range. The order of equivalent elements is preserved. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator or output iterator with sequential execution.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_intersection requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1

  • +
+
+
Returns
+

The set_intersection algorithm returns a hpx::future<FwdIter3> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter3 otherwise. The set_intersection algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename FwdIter3, typename Pred = hpx::parallel::detail::less>
FwdIter3 set_intersection(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, FwdIter3 dest, Pred &&op = Pred())#
+

Constructs a sorted range beginning at dest consisting of all elements present in both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate pred.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), the first std::min(m, n) elements will be copied from the first range to the destination range. The order of equivalent elements is preserved. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator or output iterator with sequential execution.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_intersection requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1

  • +
+
+
Returns
+

The set_intersection algorithm returns a FwdIter3. The set_intersection algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::set_symmetric_difference#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename FwdIter3, typename Pred = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result<ExPolicy, FwdIter3>::type set_symmetric_difference(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, FwdIter3 dest, Pred &&op = Pred())#
+

Constructs a sorted range beginning at dest consisting of all elements present in either of the sorted ranges [first1, last1) and [first2, last2), but not in both of them are copied to the range beginning at dest. The resulting range is also sorted. This algorithm expects both input ranges to be sorted with the given binary predicate pred. Executed according to the policy.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::abs(m-n) times. If m>n, then the last m-n of those elements are copied from [first1,last1), otherwise the last n-m elements are copied from [first2,last2). The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator or output iterator and sequential execution.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_symmetric_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1

  • +
+
+
Returns
+

The set_symmetric_difference algorithm returns a hpx::future<FwdIter3> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter3 otherwise. The set_symmetric_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename FwdIter3, typename Pred = hpx::parallel::detail::less>
FwdIter3 set_symmetric_difference(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, FwdIter3 dest, Pred &&op = Pred())#
+

Constructs a sorted range beginning at dest consisting of all elements present in either of the sorted ranges [first1, last1) and [first2, last2), but not in both of them are copied to the range beginning at dest. The resulting range is also sorted. This algorithm expects both input ranges to be sorted with the given binary predicate pred.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::abs(m-n) times. If m>n, then the last m-n of those elements are copied from [first1,last1), otherwise the last n-m elements are copied from [first2,last2). The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator or output iterator and sequential execution.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_symmetric_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1

  • +
+
+
Returns
+

The set_symmetric_difference algorithm returns a FwdIter3. The set_symmetric_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::set_union#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename FwdIter3, typename Pred = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter3> set_union(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, FwdIter3 dest, Pred &&op = Pred())#
+

Constructs a sorted range beginning at dest consisting of all elements present in one or both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate pred. Executed according to the policy.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), then all m elements will be copied from [first1, last1) to dest, preserving order, and then exactly std::max(n-m, 0) elements will be copied from [first2, last2) to dest, also preserving order.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator or output iterator and sequential execution.

  • +
  • Op – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_union requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1

  • +
+
+
Returns
+

The set_union algorithm returns a hpx::future<FwdIter3> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter3 otherwise. The set_union algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename FwdIter3, typename Pred = hpx::parallel::detail::less>
FwdIter3 set_union(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter2 last2, FwdIter3 dest, Pred &&op = Pred())#
+

Constructs a sorted range beginning at dest consisting of all elements present in one or both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate pred. Executed according to the policy.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), then all m elements will be copied from [first1, last1) to dest, preserving order, and then exactly std::max(n-m, 0) elements will be copied from [first2, last2) to dest, also preserving order.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator or output iterator and sequential execution.

  • +
  • Op – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_union requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1

  • +
+
+
Returns
+

The set_union algorithm returns a FwdIter3. The set_union algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::shift_left#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter, typename Size>
FwdIter shift_left(FwdIter first, FwdIter last, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the beginning of the range. For every integer i in [0, last - first

    +
  • n), moves the element originally at position first + n + i to position first + i.

  • +
+

+

+The assignment operations in the parallel shift_left algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_left algorithm returns FwdIter. The shift_left algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size>
hpx::parallel::util::detail::algorithm_result<ExPolicy, FwdIter> shift_left(ExPolicy &&policy, FwdIter first, FwdIter last, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the beginning of the range. For every integer i in [0, last - first

    +
  • n), moves the element originally at position first + n + i to position first + i. Executed according to the policy.

  • +
+

+

+The assignment operations in the parallel shift_left algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignment operations in the parallel shift_left algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_left algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The shift_left algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+ +
+
+
hpx::shift_right#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter, typename Size>
FwdIter shift_right(FwdIter first, FwdIter last, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the end of the range. For every integer i in [0, last - first - n), moves the element originally at position first + i to position first

    +
  • n + i.

  • +
+

+

+The assignment operations in the parallel shift_right algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_right algorithm returns FwdIter. The shift_right algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size>
hpx::parallel::util::detail::algorithm_result<ExPolicy, FwdIter> shift_right(ExPolicy &&policy, FwdIter first, FwdIter last, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the end of the range. For every integer i in [0, last - first - n), moves the element originally at position first + i to position first

    +
  • n + i. Executed according to the policy.

  • +
+

+

+The assignment operations in the parallel shift_right algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignment operations in the parallel shift_right algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_right algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The shift_right algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+ +
+
+
hpx::sort#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename RandomIt, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
void sort(RandomIt first, RandomIt last, Comp &&comp, Proj &&proj = Proj())#
+

Sorts the elements in the range [first, last) in ascending order. The order of equal elements is not guaranteed to be preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The assignments in the parallel sort algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • RandomIt – The type of the source iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The sort algorithm returns void.

+
+
+
+ +
+
+template<typename ExPolicy, typename RandomIt, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> sort(ExPolicy &&policy, RandomIt first, RandomIt last, Comp &&comp, Proj &&proj)#
+

Sorts the elements in the range [first, last) in ascending order. The order of equal elements is not guaranteed to be preserved. The function uses the given comparison function object comp (defaults to using operator<()). Executed according to the policy.

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • RandomIt – The type of the source iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The sort algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+ +
+
+
hpx::experimental::sort_by_key#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace experimental
+

Top-level namespace.

+
+

Functions

+
+
+template<typename ExPolicy, typename KeyIter, typename ValueIter, typename Compare = detail::less>
util::detail::algorithm_result_t<ExPolicy, sort_by_key_result<KeyIter, ValueIter>> sort_by_key(ExPolicy &&policy, KeyIter key_first, KeyIter key_last, ValueIter value_first, Compare &&comp = Compare())#
+

Sorts one range of data using keys supplied in another range. The key elements in the range [key_first, key_last) are sorted in ascending order with the corresponding elements in the value range moved to follow the sorted order. The algorithm is not stable, the order of equal elements is not guaranteed to be preserved. The function uses the given comparison function object comp (defaults to using operator<()). Executed according to the policy.

+

+A sequence is sorted with respect to a comparator comp if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, *(i + n), *i) == false.

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • KeyIter – The type of the key iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • ValueIter – The type of the value iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Compare – The type of the function/function object to use (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • key_first – Refers to the beginning of the sequence of key elements the algorithm will be applied to.

  • +
  • key_last – Refers to the end of the sequence of key elements the algorithm will be applied to.

  • +
  • value_first – Refers to the beginning of the sequence of value elements the algorithm will be applied to, the range of elements must match [key_first, key_last)

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
+
+
Returns
+

The sort_by_key algorithm returns a hpx::future<sort_by_key_result<KeyIter,ValueIter>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns otherwise. The algorithm returns a pair holding an iterator pointing to the first element after the last element in the input key sequence and an iterator pointing to the first element after the last element in the input value sequence.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::stable_sort#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename RandomIt, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
void stable_sort(RandomIt first, RandomIt last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range [first, last) in ascending order. The relative order of equal elements is preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The assignments in the parallel stable_sort algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • RandomIt – The type of the source iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The stable_sort algorithm returns void.

+
+
+
+ +
+
+template<typename ExPolicy, typename RandomIt, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> stable_sort(ExPolicy &&policy, RandomIt first, RandomIt last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range [first, last) in ascending order. The relative order of equal elements is preserved. The function uses the given comparison function object comp (defaults to using operator<()). Executed according to the policy.

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • RandomIt – The type of the source iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The stable_sort algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+ +
+
+
hpx::starts_with#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter1, typename InIter2, typename Pred = hpx::parallel::detail::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
bool starts_with(InIter1 first1, InIter1 last1, InIter2 first2, InIter2 last2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks whether the second range defined by [first1, last1) matches the prefix of the first range defined by [first2, last2)

+

+The assignments in the parallel starts_with algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • InIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • InIter2 – The type of the destination iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Pred – The binary predicate that compares the projected elements. This defaults to hpx::parallel::detail::equal_to.

  • +
  • Proj1 – The type of an optional projection function for the source range. This defaults to hpx::identity.

  • +
  • Proj2 – The type of an optional projection function for the destination range. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the source range.

  • +
  • last1 – Sentinel value referring to the end of the source range.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Sentinel value referring to the end of the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements in the source range as a projection operation before the actual predicate pred is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements in the destination range as a projection operation before the actual predicate pred is invoked.

  • +
+
+
Returns
+

The starts_with algorithm returns bool. The starts_with algorithm returns a boolean with the value true if the second range matches the prefix of the first range, false otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename InIter1, typename InIter2, typename Pred = hpx::parallel::detail::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> starts_with(ExPolicy &&policy, InIter1 first1, InIter1 last1, InIter2 first2, InIter2 last2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks whether the second range defined by [first1, last1) matches the prefix of the first range defined by [first2, last2). Executed according to the policy.

+

+The assignments in the parallel starts_with algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • InIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • InIter2 – The type of the destination iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Pred – The binary predicate that compares the projected elements. This defaults to hpx::parallel::detail::equal_to.

  • +
  • Proj1 – The type of an optional projection function for the source range. This defaults to hpx::identity.

  • +
  • Proj2 – The type of an optional projection function for the destination range. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the source range.

  • +
  • last1 – Sentinel value referring to the end of the source range.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Sentinel value referring to the end of the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements in the source range as a projection operation before the actual predicate pred is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements in the destination range as a projection operation before the actual predicate pred is invoked.

  • +
+
+
Returns
+

The starts_with algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The starts_with algorithm returns a boolean with the value true if the second range matches the prefix of the first range, false otherwise.

+
+
+
+ +
+
+ +
+
+
hpx::swap_ranges#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter1, typename FwdIter2>
FwdIter2 swap_ranges(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2)#
+

Exchanges elements between range [first1, last1) and another range starting at first2.

+

+The swap operations in the parallel swap_ranges algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first1 and last1.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the first range of iterators to swap (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the second range of iterators to swap (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The swap_ranges algorithm returns FwdIter2. The swap_ranges algorithm returns iterator to the element past the last element exchanged in the range beginning with first2.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> swap_ranges(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2)#
+

Exchanges elements between range [first1, last1) and another range starting at first2. Executed according to the policy.

+

+The swap operations in the parallel swap_ranges algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The swap operations in the parallel swap_ranges algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first1 and last1.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the swap operations.

  • +
  • FwdIter1 – The type of the first range of iterators to swap (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the second range of iterators to swap (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The swap_ranges algorithm returns a hpx::future<FwdIter2> if the execution policy is of type parallel_task_policy and returns FwdIter2 otherwise. The swap_ranges algorithm returns iterator to the element past the last element exchanged in the range beginning with first2.

+
+
+
+ +
+
+ +
+
+
hpx::transform#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter1, typename FwdIter2, typename F>
FwdIter2 transform(FwdIter1 first, FwdIter1 last, FwdIter2 dest, F &&f)#
+

Applies the given function f to the range [first, last) and stores the result in another range, beginning at dest.

+
+

Note

+

Complexity: Exactly last - first applications of f

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type Ret must be such that an object of type FwdIter2 can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The transform algorithm returns a FwdIter2. The transform algorithm returns a tuple holding an iterator referring to the first element after the input sequence and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename F>
parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> transform(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, F &&f)#
+

Applies the given function f to the range [first, last) and stores the result in another range, beginning at dest. Executed according to the policy.

+

+The invocations of f in the parallel transform algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The invocations of f in the parallel transform algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly last - first applications of f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the invocations of f.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type Ret must be such that an object of type FwdIter2 can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The transform algorithm returns a hpx::future<FwdIter2> if the execution policy is of type parallel_task_policy and returns FwdIter2 otherwise. The transform algorithm returns a tuple holding an iterator referring to the first element after the input sequence and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename FwdIter3, typename F>
FwdIter3 transform(FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter3 dest, F &&f)#
+

Applies the given function f to pairs of elements from two ranges: one defined by [first1, last1) and the other beginning at first2, and stores the result in another range, beginning at dest.

+
+

Note

+

Complexity: Exactly last - first applications of f

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators for the second range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively. The type Ret must be such that an object of type FwdIter3 can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The transform algorithm returns a FwdIter3. The transform algorithm returns a tuple holding an iterator referring to the first element after the first input sequence, an iterator referring to the first element after the second input sequence, and the output iterator referring to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename FwdIter3, typename F>
parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter3> transform(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, FwdIter3 dest, F &&f)#
+

Applies the given function f to pairs of elements from two ranges: one defined by [first1, last1) and the other beginning at first2, and stores the result in another range, beginning at dest. Executed according to the policy.

+

+The invocations of f in the parallel transform algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The invocations of f in the parallel transform algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly last - first applications of f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the invocations of f.

  • +
  • FwdIter1 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the source iterators for the second range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively. The type Ret must be such that an object of type FwdIter3 can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The transform algorithm returns a hpx::future<FwdIter3> if the execution policy is of type parallel_task_policy and returns FwdIter3 otherwise. The transform algorithm returns a tuple holding an iterator referring to the first element after the first input sequence, an iterator referring to the first element after the second input sequence, and the output iterator referring to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::transform_exclusive_scan#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename OutIter, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<InIter>::value_type>
OutIter transform_exclusive_scan(InIter first, InIter last, OutIter dest, T init, BinOp &&binary_op, UnOp &&unary_op)#
+

Transforms each element in the range [first, last) with unary_op, then computes an exclusive prefix sum operation using binary_op over the resulting range, with init as the initial value, and writes the results to the range beginning at dest. “exclusive” means that the i-th input element is not included in the i-th sum. Formally, assigns through each iterator i in [dest, d_first + (last - first)) the value of the generalized noncommutative sum of init, unary_op(*j)… for every j in [first, first + (i - d_first)) over binary_op, where generalized noncommutative sum GNSUM(op, a1, …, a N) is defined as follows:

    +
  • if N=1, a1

  • +
  • if N > 1, op(GNSUM(op, a1, …, aK), GNSUM(op, aM, …, aN)) for any K where 1 < K+1 = M <= N In other words, the summation operations may be performed in arbitrary order, and the behavior is nondeterministic if binary_op is not associative.

  • +
+

+

+The reduce operations in the parallel transform_exclusive_scan algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+

+Neither unary_op nor binary_op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_exclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of each of binary_op and unary_op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • BinOp – The type of binary_op.

  • +
  • UnOp – The type of unary_op.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • binary_op – Binary FunctionObject that will be applied to the result of unary_op, the results of other binary_op, and init.

  • +
  • unary_op – Unary FunctionObject that will be applied to each element of the input range. The return type must be acceptable as input to binary_op.

  • +
+
+
Returns
+

The transform_exclusive_scan algorithm returns a returns OutIter. The transform_exclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<FwdIter1>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter2>::type transform_exclusive_scan(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, T init, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, conv(*first), …, conv(*(first + (i - result) - 1))). Executed according to the policy.

+

+The reduce operations in the parallel transform_exclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_exclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+Neither unary_op nor binary_op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_exclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of each of binary_op and unary_op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • BinOp – The type of binary_op.

  • +
  • UnOp – The type of unary_op.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • binary_op – Binary FunctionObject that will be applied in to the result of unary_op, the results of other binary_op, and init.

  • +
  • unary_op – Unary FunctionObject that will be applied to each element of the input range. The return type must be acceptable as input to binary_op.

  • +
+
+
Returns
+

The transform_exclusive_scan algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The transform_exclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::transform_inclusive_scan#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename OutIter, typename BinOp, typename UnOp>
OutIter transform_inclusive_scan(InIter first, InIter last, OutIter dest, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, conv(*first), …, conv(*(first + (i - result)))).

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+

+Neither binary_op nor unary_op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The difference between inclusive_scan and transform_inclusive_scan is that transform_inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of each of binary_op and unary_op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • BinOp – The type of binary_op.

  • +
  • UnOp – The type of unary_op.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Binary FunctionObject that will be applied in to the result of unary_op, the results of other binary_op, and init if provided.

  • +
  • unary_op – Unary FunctionObject that will be applied to each element of the input range. The return type must be acceptable as input to binary_op.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns a returns OutIter. The transform_inclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename BinOp, typename UnOp>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter2>::type transform_inclusive_scan(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, conv(*first), …, conv(*(first + (i - result)))). Executed according to the policy.

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+Neither binary_op nor unary_op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The difference between inclusive_scan and transform_inclusive_scan is that transform_inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of each of binary_op and unary_op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • BinOp – The type of binary_op.

  • +
  • UnOp – The type of unary_op.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Binary FunctionObject that will be applied in to the result of unary_op, the results of other binary_op, and init if provided.

  • +
  • unnary_op – Unary FunctionObject that will be applied to each element of the input range. The return type must be acceptable as input to binary_op.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The transform_inclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename InIter, typename OutIter, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<InIter>::value_type>
OutIter transform_inclusive_scan(InIter first, InIter last, OutIter dest, BinOp &&binary_op, UnOp &&unary_op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, init, conv(*first), …, conv(*(first + (i - result)))).

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+

+Neither binary_op nor unary_op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The difference between inclusive_scan and transform_inclusive_scan is that transform_inclusive_scan includes the ith input element in the ith sum. If binary_op is not mathematically associative, the behavior of transform_inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of each of binary_op and unary_op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • BinOp – The type of binary_op.

  • +
  • UnOp – The type of unary_op.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Binary FunctionObject that will be applied in to the result of unary_op, the results of other binary_op, and init if provided.

  • +
  • unnary_op – Unary FunctionObject that will be applied to each element of the input range. The return type must be acceptable as input to binary_op.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns a returns OutIter. The transform_inclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<FwdIter1>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter2>::type transform_inclusive_scan(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, BinOp &&binary_op, UnOp &&unary_op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, init, conv(*first), …, conv(*(first + (i - result)))). Executed according to the policy.

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+Neither binary_op nor unary_op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The difference between inclusive_scan and transform_inclusive_scan is that transform_inclusive_scan includes the ith input element in the ith sum. If binary_op is not mathematically associative, the behavior of transform_inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of each of binary_op and unary_op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • BinOp – The type of binary_op.

  • +
  • UnOp – The type of unary_op.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Binary FunctionObject that will be applied in to the result of unary_op, the results of other binary_op, and init if provided.

  • +
  • unnary_op – Unary FunctionObject that will be applied to each element of the input range. The return type must be acceptable as input to binary_op.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The transform_inclusive_scan algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::transform_reduce#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter, typename T, typename Reduce, typename Convert>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> transform_reduce(ExPolicy &&policy, FwdIter first, FwdIter last, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns GENERALIZED_SUM(red_op, init, conv_op(*first), …, conv_op(*(first + (last - first) - 1))). Executed according to the policy.

+

+The reduce operations in the parallel transform_reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_reduce algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between transform_reduce and accumulate is that the behavior of transform_reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates red_op and conv_op.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the reduction operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for each of the values returned from the invocation of conv_op. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1, Type2, and Ret must be such that an object of a type as returned from conv_op can be implicitly converted to any of those types.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a hpx::future<T> if the execution policy is of type parallel_task_policy and returns T otherwise. The transform_reduce algorithm returns the result of the generalized sum over the values returned from conv_op when applied to the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename InIter, typename T, typename Reduce, typename Convert>
T transform_reduce(InIter first, InIter last, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns GENERALIZED_SUM(red_op, init, conv_op(*first), …, conv_op(*(first + (last - first) - 1))).

+

+The difference between transform_reduce and accumulate is that the behavior of transform_reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates red_op and conv_op.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the reduction operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for each of the values returned from the invocation of conv_op. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1, Type2, and Ret must be such that an object of a type as returned from conv_op can be implicitly converted to any of those types.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a T. The transform_reduce algorithm returns the result of the generalized sum over the values returned from conv_op when applied to the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename T>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> transform_reduce(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, T init)#
+

Returns the result of accumulating init with the inner products of the pairs formed by the elements of two ranges starting at first1 and first2. Executed according to the policy.

+

+The operations in the parallel transform_reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The operations in the parallel transform_reduce algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(last - first) applications each of reduce and transform.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the first source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the second source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • T – The type of the value to be used as return) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the first sequence of elements the result will be calculated with.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the result will be calculated with.

  • +
  • init – The initial value for the sum.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise.

+
+
+
+ +
+
+template<typename InIter1, typename InIter2, typename T>
T transform_reduce(InIter1 first1, InIter1 last1, InIter2 first2, T init)#
+

Returns the result of accumulating init with the inner products of the pairs formed by the elements of two ranges starting at first1 and first2.

+
+

Note

+

Complexity: O(last - first) applications each of reduce and transform.

+
+
+
Template Parameters
+
    +
  • InIter1 – The type of the first source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • InIter2 – The type of the second source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be used as return) values (deduced).

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the first sequence of elements the result will be calculated with.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the result will be calculated with.

  • +
  • init – The initial value for the sum.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a T.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename T, typename Reduce, typename Convert>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> transform_reduce(ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns the result of accumulating init with the inner products of the pairs formed by the elements of two ranges starting at first1 and first2. Executed according to the policy.

+

+The operations in the parallel transform_reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The operations in the parallel transform_reduce algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(last - first) applications each of reduce and transform.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the first source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the second source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • T – The type of the value to be used as return) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the multiplication operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the first sequence of elements the result will be calculated with.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the result will be calculated with.

  • +
  • init – The initial value for the sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for the initial value and each of the return values of conv_op. This is a binary predicate. The signature of this predicate should be equivalent to should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Ret must be such that it can be implicitly converted to a type of T.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the input values of the sequence. This is a binary predicate. The signature of this predicate should be equivalent to

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Ret must be such that it can be implicitly converted to an object for the second argument type of red_op.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise.

+
+
+
+ +
+
+template<typename InIter1, typename InIter2, typename T, typename Reduce, typename Convert>
T transform_reduce(ExPolicy &&policy, InIter1 first1, InIter1 last1, InIter2 first2, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns the result of accumulating init with the inner products of the pairs formed by the elements of two ranges starting at first1 and first2.

+
+

Note

+

Complexity: O(last - first) applications each of reduce and transform.

+
+
+
Template Parameters
+
    +
  • InIter1 – The type of the first source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • InIter2 – The type of the second source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be used as return) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the multiplication operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the first sequence of elements the result will be calculated with.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the result will be calculated with.

  • +
  • init – The initial value for the sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for the initial value and each of the return values of conv_op. This is a binary predicate. The signature of this predicate should be equivalent to should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Ret must be such that it can be implicitly converted to a type of T.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the input values of the sequence. This is a binary predicate. The signature of this predicate should be equivalent to

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Ret must be such that it can be implicitly converted to an object for the second argument type of red_op.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a T.

+
+
+
+ +
+
+ +
+
+
hpx/parallel/algorithms/transform_reduce_binary.hpp#
+

Defined in header hpx/parallel/algorithms/transform_reduce_binary.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::uninitialized_copy, hpx::uninitialized_copy_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename FwdIter>
FwdIter uninitialized_copy(InIter first, InIter last, FwdIter dest)#
+

Copies the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the copy operation, the function has no effects.

+

+The assignments in the parallel uninitialized_copy algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_copy algorithm returns FwdIter. The uninitialized_copy algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> uninitialized_copy(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest)#
+

Copies the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the copy operation, the function has no effects. Executed according to the policy.

+

+The assignments in the parallel uninitialized_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_copy algorithm returns a hpx::future<FwdIter2>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The uninitialized_copy algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename InIter, typename Size, typename FwdIter>
FwdIter uninitialized_copy_n(InIter first, Size count, FwdIter dest)#
+

Copies the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest. If an exception is thrown during the copy operation, the function has no effects.

+

+The assignments in the parallel uninitialized_copy_n algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_copy_n algorithm returns a returns FwdIter. The uninitialized_copy_n algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Size, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> uninitialized_copy_n(ExPolicy &&policy, FwdIter1 first, Size count, FwdIter2 dest)#
+

Copies the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest. If an exception is thrown during the copy operation, the function has no effects.

+

+The assignments in the parallel uninitialized_copy_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_copy_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_copy_n algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The uninitialized_copy_n algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::uninitialized_default_construct, hpx::uninitialized_default_construct_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter>
void uninitialized_default_construct(FwdIter first, FwdIter last)#
+

Constructs objects of type typename iterator_traits<ForwardIt> ::value_type in the uninitialized storage designated by the range by default-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_default_construct algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+

FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_default_construct algorithm returns nothing

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> uninitialized_default_construct(ExPolicy &&policy, FwdIter first, FwdIter last)#
+

Constructs objects of type typename iterator_traits<ForwardIt> ::value_type in the uninitialized storage designated by the range by default-initialization. If an exception is thrown during the initialization, the function has no effects. Executed according to the policy.

+

+The assignments in the parallel uninitialized_default_construct algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_default_construct algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_default_construct algorithm returns a hpx::future<void>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns nothing otherwise.

+
+
+
+ +
+
+template<typename FwdIter, typename Size>
FwdIter uninitialized_default_construct_n(FwdIter first, Size count)#
+

Constructs objects of type typename iterator_traits<ForwardIt> ::value_type in the uninitialized storage designated by the range [first, first + count) by default-initialization. If an exception is thrown during the initialization, the function has no effects.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_default_construct_n algorithm returns a returns FwdIter. The uninitialized_default_construct_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> uninitialized_default_construct_n(ExPolicy &&policy, FwdIter first, Size count)#
+

Constructs objects of type typename iterator_traits<ForwardIt> ::value_type in the uninitialized storage designated by the range [first, first + count) by default-initialization. If an exception is thrown during the initialization, the function has no effects. Executed according to the policy.

+

+The assignments in the parallel uninitialized_default_construct_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_default_construct_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_default_construct_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The uninitialized_default_construct_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+ +
+
+
hpx::uninitialized_fill, hpx::uninitialized_fill_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter, typename T>
void uninitialized_fill(FwdIter first, FwdIter last, T const &value)#
+

Copies the given value to an uninitialized memory area, defined by the range [first, last). If an exception is thrown during the initialization, the function has no effects.

+
+

Note

+

Complexity: Linear in the distance between first and last

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The uninitialized_fill algorithm returns nothing

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename T>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> uninitialized_fill(ExPolicy &&policy, FwdIter first, FwdIter last, T const &value)#
+

Copies the given value to an uninitialized memory area, defined by the range [first, last). If an exception is thrown during the initialization, the function has no effects. Executed according to the policy.

+

+The initializations in the parallel uninitialized_fill algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The initializations in the parallel uninitialized_fill algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The uninitialized_fill algorithm returns a hpx::future<void>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns nothing otherwise.

+
+
+
+ +
+
+template<typename FwdIter, typename Size, typename T>
FwdIter uninitialized_fill_n(FwdIter first, Size count, T const &value)#
+

Copies the given value value to the first count elements in an uninitialized memory area beginning at first. If an exception is thrown during the initialization, the function has no effects.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The uninitialized_fill_n algorithm returns a returns FwdIter. The uninitialized_fill_n algorithm returns the output iterator to the element in the range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size, typename T>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> uninitialized_fill_n(ExPolicy &&policy, FwdIter first, Size count, T const &value)#
+

Copies the given value value to the first count elements in an uninitialized memory area beginning at first. If an exception is thrown during the initialization, the function has no effects. Executed according to the policy.

+

+The initializations in the parallel uninitialized_fill_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The initializations in the parallel uninitialized_fill_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The uninitialized_fill_n algorithm returns a hpx::future<FwdIter>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The uninitialized_fill_n algorithm returns the output iterator to the element in the range, one past the last element copied.

+
+
+
+ +
+
+ +
+
+
hpx::uninitialized_move, hpx::uninitialized_move_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter, typename FwdIter>
FwdIter uninitialized_move(InIter first, InIter last, FwdIter dest)#
+

Moves the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the initialization, some objects in [first, last) are left in a valid but unspecified state.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_move algorithm returns FwdIter. The uninitialized_move algorithm returns the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> uninitialized_move(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest)#
+

Moves the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the initialization, some objects in [first, last) are left in a valid but unspecified state. Executed according to the policy.

+

+The assignments in the parallel uninitialized_move algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_move algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_move algorithm returns a hpx::future<FwdIter2>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The uninitialized_move algorithm returns the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename InIter, typename Size, typename FwdIter>
std::pair<InIter, FwdIter> uninitialized_move_n(InIter first, Size count, FwdIter dest)#
+

Moves the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest. If an exception is thrown during the initialization, some objects in [first, first + count) are left in a valid but unspecified state.

+
+

Note

+

Complexity: Performs exactly count movements, if count > 0, no move operations otherwise.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_move_n algorithm returns a returns std::pair<InIter,FwdIter>. The uninitialized_move_n algorithm returns A pair whose first element is an iterator to the element past the last element moved in the source range, and whose second element is an iterator to the element past the last element moved in the destination range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Size, typename FwdIter2>
parallel::util::detail::algorithm_result<ExPolicy, std::pair<FwdIter1, FwdIter2>>::type uninitialized_move_n(ExPolicy &&policy, FwdIter1 first, Size count, FwdIter2 dest)#
+

Moves the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest. If an exception is thrown during the initialization, some objects in [first, first + count) are left in a valid but unspecified state. Executed according to the policy.

+

+The assignments in the parallel uninitialized_move_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_move_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count movements, if count > 0, no move operations otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_move_n algorithm returns a hpx::future<std::pair<FwdIter1,FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns std::pair<FwdIter1,FwdIter2> otherwise. The uninitialized_move_n algorithm returns A pair whose first element is an iterator to the element past the last element moved in the source range, and whose second element is an iterator to the element past the last element moved in the destination range.

+
+
+
+ +
+
+ +
+
+
hpx::uninitialized_relocate, hpx::uninitialized_relocate_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename InIter1, typename InIter2, typename FwdIter>
FwdIter uninitialized_relocate(InIter1 first, InIter2 last, FwdIter dest)#
+

Relocates the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the move-construction of an element, all elements left in the input range, as well as all objects already constructed in the destination range are destroyed. After this algorithm completes, the source range should be freed or reused without destroying the objects.

+

+The assignments in the parallel uninitialized_relocate algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: time: O(n), space: O(1) 1) For “trivially relocatable” underlying types (T) and a contiguous iterator range [first, last): std::distance(first, last)*sizeof(T) bytes are copied. 2) For “trivially relocatable” underlying types (T) and a non-contiguous iterator range [first, last): std::distance(first, last) memory copies of sizeof(T) bytes each are performed. 3) For “non-trivially relocatable” underlying types (T): std::distance(first, last) move assignments and destructions are performed.

+
+
+

Note

+

Declare a type as “trivially relocatable” using the HPX_DECLARE_TRIVIALLY_RELOCATABLE macros found in <hpx/type_support/is_trivially_relocatable.hpp>.

+
+
+
Template Parameters
+
    +
  • InIter1 – The type of the source iterator first (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • InIter2 – The type of the source iterator last (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_relocate algorithm returns FwdIter. The uninitialized_relocate algorithm returns the output iterator to the element in the destination range, one past the last element relocated.

+
+
+
+ +
+
+template<typename ExPolicy, typename InIter1, typename InIter2, typename FwdIter>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> uninitialized_relocate(ExPolicy &&policy, InIter1 first, InIter2 last, FwdIter dest)#
+

Relocates the elements in the range defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the move-construction of an element, all elements left in the input range, as well as all objects already constructed in the destination range are destroyed. After this algorithm completes, the source range should be freed or reused without destroying the objects.

+

+The assignments in the parallel uninitialized_relocate algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: time: O(n), space: O(1) 1) For “trivially relocatable” underlying types (T) and a contiguous iterator range [first, last): std::distance(first, last)*sizeof(T) bytes are copied. 2) For “trivially relocatable” underlying types (T) and a non-contiguous iterator range [first, last): std::distance(first, last) memory copies of sizeof(T) bytes each are performed. 3) For “non-trivially relocatable” underlying types (T): std::distance(first, last) move assignments and destructions are performed.

+
+
+

Note

+

Declare a type as “trivially relocatable” using the HPX_DECLARE_TRIVIALLY_RELOCATABLE macros found in <hpx/type_support/is_trivially_relocatable.hpp>.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • InIter1 – The type of the source iterator first (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • InIter2 – The type of the source iterator last (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range. The assignments in the parallel uninitialized_relocate_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

  • +
+
+
Returns
+

The uninitialized_relocate algorithm returns a hpx::future<FwdIter>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The uninitialized_relocate algorithm returns the output iterator to the element in the destination range, one past the last element relocated.

+
+
+
+ +
+
+template<typename BiIter1, typename BiIter2>
BiIter2 uninitialized_relocate_backward(BiIter1 first, BiIter1 last, BiIter2 dest_last)#
+

Relocates the elements in the range, defined by [first, last), to an uninitialized memory area ending at dest_last. The objects are processed in reverse order. If an exception is thrown during the the move-construction of an element, all elements left in the input range, as well as all objects already constructed in the destination range are destroyed. After this algorithm completes, the source range should be freed or reused without destroying the objects.

+

+The assignments in the parallel uninitialized_relocate algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: time: O(n), space: O(1) 1) For “trivially relocatable” underlying types (T) and a contiguous iterator range [first, last): std::distance(first, last)*sizeof(T) bytes are copied. 2) For “trivially relocatable” underlying types (T) and a non-contiguous iterator range [first, last): std::distance(first, last) memory copies of sizeof(T) bytes each are performed. 3) For “non-trivially relocatable” underlying types (T): std::distance(first, last) move assignments and destructions are performed.

+
+
+

Note

+

Declare a type as “trivially relocatable” using the HPX_DECLARE_TRIVIALLY_RELOCATABLE macros found in <hpx/type_support/is_trivially_relocatable.hpp>.

+
+
+
Template Parameters
+
    +
  • BiIter1 – The type of the source range (deduced). This iterator type must meet the requirements of a Bidirectional iterator.

  • +
  • BiIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a Bidirectional iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest_last – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_relocate_backward algorithm returns BiIter2. The uninitialized_relocate_backward algorithm returns the bidirectional iterator to the first element in the destination range.

+
+
+
+ +
+
+template<typename ExPolicy, typename BiIter1, typename BiIter2>
hpx::parallel::util::detail::algorithm_result<ExPolicy, BiIter2> uninitialized_relocate_backward(ExPolicy &&policy, BiIter1 first, BiIter1 last, BiIter2 dest_last)#
+

Relocates the elements in the range, defined by [first, last), to an uninitialized memory area ending at dest_last. The order of the relocation of the objects depends on the execution policy. If an exception is thrown during the the move-construction of an element, all elements left in the input range, as well as all objects already constructed in the destination range are destroyed. After this algorithm completes, the source range should be freed or reused without destroying the objects.

+

+The assignments in the parallel uninitialized_relocate_backward algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Using the uninitialized_relocate_backward algorithm with the with a non-sequenced execution policy, will not guarantee the order of the relocation of the objects.

+
+
+

Note

+

Complexity: time: O(n), space: O(1) 1) For “trivially relocatable” underlying types (T) and a contiguous iterator range [first, last): std::distance(first, last)*sizeof(T) bytes are copied. 2) For “trivially relocatable” underlying types (T) and a non-contiguous iterator range [first, last): std::distance(first, last) memory copies of sizeof(T) bytes each are performed. 3) For “non-trivially relocatable” underlying types (T): std::distance(first, last) move assignments and destructions are performed.

+
+
+

Note

+

Declare a type as “trivially relocatable” using the HPX_DECLARE_TRIVIALLY_RELOCATABLE macros found in <hpx/type_support/is_trivially_relocatable.hpp>.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • BiIter1 – The type of the source range (deduced). This iterator type must meet the requirements of a Bidirectional iterator.

  • +
  • BiIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a Bidirectional iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest_last – Refers to the end of the destination range.

  • +
+
+
Returns
+

The uninitialized_relocate_backward algorithm returns a hpx::future<FwdIter>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns BiIter2 otherwise. The uninitialized_relocate_backward algorithm returns the bidirectional iterator to the first element in the destination range.

+
+
+
+ +
+
+template<typename InIter, typename Size, typename FwdIter>
FwdIter uninitialized_relocate_n(InIter first, Size count, FwdIter dest)#
+

Relocates the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the move-construction of an element, all elements left in the input range, as well as all objects already constructed in the destination range are destroyed. After this algorithm completes, the source range should be freed or reused without destroying the objects.

+

+The assignments in the parallel uninitialized_relocate_n algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: time: O(n), space: O(1) 1) For “trivially relocatable” underlying types (T) and a contiguous iterator range [first, first+count): count*sizeof(T) bytes are copied. 2) For “trivially relocatable” underlying types (T) and a non-contiguous iterator range [first, first+count): count memory copies of sizeof(T) bytes each are performed. 3) For “non-trivially relocatable” underlying types (T): count move assignments and destructions are performed.

+
+
+

Note

+

Declare a type as “trivially relocatable” using the HPX_DECLARE_TRIVIALLY_RELOCATABLE macros found in <hpx/type_support/is_trivially_relocatable.hpp>.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterator first (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Size – The type of the argument specifying the number of elements to relocate.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_relocate_n algorithm returns FwdIter. The uninitialized_relocate_n algorithm returns the output iterator to the element in the destination range, one past the last element relocated.

+
+
+
+ +
+
+template<typename ExPolicy, typename InIter, typename Size, typename FwdIter>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> uninitialized_relocate_n(ExPolicy &&policy, InIter first, Size count, FwdIter dest)#
+

Relocates the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the move-construction of an element, all elements left in the input range, as well as all objects already constructed in the destination range are destroyed. After this algorithm completes, the source range should be freed or reused without destroying the objects.

+

+The assignments in the parallel uninitialized_relocate_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_relocate_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: time: O(n), space: O(1) 1) For “trivially relocatable” underlying types (T) and a contiguous iterator range [first, first+count): count*sizeof(T) bytes are copied. 2) For “trivially relocatable” underlying types (T) and a non-contiguous iterator range [first, first+count): count memory copies of sizeof(T) bytes each are performed. 3) For “non-trivially relocatable” underlying types (T): count move assignments and destructions are performed.

+
+
+

Note

+

Declare a type as “trivially relocatable” using the HPX_DECLARE_TRIVIALLY_RELOCATABLE macros found in <hpx/type_support/is_trivially_relocatable.hpp>.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • InIter – The type of the source iterator first (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Size – The type of the argument specifying the number of elements to relocate.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The uninitialized_relocate_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The uninitialized_relocate_n algorithm returns the output iterator to the element in the destination range, one past the last element relocated.

+
+
+
+ +
+
+ +
+
+
hpx::uninitialized_value_construct, hpx::uninitialized_value_construct_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter>
void uninitialized_value_construct(FwdIter first, FwdIter last)#
+

Constructs objects of type typename iterator_traits<ForwardIt> ::value_type in the uninitialized storage designated by the range by value-initialization. If an exception is thrown during the initialization, the function has no effects.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+

FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_value_construct algorithm returns nothing

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> uninitialized_value_construct(ExPolicy &&policy, FwdIter first, FwdIter last)#
+

Constructs objects of type typename iterator_traits<ForwardIt> ::value_type in the uninitialized storage designated by the range by value-initialization. If an exception is thrown during the initialization, the function has no effects. Executed according to the policy.

+

+The assignments in the parallel uninitialized_value_construct algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_value_construct algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_value_construct algorithm returns a hpx::future<void>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns nothing otherwise.

+
+
+
+ +
+
+template<typename FwdIter, typename Size>
FwdIter uninitialized_value_construct_n(FwdIter first, Size count)#
+

Constructs objects of type typename iterator_traits<ForwardIt> ::value_type in the uninitialized storage designated by the range [first, first + count) by value-initialization. If an exception is thrown during the initialization, the function has no effects.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_value_construct_n algorithm returns a returns FwdIter. The uninitialized_value_construct_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> uninitialized_value_construct_n(ExPolicy &&policy, FwdIter first, Size count)#
+

Constructs objects of type typename iterator_traits<ForwardIt> ::value_type in the uninitialized storage designated by the range [first, first + count) by value-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_value_construct_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_value_construct_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_value_construct_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The uninitialized_value_construct_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+ +
+
+
hpx::unique, hpx::unique_copy#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename FwdIter, typename Pred = hpx::parallel::detail::equal_to, typename Proj = hpx::identity>
FwdIter unique(FwdIter first, FwdIter last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Eliminates all but the first element from every consecutive group of equivalent elements from the range [first, last) and returns a past-the-end iterator for the new logical end of the range.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first - 1 applications of the predicate pred and no more than twice as many applications of the projection proj.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate pred is invoked.

  • +
+
+
Returns
+

The unique algorithm returns FwdIter. The unique algorithm returns the iterator to the new end of the range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Pred = hpx::parallel::detail::equal_to, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type unique(ExPolicy &&policy, FwdIter first, FwdIter last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Eliminates all but the first element from every consecutive group of equivalent elements from the range [first, last) and returns a past-the-end iterator for the new logical end of the range. Executed according to the policy.

+

+The assignments in the parallel unique algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel unique algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first - 1 applications of the predicate pred and no more than twice as many applications of the projection proj.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate pred is invoked.

  • +
+
+
Returns
+

The unique algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The unique algorithm returns the iterator to the new end of the range.

+
+
+
+ +
+
+template<typename InIter, typename OutIter, typename Pred = hpx::parallel::detail::equal_to, typename Proj = hpx::identity>
OutIter unique_copy(InIter first, InIter last, OutIter dest, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Copies the elements from the range [first, last), to another range beginning at dest in such a way that there are no consecutive equal elements. Only the first element of each group of equal elements is copied.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first - 1 applications of the predicate pred and no more than twice as many applications of the projection proj

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique_copy requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate pred is invoked.

  • +
+
+
Returns
+

The unique_copy algorithm returns a returns OutIter. The unique_copy algorithm returns the destination iterator to the end of the dest range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Pred = hpx::parallel::detail::equal_to, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter2>::type unique_copy(ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Copies the elements from the range [first, last), to another range beginning at dest in such a way that there are no consecutive equal elements. Only the first element of each group of equal elements is copied. Executed according to the policy.

+

+The assignments in the parallel unique_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel unique_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first - 1 applications of the predicate pred and no more than twice as many applications of the projection proj

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique_copy requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate pred is invoked.

  • +
+
+
Returns
+

The unique_copy algorithm returns a hpx::future<FwdIter2> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The unique_copy algorithm returns the pair of the source iterator to last, and the destination iterator to the end of the dest range.

+
+
+
+ +
+
+ +
+
+
hpx::ranges::adjacent_difference#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges#
+
+

Functions

+
+
+template<typename FwdIter1, typename FwdIter2, typename Sent>
FwdIter2 adjacent_difference(FwdIter1 first, Sent last, FwdIter2 dest)#
+

Searches the range [first, last) for two consecutive identical elements.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The adjacent_difference algorithm returns an iterator to the first of the identical elements. If no such elements are found, last is returned.

+
+
+
+ +
+
+template<typename Rng, typename FwdIter2>
FwdIter2 adjacent_difference(Rng &&rng, FwdIter2 dest)#
+

Searches the rng for two consecutive identical elements.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • FwdIter2 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The adjacent_difference algorithm returns an iterator to the first of the identical elements.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> adjacent_difference(ExPolicy &&policy, FwdIter1 first, Sent last, FwdIter2 dest)#
+

Searches the range [first, last) for two consecutive identical elements.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The adjacent_difference algorithm returns an iterator to the first of the identical elements. If no such elements are found, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> adjacent_difference(ExPolicy &&policy, Rng &&rng, FwdIter2 dest)#
+

Searches the rng for two consecutive identical elements.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter2 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The adjacent_difference algorithm returns an iterator to the first of the identical elements.

+
+
+
+ +
+
+template<typename FwdIter1, typename Sent, typename FwdIter2, typename Op>
FwdIter2 adjacent_difference(FwdIter1 first, Sent last, FwdIter2 dest, Op &&op)#
+

Searches the range [first, last) for two consecutive identical elements.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • Op – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of adjacent_difference requires Op to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Binary operation function object that will be applied. The signature of the function should be equivalent to the following:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &. The types Type1 and Type2 must be such that an object of type iterator_traits<InputIt>::value_type can be implicitly converted to both of them. The type Ret must be such that an object of type OutputIt can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The adjacent_difference algorithm returns an iterator to the first of the identical elements. If no such elements are found, last is returned.

+
+
+
+ +
+
+template<typename Rng, typename FwdIter2, typename Op>
FwdIter2 adjacent_difference(Rng &&rng, FwdIter2 dest, Op &&op)#
+

Searches the rng for two consecutive identical elements.

+
+
Template Parameters
+
    +
  • FwdIter2 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Op – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of adjacent_difference requires Op to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Binary operation function object that will be applied. The signature of the function should be equivalent to the following:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &. The types Type1 and Type2 must be such that an object of type iterator_traits<InputIt>::value_type can be implicitly converted to both of them. The type Ret must be such that an object of type OutputIt can be dereferenced and assigned a value of type Ret.?

  • +
+
+
Returns
+

The adjacent_difference algorithm returns an iterator to the first of the identical elements.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2, typename Op>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> adjacent_difference(ExPolicy &&policy, FwdIter1 first, Sent last, FwdIter2 dest, Op &&op)#
+

Searches the range [first, last) for two consecutive identical elements.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • Op – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of adjacent_difference requires Op to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Binary operation function object that will be applied. The signature of the function should be equivalent to the following:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &. The types Type1 and Type2 must be such that an object of type iterator_traits<InputIt>::value_type can be implicitly converted to both of them. The type Ret must be such that an object of type OutputIt can be dereferenced and assigned a value of type Ret.?

  • +
+
+
Returns
+

The adjacent_difference algorithm returns an iterator to the first of the identical elements. If no such elements are found, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename FwdIter2, typename Op>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> adjacent_difference(ExPolicy &&policy, Rng &&rng, FwdIter2 dest, Op &&op)#
+

Searches the rng for two consecutive identical elements.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter2 – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Op – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of adjacent_difference requires Op to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Binary operation function object that will be applied. The signature of the function should be equivalent to the following:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &. The types Type1 and Type2 must be such that an object of type iterator_traits<InputIt>::value_type can be implicitly converted to both of them. The type Ret must be such that an object of type OutputIt can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The adjacent_difference algorithm returns an iterator to the first of the identical elements.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::adjacent_find#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent, typename Proj = hpx::identity, typename Pred = detail::equal_to>
FwdIter adjacent_find(FwdIter first, Sent last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Searches the range [first, last) for two consecutive identical elements.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
  • Pred – The type of an optional function/function object to use.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • pred – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1 .

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The adjacent_find algorithm returns an iterator to the first of the identical elements. If no such elements are found, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename Proj = hpx::identity, typename Pred = detail::equal_to>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type adjacent_find(ExPolicy &&policy, FwdIter first, Sent last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Searches the range [first, last) for two consecutive identical elements. This version uses the given binary predicate pred

+

+The comparison operations in the parallel adjacent_find invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel adjacent_find invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+This overload of adjacent_find is available if the user decides to provide their algorithm their own binary predicate pred.

+
+

Note

+

Complexity: Exactly the smaller of (result - first) + 1 and (last - first) - 1 application of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • pred – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1 .

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The adjacent_find algorithm returns a hpx::future<InIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns InIter otherwise. The adjacent_find algorithm returns an iterator to the first of the identical elements. If no such elements are found, last is returned.

+
+
+
+ +
+
+template<typename Rng, typename Proj = hpx::identity, typename Pred = detail::equal_to>
hpx::traits::range_traits<Rng>::iterator_type adjacent_find(Rng &&rng, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Searches the range rng for two consecutive identical elements.

+
+

Note

+

Complexity: Exactly the smaller of (result - std::begin(rng)) + 1 and (std::begin(rng) - std::end(rng)) - 1 applications of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
  • Pred – The type of an optional function/function object to use.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1 .

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The adjacent_find algorithm returns an iterator to the first of the identical elements. If no such elements are found, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Proj = hpx::identity, typename Pred = detail::equal_to>
parallel::util::detail::algorithm_result<ExPolicy, typename hpx::traits::range_traits<Rng>::iterator_type>::type adjacent_find(ExPolicy &&policy, Rng &&rng, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Searches the range rng for two consecutive identical elements.

+

+The comparison operations in the parallel adjacent_find invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel adjacent_find invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+This overload of adjacent_find is available if the user decides to provide their algorithm their own binary predicate pred.

+
+

Note

+

Complexity: Exactly the smaller of (result - std::begin(rng)) + 1 and (std::begin(rng) - std::end(rng)) - 1 applications of the predicate where result is the value returned

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1 .

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The adjacent_find algorithm returns a hpx::future<InIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns InIter otherwise. The adjacent_find algorithm returns an iterator to the first of the identical elements. If no such elements are found, last is returned.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::all_of, hpx::ranges::any_of, hpx::ranges::none_of#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Rng, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> none_of(ExPolicy &&policy, Rng &&rng, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for no elements in the range rng.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most std::distance(begin(rng), end(rng)) applications of the predicate f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The none_of algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The none_of algorithm returns true if the unary predicate f returns true for no elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> none_of(ExPolicy &&policy, Iter first, Sent last, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for no elements in the range [first, last).

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the predicate f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The none_of algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The none_of algorithm returns true if the unary predicate f returns true for no elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+template<typename Rng, typename F, typename Proj = hpx::identity>
bool none_of(Rng &&rng, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for no elements in the range rng.

+
+

Note

+

Complexity: At most std::distance(begin(rng), end(rng)) applications of the predicate f

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The none_of algorithm returns true if the unary predicate f returns true for no elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename F, typename Proj = hpx::identity>
bool none_of(Iter first, Sent last, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for no elements in the range [first, last).

+
+

Note

+

Complexity: At most last - first applications of the predicate f

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The none_of algorithm returns true if the unary predicate f returns true for no elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> any_of(ExPolicy &&policy, Rng &&rng, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for at least one element in the range rng.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most std::distance(begin(rng), end(rng)) applications of the predicate f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The any_of algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The any_of algorithm returns true if the unary predicate f returns true for at least one element in the range, false otherwise. It returns false if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> any_of(ExPolicy &&policy, Iter first, Sent last, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for at least one element in the range rng.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most std::distance(begin(rng), end(rng)) applications of the predicate f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The any_of algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The any_of algorithm returns true if the unary predicate f returns true for at least one element in the range, false otherwise. It returns false if the range is empty.

+
+
+
+ +
+
+template<typename Rng, typename F, typename Proj = hpx::identity>
bool any_of(Rng &&rng, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for at least one element in the range rng.

+
+

Note

+

Complexity: At most std::distance(begin(rng), end(rng)) applications of the predicate f

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The any_of algorithm returns true if the unary predicate f returns true for at least one element in the range, false otherwise. It returns false if the range is empty.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename F, typename Proj = hpx::identity>
bool any_of(Iter first, Sent last, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for at least one element in the range rng.

+
+

Note

+

Complexity: At most std::distance(begin(rng), end(rng)) applications of the predicate f

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The any_of algorithm returns true if the unary predicate f returns true for at least one element in the range, false otherwise. It returns false if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> all_of(ExPolicy &&policy, Rng &&rng, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for all elements in the range rng.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most std::distance(begin(rng), end(rng)) applications of the predicate f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The all_of algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The all_of algorithm returns true if the unary predicate f returns true for all elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> all_of(ExPolicy &&policy, Iter first, Sent last, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for all elements in the range rng.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most std::distance(begin(rng), end(rng)) applications of the predicate f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The all_of algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The all_of algorithm returns true if the unary predicate f returns true for all elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+template<typename Rng, typename F, typename Proj = hpx::identity>
bool all_of(Rng &&rng, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for all elements in the range rng.

+
+

Note

+

Complexity: At most std::distance(begin(rng), end(rng)) applications of the predicate f

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The all_of algorithm returns true if the unary predicate f returns true for all elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename F, typename Proj = hpx::identity>
bool all_of(Iter first, Sent last, F &&f, Proj &&proj = Proj())#
+

Checks if unary predicate f returns true for all elements in the range rng.

+
+

Note

+

Complexity: At most std::distance(begin(rng), end(rng)) applications of the predicate f

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of none_of requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The all_of algorithm returns true if the unary predicate f returns true for all elements in the range, false otherwise. It returns true if the range is empty.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::copy, hpx::ranges::copy_n, hpx::ranges::copy_if#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename Sent1, typename FwdIter>
parallel::util::detail::algorithm_result<ExPolicy, ranges::copy_result<FwdIter1, FwdIter>>::type copy(ExPolicy &&policy, FwdIter1 iter, Sent1 sent, FwdIter dest)#
+

Copies the elements in the range, defined by [first, last), to another range beginning at dest.

+

+The assignments in the parallel copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • iter – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The copy algorithm returns a hpx::future<ranges::copy_result<FwdIter1, FwdIter> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::copy_result<FwdIter1, FwdIter> otherwise. The copy algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename FwdIter>
parallel::util::detail::algorithm_result<ExPolicy, ranges::copy_result<typename hpx::traits::range_traits<Rng>::iterator_type, FwdIter>>::type copy(ExPolicy &&policy, Rng &&rng, FwdIter dest)#
+

Copies the elements in the range rng to another range beginning at dest.

+

+The assignments in the parallel copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly std::distance(begin(rng), end(rng)) assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The copy algorithm returns a hpx::future<ranges::copy_result<iterator_t<Rng>, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::copy_result<iterator_t<Rng>, FwdIter2> otherwise. The copy algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename Sent1, typename FwdIter>
ranges::copy_result<FwdIter1, FwdIter> copy(FwdIter1 iter, Sent1 sent, FwdIter dest)#
+

Copies the elements in the range, defined by [first, last), to another range beginning at dest.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • iter – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The copy algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename FwdIter>
ranges::copy_result<typename hpx::traits::range_traits<Rng>::iterator_type, FwdIter> copy(Rng &&rng, FwdIter dest)#
+

Copies the elements in the range rng to another range beginning at dest.

+
+

Note

+

Complexity: Performs exactly std::distance(begin(rng), end(rng)) assignments.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The copy algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Size, typename FwdIter2>
hpx::parallel::util::detail::algorithm_result<ExPolicy, ranges::copy_n_result<FwdIter1, FwdIter2>>::type copy_n(ExPolicy &&policy, FwdIter1 first, Size count, FwdIter2 dest)#
+

Copies the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest.

+

+The assignments in the parallel copy_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel copy_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The copy_n algorithm returns a hpx::future<ranges::copy_n_result<FwdIter1, FwdIter2> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::copy_n_result<FwdIter1, FwdIter2> otherwise. The copy algorithm returns the pair of the input iterator forwarded to the first element after the last in the input sequence and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename Size, typename FwdIter2>
ranges::copy_n_result<FwdIter1, FwdIter2> copy_n(FwdIter1 first, Size count, FwdIter2 dest)#
+

Copies the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The copy algorithm returns the pair of the input iterator forwarded to the first element after the last in the input sequence and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent1, typename FwdIter, typename Pred, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, ranges::copy_if_result<FwdIter1, FwdIter>>::type copy_if(ExPolicy &&policy, FwdIter1 iter, Sent1 sent, FwdIter dest, Pred &&pred, Proj &&proj = Proj())#
+

Copies the elements in the range, defined by [first, last) to another range beginning at dest. The order of the elements that are not removed is preserved.

+

+The assignments in the parallel copy_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for FwdIter1.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • iter – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1 .

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The copy_if algorithm returns a hpx::future<ranges::copy_if_result<iterator_t<Rng>, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::copy_if_result<iterator_t<Rng>, FwdIter2> otherwise. The copy_if algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename FwdIter, typename Pred, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, ranges::copy_if_result<typename hpx::traits::range_traits<Rng>::iterator_type, FwdIter>>::type copy_if(ExPolicy &&policy, Rng &&rng, FwdIter dest, Pred &&pred, Proj &&proj = Proj())#
+

Copies the elements in the range, defined by rng to another range beginning at dest. The order of the elements that are not removed is preserved.

+

+The assignments in the parallel copy_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1 .

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The copy_if algorithm returns a hpx::future<ranges::copy_if_result<iterator_t<Rng>, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::copy_if_result<iterator_t<Rng>, FwdIter2> otherwise. The copy_if algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename Sent1, typename FwdIter, typename Pred, typename Proj = hpx::identity>
ranges::copy_if_result<FwdIter1, FwdIter> copy_if(FwdIter1 iter, Sent1 sent, FwdIter dest, Pred &&pred, Proj &&proj = Proj())#
+

Copies the elements in the range, defined by [first, last) to another range beginning at dest. The order of the elements that are not removed is preserved.

+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for FwdIter1.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • iter – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1 .

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The copy_if algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename FwdIter, typename Pred, typename Proj = hpx::identity>
ranges::copy_if_result<typename hpx::traits::range_traits<Rng>::iterator_type, FwdIter> copy_if(Rng &&rng, FwdIter dest, Pred &&pred, Proj &&proj = Proj())#
+

Copies the elements in the range, defined by rng to another range beginning at dest. The order of the elements that are not removed is preserved.

+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1 .

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The copy_if algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::count, hpx::ranges::count_if#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Rng, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type>
hpx::parallel::util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<typename hpx::traits::range_traits<Rng>::iterator_type>::difference_type>::type count(ExPolicy &&policy, Rng &&rng, T const &value, Proj &&proj = Proj())#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts the elements that are equal to the given value.

+

+The comparisons in the parallel count algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first comparisons.

+
+
+

Note

+

The comparisons in the parallel count algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the comparisons.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to search for (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to search for.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The count algorithm returns a hpx::future<difference_type> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by std::iterator_traits<FwdIter>::difference_type. The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<Iter, Proj>::value_type>
hpx::parallel::util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<Iter>::difference_type>::type count(ExPolicy &&policy, Iter first, Sent last, T const &value, Proj &&proj = Proj())#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts the elements that are equal to the given value.

+

+The comparisons in the parallel count algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first comparisons.

+
+
+

Note

+

The comparisons in the parallel count algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the comparisons.

  • +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • T – The type of the value to search for (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to search for.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The count algorithm returns a hpx::future<difference_type> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by std::iterator_traits<FwdIter>::difference_type. The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+template<typename Rng, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type>
std::iterator_traits<typename hpx::traits::range_traits<Rng>::iterator_type>::difference_type count(Rng &&rng, T const &value, Proj &&proj = Proj())#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts the elements that are equal to the given value.

+
+

Note

+

Complexity: Performs exactly last - first comparisons.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to search for (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to search for.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<Iter, Proj>::value_type>
std::iterator_traits<Iter>::difference_type count(Iter first, Sent last, T const &value, Proj &&proj = Proj())#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts the elements that are equal to the given value.

+
+

Note

+

Complexity: Performs exactly last - first comparisons.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • T – The type of the value to search for (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to search for.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<typename hpx::traits::range_traits<Rng>::iterator_type>::difference_type>::type count_if(ExPolicy &&policy, Rng &&rng, F &&f, Proj &&proj = Proj())#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts elements for which predicate f returns true.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+

Note

+

The assignments in the parallel count_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+
+
+

Note

+

The assignments in the parallel count_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the comparisons.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of count_if requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The count_if algorithm returns hpx::future<difference_type> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by std::iterator_traits<FwdIter>::difference_type. The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<Iter>::difference_type>::type count_if(ExPolicy &&policy, Iter first, Sent last, F &&f, Proj &&proj = Proj())#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts elements for which predicate f returns true.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+

Note

+

The assignments in the parallel count_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+
+
+

Note

+

The assignments in the parallel count_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the comparisons.

  • +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of count_if requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The count_if algorithm returns hpx::future<difference_type> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by std::iterator_traits<FwdIter>::difference_type. The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+template<typename Rng, typename F, typename Proj = hpx::identity>
std::iterator_traits<typename hpx::traits::range_traits<Rng>::iterator_type>::difference_type count_if(Rng &&rng, F &&f, Proj &&proj = Proj())#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts elements for which predicate f returns true.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of count_if requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename F, typename Proj = hpx::identity>
std::iterator_traits<Iter>::difference_type count_if(Iter first, Sent last, F &&f, Proj &&proj = Proj())#
+

Returns the number of elements in the range [first, last) satisfying a specific criteria. This version counts elements for which predicate f returns true.

+
+

Note

+

Complexity: Performs exactly last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of count_if requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The count algorithm returns the number of elements satisfying the given criteria.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::destroy, hpx::ranges::destroy_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Rng>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> destroy(ExPolicy &&policy, Rng &&rng)#
+

Destroys objects of type typename iterator_traits<ForwardIt>::value_type in the range [first, last).

+

+The operations in the parallel destroy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The operations in the parallel destroy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first operations.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The destroy algorithm returns a hpx::future<void>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> destroy(ExPolicy &&policy, Iter first, Sent last)#
+

Destroys objects of type typename iterator_traits<ForwardIt>::value_type in the range [first, last).

+

+The operations in the parallel destroy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The operations in the parallel destroy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first operations.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The destroy algorithm returns a hpx::future<void>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename Rng>
hpx::traits::range_iterator<Rng>::type destroy(Rng &&rng)#
+

Destroys objects of type typename iterator_traits<ForwardIt>::value_type in the range [first, last).

+
+

Note

+

Complexity: Performs exactly last - first operations.

+
+
+
Template Parameters
+

Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

+
+
Parameters
+

rng – Refers to the sequence of elements the algorithm will be applied to.

+
+
Returns
+

The destroy algorithm returns void.

+
+
+
+ +
+
+template<typename Iter, typename Sent>
Iter destroy(Iter first, Sent last)#
+

Destroys objects of type typename iterator_traits<ForwardIt>::value_type in the range [first, last).

+
+

Note

+

Complexity: Performs exactly last - first operations.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The destroy algorithm returns void.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size>
hpx::parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type destroy_n(ExPolicy &&policy, FwdIter first, Size count)#
+

Destroys objects of type typename iterator_traits<ForwardIt>::value_type in the range [first, first + count).

+

+The operations in the parallel destroy_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The operations in the parallel destroy_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count operations, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply this algorithm to.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The destroy_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The destroy_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+template<typename FwdIter, typename Size>
FwdIter destroy_n(FwdIter first, Size count)#
+

Destroys objects of type typename iterator_traits<ForwardIt>::value_type in the range [first, first + count).

+
+

Note

+

Complexity: Performs exactly count operations, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply this algorithm to.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The destroy_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::ends_with#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
bool ends_with(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks whether the second range defined by [first1, last1) matches the suffix of the first range defined by [first2, last2)

+

+The assignments in the parallel ends_with algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent1 – The type of the end source iterators used(deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the begin destination iterators used deduced). This iterator type must meet the requirements of a input iterator.

  • +
  • Sent2 – The type of the end destination iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Pred – The binary predicate that compares the projected elements.

  • +
  • Proj1 – The type of an optional projection function for the source range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for the destination range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the source range.

  • +
  • last1 – Sentinel value referring to the end of the source range.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Sentinel value referring to the end of the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements in the source range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements in the destination range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The ends_with algorithm returns bool. The ends_with algorithm returns a boolean with the value true if the second range matches the suffix of the first range, false otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent1, typename FwdIter2, typename Sent2, typename Pred = ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, bool>::type ends_with(ExPolicy &&policy, FwdIter1 first1, Sent1 last1, FwdIter2 first2, Sent2 last2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks whether the second range defined by [first1, last1) matches the suffix of the first range defined by [first2, last2)

+

+The assignments in the parallel ends_with algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel ends_with algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used(deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • FwdIter2 – The type of the begin destination iterators used deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the end destination iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Pred – The binary predicate that compares the projected elements.

  • +
  • Proj1 – The type of an optional projection function for the source range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for the destination range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the source range.

  • +
  • last1 – Sentinel value referring to the end of the source range.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Sentinel value referring to the end of the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements in the source range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements in the destination range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The ends_with algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The ends_with algorithm returns a boolean with the value true if the second range matches the suffix of the first range, false otherwise.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Pred = ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
bool ends_with(Rng1 &&rng1, Rng2 &&rng2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks whether the second range rng2 matches the suffix of the first range rng1.

+

+The assignments in the parallel ends_with algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The binary predicate that compares the projected elements.

  • +
  • Proj1 – The type of an optional projection function for the source range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for the destination range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the source range.

  • +
  • rng2 – Refers to the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements in the source range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements in the destination range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The ends_with algorithm returns bool. The ends_with algorithm returns a boolean with the value true if the second range matches the suffix of the first range, false otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Pred = ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, bool>::type ends_with(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks whether the second range rng2 matches the suffix of the first range rng1.

+

+The assignments in the parallel ends_with algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel ends_with algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The binary predicate that compares the projected elements.

  • +
  • Proj1 – The type of an optional projection function for the source range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for the destination range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the source range.

  • +
  • rng2 – Refers to the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements in the source range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements in the destination range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The ends_with algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The ends_with algorithm returns a boolean with the value true if the second range matches the suffix of the first range, false otherwise.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::equal#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> equal(ExPolicy &&policy, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns true if the range [first1, last1) is equal to the range [first2, last2), and false otherwise.

+

+The comparison operations in the parallel equal algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel equal algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most min(last1 - first1, last2 - first2) applications of the predicate f.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the source iterators used for the end of the first range (deduced).

  • +
  • Iter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the source iterators used for the end of the second range (deduced).

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The equal algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false. If the length of the range [first1, last1) does not equal the length of the range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> equal(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns true if the range [first1, last1) is equal to the range starting at first2, and false otherwise.

+

+The comparison operations in the parallel equal algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel equal algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last1 - first1 applications of the predicate f.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the first source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Rng2 – The type of the second source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The equal algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false.

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
bool equal(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns true if the range [first1, last1) is equal to the range [first2, last2), and false otherwise.

+
+

Note

+

Complexity: At most min(last1 - first1, last2 - first2) applications of the predicate f.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the source iterators used for the end of the first range (deduced).

  • +
  • Iter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the source iterators used for the end of the second range (deduced).

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false. If the length of the range [first1, last1) does not equal the length of the range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
bool equal(Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns true if the range [first1, last1) is equal to the range starting at first2, and false otherwise.

+
+

Note

+

Complexity: At most last1 - first1 applications of the predicate f.

+
+
+

Note

+

The two ranges are considered equal if, for every iterator i in the range [first1,last1), *i equals *(first2 + (i - first1)). This overload of equal uses operator== to determine if two elements are equal.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the first source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Rng2 – The type of the second source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The equal algorithm returns true if the elements in the two ranges are equal, otherwise it returns false.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::exclusive_scan#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename InIter, typename Sent, typename OutIter, typename T = typename std::iterator_traits<InIter>::value_type, typename Op = std::plus<T>>
exclusive_scan_result<InIter, OutIter> exclusive_scan(InIter first, Sent last, OutIter dest, T init, Op &&op = Op())#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, *first, …, *(first + (i - result) - 1)).

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum. If op is not mathematically associative, the behavior of inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter1.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The exclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2, typename T = typename std::iterator_traits<FwdIter1>::value_type, typename Op = std::plus<T>>
parallel::util::detail::algorithm_result<ExPolicy, exclusive_scan_result<FwdIter1, FwdIter2>>::type exclusive_scan(ExPolicy &&policy, FwdIter1 first, Sent last, FwdIter2 dest, T init, Op &&op = Op())#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, *first, …, *(first + (i - result) - 1)).

+

+The reduce operations in the parallel exclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel exclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum. If op is not mathematically associative, the behavior of inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter1.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The exclusive_scan algorithm returns a hpx::future<util::in_out_result<FwdIter1, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns util::in_out_result<FwdIter1, FwdIter2> otherwise. The exclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename O, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type, typename Op = std::plus<T>>
exclusive_scan_result<traits::range_iterator_t<Rng>, O> exclusive_scan(Rng &&rng, O dest, T init, Op &&op = Op())#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(+, init, *first, …, *(first + (i - result) - 1))

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate std::plus<T>.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The exclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename O, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type, typename Op = std::plus<T>>
parallel::util::detail::algorithm_result<ExPolicy, exclusive_scan_result<traits::range_iterator_t<Rng>, O>> exclusive_scan(ExPolicy &&policy, Rng &&rng, O dest, T init, Op &&op = Op())#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(+, init, *first, …, *(first + (i - result) - 1))

+

+The reduce operations in the parallel exclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel exclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate std::plus<T>.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The exclusive_scan algorithm returns a hpx::future<util::in_out_result <traits::range_iterator_t<Rng>, O>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns util::in_out_result <traits::range_iterator_t<Rng>, O> otherwise. The exclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::fill, hpx::ranges::fill_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Rng, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
hpx::parallel::util::detail::algorithm_result<ExPolicy, typename hpx::traits::range_traits<Rng>::iterator_type>::type fill(ExPolicy &&policy, Rng &&rng, T const &value)#
+

Assigns the given value to the elements in the range [first, last).

+

+The comparisons in the parallel fill algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel fill algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by void.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename T = typename std::iterator_traits<Iter>::value_type>
hpx::parallel::util::detail::algorithm_result<ExPolicy, Iter>::type fill(ExPolicy &&policy, Iter first, Sent last, T const &value)#
+

Assigns the given value to the elements in the range [first, last).

+

+The comparisons in the parallel fill algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel fill algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by void.

+
+
+
+ +
+
+template<typename Rng, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
hpx::traits::range_iterator_t<Rng> fill(Rng &&rng, T const &value)#
+

Assigns the given value to the elements in the range [first, last).

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill algorithm returns void.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename T = typename std::iterator_traits<Iter>::value_type>
Iter fill(Iter first, Sent last, T const &value)#
+

Assigns the given value to the elements in the range [first, last).

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the range (deduced).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the range the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill algorithm returns void.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, hpx::traits::range_iterator_t<Rng>> fill_n(ExPolicy &&policy, Rng &&rng, T const &value)#
+

Assigns the given value value to the first count elements in the range beginning at first if count > 0. Does nothing otherwise.

+

+The comparisons in the parallel fill_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel fill_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill_n algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by void.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size, typename T = typename std::iterator_traits<FwdIter>::value_type>
hpx::parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type fill_n(ExPolicy &&policy, FwdIter first, Size count, T const &value)#
+

Assigns the given value value to the first count elements in the range beginning at first if count > 0. Does nothing otherwise.

+

+The comparisons in the parallel fill_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel fill_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, for count > 0.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill_n algorithm returns a hpx::future<void> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns difference_type otherwise (where difference_type is defined by void.

+
+
+
+ +
+
+template<typename Rng, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
hpx::traits::range_traits<Rng>::iterator_type fill_n(Rng &&rng, T const &value)#
+

Assigns the given value value to the first count elements in the range beginning at first if count > 0. Does nothing otherwise.

+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill_n algorithm returns an output iterator that compares equal to last.

+
+
+
+ +
+
+template<typename FwdIter, typename Size, typename T = typename std::iterator_traits<FwdIter>::value_type>
FwdIter fill_n(Iterator first, Size count, T const &value)#
+

Assigns the given value value to the first count elements in the range beginning at first if count > 0. Does nothing otherwise.

+
+

Note

+

Complexity: Performs exactly count assignments, for count > 0.

+
+
+
Template Parameters
+
    +
  • Iterator – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The fill_n algorithm returns an output iterator that compares equal to last.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::find, hpx::ranges::find_if, hpx::ranges::find_if_not, hpx::ranges::find_end, hpx::ranges::find_first_of#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<Iter, Proj>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> find(ExPolicy &&policy, Iter first, Sent last, T const &val, Proj &&proj = Proj())#
+

Returns the first element in the range [first, last) that is equal to value

+

+The comparison operations in the parallel find algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the operator==().

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • T – The type of the value to find (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • val – the value to compare the elements to

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find algorithm returns the first element in the range [first,last) that is equal to val. If no such element in the range of [first,last) is equal to val, then the algorithm returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> find(ExPolicy &&policy, Rng &&rng, T const &val, Proj &&proj = Proj())#
+

Returns the first element in the range [first, last) that is equal to value

+

+The comparison operations in the parallel find algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the operator==().

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to find (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • val – the value to compare the elements to

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find algorithm returns the first element in the range [first,last) that is equal to val. If no such element in the range of [first,last) is equal to val, then the algorithm returns last.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<Iter, Proj>::value_type>
Iter find(Iter first, Sent last, T const &val, Proj &&proj = Proj())#
+

Returns the first element in the range [first, last) that is equal to value

+
+

Note

+

Complexity: At most last - first applications of the operator==().

+
+
+
Template Parameters
+
    +
  • Iter – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • T – The type of the value to find (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • val – the value to compare the elements to

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find algorithm returns the first element in the range [first,last) that is equal to val. If no such element in the range of [first,last) is equal to val, then the algorithm returns last.

+
+
+
+ +
+
+template<typename Rng, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type>
hpx::traits::range_iterator_t<Rng> find(Rng &&rng, T const &val, Proj &&proj = Proj())#
+

Returns the first element in the range [first, last) that is equal to value

+

+The comparison operations in the parallel find algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the operator==().

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to find (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • val – the value to compare the elements to

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find algorithm returns the first element in the range [first,last) that is equal to val. If no such element in the range of [first,last) is equal to val, then the algorithm returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Pred, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> find_if(ExPolicy &&policy, Iter first, Sent last, Pred &&pred, Proj &&proj = Proj())#
+

Returns the first element in the range [first, last) for which predicate pred returns true

+

+The comparison operations in the parallel find_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • pred – The unary predicate which returns true for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find_if algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find_if algorithm returns the first element in the range [first,last) that satisfies the predicate f. If no such element exists that satisfies the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> find_if(ExPolicy &&policy, Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Returns the first element in the range rng for which predicate pred returns true

+

+The comparison operations in the parallel find_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – The unary predicate which returns true for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find_if algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find_if algorithm returns the first element in the range [first,last) that satisfies the predicate f. If no such element exists that satisfies the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Pred, typename Proj = hpx::identity>
Iter find_if(Iter first, Sent last, Pred &&pred, Proj &&proj = Proj())#
+

Returns the first element in the range [first, last) for which predicate pred returns true

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • pred – The unary predicate which returns true for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find_if algorithm returns the first element in the range [first,last) that satisfies the predicate f. If no such element exists that satisfies the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename Rng, typename Pred, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> find_if(Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Returns the first element in the range rng for which predicate pred returns true

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – The unary predicate which returns true for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find_if algorithm returns the first element in the range [first,last) that satisfies the predicate f. If no such element exists that satisfies the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Pred, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, Iter>::type find_if_not(ExPolicy &&policy, Iter first, Sent last, Pred &&pred, Proj &&proj = Proj())#
+

Returns the first element in the range [first, last) for which predicate f returns false

+

+The comparison operations in the parallel find_if_not algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_if_not algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • pred – The unary predicate which returns false for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find_if_not algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find_if_not algorithm returns the first element in the range [first, last) that does not satisfy the predicate f. If no such element exists that does not satisfy the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> find_if_not(ExPolicy &&policy, Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Returns the first element in the range rng for which predicate f returns false

+

+The comparison operations in the parallel find_if_not algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_if_not algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – The unary predicate which returns false for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find_if_not algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The find_if_not algorithm returns the first element in the range [first, last) that does not satisfy the predicate f. If no such element exists that does not satisfy the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Pred, typename Proj = hpx::identity>
Iter find_if_not(Iter first, Sent last, Pred &&pred, Proj &&proj = Proj())#
+

Returns the first element in the range [first, last) for which predicate f returns false

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • pred – The unary predicate which returns false for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find_if_not algorithm returns the first element in the range [first, last) that does not satisfy the predicate f. If no such element exists that does not satisfy the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename Rng, typename Pred, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> find_if_not(Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Returns the first element in the range rng for which predicate f returns false

+
+

Note

+

Complexity: At most last - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – The unary predicate which returns false for the required element. The signature of the predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The find_if_not algorithm returns the first element in the range [first, last) that does not satisfy the predicate f. If no such element exists that does not satisfy the predicate f, the algorithm returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng1>> find_end(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns the last subsequence of elements rng2 found in the range rng using the given predicate f to compare elements.

+

+The comparison operations in the parallel find_end algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_end algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+This overload of find_end is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most S*(N-S+1) comparisons where S = distance(begin(rng2), end(rng2)) and N = distance(begin(rng), end(rng)).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the first source range (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Rng2 – The type of the second source range (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of replace requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types iterator_t<Rng> and iterator_t<Rng2> can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range of type dereferenced iterator_t<Rng1> as a projection operation before the function op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range of type dereferenced iterator_t<Rng2> as a projection operation before the function op is invoked.

  • +
+
+
Returns
+

The find_end algorithm returns a hpx::future<iterator_t<Rng> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns iterator_t<Rng> otherwise. The find_end algorithm returns an iterator to the beginning of the last subsequence rng2 in range rng. If the length of the subsequence rng2 is greater than the length of the range rng, end(rng) is returned. Additionally if the size of the subsequence is empty or no subsequence is found, end(rng) is also returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter1> find_end(ExPolicy &&policy, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns the last subsequence of elements [first2, last2) found in the range [first1, last1) using the given predicate f to compare elements.

+

+The comparison operations in the parallel find_end algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_end algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+This overload of find_end is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most S*(N-S+1) comparisons where S = distance(first2, last2) and N = distance(first1, last1).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter1 – The type of the begin source iterators for the first sequence used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators for the first sequence used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the begin source iterators for the second sequence used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators for the second sequence used (deduced). This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of replace requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types iterator_t<Rng> and iterator_t<Rng2> can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range of type dereferenced iterator_t<Rng1> as a projection operation before the function op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range of type dereferenced iterator_t<Rng2> as a projection operation before the function op is invoked.

  • +
+
+
Returns
+

The find_end algorithm returns a hpx::future<iterator_t<Rng> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns iterator_t<Rng> otherwise. The find_end algorithm returns an iterator to the beginning of the last subsequence rng2 in range rng. If the length of the subsequence rng2 is greater than the length of the range rng, end(rng) is returned. Additionally if the size of the subsequence is empty or no subsequence is found, end(rng) is also returned.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::traits::range_iterator_t<Rng1> find_end(Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns the last subsequence of elements rng2 found in the range rng using the given predicate f to compare elements.

+

+This overload of find_end is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most S*(N-S+1) comparisons where S = distance(begin(rng2), end(rng2)) and N = distance(begin(rng), end(rng)).

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the first source range (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Rng2 – The type of the second source range (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of replace requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types iterator_t<Rng> and iterator_t<Rng2> can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range of type dereferenced iterator_t<Rng1> as a projection operation before the function op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range of type dereferenced iterator_t<Rng2> as a projection operation before the function op is invoked.

  • +
+
+
Returns
+

The find_end algorithm returns an iterator to the beginning of the last subsequence rng2 in range rng. If the length of the subsequence rng2 is greater than the length of the range rng, end(rng) is returned. Additionally if the size of the subsequence is empty or no subsequence is found, end(rng) is also returned.

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
Iter1 find_end(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns the last subsequence of elements [first2, last2) found in the range [first1, last1) using the given predicate f to compare elements.

+

+This overload of find_end is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most S*(N-S+1) comparisons where S = distance(first2, last2) and N = distance(first1, last1).

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the begin source iterators for the first sequence used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators for the first sequence used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the begin source iterators for the second sequence used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators for the second sequence used (deduced). This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of replace requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types iterator_t<Rng> and iterator_t<Rng2> can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range of type dereferenced iterator_t<Rng1> as a projection operation before the function op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range of type dereferenced iterator_t<Rng2> as a projection operation before the function op is invoked.

  • +
+
+
Returns
+

The find_end algorithm returns an iterator to the beginning of the last subsequence rng2 in range rng. If the length of the subsequence rng2 is greater than the length of the range rng, end(rng) is returned. Additionally if the size of the subsequence is empty or no subsequence is found, end(rng) is also returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng1>> find_first_of(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range rng1 for any elements in the range rng2. Uses binary predicate p to compare elements

+

+The comparison operations in the parallel find_first_of algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_first_of algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+This overload of find_first_of is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(begin(rng2), end(rng2)) and N = distance(begin(rng1), end(rng1)).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the first source range (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Rng2 – The type of the second source range (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of replace requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements in rng1.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements in rng2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types iterator_t<Rng1> and iterator_t<Rng2> can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced iterator_t<Rng1> before the function op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced iterator_t<Rng2> before the function op is invoked.

  • +
+
+
Returns
+

The find_end algorithm returns a hpx::future<iterator_t<Rng1> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns iterator_t<Rng1> otherwise. The find_first_of algorithm returns an iterator to the first element in the range rng1 that is equal to an element from the range rng2. If the length of the subsequence rng2 is greater than the length of the range rng1, end(rng1) is returned. Additionally if the size of the subsequence is empty or no subsequence is found, end(rng1) is also returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter1> find_first_of(ExPolicy &&policy, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range [first1, last1) for any elements in the range [first2, last2). Uses binary predicate p to compare elements

+

+The comparison operations in the parallel find_first_of algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel find_first_of algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+This overload of find_first_of is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(first2, last2) and N = distance(first1, last1).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter1 – The type of the begin source iterators for the first sequence used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators for the first sequence used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the begin source iterators for the second sequence used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators for the second sequence used (deduced). This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of replace requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements in rng1.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements in rng2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types iterator_t<Rng1> and iterator_t<Rng2> can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced iterator_t<Rng1> before the function op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced iterator_t<Rng2> before the function op is invoked.

  • +
+
+
Returns
+

The find_end algorithm returns a hpx::future<iterator_t<Rng1> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns iterator_t<Rng1> otherwise. The find_first_of algorithm returns an iterator to the first element in the range rng1 that is equal to an element from the range rng2. If the length of the subsequence rng2 is greater than the length of the range rng1, end(rng1) is returned. Additionally if the size of the subsequence is empty or no subsequence is found, end(rng1) is also returned.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::traits::range_iterator_t<Rng1> find_first_of(Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range rng1 for any elements in the range rng2. Uses binary predicate p to compare elements

+

+This overload of find_first_of is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(begin(rng2), end(rng2)) and N = distance(begin(rng1), end(rng1)).

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the first source range (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Rng2 – The type of the second source range (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of replace requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements in rng1.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements in rng2.

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types iterator_t<Rng1> and iterator_t<Rng2> can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced iterator_t<Rng1> before the function op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced iterator_t<Rng2> before the function op is invoked.

  • +
+
+
Returns
+

The find_first_of algorithm returns an iterator to the first element in the range rng1 that is equal to an element from the range rng2. If the length of the subsequence rng2 is greater than the length of the range rng1, end(rng1) is returned. Additionally if the size of the subsequence is empty or no subsequence is found, end(rng1) is also returned.

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
Iter1 find_first_of(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range [first1, last1) for any elements in the range [first2, last2). Uses binary predicate p to compare elements

+

+This overload of find_first_of is available if the user decides to provide the algorithm their own predicate op.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(first2, last2) and N = distance(first1, last1).

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the begin source iterators for the first sequence used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators for the first sequence used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the begin source iterators for the second sequence used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators for the second sequence used (deduced). This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of replace requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements in rng1.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements in rng2.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types iterator_t<Rng1> and iterator_t<Rng2> can be dereferenced and then implicitly converted to Type1 and Type2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced iterator_t<Rng1> before the function op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced iterator_t<Rng2> before the function op is invoked.

  • +
+
+
Returns
+

The find_first_of algorithm returns an iterator to the first element in the range rng1 that is equal to an element from the range rng2. If the length of the subsequence rng2 is greater than the length of the range rng1, end(rng1) is returned. Additionally if the size of the subsequence is empty or no subsequence is found, end(rng1) is also returned.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::for_each, hpx::ranges::for_each_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename InIter, typename Sent, typename F, typename Proj = hpx::identity>
for_each_result<InIter, F> for_each(InIter first, Sent last, F &&f, Proj &&proj = Proj())#
+

Applies f to the result of dereferencing every iterator in the range [first, last).

+

+If f returns a result, the result is ignored.

+

If the type of first satisfies the requirements of a mutable iterator, f may apply non-constant functions through the dereferenced iterator.

+
+

Note

+

Complexity: Applies f exactly last - first times.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of for_each requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    <ignored> pred(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

{last, HPX_MOVE(f)} where last is the iterator corresponding to the input sentinel last.

+
+
+
+ +
+
+template<typename Rng, typename F, typename Proj = hpx::identity>
for_each_result<hpx::traits::range_iterator_t<Rng>, F> for_each(Rng &&rng, F &&f, Proj &&proj = Proj())#
+

Applies f to the result of dereferencing every iterator in the given range rng.

+

+If f returns a result, the result is ignored.

+

If the type of first satisfies the requirements of a mutable iterator, f may apply non-constant functions through the dereferenced iterator.

+
+

Note

+

Complexity: Applies f exactly size(rng) times.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of for_each requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    <ignored> pred(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

{std::end(rng), HPX_MOVE(f)}

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> for_each(ExPolicy &&policy, FwdIter first, Sent last, F &&f, Proj &&proj = Proj())#
+

Applies f to the result of dereferencing every iterator in the range [first, last).

+

+If f returns a result, the result is ignored.

+

If the type of first satisfies the requirements of a mutable iterator, f may apply non-constant functions through the dereferenced iterator.

+

Unlike its sequential form, the parallel overload of for_each does not return a copy of its Function parameter, since parallelization may not permit efficient state accumulation.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Applies f exactly last - first times.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of for_each requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    <ignored> pred(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The for_each algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> for_each(ExPolicy &&policy, Rng &&rng, F &&f, Proj &&proj = Proj())#
+

Applies f to the result of dereferencing every iterator in the given range rng.

+

+If f returns a result, the result is ignored.

+

If the type of first satisfies the requirements of a mutable iterator, f may apply non-constant functions through the dereferenced iterator.

+

Unlike its sequential form, the parallel overload of for_each does not return a copy of its Function parameter, since parallelization may not permit efficient state accumulation.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Applies f exactly size(rng) times.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of for_each requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    <ignored> pred(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The for_each algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. It returns last.

+
+
+
+ +
+
+template<typename InIter, typename Size, typename F, typename Proj = hpx::identity>
for_each_n_result<InIter, F> for_each_n(InIter first, Size count, F &&f, Proj &&proj = Proj())#
+

Applies f to the result of dereferencing every iterator in the range [first, first + count), starting from first and proceeding to first + count - 1.

+

+If f returns a result, the result is ignored.

+

If the type of first satisfies the requirements of a mutable iterator, f may apply non-constant functions through the dereferenced iterator.

+

Unlike its sequential form, the parallel overload of for_each does not return a copy of its Function parameter, since parallelization may not permit efficient state accumulation.

+
+

Note

+

Complexity: Applies f exactly count times.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of for_each requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    <ignored> pred(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size, typename F, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type for_each_n(ExPolicy &&policy, FwdIter first, Size count, F &&f, Proj &&proj = Proj())#
+

Applies f to the result of dereferencing every iterator in the range [first, first + count), starting from first and proceeding to first + count - 1.

+

+If f returns a result, the result is ignored.

+

If the type of first satisfies the requirements of a mutable iterator, f may apply non-constant functions through the dereferenced iterator.

+

Unlike its sequential form, the parallel overload of for_each does not return a copy of its Function parameter, since parallelization may not permit efficient state accumulation.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Applies f exactly count times.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • FwdIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of for_each requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    <ignored> pred(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The for_each algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. It returns last.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::experimental::for_loop, hpx::ranges::experimental::for_loop_strided, hpx::ranges::experimental::for_loop_n, hpx::ranges::experimental::for_loop_n_strided#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+
+namespace experimental#
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter, typename Sent, typename ...Args>
hpx::parallel::util::detail::algorithm_result<ExPolicy>::type for_loop(ExPolicy &&policy, Iter first, Sent last, Args&&... args)#
+

The for_loop implements loop functionality over a range specified by iterator bounds. These algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

+Requires: Iter shall meet the requirements of a forward iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Iter – The type of the iteration variable (forward iterator).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(Iter const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
Returns
+

The for_loop algorithm returns a hpx::future<void> if the execution policy is of type hpx::execution::sequenced_task_policy or hpx::execution::parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename ...Args>
void for_loop(Iter first, Sent last, Args&&... args)#
+

The for_loop implements loop functionality over a range specified by iterator bounds. These algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

The execution of for_loop without specifying an execution policy is equivalent to specifying hpx::execution::seq as the execution policy.

+

+Requires: Iter shall meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the iteration variable (input iterator).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(Iter const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
+
+ +
+
+template<typename ExPolicy, typename R, typename ...Args>
hpx::parallel::util::detail::algorithm_result<ExPolicy>::type for_loop(ExPolicy &&policy, R &&rng, Args&&... args)#
+

The for_loop implements loop functionality over a range specified by a range. These algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

+Requires: Rng::iterator shall meet the requirements of a forward iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • R – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to theof the sequence of elements the algorithm will be applied to.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(Rng::iterator const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
Returns
+

The for_loop algorithm returns a hpx::future<void> if the execution policy is of type hpx::execution::sequenced_task_policy or hpx::execution::parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename Rng, typename ...Args>
void for_loop(Rng &&rng, Args&&... args)#
+

The for_loop implements loop functionality over a range specified by a range. These algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

The execution of for_loop without specifying an execution policy is equivalent to specifying hpx::execution::seq as the execution policy.

+

+Requires: Rng::iterator shall meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • rng – Refers to theof the sequence of elements the algorithm will be applied to.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(Rng::iterator const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename S, typename ...Args>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> for_loop_strided(ExPolicy &&policy, Iter first, Sent last, S stride, Args&&... args)#
+

The for_loop_strided implements loop functionality over a range specified by iterator bounds. These algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

+Requires: Iter shall meet the requirements of a forward iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Iter – The type of the iteration variable (forward iterator).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • S – The type of the stride variable. This should be an integral type.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • stride – Refers to the stride of the iteration steps. This shall have non-zero value and shall be negative only if Iter meets the requirements a bidirectional iterator.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(Iter const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
Returns
+

The for_loop_strided algorithm returns a hpx::future<void> if the execution policy is of type hpx::execution::sequenced_task_policy or hpx::execution::parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename S, typename ...Args>
void for_loop_strided(Iter first, Sent last, S stride, Args&&... args)#
+

The for_loop_strided implements loop functionality over a range specified by iterator bounds. These algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

The execution of for_loop_strided without specifying an execution policy is equivalent to specifying hpx::execution::seq as the execution policy.

+

+Requires: Iter shall meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the iteration variable (input iterator).

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • S – The type of the stride variable. This should be an integral type.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • stride – Refers to the stride of the iteration steps. This shall have non-zero value and shall be negative only if Iter meets the requirements a bidirectional iterator.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(Iter const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename S, typename ...Args>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy> for_loop_strided(ExPolicy &&policy, Rng &&rng, S stride, Args&&... args)#
+

The for_loop_strided implements loop functionality over a range specified by a range. These algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

+Requires: Rng::iterator shall meet the requirements of a forward iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • S – The type of the stride variable. This should be an integral type.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to theof the sequence of elements the algorithm will be applied to.

  • +
  • stride – Refers to the stride of the iteration steps. This shall have non-zero value and shall be negative only if Rng::iterator meets the requirements a bidirectional iterator.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(Rng::iterator const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
Returns
+

The for_loop_strided algorithm returns a hpx::future<void> if the execution policy is of type hpx::execution::sequenced_task_policy or hpx::execution::parallel_task_policy and returns void otherwise.

+
+
+
+ +
+
+template<typename Rng, typename S, typename ...Args>
void for_loop_strided(Rng &&rng, S stride, Args&&... args)#
+

The for_loop_strided implements loop functionality over a range specified by a range. These algorithms resemble for_each from the Parallelism TS, but leave to the programmer when and if to dereference the iterator.

+

The execution of for_loop_strided without specifying an execution policy is equivalent to specifying hpx::execution::seq as the execution policy.

+

+Requires: Rng::iterator shall meet the requirements of an input iterator type. The args parameter pack shall have at least one element, comprising objects returned by invocations of reduction and/or induction function templates followed by exactly one element invocable element-access function, f. f shall meet the requirements of MoveConstructible.

+

Effects: Applies f to each element in the input sequence, with additional arguments corresponding to the reductions and inductions in the args parameter pack. The length of the input sequence is last - first.

+

The first element in the input sequence is specified by first. Each subsequent element is generated by incrementing the previous element.

+

+Along with an element from the input sequence, for each member of the args parameter pack excluding f, an additional argument is passed to each application of f as follows:

+

If the pack member is an object returned by a call to a reduction function listed in section, then the additional argument is a reference to a view of that reduction object. If the pack member is an object returned by a call to induction, then the additional argument is the induction value for that induction object corresponding to the position of the application of f in the input sequence.

+

Complexity: Applies f exactly once for each element of the input sequence.

+

Remarks: If f returns a result, the result is ignored.

+
+

Note

+

As described in the C++ standard, arithmetic on non-random-access iterators is performed using advance and distance.

+
+
+

Note

+

The order of the elements of the input sequence is important for determining ordinal position of an application of f, even though the applications themselves may be unordered.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • S – The type of the stride variable. This should be an integral type.

  • +
  • Args – A parameter pack, it’s last element is a function object to be invoked for each iteration, the others have to be either conforming to the induction or reduction concept.

  • +
+
+
Parameters
+
    +
  • rng – Refers to theof the sequence of elements the algorithm will be applied to.

  • +
  • stride – Refers to the stride of the iteration steps. This shall have non-zero value and shall be negative only if Rng::iterator meets the requirements a bidirectional iterator.

  • +
  • args – The last element of this parameter pack is the function (object) to invoke, while the remaining elements of the parameter pack are instances of either induction or reduction objects. The function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last) should expose a signature equivalent to:

    <ignored> pred(Rng::iterator const& a, ...);
    +
    +
    + + The signature does not need to have const&. It will receive the current value of the iteration variable and one argument for each of the induction or reduction objects passed to the algorithms, representing their current values.

  • +
+
+
+
+ +
+
+ +
+ +
+ +
+
+
hpx::ranges::generate, hpx::ranges::generate_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Rng, typename F>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> generate(ExPolicy &&policy, Rng &&rng, F &&f)#
+

Assign each element in range [first, last) a value generated by the given function object f

+

+The assignments in the parallel generate algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel generate algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly distance(first, last) invocations of f and assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – generator function that will be called. signature of function should be equivalent to the following:

    Ret fun();
    +
    +
    + + The type Ret must be such that an object of type FwdIter can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The replace_if algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename F>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> generate(ExPolicy &&policy, Iter first, Sent last, F &&f)#
+

Assign each element in range [first, last) a value generated by the given function object f

+

+The assignments in the parallel generate algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel generate algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly distance(first, last) invocations of f and assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source end iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – generator function that will be called. signature of function should be equivalent to the following:

    Ret fun();
    +
    +
    + + The type Ret must be such that an object of type FwdIter can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The replace_if algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. It returns last.

+
+
+
+ +
+
+template<typename Rng, typename F>
hpx::traits::range_iterator_t<Rng> generate(Rng &&rng, F &&f)#
+

Assign each element in range [first, last) a value generated by the given function object f

+
+

Note

+

Complexity: Exactly distance(first, last) invocations of f and assignments.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – generator function that will be called. signature of function should be equivalent to the following:

    Ret fun();
    +
    +
    + + The type Ret must be such that an object of type FwdIter can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The replace_if algorithm returns last.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename F>
Iter generate(Iter first, Sent last, F &&f)#
+

Assign each element in range [first, last) a value generated by the given function object f

+
+

Note

+

Complexity: Exactly distance(first, last) invocations of f and assignments.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source end iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – generator function that will be called. signature of function should be equivalent to the following:

    Ret fun();
    +
    +
    + + The type Ret must be such that an object of type FwdIter can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The replace_if algorithm returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size, typename F>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> generate_n(ExPolicy &&policy, FwdIter first, Size count, F &&f)#
+

Assigns each element in range [first, first+count) a value generated by the given function object g.

+

+The assignments in the parallel generate_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel generate_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly count invocations of f and assignments, for count > 0.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements in the sequence the algorithm will be applied to.

  • +
  • f – Refers to the generator function object that will be called. The signature of the function should be equivalent to

    Ret fun();
    +
    +
    + + The type Ret must be such that an object of type OutputIt can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The replace_if algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. It returns last.

+
+
+
+ +
+
+template<typename FwdIter, typename Size, typename F>
FwdIter generate_n(FwdIter first, Size count, F &&f)#
+

Assigns each element in range [first, first+count) a value generated by the given function object g.

+
+

Note

+

Complexity: Exactly count invocations of f and assignments, for count > 0.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements in the sequence the algorithm will be applied to.

  • +
  • f – Refers to the generator function object that will be called. The signature of the function should be equivalent to

    Ret fun();
    +
    +
    + + The type Ret must be such that an object of type OutputIt can be dereferenced and assigned a value of type Ret.

  • +
+
+
Returns
+

The replace_if algorithm returns last.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::includes#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> includes(ExPolicy &&policy, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns true if every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty. The version expects both ranges to be sorted with the user supplied binary predicate f.

+

+The comparison operations in the parallel includes algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel includes algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

At most 2*(N1+N2-1) comparisons, where N1 = std::distance(first1, last1) and N2 = std::distance(first2, last2).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of includes requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as includes. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The includes algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The includes algorithm returns true every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty.

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
bool includes(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns true if every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty. The version expects both ranges to be sorted with the user supplied binary predicate f.

+
+

Note

+

At most 2*(N1+N2-1) comparisons, where N1 = std::distance(first1, last1) and N2 = std::distance(first2, last2).

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of includes requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as includes. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The includes algorithm returns true every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> includes(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns true if every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty. The version expects both ranges to be sorted with the user supplied binary predicate f.

+

+The comparison operations in the parallel includes algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel includes algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

At most 2*(N1+N2-1) comparisons, where N1 = std::distance(first1, last1) and N2 = std::distance(first2, last2).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of includes requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as includes. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The includes algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The includes algorithm returns true every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
bool includes(Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns true if every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty. The version expects both ranges to be sorted with the user supplied binary predicate f.

+
+

Note

+

At most 2*(N1+N2-1) comparisons, where N1 = std::distance(first1, last1) and N2 = std::distance(first2, last2).

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of includes requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as includes. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The includes algorithm returns true every element from the sorted range [first2, last2) is found within the sorted range [first1, last1). Also returns true if [first2, last2) is empty.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::inclusive_scan#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename InIter, typename Sent, typename OutIter, typename Op = std::plus<typename std::iterator_traits<InIter>::value_type>>
inclusive_scan_result<InIter, OutIter> inclusive_scan(InIter first, Sent last, OutIter dest, Op &&op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns util::in_out_result<InIter, OutIter>. The inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2, typename Op = std::plus<typename std::iterator_traits<FwdIter1>::value_type>>
parallel::util::detail::algorithm_result<ExPolicy, inclusive_scan_result<FwdIter1, FwdIter2>>::type inclusive_scan(ExPolicy &&policy, FwdIter1 first, Sent last, FwdIter2 dest, Op &&op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns a hpx::future<util::in_out_result<FwdIter1, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns util::in_out_result<FwdIter1, FwdIter2> otherwise. The inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename O, typename Op = std::plus<typename hpx::traits::range_traits<Rng>::value_type>>
inclusive_scan_result<hpx::traits::range_iterator_t<Rng>, O> inclusive_scan(Rng &&rng, O dest, Op &&op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns util::in_out_result<traits::range_iterator_t<Rng>, O> The inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename O, typename Op = std::plus<typename hpx::traits::range_traits<Rng>::value_type>>
parallel::util::detail::algorithm_result<ExPolicy, inclusive_scan_result<hpx::traits::range_iterator_t<Rng>, O>> inclusive_scan(ExPolicy &&policy, Rng &&rng, O dest, Op &&op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(+, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK)

      +
    • GENERALIZED_NONCOMMUTATIVE_SUM(+, aM, …, aN) where 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns a hpx::future<util::in_out_result <traits::range_iterator_t<Rng>, O>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns util::in_out_result <traits::range_iterator_t<Rng>, O> otherwise. The inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied

+
+
+
+ +
+
+template<typename InIter, typename Sent, typename OutIter, typename Op, typename T = typename std::iterator_traits<InIter>::value_type>
inclusive_scan_result<InIter, OutIter> inclusive_scan(InIter first, Sent last, OutIter dest, Op &&op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, init, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum. If op is not mathematically associative, the behavior of inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns util::in_out_result<InIter, OutIter>. The inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2, typename Op, typename T = typename std::iterator_traits<FwdIter1>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, inclusive_scan_result<FwdIter1, FwdIter2>>::type inclusive_scan(ExPolicy &&policy, InIter first, Sent last, OutIter dest, Op &&op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, init, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum. If op is not mathematically associative, the behavior of inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns a hpx::future<util::in_out_result<InIter, OutIter>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns util::in_out_result<InIter, OutIter> otherwise. The inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename O, typename Op, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
inclusive_scan_result<hpx::traits::range_iterator_t<Rng>, O> inclusive_scan(Rng &&rng, O dest, Op &&op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, init, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum. If op is not mathematically associative, the behavior of inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns util::in_out_result<traits::range_iterator_t<Rng>, O> The inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename O, typename Op, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, inclusive_scan_result<hpx::traits::range_iterator_t<Rng>, O>> inclusive_scan(ExPolicy &&policy, Rng &&rng, O dest, Op &&op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, init, *first, …, *(first + (i - result))).

+

+The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between exclusive_scan and inclusive_scan is that inclusive_scan includes the ith input element in the ith sum. If op is not mathematically associative, the behavior of inclusive_scan may be non-deterministic.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN)) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Op – The type of the binary function object used for the reduction operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The inclusive_scan algorithm returns a hpx::future<util::in_out_result <traits::range_iterator_t<Rng>, O>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns util::in_out_result <traits::range_iterator_t<Rng>, O> otherwise. The inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::is_heap, hpx::ranges::is_heap_until#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Rng, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> is_heap(ExPolicy &&policy, Rng &&rng, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Returns whether the range is max heap. That is, true if the range is max heap, false otherwise. The function uses the given comparison function object comp (defaults to using operator<()).

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs at most N applications of the comparison comp, at most 2 * N applications of the projection proj, where N = last - first.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_heap algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The is_heap algorithm returns whether the range is max heap. That is, true if the range is max heap, false otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> is_heap(ExPolicy &&policy, Iter first, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Returns whether the range is max heap. That is, true if the range is max heap, false otherwise. The function uses the given comparison function object comp (defaults to using operator<()).

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs at most N applications of the comparison comp, at most 2 * N applications of the projection proj, where N = last - first.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_heap algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The is_heap algorithm returns whether the range is max heap. That is, true if the range is max heap, false otherwise.

+
+
+
+ +
+
+template<typename Rng, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
bool is_heap(Rng &&rng, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Returns whether the range is max heap. That is, true if the range is max heap, false otherwise. The function uses the given comparison function object comp (defaults to using operator<()).

+

comp has to induce a strict weak ordering on the values.

+
+

Note

+

Complexity: Performs at most N applications of the comparison comp, at most 2 * N applications of the projection proj, where N = last - first.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_heap algorithm returns bool. The is_heap algorithm returns whether the range is max heap. That is, true if the range is max heap, false otherwise.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
bool is_heap(Iter first, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Returns whether the range is max heap. That is, true if the range is max heap, false otherwise. The function uses the given comparison function object comp (defaults to using operator<()).

+

comp has to induce a strict weak ordering on the values.

+
+

Note

+

Complexity: Performs at most N applications of the comparison comp, at most 2 * N applications of the projection proj, where N = last - first.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_heap algorithm returns bool. The is_heap algorithm returns whether the range is max heap. That is, true if the range is max heap, false otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> is_heap_until(ExPolicy &&policy, Rng &&rng, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap. The function uses the given comparison function object comp (defaults to using operator<()).

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs at most N applications of the comparison comp, at most 2 * N applications of the projection proj, where N = last - first.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_heap_until algorithm returns a hpx::future<RandIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns RandIter otherwise. The is_heap_until algorithm returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> is_heap_until(ExPolicy &&policy, Iter first, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap. The function uses the given comparison function object comp (defaults to using operator<()).

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs at most N applications of the comparison comp, at most 2 * N applications of the projection proj, where N = last - first.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_heap_until algorithm returns a hpx::future<RandIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns RandIter otherwise. The is_heap_until algorithm returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap.

+
+
+
+ +
+
+template<typename Rng, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> is_heap_until(Rng &&rng, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap. The function uses the given comparison function object comp (defaults to using operator<()).

+

comp has to induce a strict weak ordering on the values.

+
+

Note

+

Complexity: Performs at most N applications of the comparison comp, at most 2 * N applications of the projection proj, where N = last - first.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_heap_until algorithm returns RandIter. The is_heap_until algorithm returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Comp = hpx::parallel::detail::less, typename Proj = hpx::identity>
Iter is_heap_until(Iter first, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap. The function uses the given comparison function object comp (defaults to using operator<()).

+

comp has to induce a strict weak ordering on the values.

+
+

Note

+

Complexity: Performs at most N applications of the comparison comp, at most 2 * N applications of the projection proj, where N = last - first.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • compcomp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_heap_until algorithm returns RandIter. The is_heap_until algorithm returns the upper bound of the largest range beginning at first which is a max heap. That is, the last iterator it for which range [first, it) is a max heap.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::is_partitioned#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent, typename Pred, typename Proj = hpx::identity>
bool is_partitioned(FwdIter first, Sent last, Pred &&pred, Proj &&proj = Proj())#
+

Determines if the range [first, last) is partitioned.

+
+

Note

+

Complexity: at most (N) predicate evaluations where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the unary predicate which returns true for elements expected to be found in the beginning of the range. The signature of the function should be equivalent to

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_partitioned algorithm returns bool. The is_partitioned algorithm returns true if each element in the sequence for which pred returns true precedes those for which pred returns false. Otherwise is_partitioned returns false. If the range [first, last) contains less than two elements, the function is always true.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename Pred, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> is_partitioned(ExPolicy &&policy, FwdIter first, Sent last, Pred &&pred, Proj &&proj = Proj())#
+

Determines if the range [first, last) is partitioned.

+

+The predicate operations in the parallel is_partitioned algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel is_partitioned algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (N) predicate evaluations where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of the function/function object to use (deduced). Pred must be CopyConstructible when using a parallel policy.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the unary predicate which returns true for elements expected to be found in the beginning of the range. The signature of the function should be equivalent to

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_partitioned algorithm returns a hpx::future<bool> if the execution policy is of type task_execution_policy and returns bool otherwise. The is_partitioned algorithm returns true if each element in the sequence for which pred returns true precedes those for which pred returns false. Otherwise is_partitioned returns false. If the range [first, last) contains less than two elements, the function is always true.

+
+
+
+ +
+
+template<typename Rng, typename Pred, typename Proj = hpx::identity>
bool is_partitioned(Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Determines if the range rng is partitioned.

+
+

Note

+

Complexity: at most (N) predicate evaluations where N = std::size(rng).

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Refers to the unary predicate which returns true for elements expected to be found in the beginning of the range. The signature of the function should be equivalent to

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_partitioned algorithm returns bool. The is_partitioned algorithm returns true if each element in the sequence for which pred returns true precedes those for which pred returns false. Otherwise is_partitioned returns false. If the range rng contains less than two elements, the function is always true.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> is_partitioned(ExPolicy &&policy, Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Determines if the range [first, last) is partitioned.

+

+The predicate operations in the parallel is_partitioned algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel is_partitioned algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (N) predicate evaluations where N = std::size(rng).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Pred must be CopyConstructible when using a parallel policy.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Refers to the unary predicate which returns true for elements expected to be found in the beginning of the range. The signature of the function should be equivalent to

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_partitioned algorithm returns a hpx::future<bool> if the execution policy is of type task_execution_policy and returns bool otherwise. The is_partitioned algorithm returns true if each element in the sequence for which pred returns true precedes those for which pred returns false. Otherwise is_partitioned returns false. If the range rng contains less than two elements, the function is always true.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::is_sorted, hpx::ranges::is_sorted_until#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
bool is_sorted(FwdIter first, Sent last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Determines if the range [first, last) is sorted. Uses pred to compare elements.

+

+The comparison operations in the parallel is_sorted algorithm executes in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = distance(first, last). S = number of partitions

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of an optional function/function object to use.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_sorted algorithm returns a bool. The is_sorted algorithm returns true if each element in the sequence [first, last) satisfies the predicate passed. If the range [first, last) contains less than two elements, the function always returns true.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> is_sorted(ExPolicy &&policy, FwdIter first, Sent last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Determines if the range [first, last) is sorted. Uses pred to compare elements.

+

+The comparison operations in the parallel is_sorted algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel is_sorted algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = distance(first, last). S = number of partitions

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of is_sorted requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_sorted algorithm returns a hpx::future<bool> if the execution policy is of type task_execution_policy and returns bool otherwise. The is_sorted algorithm returns a bool if each element in the sequence [first, last) satisfies the predicate passed. If the range [first, last) contains less than two elements, the function always returns true.

+
+
+
+ +
+
+template<typename Rng, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
bool is_sorted(Rng &&rng, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Determines if the range rng is sorted. Uses pred to compare elements.

+

+The comparison operations in the parallel is_sorted algorithm executes in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = size(rng). S = number of partitions

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_sorted algorithm returns a bool. The is_sorted algorithm returns true if each element in the rng satisfies the predicate passed. If the range rng contains less than two elements, the function always returns true.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> is_sorted(ExPolicy &&policy, Rng &&rng, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Determines if the range rng is sorted. Uses pred to compare elements.

+

+The comparison operations in the parallel is_sorted algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel is_sorted algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = size(rng). S = number of partitions

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of is_sorted requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_sorted algorithm returns a hpx::future<bool> if the execution policy is of type task_execution_policy and returns bool otherwise. The is_sorted algorithm returns a bool if each element in the range rng satisfies the predicate passed. If the range rng contains less than two elements, the function always returns true.

+
+
+
+ +
+
+template<typename FwdIter, typename Sent, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
FwdIter is_sorted_until(FwdIter first, Sent last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Returns the first element in the range [first, last) that is not sorted. Uses a predicate to compare elements or the less than operator.

+

+The comparison operations in the parallel is_sorted_until algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = distance(first, last). S = number of partitions

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of an optional function/function object to use.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_sorted_until algorithm returns a FwdIter. The is_sorted_until algorithm returns the first unsorted element. If the sequence has less than two elements or the sequence is sorted, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type is_sorted_until(ExPolicy &&policy, FwdIter first, Sent last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Returns the first element in the range [first, last) that is not sorted. Uses a predicate to compare elements or the less than operator.

+

+The comparison operations in the parallel is_sorted_until algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel is_sorted_until algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = distance(first, last). S = number of partitions

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of is_sorted_until requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of that the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of that the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_sorted_until algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The is_sorted_until algorithm returns the first unsorted element. If the sequence has less than two elements or the sequence is sorted, last is returned.

+
+
+
+ +
+
+template<typename Rng, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> is_sorted_until(Rng &&rng, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Returns the first element in the range rng that is not sorted. Uses a predicate to compare elements or the less than operator.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = size(rng). S = number of partitions

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of is_sorted_until requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_sorted_until returns FwdIter. The is_sorted_until algorithm returns the first unsorted element. If the sequence has less than two elements or the sequence is sorted, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> is_sorted_until(ExPolicy &&policy, Rng &&rng, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Returns the first element in the range rng that is not sorted. Uses a predicate to compare elements or the less than operator.

+

+The comparison operations in the parallel is_sorted_until algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel is_sorted_until algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (N+S-1) comparisons where N = size(rng). S = number of partitions

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of is_sorted_until requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Refers to the binary predicate which returns true if the first argument should be treated as less than the second argument. The signature of the function should be equivalent to

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The is_sorted_until algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The is_sorted_until algorithm returns the first unsorted element. If the sequence has less than two elements or the sequence is sorted, last is returned.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::lexicographical_compare#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename InIter1, typename Sent1, typename InIter2, typename Sent2, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity, typename Pred = hpx::parallel::detail::less>
bool lexicographical_compare(InIter1 first1, Sent1 last1, InIter2 first2, Sent2 last2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks if the first range [first1, last1) is lexicographically less than the second range [first2, last2). uses a provided predicate to compare elements.

+

+The comparison operations in the parallel lexicographical_compare algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most 2 * min(N1, N2) applications of the comparison operation, where N1 = std::distance(first1, last) and N2 = std::distance(first2, last2).

+
+
+

Note

+

Lexicographical comparison is an operation with the following properties

    +
  • Two ranges are compared element by element

  • +
  • The first mismatching element defines which range is lexicographically less or greater than the other

  • +
  • If one range is a prefix of another, the shorter range is lexicographically less than the other

  • +
  • If two ranges have equivalent elements and are of the same length, then the ranges are lexicographically equal

  • +
  • An empty range is lexicographically less than any non-empty range

  • +
  • Two empty ranges are lexicographically equal

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent1 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter1.

  • +
  • InIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent2 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter2.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of lexicographical_compare requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function for FwdIter1. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for FwdIter2. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • pred – Refers to the comparison function that the first and second ranges will be applied to

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The lexicographically_compare algorithm returns bool. The lexicographically_compare algorithm returns true if the first range is lexicographically less, otherwise it returns false. range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent1, typename FwdIter2, typename Sent2, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity, typename Pred = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> lexicographical_compare(ExPolicy &&policy, FwdIter1 first1, Sent1 last1, FwdIter2 first2, Sent2 last2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks if the first range [first1, last1) is lexicographically less than the second range [first2, last2). uses a provided predicate to compare elements.

+

+The comparison operations in the parallel lexicographical_compare algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel lexicographical_compare algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2 * min(N1, N2) applications of the comparison operation, where N1 = std::distance(first1, last) and N2 = std::distance(first2, last2).

+
+
+

Note

+

Lexicographical comparison is an operation with the following properties

    +
  • Two ranges are compared element by element

  • +
  • The first mismatching element defines which range is lexicographically less or greater than the other

  • +
  • If one range is a prefix of another, the shorter range is lexicographically less than the other

  • +
  • If two ranges have equivalent elements and are of the same length, then the ranges are lexicographically equal

  • +
  • An empty range is lexicographically less than any non-empty range

  • +
  • Two empty ranges are lexicographically equal

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter1.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter2.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of lexicographical_compare requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function for FwdIter1. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for FwdIter2. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • pred – Refers to the comparison function that the first and second ranges will be applied to

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The lexicographically_compare algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The lexicographically_compare algorithm returns true if the first range is lexicographically less, otherwise it returns false. range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity, typename Pred = hpx::parallel::detail::less>
bool lexicographical_compare(Rng1 &&rng1, Rng2 &&rng2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks if the first range rng1 is lexicographically less than the second range rng2. uses a provided predicate to compare elements.

+

+The comparison operations in the parallel lexicographical_compare algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most 2 * min(N1, N2) applications of the comparison operation, where N1 = std::distance(std::begin(rng1), std::end(rng1)) and N2 = std::distance(std::begin(rng2), std::end(rng2)).

+
+
+

Note

+

Lexicographical comparison is an operation with the following properties

    +
  • Two ranges are compared element by element

  • +
  • The first mismatching element defines which range is lexicographically less or greater than the other

  • +
  • If one range is a prefix of another, the shorter range is lexicographically less than the other

  • +
  • If two ranges have equivalent elements and are of the same length, then the ranges are lexicographically equal

  • +
  • An empty range is lexicographically less than any non-empty range

  • +
  • Two empty ranges are lexicographically equal

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of lexicographical_compare requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function for elements of the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for elements of the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Refers to the comparison function that the first and second ranges will be applied to

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The lexicographically_compare algorithm returns bool. The lexicographically_compare algorithm returns true if the first range is lexicographically less, otherwise it returns false. range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity, typename Pred = hpx::parallel::detail::less>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> lexicographical_compare(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks if the first range rng1 is lexicographically less than the second range rng2. uses a provided predicate to compare elements.

+

+The comparison operations in the parallel lexicographical_compare algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel lexicographical_compare algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2 * min(N1, N2) applications of the comparison operation, where N1 = std::distance(std::begin(rng1), std::end(rng1)) and N2 = std::distance(std::begin(rng2), std::end(rng2)).

+
+
+

Note

+

Lexicographical comparison is an operation with the following properties

    +
  • Two ranges are compared element by element

  • +
  • The first mismatching element defines which range is lexicographically less or greater than the other

  • +
  • If one range is a prefix of another, the shorter range is lexicographically less than the other

  • +
  • If two ranges have equivalent elements and are of the same length, then the ranges are lexicographically equal

  • +
  • An empty range is lexicographically less than any non-empty range

  • +
  • Two empty ranges are lexicographically equal

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of lexicographical_compare requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function for elements of the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for elements of the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Refers to the comparison function that the first and second ranges will be applied to

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The lexicographically_compare algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The lexicographically_compare algorithm returns true if the first range is lexicographically less, otherwise it returns false. range [first2, last2), it returns false.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::make_heap#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Comp, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> make_heap(ExPolicy &&policy, Iter first, Sent last, Comp &&comp, Proj &&proj = Proj{})#
+

Constructs a max heap in the range [first, last).

+

+The predicate operations in the parallel make_heap algorithm invoked with an execution policy object of type sequential_execution_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel make_heap algorithm invoked with an execution policy object of type parallel_execution_policy or parallel_task_execution_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • comp – Refers to the binary predicate which returns true if the first argument should be treated as less than the second. The signature of the function should be equivalent to

    bool comp(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types RndIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The make_heap algorithm returns a hpx::future<Iter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns Iter otherwise. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Comp, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> make_heap(ExPolicy &&policy, Rng &&rng, Comp &&comp, Proj &&proj = Proj{})#
+

Constructs a max heap in the range [first, last).

+

+The predicate operations in the parallel make_heap algorithm invoked with an execution policy object of type sequential_execution_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel make_heap algorithm invoked with an execution policy object of type parallel_execution_policy or parallel_task_execution_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • comp – Refers to the binary predicate which returns true if the first argument should be treated as less than the second. The signature of the function should be equivalent to

    bool comp(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types RndIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The make_heap algorithm returns a hpx::future<Iter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns Iter otherwise. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> make_heap(ExPolicy &&policy, Iter first, Sent last, Proj &&proj = Proj{})#
+

Constructs a max heap in the range [first, last).

+

+The predicate operations in the parallel make_heap algorithm invoked with an execution policy object of type sequential_execution_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel make_heap algorithm invoked with an execution policy object of type parallel_execution_policy or parallel_task_execution_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The make_heap algorithm returns a hpx::future<Iter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns Iter otherwise. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> make_heap(ExPolicy &&policy, Rng &&rng, Proj &&proj = Proj{})#
+

Constructs a max heap in the range [first, last).

+

+The predicate operations in the parallel make_heap algorithm invoked with an execution policy object of type sequential_execution_policy executes in sequential order in the calling thread.

+

The comparison operations in the parallel make_heap algorithm invoked with an execution policy object of type parallel_execution_policy or parallel_task_execution_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The make_heap algorithm returns a hpx::future<Iter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns Iter otherwise. It returns last.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Comp, typename Proj = hpx::identity>
Iter make_heap(Iter first, Sent last, Comp &&comp, Proj &&proj = Proj{})#
+

Constructs a max heap in the range [first, last).

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • Iter – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • comp – Refers to the binary predicate which returns true if the first argument should be treated as less than the second. The signature of the function should be equivalent to

    bool comp(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types RndIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The make_heap algorithm returns Iter. It returns last.

+
+
+
+ +
+
+template<typename Rng, typename Comp, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> make_heap(Rng &&rng, Comp &&comp, Proj &&proj = Proj{})#
+

Constructs a max heap in the range [first, last).

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • comp – Refers to the binary predicate which returns true if the first argument should be treated as less than the second. The signature of the function should be equivalent to

    bool comp(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type must be such that objects of types RndIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The make_heap algorithm returns Iter. It returns last.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Proj = hpx::identity>
Iter make_heap(Iter first, Sent last, Proj &&proj = Proj{})#
+

Constructs a max heap in the range [first, last).

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • Iter – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The make_heap algorithm returns Iter. It returns last.

+
+
+
+ +
+
+template<typename Rng, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> make_heap(Rng &&rng, Proj &&proj = Proj{})#
+

Constructs a max heap in the range [first, last).

+
+

Note

+

Complexity: at most (3*N) comparisons where N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The make_heap algorithm returns Iter. It returns last.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::merge, hpx::ranges::inplace_merge#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Iter3, typename Comp = hpx::ranges::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::ranges::merge_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, Iter3>> merge(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Iter3 dest, Comp &&comp = Comp(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Merges two sorted ranges [first1, last1) and [first2, last2) into one sorted range beginning at dest. The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range. The destination range cannot overlap with either of the input ranges.

+

+The assignments in the parallel merge algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel merge algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs O(std::distance(first1, last1) + std::distance(first2, last2)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the first source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Rng2 – The type of the second source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function to be used for elements of the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function to be used for elements of the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first range of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second range of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types Iter1 and Iter2 can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual comparison comp is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual comparison comp is invoked.

  • +
+
+
Returns
+

The merge algorithm returns a hpx::future<merge_result<Iter1, Iter2, Iter3>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns merge_result<Iter1, Iter2, Iter3> otherwise. The merge algorithm returns the tuple of the source iterator last1, the source iterator last2, the destination iterator to the end of the dest range.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Comp = hpx::ranges::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::ranges::merge_result<Iter1, Iter2, Iter3>>::type merge(ExPolicy &&policy, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Iter3 dest, Comp &&comp = Comp(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Merges two sorted ranges [first1, last1) and [first2, last2) into one sorted range beginning at dest. The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range. The destination range cannot overlap with either of the input ranges.

+

+The assignments in the parallel merge algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel merge algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs O(std::distance(first1, last1) + std::distance(first2, last2)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function to be used for elements of the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function to be used for elements of the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types Iter1 and Iter2 can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual comparison comp is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual comparison comp is invoked.

  • +
+
+
Returns
+

The merge algorithm returns a hpx::future<merge_result<Iter1, Iter2, Iter3>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns merge_result<Iter1, Iter2, Iter3> otherwise. The merge algorithm returns the tuple of the source iterator last1, the source iterator last2, the destination iterator to the end of the dest range.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Iter3, typename Comp = hpx::ranges::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::ranges::merge_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, Iter3> merge(Rng1 &&rng1, Rng2 &&rng2, Iter3 dest, Comp &&comp = Comp(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Merges two sorted ranges [first1, last1) and [first2, last2) into one sorted range beginning at dest. The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range. The destination range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: Performs O(std::distance(first1, last1) + std::distance(first2, last2)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the first source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Rng2 – The type of the second source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function to be used for elements of the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function to be used for elements of the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first range of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second range of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types Iter1 and Iter2 can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual comparison comp is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual comparison comp is invoked.

  • +
+
+
Returns
+

The merge algorithm returns merge_result<Iter1, Iter2, Iter3>. The merge algorithm returns the tuple of the source iterator last1, the source iterator last2, the destination iterator to the end of the dest range.

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Comp = hpx::ranges::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::ranges::merge_result<Iter1, Iter2, Iter3> merge(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Iter3 dest, Comp &&comp = Comp(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Merges two sorted ranges [first1, last1) and [first2, last2) into one sorted range beginning at dest. The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range. The destination range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: Performs O(std::distance(first1, last1) + std::distance(first2, last2)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function to be used for elements of the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function to be used for elements of the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types Iter1 and Iter2 can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual comparison comp is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual comparison comp is invoked.

  • +
+
+
Returns
+

The merge algorithm returns merge_result<Iter1, Iter2, Iter3>. The merge algorithm returns the tuple of the source iterator last1, the source iterator last2, the destination iterator to the end of the dest range.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Iter, typename Comp = hpx::ranges::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> inplace_merge(ExPolicy &&policy, Rng &&rng, Iter middle, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Merges two consecutive sorted ranges [first, middle) and [middle, last) into one sorted range [first, last). The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range.

+

+The assignments in the parallel inplace_merge algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel inplace_merge algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs O(std::distance(first, last)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of inplace_merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the range of elements the algorithm will be applied to.

  • +
  • middle – Refers to the end of the first sorted range and the beginning of the second sorted range the algorithm will be applied to.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types Iter can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The inplace_merge algorithm returns a hpx::future<Iter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns Iter otherwise. The inplace_merge algorithm returns the source iterator last

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Comp = hpx::ranges::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> inplace_merge(ExPolicy &&policy, Iter first, Iter middle, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Merges two consecutive sorted ranges [first, middle) and [middle, last) into one sorted range [first, last). The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range.

+

+The assignments in the parallel inplace_merge algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel inplace_merge algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs O(std::distance(first, last)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of inplace_merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the first sorted range the algorithm will be applied to.

  • +
  • middle – Refers to the end of the first sorted range and the beginning of the second sorted range the algorithm will be applied to.

  • +
  • last – Refers to the end of the second sorted range the algorithm will be applied to.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types Iter can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The inplace_merge algorithm returns a hpx::future<Iter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns Iter otherwise. The inplace_merge algorithm returns the source iterator last

+
+
+
+ +
+
+template<typename Rng, typename Iter, typename Comp = hpx::ranges::less, typename Proj = hpx::identity>
Iter inplace_merge(Rng &&rng, Iter middle, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Merges two consecutive sorted ranges [first, middle) and [middle, last) into one sorted range [first, last). The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range.

+
+

Note

+

Complexity: Performs O(std::distance(first, last)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of inplace_merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the range of elements the algorithm will be applied to.

  • +
  • middle – Refers to the end of the first sorted range and the beginning of the second sorted range the algorithm will be applied to.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types Iter can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The inplace_merge algorithm returns Iter. The inplace_merge algorithm returns the source iterator last

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Comp = hpx::ranges::less, typename Proj = hpx::identity>
Iter inplace_merge(Iter first, Iter middle, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Merges two consecutive sorted ranges [first, middle) and [middle, last) into one sorted range [first, last). The order of equivalent elements in the each of original two ranges is preserved. For equivalent elements in the original two ranges, the elements from the first range precede the elements from the second range.

+
+

Note

+

Complexity: Performs O(std::distance(first, last)) applications of the comparison comp and the each projection.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Comp – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of inplace_merge requires Comp to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the first sorted range the algorithm will be applied to.

  • +
  • middle – Refers to the end of the first sorted range and the beginning of the second sorted range the algorithm will be applied to.

  • +
  • last – Refers to the end of the second sorted range the algorithm will be applied to.

  • +
  • compcomp is a callable object which returns true if the first argument is less than the second, and false otherwise. The signature of this comparison should be equivalent to:

    bool comp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types Iter can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The inplace_merge algorithm Iter. The inplace_merge algorithm returns the source iterator last

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::min_element, hpx::ranges::max_element, hpx::ranges::minmax_element#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
FwdIter min_element(FwdIter first, Sent last, F &&f = F(), Proj &&proj = Proj())#
+

Finds the smallest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel min_element algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • F – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The min_element algorithm returns FwdIter. The min_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename Rng, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> min_element(Rng &&rng, F &&f = F(), Proj &&proj = Proj())#
+

Finds the smallest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel min_element algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The min_element algorithm returns a hpx::traits::range_iterator<Rng>::type otherwise. The min_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> min_element(ExPolicy &&policy, FwdIter first, Sent last, F &&f = F(), Proj &&proj = Proj())#
+

Finds the smallest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel min_element algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel min_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of min_element requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The min_element algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The min_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, hpx::traits::range_iterator_t<Rng>> min_element(ExPolicy &&policy, Rng &&rng, F &&f = F(), Proj &&proj = Proj())#
+

Finds the smallest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel min_element algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel min_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of min_element requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The min_element algorithm returns a hpx::future<hpx::traits::range_iterator<Rng>::type> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The min_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename FwdIter, typename Sent, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
FwdIter max_element(FwdIter first, Sent last, F &&f = F(), Proj &&proj = Proj())#
+

Finds the greatest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel max_element algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • F – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the This argument is optional and defaults to std::less. the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The max_element algorithm returns a FwdIter. The max_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename Rng, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> max_element(Rng &&rng, F &&f = F(), Proj &&proj = Proj())#
+

Finds the greatest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel max_element algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the This argument is optional and defaults to std::less. the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The max_element algorithm returns a hpx::traits::range_iterator<Rng>::type otherwise. The max_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> max_element(ExPolicy &&policy, FwdIter first, Sent last, F &&f = F(), Proj &&proj = Proj())#
+

Finds the greatest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel max_element algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel max_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of max_element requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the This argument is optional and defaults to std::less. the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The max_element algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The max_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, hpx::traits::range_iterator_t<Rng>> max_element(ExPolicy &&policy, Rng &&rng, F &&f = F(), Proj &&proj = Proj())#
+

Finds the greatest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel max_element algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel max_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly max(N-1, 0) comparisons, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of max_element requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the This argument is optional and defaults to std::less. the left argument is less than the right element. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The max_element algorithm returns a hpx::future<hpx::traits::range_iterator<Rng>::type> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The max_element algorithm returns the iterator to the smallest element in the range [first, last). If several elements in the range are equivalent to the smallest element, returns the iterator to the first such element. Returns last if the range is empty.

+
+
+
+ +
+
+template<typename FwdIter, typename Sent, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
minmax_element_result<FwdIter> minmax_element(FwdIter first, Sent last, F &&f = F(), Proj &&proj = Proj())#
+

Finds the greatest element in the range [first, last) using the given comparison function f.

+

+The assignments in the parallel minmax_element algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most max(floor(3/2*(N-1)), 0) applications of the predicate, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • F – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. This argument is optional and defaults to std::less. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The minmax_element algorithm returns a minmax_element_result<FwdIter, FwdIter> The minmax_element algorithm returns a min_max_result consisting of an iterator to the smallest element as the min element and an iterator to the greatest element as the max element. Returns minmax_element_result{first, first} if the range is empty. If several elements are equivalent to the smallest element, the iterator to the first such element is returned. If several elements are equivalent to the largest element, the iterator to the last such element is returned.

+
+
+
+ +
+
+template<typename Rng, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
minmax_element_result<hpx::traits::range_iterator_t<Rng>> minmax_element(Rng &&rng, F &&f = F(), Proj &&proj = Proj())#
+

Finds the greatest element in the range [first, last) using the given comparison function f.

+

+The assignments in the parallel minmax_element algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most max(floor(3/2*(N-1)), 0) applications of the predicate, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. This argument is optional and defaults to std::less. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The minmax_element algorithm returns a minmax_element_result<hpx::traits::range_iterator<Rng>::type , hpx::traits::range_iterator<Rng>::type> The minmax_element algorithm returns a min_max_result consisting of an range iterator to the smallest element as the min element and an range iterator to the greatest element as the max element. If several elements are equivalent to the smallest element, the iterator to the first such element is returned. If several elements are equivalent to the largest element, the iterator to the last such element is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, minmax_element_result<FwdIter>> minmax_element(ExPolicy &&policy, FwdIter first, Sent last, F &&f = F(), Proj &&proj = Proj())#
+

Finds the greatest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel minmax_element algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel minmax_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most max(floor(3/2*(N-1)), 0) applications of the predicate, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of minmax_element requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. This argument is optional and defaults to std::less. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The minmax_element algorithm returns a minmax_element_result<FwdIter, FwdIter> The minmax_element algorithm returns a min_max_result consisting of an iterator to the smallest element as the min element and an iterator to the greatest element as the max element. Returns minmax_element_result{first, first} if the range is empty. If several elements are equivalent to the smallest element, the iterator to the first such element is returned. If several elements are equivalent to the largest element, the iterator to the last such element is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename F = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, minmax_element_result<hpx::traits::range_iterator_t<Rng>>> minmax_element(ExPolicy &&policy, Rng &&rng, F &&f = F(), Proj &&proj = Proj())#
+

Finds the greatest element in the range [first, last) using the given comparison function f.

+

+The comparisons in the parallel minmax_element algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparisons in the parallel minmax_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most max(floor(3/2*(N-1)), 0) applications of the predicate, where N = std::distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of minmax_element requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – The binary predicate which returns true if the the left argument is less than the right element. This argument is optional and defaults to std::less. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type FwdIter can be dereferenced and then implicitly converted to Type1.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The minmax_element algorithm returns a minmax_element_result<hpx::traits::range_iterator<Rng>::type, hpx::traits::range_iterator<Rng>::type> The minmax_element algorithm returns a min_max_result consisting of an range iterator to the smallest element as the min element and an range iterator to the greatest element as the max element. If several elements are equivalent to the smallest element, the iterator to the first such element is returned. If several elements are equivalent to the largest element, the iterator to the last such element is returned.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::mismatch#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, mismatch_result<Iter1, Iter2>>::type mismatch(ExPolicy &&policy, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns true if the range [first1, last1) is mismatch to the range [first2, last2), and false otherwise.

+

+The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most min(last1 - first1, last2 - first2) applications of the predicate f. If FwdIter1 and FwdIter2 meet the requirements of RandomAccessIterator and (last1 - first1) != (last2 - first2) then no applications of the predicate f are made.

+
+
+

Note

+

The two ranges are considered mismatch if, for every iterator i in the range [first1,last1), *i mismatchs *(first2 + (i - first1)). This overload of mismatch uses operator== to determine if two elements are mismatch.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the source iterators used for the end of the first range (deduced).

  • +
  • Iter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the source iterators used for the end of the second range (deduced).

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of mismatch requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as mismatch. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The mismatch algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The mismatch algorithm returns true if the elements in the two ranges are mismatch, otherwise it returns false. If the length of the range [first1, last1) does not mismatch the length of the range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, mismatch_result<typename hpx::traits::range_traits<Rng1>::iterator_type, typename hpx::traits::range_traits<Rng2>::iterator_type>>::type mismatch(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns std::pair with iterators to the first two non-equivalent elements.

+

+The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel mismatch algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most last1 - first1 applications of the predicate f.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the first source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Rng2 – The type of the second source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of mismatch requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as mismatch. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The mismatch algorithm returns a hpx::future<std::pair<FwdIter1, FwdIter2> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns std::pair<FwdIter1, FwdIter2> otherwise. The mismatch algorithm returns the first mismatching pair of elements from two ranges: one defined by [first1, last1) and another defined by [first2, last2).

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
mismatch_result<Iter1, Iter2> mismatch(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns true if the range [first1, last1) is mismatch to the range [first2, last2), and false otherwise.

+
+

Note

+

Complexity: At most min(last1 - first1, last2 - first2) applications of the predicate f. If FwdIter1 and FwdIter2 meet the requirements of RandomAccessIterator and (last1 - first1) != (last2 - first2) then no applications of the predicate f are made.

+
+
+

Note

+

The two ranges are considered mismatch if, for every iterator i in the range [first1,last1), *i mismatchs *(first2 + (i - first1)). This overload of mismatch uses operator== to determine if two elements are mismatch.

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the source iterators used for the end of the first range (deduced).

  • +
  • Iter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the source iterators used for the end of the second range (deduced).

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of mismatch requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as mismatch. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The mismatch algorithm returns bool. The mismatch algorithm returns true if the elements in the two ranges are mismatch, otherwise it returns false. If the length of the range [first1, last1) does not mismatch the length of the range [first2, last2), it returns false.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Pred = equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
mismatch_result<typename hpx::traits::range_traits<Rng1>::iterator_type, typename hpx::traits::range_traits<Rng2>::iterator_type> mismatch(Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Returns std::pair with iterators to the first two non-equivalent elements.

+
+

Note

+

Complexity: At most last1 - first1 applications of the predicate f.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the first source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Rng2 – The type of the second source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of mismatch requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function applied to the first range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • op – The binary predicate which returns true if the elements should be treated as mismatch. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The mismatch algorithm returns std::pair<FwdIter1, FwdIter2>. The mismatch algorithm returns the first mismatching pair of elements from two ranges: one defined by [first1, last1) and another defined by [first2, last2).

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::move#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2>
hpx::parallel::util::detail::algorithm_result<ExPolicy, move_result<Iter1, Iter2>>::type move(ExPolicy &&policy, Iter1 first, Sent1 last, Iter2 dest)#
+

Moves the elements in the range rng to another range beginning at dest. After this operation the elements in the moved-from range will still contain valid values of the appropriate type, but not necessarily the same values as before the move.

+

+The assignments in the parallel copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly std::distance(begin(rng), end(rng)) assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the source iterators used for the end of the first range (deduced).

  • +
  • Iter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The move algorithm returns a hpx::future<ranges::move_result<iterator_t<Rng>, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::move_result<iterator_t<Rng>, FwdIter2> otherwise. The move algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Iter2>
hpx::parallel::util::detail::algorithm_result<ExPolicy, move_result<hpx::traits::range_iterator_t<Rng>, Iter2>>::type move(ExPolicy &&policy, Rng &&rng, Iter2 dest)#
+

Moves the elements in the range rng to another range beginning at dest. After this operation the elements in the moved-from range will still contain valid values of the appropriate type, but not necessarily the same values as before the move.

+

+The assignments in the parallel copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly std::distance(begin(rng), end(rng)) assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The move algorithm returns a hpx::future<ranges::move_result<iterator_t<Rng>, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::move_result<iterator_t<Rng>, FwdIter2> otherwise. The move algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2>
move_result<Iter1, Iter2> move(Iter1 first, Sent1 last, Iter2 dest)#
+

Moves the elements in the range rng to another range beginning at dest. After this operation the elements in the moved-from range will still contain valid values of the appropriate type, but not necessarily the same values as before the move.

+
+

Note

+

Complexity: Performs exactly std::distance(begin(rng), end(rng)) assignments.

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the source iterators used for the end of the first range (deduced).

  • +
  • Iter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The move algorithm returns ranges::move_result<iterator_t<Rng>, FwdIter2>. The move algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename Rng, typename Iter2>
move_result<hpx::traits::range_iterator_t<Rng>, Iter2> move(Rng &&rng, Iter2 dest)#
+

Moves the elements in the range rng to another range beginning at dest. After this operation the elements in the moved-from range will still contain valid values of the appropriate type, but not necessarily the same values as before the move.

+
+

Note

+

Complexity: Performs exactly std::distance(begin(rng), end(rng)) assignments.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
+
+
Returns
+

The move algorithm returns a ranges::move_result<iterator_t<Rng>, FwdIter2>. The move algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::nth_element#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename RandomIt, typename Sent, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
RandomIt nth_element(RandomIt first, RandomIt nth, Sent last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

nth_element is a partial sorting algorithm that rearranges elements in [first, last) such that the element pointed at by nth is changed to whatever element would occur in that position if [first, last) were sorted and all of the elements before this new nth element are less than or equal to the elements after the new nth element.

+

+The comparison operations in the parallel nth_element algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in std::distance(first, last) on average. O(N) applications of the predicate, and O(N log N) swaps, where N = last - first.

+
+
+
Template Parameters
+
    +
  • RandomIt – The type of the source begin, nth, and end iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for RandomIt.

  • +
  • Pred – Comparison function object which returns true if the first argument is less than the second.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • nth – Refers to the iterator defining the sort partition point

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • pred – Specifies the comparison function object which returns true if the first argument is less than (i.e. is ordered before) the second. The signature of this comparison function should be equivalent to:

    bool cmp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type must be such that an object of type randomIt can be dereferenced and then implicitly converted to Type. This defaults to std::less<>.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked. This defaults to hpx::identity.

  • +
+
+
Returns
+

The nth_element algorithm returns returns RandomIt. The nth_element algorithm returns an iterator equal to last.

+
+
+
+ +
+
+template<typename ExPolicy, typename RandomIt, typename Sent, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result_t<ExPolicy, RandomIt> nth_element(ExPolicy &&policy, RandomIt first, RandomIt nth, Sent last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

nth_element is a partial sorting algorithm that rearranges elements in [first, last) such that the element pointed at by nth is changed to whatever element would occur in that position if [first, last) were sorted and all of the elements before this new nth element are less than or equal to the elements after the new nth element.

+

+The comparison operations in the parallel nth_element invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel nth_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in std::distance(first, last) on average. O(N) applications of the predicate, and O(N log N) swaps, where N = last - first.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RandomIt – The type of the source begin, nth, and end iterators used (deduced). This iterator type must meet the requirements of a random access iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for RandomIt.

  • +
  • Pred – Comparison function object which returns true if the first argument is less than the second.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • nth – Refers to the iterator defining the sort partition point

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • pred – Specifies the comparison function object which returns true if the first argument is less than (i.e. is ordered before) the second. The signature of this comparison function should be equivalent to:

    bool cmp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type must be such that an object of type randomIt can be dereferenced and then implicitly converted to Type. This defaults to std::less<>.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked. This defaults to hpx::identity.

  • +
+
+
Returns
+

The partition algorithm returns a hpx::future<RandomIt> if the execution policy is of type parallel_task_policy and returns RandomIt otherwise. The nth_element algorithm returns an iterator equal to last.

+
+
+
+ +
+
+template<typename Rng, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> nth_element(Rng &&rng, hpx::traits::range_iterator_t<Rng> nth, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

nth_element is a partial sorting algorithm that rearranges elements in [first, last) such that the element pointed at by nth is changed to whatever element would occur in that position if [first, last) were sorted and all of the elements before this new nth element are less than or equal to the elements after the new nth element.

+

+The comparison operations in the parallel nth_element algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in std::distance(first, last) on average. O(N) applications of the predicate, and O(N log N) swaps, where N = last - first.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Pred – Comparison function object which returns true if the first argument is less than the second.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • nth – Refers to the iterator defining the sort partition point

  • +
  • pred – Specifies the comparison function object which returns true if the first argument is less than (i.e. is ordered before) the second. The signature of this comparison function should be equivalent to:

    bool cmp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type must be such that an object of type randomIt can be dereferenced and then implicitly converted to Type. This defaults to std::less<>.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked. This defaults to hpx::identity.

  • +
+
+
Returns
+

The nth_element algorithm returns returns hpx::traits::range_iterator_t<Rng>. The nth_element algorithm returns an iterator equal to last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred = hpx::parallel::detail::less, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result_t<ExPolicy, hpx::traits::range_iterator_t<Rng>> nth_element(ExPolicy &&policy, Rng &&rng, hpx::traits::range_iterator_t<Rng> nth, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

nth_element is a partial sorting algorithm that rearranges elements in [first, last) such that the element pointed at by nth is changed to whatever element would occur in that position if [first, last) were sorted and all of the elements before this new nth element are less than or equal to the elements after the new nth element.

+

+The comparison operations in the parallel nth_element invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel nth_element algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in std::distance(first, last) on average. O(N) applications of the predicate, and O(N log N) swaps, where N = last - first.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an random access iterator.

  • +
  • Pred – Comparison function object which returns true if the first argument is less than the second.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • nth – Refers to the iterator defining the sort partition point

  • +
  • pred – Specifies the comparison function object which returns true if the first argument is less than (i.e. is ordered before) the second. The signature of this comparison function should be equivalent to:

    bool cmp(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type must be such that an object of type randomIt can be dereferenced and then implicitly converted to Type. This defaults to std::less<>.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked. This defaults to hpx::identity.

  • +
+
+
Returns
+

The partition algorithm returns a hpx::future<hpx::traits::range_iterator_t<Rng>> if the execution policy is of type parallel_task_policy and returns hpx::traits::range_iterator_t<Rng> otherwise. The nth_element algorithm returns an iterator equal to last.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::partial_sort#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename RandomIt, typename Sent, typename Comp = ranges::less, typename Proj = hpx::identity>
RandomIt partial_sort(RandomIt first, RandomIt middle, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Places the first middle - first elements from the range [first, last) as sorted with respect to comp into the range [first, middle). The rest of the elements in the range [middle, last) are placed in an unspecified order.

+

+The assignments in the parallel partial_sort algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Approximately (last - first) * log(middle - first) comparisons.

+
+
+
Template Parameters
+
    +
  • RandomIt – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for RandomIt.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the middle of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. Comp defaults to detail::less.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The partial_sort algorithm returns RandomIt. The algorithm returns an iterator pointing to the first element after the last element in the input sequence.

+
+
+
+ +
+
+template<typename ExPolicy, typename RandomIt, typename Sent, typename Comp = ranges::less, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, RandomIt>::type partial_sort(ExPolicy &&policy, RandomIt first, RandomIt middle, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Places the first middle - first elements from the range [first, last) as sorted with respect to comp into the range [first, middle). The rest of the elements in the range [middle, last) are placed in an unspecified order.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Approximately (last - first) * log(middle - first) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RandomIt – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for RandomIt.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the middle of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. Comp defaults to detail::less.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The partial_sort algorithm returns a hpx::future<RandomIt> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns RandomIt otherwise. The algorithm returns an iterator pointing to the first element after the last element in the input sequence.

+
+
+
+ +
+
+template<typename Rng, typename Comp = ranges::less, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> partial_sort(Rng &&rng, hpx::traits::range_iterator_t<Rng> middle, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Places the first middle - first elements from the range [first, last) as sorted with respect to comp into the range [first, middle). The rest of the elements in the range [middle, last) are placed in an unspecified order.

+

+The assignments in the parallel partial_sort algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Approximately (last - first) * log(middle - first) comparisons.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the middle of the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. Comp defaults to detail::less.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The partial_sort algorithm returns hpx::traits::range_iterator_t<Rng>. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Comp = ranges::less, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result_t<ExPolicy, hpx::traits::range_iterator_t<Rng>> partial_sort(ExPolicy &&policy, Rng &&rng, hpx::traits::range_iterator_t<Rng> middle, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range [first, last) in ascending order. The relative order of equal elements is preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less;

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the middle of the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. Comp defaults to detail::less.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The partial_sort algorithm returns a hpx::future<hpx::traits::range_iterator_t<Rng> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns hpx::traits::range_iterator_t<Rng> otherwise. It returns last.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::partial_sort_copy#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename InIter, typename Sent1, typename RandIter, typename Sent2, typename Comp = ranges::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
partial_sort_copy_result<InIter, RandIter> partial_sort_copy(InIter first, Sent1 last, RandIter r_first, Sent2 r_last, Comp &&comp = Comp(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Sorts some of the elements in the range [first, last) in ascending order, storing the result in the range [r_first, r_last). At most r_last - r_first of the elements are placed sorted to the range [r_first, r_first + n) where n is the number of elements to sort (n = min(last - first, r_last - r_first)).

+

+The assignments in the parallel partial_sort_copy algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: O(N log(min(D,N))), where N = std::distance(first, last) and D = std::distance(r_first, r_last) comparisons.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent1 – The type of the source sentinel (deduced).This sentinel type must be a sentinel for InIter.

  • +
  • RandIter – The type of the destination iterators used(deduced) This iterator type must meet the requirements of an random iterator.

  • +
  • Sent2 – The type of the destination sentinel (deduced).This sentinel type must be a sentinel for RandIter.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
  • Proj1 – The type of an optional projection function for the input range. This defaults to hpx::identity.

  • +
  • Proj1 – The type of an optional projection function for the output range. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the sentinel value denoting the end of the sequence of elements the algorithm will be applied to.

  • +
  • r_first – Refers to the beginning of the destination range.

  • +
  • r_last – Refers to the sentinel denoting the end of the destination range.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. This defaults to detail::less.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation after the actual predicate comp is invoked.

  • +
+
+
Returns
+

The partial_sort_copy algorithm returns a returns partial_sort_copy_result<InIter, RandIter>. The algorithm returns {last, result_first + N}.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent1, typename RandIter, typename Sent2, typename Comp = ranges::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
parallel::util::detail::algorithm_result_t<ExPolicy, partial_sort_copy_result<FwdIter, RandIter>> partial_sort_copy(ExPolicy &&policy, FwdIter first, Sent1 last, RandIter r_first, Sent2 r_last, Comp &&comp = Comp(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Sorts some of the elements in the range [first, last) in ascending order, storing the result in the range [r_first, r_last). At most r_last - r_first of the elements are placed sorted to the range [r_first, r_first + n) where n is the number of elements to sort (n = min(last - first, r_last - r_first)).

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(min(D,N))), where N = std::distance(first, last) and D = std::distance(r_first, r_last) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the source sentinel (deduced).This sentinel type must be a sentinel for FwdIter.

  • +
  • RandIter – The type of the destination iterators used(deduced) This iterator type must meet the requirements of an random iterator.

  • +
  • Sent2 – The type of the destination sentinel (deduced).This sentinel type must be a sentinel for RandIter.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
  • Proj1 – The type of an optional projection function for the input range. This defaults to hpx::identity.

  • +
  • Proj1 – The type of an optional projection function for the output range. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the sentinel value denoting the end of the sequence of elements the algorithm will be applied to.

  • +
  • r_first – Refers to the beginning of the destination range.

  • +
  • r_last – Refers to the sentinel denoting the end of the destination range.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. This defaults to detail::less.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation after the actual predicate comp is invoked.

  • +
+
+
Returns
+

The partial_sort_copy algorithm returns a hpx::future<partial_sort_copy_result<FwdIter, RandIter>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns partial_sort_copy_result<FwdIter, RandIter> otherwise. The algorithm returns {last, result_first + N}.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Comp = ranges::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
partial_sort_copy_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>> partial_sort_copy(Rng1 &&rng1, Rng2 &&rng2, Comp &&comp = Comp(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Sorts some of the elements in the range [first, last) in ascending order, storing the result in the range [r_first, r_last). At most r_last - r_first of the elements are placed sorted to the range [r_first, r_first + n) where n is the number of elements to sort (n = min(last - first, r_last - r_first)).

+

+The assignments in the parallel partial_sort_copy algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: O(N log(min(D,N))), where N = std::distance(first, last) and D = std::distance(r_first, r_last) comparisons.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a input iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of a random iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
  • Proj1 – The type of an optional projection function for the input range. This defaults to hpx::identity.

  • +
  • Proj2 – The type of an optional projection function for the output range. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the source range.

  • +
  • rng2 – Refers to the destination range.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. This defaults to detail::less.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation after the actual predicate comp is invoked.

  • +
+
+
Returns
+

The partial_sort_copy algorithm returns partial_sort_copy_result<range_iterator_t<Rng1>, range_iterator_t<Rng2>>. The algorithm returns {last, result_first + N}.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Comp = ranges::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
parallel::util::detail::algorithm_result_t<ExPolicy, partial_sort_copy_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>>> partial_sort_copy(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Comp &&comp = Comp(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Sorts some of the elements in the range [first, last) in ascending order, storing the result in the range [r_first, r_last). At most r_last - r_first of the elements are placed sorted to the range [r_first, r_first + n) where n is the number of elements to sort (n = min(last - first, r_last - r_first)).

+

+The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(min(D,N))), where N = std::distance(first, last) and D = std::distance(r_first, r_last) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of a random iterator.

  • +
  • Comp – The type of the function/function object to use (deduced). Comp defaults to detail::less.

  • +
  • Proj1 – The type of an optional projection function for the input range. This defaults to hpx::identity.

  • +
  • Proj2 – The type of an optional projection function for the output range. This defaults to hpx::identity.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the source range.

  • +
  • rng2 – Refers to the destination range.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator. This defaults to detail::less.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation after the actual predicate comp is invoked.

  • +
+
+
Returns
+

The partial_sort_copy algorithm returns a hpx::future<partial_sort_copy_result< range_iterator_t<Rng1>, range_iterator_t<Rng2>>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns partial_sort_copy_result<range_iterator_t<Rng1>, range_iterator_t<Rng2>> otherwise. The algorithm returns {last, result_first + N}.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::partition, hpx::ranges::stable_partition, hpx::ranges::partition_copy#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename Rng, typename Pred, typename Proj = hpx::identity>
subrange_t<hpx::traits::range_iterator_t<Rng>> partition(Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Reorders the elements in the range rng in such a way that all elements for which the predicate pred returns true precede the elements for which the predicate pred returns false. Relative order of the elements is not preserved.

+

+The assignments in the parallel partition algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs at most 2 * N swaps, exactly N applications of the predicate and projection, where N = std::distance(begin(rng), end(rng)).

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by the range rng. This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition algorithm returns subrange_t<hpx::traits::range_iterator_t<Rng>> The partition algorithm returns a subrange starting with an iterator to the first element of the second group and finishing with an iterator equal to last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<hpx::traits::range_iterator_t<Rng>>> partition(ExPolicy &&policy, Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Reorders the elements in the range rng in such a way that all elements for which the predicate pred returns true precede the elements for which the predicate pred returns false. Relative order of the elements is not preserved.

+

+The assignments in the parallel partition algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel partition algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs at most 2 * N swaps, exactly N applications of the predicate and projection, where N = std::distance(begin(rng), end(rng)).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by the range rng. This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition algorithm returns a hpx::future<subrange_t<hpx::traits::range_iterator_t<Rng>>> if the execution policy is of type parallel_task_policy and returns subrange_t<hpx::traits::range_iterator_t<Rng>> The partition algorithm returns a subrange starting with an iterator to the first element of the second group and finishing with an iterator equal to last.

+
+
+
+ +
+
+template<typename FwdIter, typename Sent, typename Pred, typename Proj = hpx::identity>
subrange_t<FwdIter> partition(FwdIter first, Sent last, Pred &&pred, Proj &&proj = Proj())#
+

Reorders the elements in the range [first, last) in such a way that all elements for which the predicate pred returns true precede the elements for which the predicate pred returns false. Relative order of the elements is not preserved.

+

+The assignments in the parallel partition algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most 2 * (last - first) swaps. Exactly last - first applications of the predicate and projection.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition algorithm returns returns subrange_t<FwdIter>. The partition algorithm returns a subrange starting with an iterator to the first element of the second group and finishing with an iterator equal to last.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename Pred, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<FwdIter>>::type partition(ExPolicy &&policy, FwdIter first, Sent last, Pred &&pred, Proj &&proj = Proj())#
+

Reorders the elements in the range [first, last) in such a way that all elements for which the predicate pred returns true precede the elements for which the predicate pred returns false. Relative order of the elements is not preserved.

+

+The assignments in the parallel partition algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel partition algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2 * (last - first) swaps. Exactly last - first applications of the predicate and projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition algorithm returns a hpx::future<subrange_t<FwdIter>> if the execution policy is of type parallel_task_policy and returns subrange_t<FwdIter> otherwise. The partition algorithm returns a subrange starting with an iterator to the first element of the second group and finishing with an iterator equal to last.

+
+
+
+ +
+
+template<typename Rng, typename Pred, typename Proj = hpx::identity>
subrange_t<hpx::traits::range_iterator_t<Rng>> stable_partition(Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Permutes the elements in the range [first, last) such that there exists an iterator i such that for every iterator j in the range [first, i) INVOKE(f, INVOKE (proj, *j)) != false, and for every iterator k in the range [i, last), INVOKE(f, INVOKE (proj, *k)) == false

+

+The invocations of f in the parallel stable_partition algorithm invoked without an execution policy object executes in sequential order in the calling thread.

+
+

Note

+

Complexity: At most (last - first) * log(last - first) swaps, but only linear number of swaps if there is enough extra memory Exactly last - first applications of the predicate and projection.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an birdirectional iterator

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Unary predicate which returns true if the element should be ordered before other elements. Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type BidirIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The stable_partition algorithm returns an iterator i such that for every iterator j in the range [first, i), f(*j) != false INVOKE(f, INVOKE(proj, *j)) != false, and for every iterator k in the range [i, last), f(*k) == false INVOKE(f, INVOKE (proj, *k)) == false. The relative order of the elements in both groups is preserved.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<hpx::traits::range_iterator_t<Rng>>> stable_partition(ExPolicy &&policy, Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Permutes the elements in the range [first, last) such that there exists an iterator i such that for every iterator j in the range [first, i) INVOKE(f, INVOKE (proj, *j)) != false, and for every iterator k in the range [i, last), INVOKE(f, INVOKE (proj, *k)) == false

+

+The invocations of f in the parallel stable_partition algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The invocations of f in the parallel stable_partition algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most (last - first) * log(last - first) swaps, but only linear number of swaps if there is enough extra memory. Exactly last - first applications of the predicate and projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the invocations of f.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an birdirectional iterator

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Unary predicate which returns true if the element should be ordered before other elements. Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type BidirIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The stable_partition algorithm returns an iterator i such that for every iterator j in the range [first, i), f(*j) != false INVOKE(f, INVOKE(proj, *j)) != false, and for every iterator k in the range [i, last), f(*k) == false INVOKE(f, INVOKE (proj, *k)) == false. The relative order of the elements in both groups is preserved. If the execution policy is of type parallel_task_policy the algorithm returns a future<> referring to this iterator.

+
+
+
+ +
+
+template<typename BidirIter, typename Sent, typename Pred, typename Proj = hpx::identity>
subrange_t<BidirIter> stable_partition(BidirIter first, Sent last, Pred &&pred, Proj &&proj = Proj())#
+

Permutes the elements in the range [first, last) such that there exists an iterator i such that for every iterator j in the range [first, i) INVOKE(f, INVOKE (proj, *j)) != false, and for every iterator k in the range [i, last), INVOKE(f, INVOKE (proj, *k)) == false

+

+The invocations of f in the parallel stable_partition algorithm invoked without an execution policy object executes in sequential order in the calling thread.

+
+

Note

+

Complexity: At most (last - first) * log(last - first) swaps, but only linear number of swaps if there is enough extra memory Exactly last - first applications of the predicate and projection.

+
+
+
Template Parameters
+
    +
  • BidirIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for BidirIter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • pred – Unary predicate which returns true if the element should be ordered before other elements. Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type BidirIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The stable_partition algorithm returns an iterator i such that for every iterator j in the range [first, i), f(*j) != false INVOKE(f, INVOKE(proj, *j)) != false, and for every iterator k in the range [i, last), f(*k) == false INVOKE(f, INVOKE (proj, *k)) == false. The relative order of the elements in both groups is preserved.

+
+
+
+ +
+
+template<typename ExPolicy, typename BidirIter, typename Sent, typename Pred, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<BidirIter>>::type stable_partition(ExPolicy &&policy, BidirIter first, Sent last, Pred &&pred, Proj &&proj = Proj())#
+

Permutes the elements in the range [first, last) such that there exists an iterator i such that for every iterator j in the range [first, i) INVOKE(f, INVOKE (proj, *j)) != false, and for every iterator k in the range [i, last), INVOKE(f, INVOKE (proj, *k)) == false

+

+The invocations of f in the parallel stable_partition algorithm invoked with an execution policy object of type sequenced_policy executes in sequential order in the calling thread.

+

The invocations of f in the parallel stable_partition algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most (last - first) * log(last - first) swaps, but only linear number of swaps if there is enough extra memory Exactly last - first applications of the predicate and projection.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the invocations of f.

  • +
  • BidirIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for BidirIter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • pred – Unary predicate which returns true if the element should be ordered before other elements. Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). The signature of this predicate should be equivalent to:

    bool fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type BidirIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The stable_partition algorithm returns an iterator i such that for every iterator j in the range [first, i), f(*j) != false INVOKE(f, INVOKE(proj, *j)) != false, and for every iterator k in the range [i, last), f(*k) == false INVOKE(f, INVOKE (proj, *k)) == false. The relative order of the elements in both groups is preserved. If the execution policy is of type parallel_task_policy the algorithm returns a future<> referring to this iterator.

+
+
+
+ +
+
+template<typename Rng, typename OutIter2, typename OutIter3, typename Pred, typename Proj = hpx::identity>
partition_copy_result<hpx::traits::range_iterator_t<Rng>, OutIter2, OutIter3> partition_copy(Rng &&rng, OutIter2 dest_true, OutIter3 dest_false, Pred &&pred, Proj &&proj = Proj())#
+

Copies the elements in the range rng, to two different ranges depending on the value returned by the predicate pred. The elements, that satisfy the predicate pred are copied to the range beginning at dest_true. The rest of the elements are copied to the range beginning at dest_false. The order of the elements is preserved.

+

+The assignments in the parallel partition_copy algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than N assignments, exactly N applications of the predicate pred, where N = std::distance(begin(rng), end(rng)).

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • OutIter2 – The type of the iterator representing the destination range for the elements that satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • OutIter3 – The type of the iterator representing the destination range for the elements that don’t satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition_copy requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest_true – Refers to the beginning of the destination range for the elements that satisfy the predicate pred

  • +
  • dest_false – Refers to the beginning of the destination range for the elements that don’t satisfy the predicate pred.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition_copy algorithm returns a partition_copy_result<hpx::traits::range_iterator_t<Rng>, FwdIter2, FwdIter3>>. The partition_copy algorithm returns the tuple of the source iterator last, the destination iterator to the end of the dest_true range, and the destination iterator to the end of the dest_false range.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename FwdIter2, typename FwdIter3, typename Pred, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, partition_copy_result<hpx::traits::range_iterator_t<Rng>, FwdIter2, FwdIter3>>::type partition_copy(ExPolicy &&policy, Rng &&rng, FwdIter2 dest_true, FwdIter3 dest_false, Pred &&pred, Proj &&proj = Proj())#
+

Copies the elements in the range rng, to two different ranges depending on the value returned by the predicate pred. The elements, that satisfy the predicate pred are copied to the range beginning at dest_true. The rest of the elements are copied to the range beginning at dest_false. The order of the elements is preserved.

+

+The assignments in the parallel partition_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel partition_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than N assignments, exactly N applications of the predicate pred, where N = std::distance(begin(rng), end(rng)).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the iterator representing the destination range for the elements that satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter3 – The type of the iterator representing the destination range for the elements that don’t satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition_copy requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest_true – Refers to the beginning of the destination range for the elements that satisfy the predicate pred

  • +
  • dest_false – Refers to the beginning of the destination range for the elements that don’t satisfy the predicate pred.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition_copy algorithm returns a hpx::future<partition_copy_result <hpx::traits::range_iterator_t<Rng>, FwdIter2, FwdIter3>> if the execution policy is of type parallel_task_policy and returns partition_copy_result<hpx::traits::range_iterator_t<Rng>, FwdIter2, FwdIter3> otherwise. The partition_copy algorithm returns the tuple of the source iterator last, the destination iterator to the end of the dest_true range, and the destination iterator to the end of the dest_false range.

+
+
+
+ +
+
+template<typename InIter, typename Sent, typename OutIter2, typename OutIter3, typename Pred, typename Proj = hpx::identity>
partition_copy_result<InIter, OutIter2, OutIter3> partition_copy(InIter first, Sent last, OutIter2 dest_true, OutIter3 dest_false, Pred &&pred, Proj &&proj = Proj())#
+

Copies the elements in the range, defined by [first, last), to two different ranges depending on the value returned by the predicate pred. The elements, that satisfy the predicate pred are copied to the range beginning at dest_true. The rest of the elements are copied to the range beginning at dest_false. The order of the elements is preserved.

+

+The assignments in the parallel partition_copy algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate f.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • OutIter2 – The type of the iterator representing the destination range for the elements that satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • OutIter3 – The type of the iterator representing the destination range for the elements that don’t satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition_copy requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest_true – Refers to the beginning of the destination range for the elements that satisfy the predicate pred

  • +
  • dest_false – Refers to the beginning of the destination range for the elements that don’t satisfy the predicate pred.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition_copy algorithm returns a partition_copy_result<FwdIter, OutIter2, OutIter3>. The partition_copy algorithm returns the tuple of the source iterator last, the destination iterator to the end of the dest_true range, and the destination iterator to the end of the dest_false range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename OutIter2, typename OutIter3, typename Pred, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, partition_copy_result<FwdIter, OutIter2, OutIter3>>::type partition_copy(ExPolicy &&policy, FwdIter first, Sent last, OutIter2 dest_true, OutIter3 dest_false, Pred &&pred, Proj &&proj = Proj())#
+

Copies the elements in the range, defined by [first, last), to two different ranges depending on the value returned by the predicate pred. The elements, that satisfy the predicate pred are copied to the range beginning at dest_true. The rest of the elements are copied to the range beginning at dest_false. The order of the elements is preserved.

+

+The assignments in the parallel partition_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel partition_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate f.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • OutIter2 – The type of the iterator representing the destination range for the elements that satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • OutIter3 – The type of the iterator representing the destination range for the elements that don’t satisfy the predicate pred (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of partition_copy requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest_true – Refers to the beginning of the destination range for the elements that satisfy the predicate pred

  • +
  • dest_false – Refers to the beginning of the destination range for the elements that don’t satisfy the predicate pred.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an unary predicate for partitioning the source iterators. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The partition_copy algorithm returns a hpx::future<partition_copy_result<FwdIter, OutIter2, OutIter3>> if the execution policy is of type parallel_task_policy and returns partition_copy_result<FwdIter, OutIter2, OutIter3> otherwise. The partition_copy algorithm returns the tuple of the source iterator last, the destination iterator to the end of the dest_true range, and the destination iterator to the end of the dest_false range.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::reduce#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename F, typename T = typename std::iterator_traits<FwdIter>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> reduce(ExPolicy &&policy, FwdIter first, Sent last, T init, F &&f)#
+

Returns GENERALIZED_SUM(f, init, *first, …, *(first + (last - first) - 1)).

+

+The reduce operations in the parallel reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicate f.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of copy_if requires F to meet the requirements of CopyConstructible.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 Ret must be such that an object of type FwdIterB can be dereferenced and then implicitly converted to any of those types.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise. The reduce algorithm returns the result of the generalized sum over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename F, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> reduce(ExPolicy &&policy, Rng &&rng, T init, F &&f)#
+

Returns GENERALIZED_SUM(f, init, *first, …, *(first + (last - first) - 1)).

+

+The reduce operations in the parallel reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicate f.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of copy_if requires F to meet the requirements of CopyConstructible.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 Ret must be such that an object of type FwdIterB can be dereferenced and then implicitly converted to any of those types.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise. The reduce algorithm returns the result of the generalized sum over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename T = typename std::iterator_traits<FwdIter>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> reduce(ExPolicy &&policy, FwdIter first, Sent last, T init)#
+

Returns GENERALIZED_SUM(+, init, *first, …, *(first + (last - first) - 1)).

+

+The reduce operations in the parallel reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise. The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> reduce(ExPolicy &&policy, Rng &&rng, T init)#
+

Returns GENERALIZED_SUM(+, init, *first, …, *(first + (last - first) - 1)).

+

+The reduce operations in the parallel reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise. The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent>
hpx::parallel::util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<FwdIter>::value_type>::type reduce(ExPolicy &&policy, FwdIter first, Sent last)#
+

Returns GENERALIZED_SUM(+, T(), *first, …, *(first + (last - first) - 1)).

+

+The reduce operations in the parallel reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

The type of the initial value (and the result type) T is determined from the value_type of the used FwdIterB.

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise (where T is the value_type of FwdIterB). The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng>
hpx::parallel::util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<typename hpx::traits::range_traits<Rng>::iterator_type>::value_type>::type reduce(ExPolicy &&policy, Rng &&rng)#
+

Returns GENERALIZED_SUM(+, T(), *first, …, *(first + (last - first) - 1)).

+

+The reduce operations in the parallel reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

The type of the initial value (and the result type) T is determined from the value_type of the used FwdIterB.

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise (where T is the value_type of FwdIterB). The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename FwdIter, typename Sent, typename F, typename T = typename std::iterator_traits<FwdIter>::value_type>
T reduce(FwdIter first, Sent last, T init, F &&f)#
+

Returns GENERALIZED_SUM(f, init, *first, …, *(first + (last - first) - 1)).

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicate f.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of copy_if requires F to meet the requirements of CopyConstructible.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 Ret must be such that an object of type FwdIterB can be dereferenced and then implicitly converted to any of those types.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The reduce algorithm returns T. The reduce algorithm returns the result of the generalized sum over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename Rng, typename F, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
T reduce(Rng &&rng, T init, F &&f)#
+

Returns GENERALIZED_SUM(f, init, *first, …, *(first + (last - first) - 1)).

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicate f.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of copy_if requires F to meet the requirements of CopyConstructible.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 Ret must be such that an object of type FwdIterB can be dereferenced and then implicitly converted to any of those types.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The reduce algorithm returns T. The reduce algorithm returns the result of the generalized sum over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename FwdIter, typename Sent, typename T = typename std::iterator_traits<FwdIter>::value_type>
T reduce(FwdIter first, Sent last, T init)#
+

Returns GENERALIZED_SUM(+, init, *first, …, *(first + (last - first) - 1)).

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The reduce algorithm returns T. The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename Rng, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
T reduce(Rng &&rng, T init)#
+

Returns GENERALIZED_SUM(+, init, *first, …, *(first + (last - first) - 1)).

+

The difference between

+reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The reduce algorithm returns T. The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename FwdIter, typename Sent>
std::iterator_traits<FwdIter>::value_type reduce(FwdIter first, Sent last)#
+

Returns GENERALIZED_SUM(+, T(), *first, …, *(first + (last - first) - 1)).

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

The type of the initial value (and the result type) T is determined from the value_type of the used FwdIterB.

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source begin iterator used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The reduce algorithm returns T (where T is the value_type of FwdIterB). The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename Rng>
std::iterator_traits<typename hpx::traits::range_traits<Rng>::iterator_type>::value_type reduce(Rng &&rng)#
+

Returns GENERALIZED_SUM(+, T(), *first, …, *(first + (last - first) - 1)).

+

+The difference between reduce and accumulate is that the behavior of reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the operator+().

+
+
+

Note

+

The type of the initial value (and the result type) T is determined from the value_type of the used FwdIterB.

+
+
+

Note

+

GENERALIZED_SUM(+, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(+, b1, …, bK), GENERALIZED_SUM(+, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+

Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

+
+
Parameters
+

rng – Refers to the sequence of elements the algorithm will be applied to.

+
+
Returns
+

The reduce algorithm returns T (where T is the value_type of FwdIterB). The reduce algorithm returns the result of the generalized sum (applying operator+()) over the elements given by the input range [first, last).

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::remove, hpx::ranges::remove_if#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename Iter, typename Sent, typename Pred, typename Proj = hpx::identity>
subrange_t<Iter, Sent> remove_if(Iter first, Sent sent, Pred &&pred, Proj &&proj = Proj())#
+

Removes all elements for which predicate pred returns true from the range [first, last) and returns a subrange [ret, last), where ret is a past-the-end iterator for the new end of the range.

+

+The assignments in the parallel remove_if algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate pred and the projection proj.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of remove_if requires Pred to meet the requirements of CopyConstructible..

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The remove_if algorithm returns a subrange_t<FwdIter, Sent>. The remove_if algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange of the values all in valid but unspecified state.

+
+
+
+ +
+
+template<typename Rng, typename Pred, typename Proj = hpx::identity>
subrange_t<hpx::traits::range_iterator_t<Rng>> remove_if(Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Removes all elements that are equal to value from the range rng and and returns a subrange [ret, util::end(rng)), where ret is a past-the-end iterator for the new end of the range.

+

+The assignments in the parallel remove_if algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than util::end(rng)

    +
  • util::begin(rng) assignments, exactly util::end(rng) - util::begin(rng) applications of the operator==() and the projection proj.

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of remove_if requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The remove_if algorithm returns a subrange_t<hpx::traits::range_iterator_t<Rng>>. The remove_if algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange of the values all in valid but unspecified state.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename Pred, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<FwdIter, Sent>>::type remove_if(ExPolicy &&policy, FwdIter first, Sent sent, Pred &&pred, Proj &&proj = Proj())#
+

Removes all elements for which predicate pred returns true from the range [first, last) and returns a subrange [ret, last), where ret is a past-the-end iterator for the new end of the range.

+

+The assignments in the parallel remove_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel remove_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the predicate pred and the projection proj.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of remove_if requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The remove_if algorithm returns a hpx::future<subrange_t<FwdIter, Sent>>. The remove_if algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange of the values all in valid but unspecified state.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<hpx::traits::range_iterator_t<Rng>>> remove_if(ExPolicy &&policy, Rng &&rng, Pred &&pred, Proj &&proj = Proj())#
+

Removes all elements that are equal to value from the range rng and and returns a subrange [ret, util::end(rng)), where ret is a past-the-end iterator for the new end of the range.

+

+The assignments in the parallel remove_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel remove_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than util::end(rng)

    +
  • util::begin(rng) assignments, exactly util::end(rng) - util::begin(rng) applications of the operator==() and the projection proj.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of remove_if requires Pred to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The remove_if algorithm returns a hpx::future<subrange_t< hpx::traits::range_iterator_t<Rng>>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The remove_if algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange of the values all in valid but unspecified state.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<Iter, Proj>::value_type>
subrange_t<Iter, Sent> remove(Iter first, Sent last, T const &value, Proj &&proj = Proj())#
+

Removes all elements that are equal to value from the range [first, last) and and returns a subrange [ret, last), where ret is a past-the-end iterator for the new end of the range.

+

+The assignments in the parallel remove algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the operator==() and the projection proj.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • T – The type of the value to remove (deduced). This value type must meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – Specifies the value of elements to remove.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The remove algorithm returns a subrange_t<FwdIter, Sent>. The remove algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange of the values all in valid but unspecified state.

+
+
+
+ +
+
+template<typename Rng, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type>
subrange_t<hpx::traits::range_iterator_t<Rng>> remove(Rng &&rng, T const &value, Proj &&proj = Proj())#
+

Removes all elements that are equal to value from the range rng and and returns a subrange [ret, util::end(rng)), where ret is a past-the-end iterator for the new end of the range.

+

+The assignments in the parallel remove algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than util::end(rng)

    +
  • util::begin(rng) assignments, exactly util::end(rng) - util::begin(rng) applications of the operator==() and the projection proj.

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to remove (deduced). This value type must meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • value – Specifies the value of elements to remove.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The remove algorithm returns a subrange_t<hpx::traits::range_iterator_t<Rng>>. The remove algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange of the values all in valid but unspecified state.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<FwdIter, Proj>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<FwdIter, Sent>>::type remove(ExPolicy &&policy, FwdIter first, Sent last, T const &value, Proj &&proj = Proj())#
+

Removes all elements that are equal to value from the range [first, last) and and returns a subrange [ret, last), where ret is a past-the-end iterator for the new end of the range.

+

+The assignments in the parallel remove algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel remove algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first applications of the operator==() and the projection proj.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • T – The type of the value to remove (deduced). This value type must meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • value – Specifies the value of elements to remove.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The remove algorithm returns a hpx::future<subrange_t<FwdIter, Sent>>. The remove algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange of the values all in valid but unspecified state.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<hpx::traits::range_iterator_t<Rng>>> remove(ExPolicy &&policy, Rng &&rng, T const &value, Proj &&proj = Proj())#
+

Removes all elements that are equal to value from the range rng and and returns a subrange [ret, util::end(rng)), where ret is a past-the-end iterator for the new end of the range.

+

+The assignments in the parallel remove algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel remove algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than util::end(rng)

    +
  • util::begin(rng) assignments, exactly util::end(rng) - util::begin(rng) applications of the operator==() and the projection proj.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to remove (deduced). This value type must meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • value – Specifies the value of elements to remove.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The remove algorithm returns a hpx::future< subrange_t<hpx::traits::range_iterator_t<Rng>>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The remove algorithm returns the iterator to the new end of the range.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::remove_copy, hpx::ranges::remove_copy_if#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+ +
+ +
+
+
hpx::ranges::replace, hpx::ranges::replace_if, hpx::ranges::replace_copy, hpx::ranges::replace_copy_if#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename Iter, typename Sent, typename Pred, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<Iter, Proj>::value_type>
Iter replace_if(Iter first, Sent sent, Pred &&pred, T const &new_value, Proj &&proj = Proj())#
+

Replaces all elements satisfying specific criteria (for which predicate f returns true) with new_value in the range [first, sent).

+

+Effects: Substitutes elements referred by the iterator it in the range [first, sent) with new_value, when the following corresponding conditions hold: INVOKE(f, INVOKE(proj, *it)) != false

+

+The assignments in the parallel replace_if algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly sent - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterator used (deduced). The iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type Iter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_if algorithm returns Iter. It returns last.

+
+
+
+ +
+
+template<typename Rng, typename Pred, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type>
hpx::traits::range_iterator_t<Rng> replace_if(Rng &&rng, Pred &&pred, T const &new_value, Proj &&proj = Proj())#
+

Replaces all elements satisfying specific criteria (for which predicate pred returns true) with new_value in the range rng.

+

+Effects: Substitutes elements referred by the iterator it in the range rng with new_value, when the following corresponding conditions hold: INVOKE(f, INVOKE(proj, *it)) != false

+
+

Note

+

Complexity: Performs exactly util::end(rng) - util::begin(rng) applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by rng.This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_if algorithm returns an hpx::traits::range_iterator<Rng>::type. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Pred, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<Iter, Proj>::value_type>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> replace_if(ExPolicy &&policy, Iter first, Sent sent, Pred &&pred, T const &new_value, Proj &&proj = Proj())#
+

Replaces all elements satisfying specific criteria (for which predicate pred returns true) with new_value in the range rng.

+

+Effects: Substitutes elements referred by the iterator it in the range rng with new_value, when the following corresponding conditions hold: INVOKE(f, INVOKE(proj, *it)) != false

+

+The assignments in the parallel replace_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly util::end(rng) - util::begin(rng) applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterator used (deduced). The iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_if algorithm returns a hpx::future<Iter> if the execution policy is of type sequenced_task_policy or parallel_task_policy. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred, typename Proj = hpx::identity, typename T = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> replace_if(ExPolicy &&policy, Rng &&rng, Pred &&pred, T const &new_value, Proj &&proj = Proj())#
+

Replaces all elements satisfying specific criteria (for which predicate pred returns true) with new_value in the range rng.

+

+Effects: Substitutes elements referred by the iterator it in the range rng with new_value, when the following corresponding conditions hold: INVOKE(f, INVOKE(proj, *it)) != false

+

+The assignments in the parallel replace algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly util::end(rng) - util::begin(rng) applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires F to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by rng.This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_if algorithm returns a hpx::future<hpx::traits::range_iterator_t<Rng>> if the execution policy is of type sequenced_task_policy or parallel_task_policy. It returns last.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Proj = hpx::identity, typename T1 = typename hpx::parallel::traits::projected<Iter, Proj>::value_type, typename T2 = T1>
Iter replace(Iter first, Sent sent, T1 const &old_value, T2 const &new_value, Proj &&proj = Proj())#
+

Replaces all elements satisfying specific criteria with new_value in the range [first, last).

+

+Effects: Substitutes elements referred by the iterator it in the range [first,last) with new_value, when the following corresponding conditions hold: INVOKE(proj, *i) == old_value

+

+The assignments in the parallel replace algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • T1 – The type of the old value to replace (deduced).

  • +
  • T2 – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace algorithm returns an Iter.

+
+
+
+ +
+
+template<typename Rng, typename Proj = hpx::identity, typename T1 = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type, typename T2 = T1>
hpx::traits::range_iterator_t<Rng> replace(Rng &&rng, T1 const &old_value, T2 const &new_value, Proj &&proj = Proj())#
+

Replaces all elements satisfying specific criteria with new_value in the range rng.

+

+Effects: Substitutes elements referred by the iterator it in the range rng with new_value, when the following corresponding conditions hold: INVOKE(proj, *i) == old_value

+

+The assignments in the parallel replace algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly util::end(rng) - util::begin(rng) assignments.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • T1 – The type of the old value to replace (deduced).

  • +
  • T2 – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace algorithm returns an hpx::traits::range_iterator<Rng>::type.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Proj = hpx::identity, typename T1 = typename hpx::parallel::traits::projected<Iter, Proj>::value_type, typename T2 = T1>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> replace(ExPolicy &&policy, Iter first, Sent sent, T1 const &old_value, T2 const &new_value, Proj &&proj = Proj())#
+

Replaces all elements satisfying specific criteria with new_value in the range [first, last).

+

+Effects: Substitutes elements referred by the iterator it in the range [first,last) with new_value, when the following corresponding conditions hold: INVOKE(proj, *i) == old_value

+

+The assignments in the parallel replace algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterator used (deduced). The iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • T1 – The type of the old value to replace (deduced).

  • +
  • T2 – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace algorithm returns a hpx::future<Iter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns Iter otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Proj = hpx::identity, typename T1 = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type, typename T2 = T1>
parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> replace(ExPolicy &&policy, Rng &&rng, T1 const &old_value, T2 const &new_value, Proj &&proj = Proj())#
+

Replaces all elements satisfying specific criteria with new_value in the range rng.

+

+Effects: Substitutes elements referred by the iterator it in the range rng with new_value, when the following corresponding conditions hold: INVOKE(proj, *i) == old_value

+

+The assignments in the parallel replace algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly util::end(rng) - util::begin(rng) assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • T1 – The type of the old value to replace (deduced).

  • +
  • T2 – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked. The assignments in the parallel replace algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

  • +
+
+
Returns
+

The replace algorithm returns an hpx::future<hpx::traits::range_iterator<Rng>::type> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns hpx::traits::range_iterator<Rng>::type otherwise.

+
+
+
+ +
+
+template<typename InIter, typename Sent, typename OutIter, typename Pred, typename T = typename std::iterator_traits<OutIter>::value_type, typename Proj = hpx::identity>
replace_copy_if_result<InIter, OutIter> replace_copy_if(InIter first, Sent sent, OutIter dest, Pred &&pred, T const &new_value, Proj &&proj = Proj())#
+

Copies the all elements from the range [first, sent) to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (sent - first)) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: INVOKE(f, INVOKE(proj, *(first + (i - result)))) != false

+

+The assignments in the parallel replace_copy_if algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly sent - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_copy_if algorithm returns a in_out_result<InIter, OutIter>. The replace_copy_if algorithm returns the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename OutIter, typename Pred, typename T = typename std::iterator_traits<OutIter>::value_type, typename Proj = hpx::identity>
replace_copy_if_result<hpx::traits::range_iterator_t<Rng>, OutIter> replace_copy_if(Rng &&rng, OutIter dest, Pred &&pred, T const &new_value, Proj &&proj = Proj())#
+

Copies the all elements from the range rng to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (util::end(rng) - util::begin(rng))) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: INVOKE(f, INVOKE(proj, *(first + (i - result)))) != false

+

+The assignments in the parallel replace_copy_if algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly util::end(rng) - util::begin(rng) applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_copy_if algorithm returns an in_out_result<hpx::traits::range_iterator_t<Rng>, OutIter>. The replace_copy_if algorithm returns the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2, typename Pred, typename T = typename std::iterator_traits<FwdIter2>::value_type, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, replace_copy_if_result<FwdIter1, FwdIter2>>::type replace_copy_if(ExPolicy &&policy, FwdIter1 first, Sent sent, FwdIter2 dest, Pred &&pred, T const &new_value, Proj &&proj = Proj())#
+

Copies the all elements from the range [first, sent) to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (sent - first)) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: INVOKE(f, INVOKE(proj, *(first + (i - result)))) != false

+

+The assignments in the parallel replace_copy_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace_copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly sent - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterator used (deduced). The iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_copy_if algorithm returns an hpx::future<FwdIter1, FwdIter2>. The replace_copy_if algorithm returns the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename FwdIter, typename Pred, typename T = typename std::iterator_traits<FwdIter>::value_type, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, replace_copy_if_result<hpx::traits::range_iterator_t<Rng>, FwdIter>>::type replace_copy_if(ExPolicy &&policy, Rng &&rng, FwdIter dest, Pred &&pred, T const &new_value, Proj &&proj = Proj())#
+

Copies the all elements from the range rng to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (util::end(rng) - util::begin(rng))) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: INVOKE(f, INVOKE(proj, *(first + (i - result)))) != false

+

+The assignments in the parallel replace_copy_if algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace_copy_if algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly util::end(rng) - util::begin(rng) applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of equal requires Pred to meet the requirements of CopyConstructible. (deduced).

  • +
  • T – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate which returns true for the elements which need to replaced. The signature of this predicate should be equivalent to:

    bool pred(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_copy_if algorithm returns an hpx::future<in_out_result<hpx::traits::range_iterator_t<Rng>, OutIter>>. The replace_copy_if algorithm returns the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename InIter, typename Sent, typename OutIter, typename Proj = hpx::identity, typename T1 = typename hpx::parallel::traits::projected<InIter, Proj>::value_type, typename T2 = T1>
replace_copy_result<InIter, OutIter> replace_copy(InIter first, Sent sent, OutIter dest, T1 const &old_value, T2 const &new_value, Proj &&proj = Proj())#
+

Copies the all elements from the range [first, sent) to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (sent - first)) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: INVOKE(proj, *(first + (i - result))) == old_value

+

+The assignments in the parallel replace_copy algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly sent - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • T1 – The type of the old value to replace (deduced).

  • +
  • T2 – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_copy algorithm returns an in_out_result<InIter, OutIter>. The copy algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename OutIter, typename Proj = hpx::identity, typename T1 = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type, typename T2 = T1>
replace_copy_result<hpx::traits::range_iterator_t<Rng>, OutIter> replace_copy(Rng &&rng, OutIter dest, T1 const &old_value, T2 const &new_value, Proj &&proj = Proj())#
+

Copies the all elements from the range rbg to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (util::end(rng) - util::begin(rng))) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: INVOKE(proj, *(first + (i - result))) == old_value

+

+The assignments in the parallel replace_copy algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly util::end(rng) - util::begin(rng) applications of the predicate.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • T1 – The type of the old value to replace (deduced).

  • +
  • T2 – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_copy algorithm returns an in_out_result<hpx::traits::range_iterator_t<Rng>, OutIter>. The copy algorithm returns the pair of the input iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2, typename Proj = hpx::identity, typename T1 = typename hpx::parallel::traits::projected<FwdIter1, Proj>::value_type, typename T2 = T1>
parallel::util::detail::algorithm_result<ExPolicy, replace_copy_result<FwdIter1, FwdIter2>>::type replace_copy(ExPolicy &&policy, FwdIter1 first, Sent sent, FwdIter2 dest, T1 const &old_value, T2 const &new_value, Proj &&proj = Proj())#
+

Copies the all elements from the range [first, sent) to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (sent - first)) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: INVOKE(proj, *(first + (i - result))) == old_value

+

+The assignments in the parallel replace_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly sent - first applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterator used (deduced). The iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T1 – The type of the old value to replace (deduced).

  • +
  • T2 – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_copy algorithm returns a hpx::future<in_out_result<FwdIter1, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns in_out_result<FwdIter1, FwdIter2> otherwise. The copy algorithm returns the pair of the forward iterator last and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename FwdIter, typename Proj = hpx::identity, typename T1 = typename hpx::parallel::traits::projected<hpx::traits::range_iterator_t<Rng>, Proj>::value_type, typename T2 = T1>
parallel::util::detail::algorithm_result<ExPolicy, replace_copy_result<hpx::traits::range_iterator_t<Rng>, FwdIter>>::type replace_copy(ExPolicy &&policy, Rng &&rng, FwdIter dest, T1 const &old_value, T2 const &new_value, Proj &&proj = Proj())#
+

Copies the all elements from the range rbg to another range beginning at dest replacing all elements satisfying a specific criteria with new_value.

+

Effects: Assigns to every iterator it in the range [result, result + (util::end(rng) - util::begin(rng))) either new_value or *(first + (it - result)) depending on whether the following corresponding condition holds: INVOKE(proj, *(first + (i - result))) == old_value

+

+The assignments in the parallel replace_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel replace_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly util::end(rng) - util::begin(rng) applications of the predicate.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T1 – The type of the old value to replace (deduced).

  • +
  • T2 – The type of the new values to replace (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • old_value – Refers to the old value of the elements to replace.

  • +
  • new_value – Refers to the new value to use as the replacement.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The replace_copy algorithm returns a hpx::future<in_out_result< hpx::traits::range_iterator_t<Rng>, FwdIter>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns in_out_result< hpx::traits::range_iterator_t<Rng>, FwdIter>> The copy algorithm returns the pair of the input iterator last and the forward iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::reverse, hpx::ranges::reverse_copy#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename Iter, typename Sent>
Iter reverse(Iter first, Sent sent)#
+

Reverses the order of the elements in the range [first, last). Behaves as if applying std::iter_swap to every pair of iterators first+i, (last-i) - 1 for each non-negative i < (last-first)/2.

+

+The assignments in the parallel reverse algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for Iter.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The reverse algorithm returns a Iter. It returns last.

+
+
+
+ +
+
+template<typename Rng>
hpx::traits::range_iterator_t<Rng> reverse(Rng &&rng)#
+

Uses rng as the source range, as if using util::begin(rng) as first and ranges::end(rng) as last. Reverses the order of the elements in the range [first, last). Behaves as if applying std::iter_swap to every pair of iterators first+i, (last-i) - 1 for each non-negative i < (last-first)/2.

+

+The assignments in the parallel reverse algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+
Template Parameters
+

Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a bidirectional iterator.

+
+
Parameters
+

rng – Refers to the sequence of elements the algorithm will be applied to.

+
+
Returns
+

The reverse algorithm returns a hpx::traits::range_iterator<Rng>::type. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, Iter> reverse(ExPolicy &&policy, Iter first, Sent sent)#
+

Reverses the order of the elements in the range [first, last). Behaves as if applying std::iter_swap to every pair of iterators first+i, (last-i) - 1 for each non-negative i < (last-first)/2.

+

+The assignments in the parallel reverse algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel reverse algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for Iter.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • sent – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The reverse algorithm returns a hpx::future<Iter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns Iter otherwise. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng>
parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> reverse(ExPolicy &&policy, Rng &&rng)#
+

Uses rng as the source range, as if using util::begin(rng) as first and ranges::end(rng) as last. Reverses the order of the elements in the range [first, last). Behaves as if applying std::iter_swap to every pair of iterators first+i, (last-i) - 1 for each non-negative i < (last-first)/2.

+

+The assignments in the parallel reverse algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel reverse algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a bidirectional iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The reverse algorithm returns a hpx::future<hpx::traits::range_iterator_t<Rng>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns hpx::future< hpx::traits::range_iterator_t<Rng>> otherwise. It returns last.

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename OutIter>
reverse_copy_result<Iter, OutIter> reverse_copy(Iter first, Sent last, OutIter result)#
+

Copies the elements from the range [first, last) to another range beginning at result in such a way that the elements in the new range are in reverse order. Behaves as if by executing the assignment *(result + (last - first) - 1 - i) = *(first + i) once for each non-negative i < (last - first) If the source and destination ranges (that is, [first, last) and [result, result+(last-first)) respectively) overlap, the behavior is undefined.

+

+The assignments in the parallel reverse_copy algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • result – Refers to the begin of the destination range.

  • +
+
+
Returns
+

The reverse_copy algorithm returns a reverse_copy_result<Iter, OutIter>. The reverse_copy algorithm returns the pair of the input iterator forwarded to the first element after the last in the input sequence and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename OutIter>
reverse_copy_result<hpx::traits::range_iterator_t<Rng>, OutIter> reverse_copy(Rng &&rng, OutIter result)#
+

Uses rng as the source range, as if using util::begin(rng) as first and ranges::end(rng) as last. Copies the elements from the range [first, last) to another range beginning at result in such a way that the elements in the new range are in reverse order. Behaves as if by executing the assignment *(result + (last - first) - 1 - i) = *(first + i) once for each non-negative i < (last - first) If the source and destination ranges (that is, [first, last) and [result, result+(last-first)) respectively) overlap, the behavior is undefined.

+

+The assignments in the parallel reverse_copy algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a bidirectional iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • result – Refers to the begin of the destination range.

  • +
+
+
Returns
+

The reverse_copy algorithm returns a ranges::reverse_copy_result< hpx::traits::range_iterator_t<Rng>, OutIter>. The reverse_copy algorithm returns an object equal to {last, result + N} where N = last - first

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename FwdIter>
parallel::util::detail::algorithm_result<ExPolicy, reverse_copy_result<Iter, FwdIter>>::type reverse_copy(ExPolicy &&policy, Iter first, Sent last, FwdIter result)#
+

Copies the elements from the range [first, last) to another range beginning at result in such a way that the elements in the new range are in reverse order. Behaves as if by executing the assignment *(result + (last - first) - 1 - i) = *(first + i) once for each non-negative i < (last - first) If the source and destination ranges (that is, [first, last) and [result, result+(last-first)) respectively) overlap, the behavior is undefined.

+

+The assignments in the parallel reverse_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel reverse_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterator used (deduced). The iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for Iter.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • result – Refers to the begin of the destination range.

  • +
+
+
Returns
+

The reverse_copy algorithm returns a hpx::future<reverse_copy_result<Iter, FwdIter> > if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns reverse_copy_result<Iter, FwdIter> otherwise. The reverse_copy algorithm returns the pair of the input iterator forwarded to the first element after the last in the input sequence and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename OutIter>
parallel::util::detail::algorithm_result<ExPolicy, reverse_copy_result<hpx::traits::range_iterator_t<Rng>, OutIter>>::type reverse_copy(ExPolicy &&policy, Rng &&rng, OutIter result)#
+

Uses rng as the source range, as if using util::begin(rng) as first and ranges::end(rng) as last. Copies the elements from the range [first, last) to another range beginning at result in such a way that the elements in the new range are in reverse order. Behaves as if by executing the assignment *(result + (last - first) - 1 - i) = *(first + i) once for each non-negative i < (last - first) If the source and destination ranges (that is, [first, last) and [result, result+(last-first)) respectively) overlap, the behavior is undefined.

+

+The assignments in the parallel reverse_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel reverse_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a bidirectional iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • result – Refers to the begin of the destination range.

  • +
+
+
Returns
+

The reverse_copy algorithm returns a hpx::future<ranges::reverse_copy_result< hpx::traits::range_iterator_t<Rng>, OutIter>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::reverse_copy_result< hpx::traits::range_iterator_t<Rng>, OutIter> otherwise. The reverse_copy algorithm returns an object equal to {last, result + N} where N = last - first

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::rotate, hpx::ranges::rotate_copy#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent>
subrange_t<FwdIter, Sent> rotate(FwdIter first, FwdIter middle, Sent last)#
+

Performs a left rotation on a range of elements. Specifically, rotate swaps the elements in the range [first, last) in such a way that the element middle becomes the first element of the new range and middle - 1 becomes the last element.

+

+The assignments in the parallel rotate algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable and MoveConstructible.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the element that should appear at the beginning of the rotated range.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The rotate algorithm returns a subrange_t<FwdIter, Sent>. The rotate algorithm returns the iterator equal to pair(first + (last - middle), last).

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<FwdIter, Sent>>::type rotate(ExPolicy &&policy, FwdIter first, FwdIter middle, Sent last)#
+

Performs a left rotation on a range of elements. Specifically, rotate swaps the elements in the range [first, last) in such a way that the element middle becomes the first element of the new range and middle - 1 becomes the last element.

+

+The assignments in the parallel rotate algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel rotate algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable and MoveConstructible.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the element that should appear at the beginning of the rotated range.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
+
+
Returns
+

The rotate algorithm returns a hpx::future<subrange_t<FwdIter, Sent>> if the execution policy is of type parallel_task_policy and returns a subrange_t<FwdIter, Sent> otherwise. The rotate algorithm returns the iterator equal to pair(first + (last - middle), last).

+
+
+
+ +
+
+template<typename Rng>
subrange_t<hpx::traits::range_iterator_t<Rng>, hpx::traits::range_iterator_t<Rng>> rotate(Rng &&rng, hpx::traits::range_iterator_t<Rng> middle)#
+

Uses rng as the source range, as if using util::begin(rng) as first and ranges::end(rng) as last. Performs a left rotation on a range of elements. Specifically, rotate swaps the elements in the range [first, last) in such a way that the element middle becomes the first element of the new range and middle - 1 becomes the last element.

+

+The assignments in the parallel rotate algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable and MoveConstructible.

+
+
+
Template Parameters
+

Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the element that should appear at the beginning of the rotated range.

  • +
+
+
Returns
+

The rotate algorithm returns a subrange_t<hpx::traits::range_iterator_t<Rng>, hpx::traits::range_iterator_t<Rng>>. The rotate algorithm returns the iterator equal to pair(first + (last - middle), last).

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<hpx::traits::range_iterator_t<Rng>, hpx::traits::range_iterator_t<Rng>>> rotate(ExPolicy &&policy, Rng &&rng, hpx::traits::range_iterator_t<Rng> middle)#
+

Uses rng as the source range, as if using util::begin(rng) as first and ranges::end(rng) as last. Performs a left rotation on a range of elements. Specifically, rotate swaps the elements in the range [first, last) in such a way that the element middle becomes the first element of the new range and middle - 1 becomes the last element.

+

+The assignments in the parallel rotate algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel rotate algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable and MoveConstructible.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the element that should appear at the beginning of the rotated range.

  • +
+
+
Returns
+

The rotate algorithm returns a hpx::future <subrange_t<hpx::traits::range_iterator_t<Rng>, hpx::traits::range_iterator_t<Rng>>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns subrange_t<hpx::traits::range_iterator_t<Rng>, hpx::traits::range_iterator_t<Rng>>. otherwise. The rotate algorithm returns the iterator equal to pair(first + (last - middle), last).

+
+
+
+ +
+
+template<typename FwdIter, typename Sent, typename OutIter>
rotate_copy_result<FwdIter, OutIter> rotate_copy(FwdIter first, FwdIter middle, Sent last, OutIter dest_first)#
+

Copies the elements from the range [first, last), to another range beginning at dest_first in such a way, that the element middle becomes the first element of the new range and middle - 1 becomes the last element.

+

+The assignments in the parallel rotate_copy algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the element that should appear at the beginning of the rotated range.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest_first – Output iterator to the initial position of the range where the reversed range is stored. The pointed type shall support being assigned the value of an element in the range [first,last).

  • +
+
+
Returns
+

The rotate_copy algorithm returns a rotate_copy_result<FwdIter, OutIter>. The rotate_copy algorithm returns the output iterator to the element past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2>
parallel::util::detail::algorithm_result<ExPolicy, rotate_copy_result<FwdIter1, FwdIter2>>::type rotate_copy(ExPolicy &&policy, FwdIter1 first, FwdIter1 middle, Sent last, FwdIter2 dest_first)#
+

Copies the elements from the range [first, last), to another range beginning at dest_first in such a way, that the element middle becomes the first element of the new range and middle - 1 becomes the last element.

+

+The assignments in the parallel rotate_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel rotate_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the end iterators used (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the element that should appear at the beginning of the rotated range.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest_first – Output iterator to the initial position of the range where the reversed range is stored. The pointed type shall support being assigned the value of an element in the range [first,last).

  • +
+
+
Returns
+

The rotate_copy algorithm returns areturns hpx::future< rotate_copy_result<FwdIter1, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns rotate_copy_result<FwdIter1, FwdIter2> otherwise. The rotate_copy algorithm returns the output iterator to the element past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename OutIter>
rotate_copy_result<hpx::traits::range_iterator_t<Rng>, OutIter> rotate_copy(Rng &&rng, hpx::traits::range_iterator_t<Rng> middle, OutIter dest_first)#
+

Uses rng as the source range, as if using util::begin(rng) as first and ranges::end(rng) as last. Copies the elements from the range [first, last), to another range beginning at dest_first in such a way, that the element middle becomes the first element of the new range and middle - 1 becomes the last element.

+

+The assignments in the parallel rotate_copy algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the element that should appear at the beginning of the rotated range.

  • +
  • dest_first – Output iterator to the initial position of the range where the reversed range is stored. The pointed type shall support being assigned the value of an element in the range [first,last).

  • +
+
+
Returns
+

The rotate algorithm returns a rotate_copy_result<hpx::traits::range_iterator_t<Rng>, OutIter>. The rotate_copy algorithm returns the output iterator to the element past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename OutIter>
parallel::util::detail::algorithm_result<ExPolicy, rotate_copy_result<hpx::traits::range_iterator_t<Rng>, OutIter>> rotate_copy(ExPolicy &&policy, Rng &&rng, hpx::traits::range_iterator_t<Rng> middle, OutIter dest_first)#
+

Uses rng as the source range, as if using util::begin(rng) as first and ranges::end(rng) as last. Copies the elements from the range [first, last), to another range beginning at dest_first in such a way, that the element new_first becomes the first element of the new range and new_first - 1 becomes the last element.

+

+The assignments in the parallel rotate_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel rotate_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of a forward iterator.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • middle – Refers to the element that should appear at the beginning of the rotated range.

  • +
  • dest_first – Output iterator to the initial position of the range where the reversed range is stored. The pointed type shall support being assigned the value of an element in the range [first,last).

  • +
+
+
Returns
+

The rotate_copy algorithm returns a hpx::future<otate_copy_result< hpx::traits::range_iterator_t<Rng>, OutIter>> if the execution policy is of type parallel_task_policy and returns rotate_copy_result< hpx::traits::range_iterator_t<Rng>, OutIter> otherwise. The rotate_copy algorithm returns the output iterator to the element past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::search, hpx::ranges::search_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent, typename FwdIter2, typename Sent2, typename Pred = hpx::ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
FwdIter search(FwdIter first, Sent last, FwdIter2 s_first, Sent2 s_last, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements.

+

+The comparison operations in the parallel search algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel used for the first range (deduced). This iterator type must meet the requirements of an sentinel.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the source sentinel used for the second range (deduced). This iterator type must meet the requirements of an sentinel.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of type dereferenced FwdIter.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of type dereferenced FwdIter2.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced FwdIter1 as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced FwdIter2 as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The search algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The search algorithm returns an iterator to the beginning of the first subsequence [s_first, s_last) in range [first, last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty first is returned. If no subsequence is found, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename FwdIter2, typename Sent2, typename Pred = hpx::ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type search(ExPolicy &&policy, FwdIter first, Sent last, FwdIter2 s_first, Sent2 s_last, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements.

+

+The comparison operations in the parallel search algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel search algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel used for the first range (deduced). This iterator type must meet the requirements of an sentinel.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the source sentinel used for the second range (deduced). This iterator type must meet the requirements of an sentinel.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of type dereferenced FwdIter.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of type dereferenced FwdIter2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced FwdIter1 as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced FwdIter2 as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The search algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The search algorithm returns an iterator to the beginning of the first subsequence [s_first, s_last) in range [first, last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty first is returned. If no subsequence is found, last is returned.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Pred = hpx::ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::traits::range_iterator_t<Rng1> search(Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements.

+

+The comparison operations in the parallel search algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the examine range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the search range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of Rng1.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of Rng2.

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the sequence of elements the algorithm will be examining.

  • +
  • rng2 – Refers to the sequence of elements the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of rng1 as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of rng2 as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The search algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The search algorithm returns an iterator to the beginning of the first subsequence [s_first, s_last) in range [first, last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty first is returned. If no subsequence is found, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Pred = hpx::ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng1>> search(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements.

+

+The comparison operations in the parallel search algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel search algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the examine range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the search range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of Rng1.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of Rng2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the sequence of elements the algorithm will be examining.

  • +
  • rng2 – Refers to the sequence of elements the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of rng1 as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of rng2 as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The search algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The search algorithm returns an iterator to the beginning of the first subsequence [s_first, s_last) in range [first, last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty first is returned. If no subsequence is found, last is returned.

+
+
+
+ +
+
+template<typename FwdIter, typename FwdIter2, typename Sent2, typename Pred = hpx::ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
FwdIter search_n(FwdIter first, std::size_t count, FwdIter2 s_first, Sent s_last, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements.

+

+The comparison operations in the parallel search_n algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = count.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the source sentinel used for the second range (deduced). This iterator type must meet the requirements of an sentinel.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of type dereferenced FwdIter.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of type dereferenced FwdIter2.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • count – Refers to the range of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced FwdIter1 as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced FwdIter2 as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The search_n algorithm returns FwdIter. The search_n algorithm returns an iterator to the beginning of the last subsequence [s_first, s_last) in range [first, first+count). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, first+count), first is returned. Additionally, if the size of the subsequence is empty or no subsequence is found, first is also returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename FwdIter2, typename Sent2, typename Pred = hpx::ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type search_n(ExPolicy &&policy, FwdIter first, std::size_t count, FwdIter2 s_first, Sent2 s_last, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements.

+

+The comparison operations in the parallel search_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel search_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = count.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used for the first range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • FwdIter2 – The type of the source iterators used for the second range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the source sentinel used for the second range (deduced). This iterator type must meet the requirements of an sentinel.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of type dereferenced FwdIter.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of type dereferenced FwdIter2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • count – Refers to the range of elements of the first range the algorithm will be applied to.

  • +
  • s_first – Refers to the beginning of the sequence of elements the algorithm will be searching for.

  • +
  • s_last – Refers to the end of the sequence of elements of the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced FwdIter1 as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of type dereferenced FwdIter2 as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The search_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The search_n algorithm returns an iterator to the beginning of the last subsequence [s_first, s_last) in range [first, first+count). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, first+count), first is returned. Additionally if the size of the subsequence is empty or no subsequence is found, first is also returned.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Pred = hpx::ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::traits::range_iterator_t<Rng1> search_n(Rng1 &&rng1, std::size_t count, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements.

+

+The comparison operations in the parallel search algorithm execute in sequential order in the calling thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the examine range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the search range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of Rng1.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of Rng2.

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the sequence of elements the algorithm will be examining.

  • +
  • count – The number of elements to apply the algorithm on.

  • +
  • rng2 – Refers to the sequence of elements the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of rng1 as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of rng2 as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The search algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The search algorithm returns an iterator to the beginning of the first subsequence [s_first, s_last) in range [first, last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty first is returned. If no subsequence is found, last is returned.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Pred = hpx::ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng1>> search_n(ExPolicy &&policy, Rng1 &&rng1, std::size_t count, Rng2 &&rng2, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Searches the range [first, last) for any elements in the range [s_first, s_last). Uses a provided predicate to compare elements.

+

+The comparison operations in the parallel search algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The comparison operations in the parallel search algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: at most (S*N) comparisons where S = distance(s_first, s_last) and N = distance(first, last).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the examine range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the search range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of adjacent_find requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj1 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of Rng1.

  • +
  • Proj2 – The type of an optional projection function. This defaults to hpx::identity and is applied to the elements of Rng2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the sequence of elements the algorithm will be examining.

  • +
  • count – The number of elements to apply the algorithm on.

  • +
  • rng2 – Refers to the sequence of elements the algorithm will be searching for.

  • +
  • op – Refers to the binary predicate which returns true if the elements should be treated as equal. the signature of the function should be equivalent to

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of rng1 as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of rng2 as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The search algorithm returns a hpx::future<FwdIter> if the execution policy is of type task_execution_policy and returns FwdIter otherwise. The search algorithm returns an iterator to the beginning of the first subsequence [s_first, s_last) in range [first, last). If the length of the subsequence [s_first, s_last) is greater than the length of the range [first, last), last is returned. Additionally if the size of the subsequence is empty first is returned. If no subsequence is found, last is returned.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::set_difference#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, set_difference_result<Iter1, Iter3>>::type set_difference(ExPolicy &&policy, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in the range [first1, last1) and not present in the range [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+Equivalent elements are treated individually, that is, if some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::max(m-n, 0) times. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_difference algorithm returns a hpx::future<ranges::set_difference_result<Iter1, Iter3>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::set_difference_result<Iter1, Iter3> otherwise. The set_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, set_difference_result<hpx::traits::range_iterator_t<Rng1>, Iter3>> set_difference(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in the range [first1, last1) and not present in the range [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+Equivalent elements are treated individually, that is, if some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::max(m-n, 0) times. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_difference algorithm returns a hpx::future<ranges::set_difference_result<Iter1, Iter3>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::set_difference_result<Iter1, Iter3> otherwise. where Iter1 is range_iterator_t<Rng1> and Iter2 is range_iterator_t<Rng2> The set_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
set_difference_result<Iter1, Iter3> set_difference(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in the range [first1, last1) and not present in the range [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+Equivalent elements are treated individually, that is, if some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::max(m-n, 0) times. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_difference algorithm returns ranges::set_difference_result<Iter1, Iter3>. The set_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
set_difference_result<hpx::traits::range_iterator_t<Rng1>, Iter3> set_difference(Rng1 &&rng1, Rng2 &&rng2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in the range [first1, last1) and not present in the range [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+Equivalent elements are treated individually, that is, if some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::max(m-n, 0) times. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_difference algorithm returns ranges::set_difference_result<Iter1, Iter3>. where Iter1 is range_iterator_t<Rng1> and Iter2 is range_iterator_t<Rng2> The set_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::set_intersection#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, set_intersection_result<Iter1, Iter2, Iter3>>::type set_intersection(ExPolicy &&policy, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), the first std::min(m, n) elements will be copied from the first range to the destination range. The order of equivalent elements is preserved. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_intersection requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_intersection algorithm returns a hpx::future<ranges::set_intersection_result<Iter1, Iter2, Iter3>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::set_intersection_result<Iter1, Iter2, Iter3> otherwise. The set_intersection algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, set_intersection_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, Iter3>> set_intersection(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), the first std::min(m, n) elements will be copied from the first range to the destination range. The order of equivalent elements is preserved. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_intersection requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_intersection algorithm returns a hpx::future<ranges::set_intersection_result<Iter1, Iter2, Iter3>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::set_intersection_result<Iter1, Iter2, Iter3> otherwise. where Iter1 is range_iterator_t<Rng1> and Iter2 is range_iterator_t<Rng2> The set_intersection algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
set_intersection_result<Iter1, Iter2, Iter3> set_intersection(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), the first std::min(m, n) elements will be copied from the first range to the destination range. The order of equivalent elements is preserved. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_intersection requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_intersection algorithm returns ranges::set_intersection_result<Iter1, Iter2, Iter3>. The set_intersection algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
set_intersection_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, Iter3> set_intersection(Rng1 &&rng1, Rng2 &&rng2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), the first std::min(m, n) elements will be copied from the first range to the destination range. The order of equivalent elements is preserved. The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_intersection requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_intersection algorithm returns ranges::set_intersection_result<Iter1, Iter2, Iter3>. where Iter1 is range_iterator_t<Rng1> and Iter2 is range_iterator_t<Rng2> The set_intersection algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::set_symmetric_difference#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, set_symmetric_difference_result<Iter1, Iter2, Iter3>>::type set_symmetric_difference(ExPolicy &&policy, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in either of the sorted ranges [first1, last1) and [first2, last2), but not in both of them are copied to the range beginning at dest. The resulting range is also sorted. This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::abs(m-n) times. If m>n, then the last m-n of those elements are copied from [first1,last1), otherwise the last n-m elements are copied from [first2,last2). The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_symmetric_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_symmetric_difference algorithm returns a hpx::future<ranges::set_symmetric_difference_result<Iter1, Iter2, Iter3>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::set_symmetric_difference_result<Iter1, Iter2, Iter3> otherwise. The set_symmetric_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, set_symmetric_difference_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, Iter3>> set_symmetric_difference(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in either of the sorted ranges [first1, last1) and [first2, last2), but not in both of them are copied to the range beginning at dest. The resulting range is also sorted. This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::abs(m-n) times. If m>n, then the last m-n of those elements are copied from [first1,last1), otherwise the last n-m elements are copied from [first2,last2). The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_symmetric_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_symmetric_difference algorithm returns a hpx::future<ranges::set_symmetric_difference_result<Iter1, Iter2, Iter3>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::set_symmetric_difference_result<Iter1, Iter2, Iter3> otherwise. where Iter1 is range_iterator_t<Rng1> and Iter2 is range_iterator_t<Rng2> The set_symmetric_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
set_symmetric_difference_result<Iter1, Iter2, Iter3> set_symmetric_difference(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in either of the sorted ranges [first1, last1) and [first2, last2), but not in both of them are copied to the range beginning at dest. The resulting range is also sorted. This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::abs(m-n) times. If m>n, then the last m-n of those elements are copied from [first1,last1), otherwise the last n-m elements are copied from [first2,last2). The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_symmetric_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_symmetric_difference algorithm returns ranges::set_symmetric_difference_result<Iter1, Iter2, Iter3>. The set_symmetric_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
set_symmetric_difference_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, Iter3> set_symmetric_difference(Rng1 &&rng1, Rng2 &&rng2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in either of the sorted ranges [first1, last1) and [first2, last2), but not in both of them are copied to the range beginning at dest. The resulting range is also sorted. This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), it will be copied to dest exactly std::abs(m-n) times. If m>n, then the last m-n of those elements are copied from [first1,last1), otherwise the last n-m elements are copied from [first2,last2). The resulting range cannot overlap with either of the input ranges.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_symmetric_difference requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_symmetric_difference algorithm returns ranges::set_symmetric_difference_result<Iter1, Iter2, Iter3>. where Iter1 is range_iterator_t<Rng1> and Iter2 is range_iterator_t<Rng2> The set_symmetric_difference algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::set_union#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, set_union_result<Iter1, Iter2, Iter3>>::type set_union(ExPolicy &&policy, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in one or both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), then all m elements will be copied from [first1, last1) to dest, preserving order, and then exactly std::max(n-m, 0) elements will be copied from [first2, last2) to dest, also preserving order.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_union requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_union algorithm returns a hpx::future<ranges::set_union_result<Iter1, Iter2, Iter3>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::set_union_result<Iter1, Iter2, Iter3> otherwise. The set_union algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, set_union_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, Iter3>> set_union(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in one or both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), then all m elements will be copied from [first1, last1) to dest, preserving order, and then exactly std::max(n-m, 0) elements will be copied from [first2, last2) to dest, also preserving order.

+

The resulting range cannot overlap with either of the input ranges.

+

+The application of function objects in parallel algorithm invoked with a sequential execution policy object execute in sequential order in the calling thread (sequenced_policy) or in a single new thread spawned from the current thread (for sequenced_task_policy).

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_union requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_union algorithm returns a hpx::future<ranges::set_union_result<Iter1, Iter2, Iter3>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns ranges::set_union_result<Iter1, Iter2, Iter3> otherwise. where Iter1 is range_iterator_t<Rng1> and Iter2 is range_iterator_t<Rng2> The set_union algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
set_union_result<Iter1, Iter2, Iter3> tag_fallback_invoke(set_union_t, Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in one or both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), then all m elements will be copied from [first1, last1) to dest, preserving order, and then exactly std::max(n-m, 0) elements will be copied from [first2, last2) to dest, also preserving order.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the source iterators used (deduced) representing the first sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_union requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the sequence of elements of the first range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_union algorithm returns ranges::set_union_result<Iter1, Iter2, Iter3>. The set_union algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Iter3, typename Pred = hpx::parallel::detail::less, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
set_union_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, Iter3> set_union(Rng1 &&rng1, Rng2 &&rng2, Iter3 dest, Pred &&op = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Constructs a sorted range beginning at dest consisting of all elements present in one or both sorted ranges [first1, last1) and [first2, last2). This algorithm expects both input ranges to be sorted with the given binary predicate f.

+

+If some element is found m times in [first1, last1) and n times in [first2, last2), then all m elements will be copied from [first1, last1) to dest, preserving order, and then exactly std::max(n-m, 0) elements will be copied from [first2, last2) to dest, also preserving order.

+

The resulting range cannot overlap with either of the input ranges.

+
+

Note

+

Complexity: At most 2*(N1 + N2 - 1) comparisons, where N1 is the length of the first sequence and N2 is the length of the second sequence.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter3 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • Pred – The type of an optional function/function object to use. Unlike its sequential form, the parallel overload of set_union requires Pred to meet the requirements of CopyConstructible. This defaults to std::less<>

  • +
  • Proj1 – The type of an optional projection function applied to the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function applied to the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • op – The binary predicate which returns true if the elements should be treated as equal. The signature of the predicate function should be equivalent to the following:

    bool pred(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const &, but the function must not modify the objects passed to it. The type Type1 must be such that objects of type InIter can be dereferenced and then implicitly converted to Type1

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate op is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate op is invoked.

  • +
+
+
Returns
+

The set_union algorithm returns ranges::set_union_result<Iter1, Iter2, Iter3>. where Iter1 is range_iterator_t<Rng1> and Iter2 is range_iterator_t<Rng2> The set_union algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::shift_left#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent, typename Size>
FwdIter shift_left(FwdIter first, Sent last, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the beginning of the range. For every integer i in [0, last - first

    +
  • n), moves the element originally at position first + n + i to position first + i.

  • +
+

+

+The assignment operations in the parallel shift_left algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_left algorithm returns FwdIter. The shift_left algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename Size>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> shift_left(ExPolicy &&policy, FwdIter first, Sent last, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the beginning of the range. For every integer i in [0, last - first

    +
  • n), moves the element originally at position first + n + i to position first + i.

  • +
+

+

+The assignment operations in the parallel shift_left algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignment operations in the parallel shift_left algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_left algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The shift_left algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+template<typename Rng, typename Size>
hpx::traits::range_iterator_t<Rng> shift_left(Rng &&rng, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the beginning of the range. For every integer i in [0, last - first

    +
  • n), moves the element originally at position first + n + i to position first + i.

  • +
+

+

+The assignment operations in the parallel shift_left algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced hpx::traits::range_iterator_t<Rng> must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the range in which the elements will be shifted.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_left algorithm returns hpx::traits::range_iterator_t<Rng>. The shift_left algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Size>
parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> shift_left(ExPolicy &&policy, Rng &&rng, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the beginning of the range. For every integer i in [0, last - first

    +
  • n), moves the element originally at position first + n + i to position first + i.

  • +
+

+

+The assignment operations in the parallel shift_left algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignment operations in the parallel shift_left algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced hpx::traits::range_iterator_t<Rng> must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the range in which the elements will be shifted.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_left algorithm returns a hpx::future<hpx::traits::range_iterator_t<Rng>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns hpx::traits::range_iterator_t<Rng> otherwise. The shift_left algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::shift_right#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent, typename Size>
FwdIter shift_right(FwdIter first, Sent last, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the end of the range. For every integer i in [0, last - first - n), moves the element originally at position first + i to position first

    +
  • n + i.

  • +
+

+

+The assignment operations in the parallel shift_right algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_right algorithm returns FwdIter. The shift_right algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename Size>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> shift_right(ExPolicy &&policy, FwdIter first, Sent last, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the end of the range. For every integer i in [0, last - first - n), moves the element originally at position first + i to position first

    +
  • n + i.

  • +
+

+

+The assignment operations in the parallel shift_right algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignment operations in the parallel shift_right algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced FwdIter must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_right algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The shift_right algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+template<typename Rng, typename Size>
hpx::traits::range_iterator_t<Rng> shift_right(Rng &&rng, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the end of the range. For every integer i in [0, last - first - n), moves the element originally at position first + i to position first

    +
  • n + i.

  • +
+

+

+The assignment operations in the parallel shift_right algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced hpx::traits::range_iterator_t<Rng> must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the range in which the elements will be shifted.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_right algorithm returns hpx::traits::range_iterator_t<Rng>. The shift_right algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Size>
parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> shift_right(ExPolicy &&policy, Rng &&rng, Size n)#
+

Shifts the elements in the range [first, last) by n positions towards the end of the range. For every integer i in [0, last - first - n), moves the element originally at position first + i to position first

    +
  • n + i.

  • +
+

+

+The assignment operations in the parallel shift_right algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignment operations in the parallel shift_right algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: At most (last - first) - n assignments.

+
+
+

Note

+

The type of dereferenced hpx::traits::range_iterator_t<Rng> must meet the requirements of MoveAssignable.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Size – The type of the argument specifying the number of positions to shift by.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the range in which the elements will be shifted.

  • +
  • n – Refers to the number of positions to shift.

  • +
+
+
Returns
+

The shift_right algorithm returns a hpx::future<hpx::traits::range_iterator_t<Rng>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns hpx::traits::range_iterator_t<Rng> otherwise. The shift_right algorithm returns an iterator to the end of the resulting range.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::sort#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename RandomIt, typename Sent, typename Comp = ranges::less, typename Proj = hpx::identity>
RandomIt sort(RandomIt first, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range [first, last) in ascending order. The order of equal elements is not guaranteed to be preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The assignments in the parallel sort algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: O(N log(N)), where N = detail::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • RandomIt – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for RandomIt.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The sort algorithm returns RandomIt. The algorithm returns an iterator pointing to the first element after the last element in the input sequence.

+
+
+
+ +
+
+template<typename ExPolicy, typename RandomIt, typename Sent, typename Comp = ranges::less, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, RandomIt>::type sort(ExPolicy &&policy, RandomIt first, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range [first, last) in ascending order. The order of equal elements is not guaranteed to be preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(N)), where N = detail::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RandomIt – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for RandomIt.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The sort algorithm returns a hpx::future<RandomIt> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns RandomIt otherwise. The algorithm returns an iterator pointing to the first element after the last element in the input sequence.

+
+
+
+ +
+
+template<typename Rng, typename Comp, typename Proj>
hpx::traits::range_iterator_t<Rng> sort(Rng &&rng, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range rng in ascending order. The order of equal elements is not guaranteed to be preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The assignments in the parallel sort algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(begin(rng), end(rng)) comparisons.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The sort algorithm returns hpx::traits::range_iterator_t<Rng>. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Comp = ranges::less, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> sort(ExPolicy &&policy, Rng &&rng, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range rng in ascending order. The order of equal elements is not guaranteed to be preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(begin(rng), end(rng)) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The sort algorithm returns a hpx::future<hpx::traits::range_iterator_t<Rng> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns hpx::traits::range_iterator_t<Rng> otherwise. It returns last.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::stable_sort#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename RandomIt, typename Sent, typename Comp = ranges::less, typename Proj = hpx::identity>
RandomIt stable_sort(RandomIt first, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range [first, last) in ascending order. The relative order of equal elements is preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The assignments in the parallel stable_sort algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • RandomIt – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for RandomIt.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The stable_sort algorithm returns RandomIt. The algorithm returns an iterator pointing to the first element after the last element in the input sequence.

+
+
+
+ +
+
+template<typename ExPolicy, typename RandomIt, typename Sent, typename Comp = ranges::less, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, RandomIt>::type stable_sort(ExPolicy &&policy, RandomIt first, Sent last, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range [first, last) in ascending order. The relative order of equal elements is preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • RandomIt – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for RandomIt.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The stable_sort algorithm returns a hpx::future<RandomIt> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns RandomIt otherwise. The algorithm returns an iterator pointing to the first element after the last element in the input sequence.

+
+
+
+ +
+
+template<typename Rng, typename Comp = ranges::less, typename Proj = hpx::identity>
hpx::traits::range_iterator_t<Rng> stable_sort(Rng &&rng, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range [first, last) in ascending order. The relative order of equal elements is preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The assignments in the parallel stable_sort algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The stable_sort algorithm returns hpx::traits::range_iterator_t<Rng>. It returns last.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Comp = ranges::less, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, hpx::traits::range_iterator_t<Rng>> stable_sort(ExPolicy &&policy, Rng &&rng, Comp &&comp = Comp(), Proj &&proj = Proj())#
+

Sorts the elements in the range [first, last) in ascending order. The relative order of equal elements is preserved. The function uses the given comparison function object comp (defaults to using operator<()).

+

+A sequence is sorted with respect to a comparator comp and a projection proj if for every iterator i pointing to the sequence and every non-negative integer n such that i + n is a valid iterator pointing to an element of the sequence, and INVOKE(comp, INVOKE(proj, *(i + n)), INVOKE(proj, *i)) == false.

+

comp has to induce a strict weak ordering on the values.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The application of function objects in parallel algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(N log(N)), where N = std::distance(first, last) comparisons.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it applies user-provided function objects.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Comp – The type of the function/function object to use (deduced).

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • comp – comp is a callable object. The return value of the INVOKE operation applied to an object of type Comp, when contextually converted to bool, yields true if the first argument of the call is less than the second, and false otherwise. It is assumed that comp will not apply any non-constant function through the dereferenced iterator.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each pair of elements as a projection operation before the actual predicate comp is invoked.

  • +
+
+
Returns
+

The stable_sort algorithm returns a hpx::future<hpx::traits::range_iterator_t<Rng> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns hpx::traits::range_iterator_t<Rng> otherwise. It returns last.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::starts_with#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Pred = ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
bool starts_with(Iter1 first1, Sent1 last1, Iter2 first2, Sent2 last2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks whether the second range defined by [first1, last1) matches the prefix of the first range defined by [first2, last2)

+

+The assignments in the parallel starts_with algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • Iter1 – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent1 – The type of the end source iterators used(deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • Iter2 – The type of the begin destination iterators used deduced). This iterator type must meet the requirements of a input iterator.

  • +
  • Sent2 – The type of the end destination iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Pred – The binary predicate that compares the projected elements.

  • +
  • Proj1 – The type of an optional projection function for the source range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for the destination range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the source range.

  • +
  • last1 – Sentinel value referring to the end of the source range.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Sentinel value referring to the end of the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements in the source range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements in the destination range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The starts_with algorithm returns bool. The starts_with algorithm returns a boolean with the value true if the second range matches the prefix of the first range, false otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent1, typename FwdIter2, typename Sent2, typename Pred = ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, bool> starts_with(ExPolicy &&policy, FwdIter1 first1, Sent1 last1, FwdIter2 first2, Sent2 last2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks whether the second range defined by [first1, last1) matches the prefix of the first range defined by [first2, last2)

+

+The assignments in the parallel starts_with algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel starts_with algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the begin source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent1 – The type of the end source iterators used(deduced). This iterator type must meet the requirements of an sentinel for Iter1.

  • +
  • FwdIter2 – The type of the begin destination iterators used deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the end destination iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter2.

  • +
  • Pred – The binary predicate that compares the projected elements.

  • +
  • Proj1 – The type of an optional projection function for the source range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for the destination range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the source range.

  • +
  • last1 – Sentinel value referring to the end of the source range.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Sentinel value referring to the end of the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements in the source range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements in the destination range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The starts_with algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The starts_with algorithm returns a boolean with the value true if the second range matches the prefix of the first range, false otherwise.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename Pred = ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
bool starts_with(Rng1 &&rng1, Rng2 &&rng2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks whether the second range rng2 matches the prefix of the first range rng1.

+

+The assignments in the parallel starts_with algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The binary predicate that compares the projected elements.

  • +
  • Proj1 – The type of an optional projection function for the source range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for the destination range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the source range.

  • +
  • rng2 – Refers to the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements in the source range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements in the destination range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The starts_with algorithm returns bool. The starts_with algorithm returns a boolean with the value true if the second range matches the prefix of the first range, false otherwise.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename Pred = ranges::equal_to, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
hpx::parallel::util::detail::algorithm_result<ExPolicy, bool>::type starts_with(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, Pred &&pred = Pred(), Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Checks whether the second range rng2 matches the prefix of the first range rng1.

+

+The assignments in the parallel starts_with algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel starts_with algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear: at most min(N1, N2) applications of the predicate and both projections.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The binary predicate that compares the projected elements.

  • +
  • Proj1 – The type of an optional projection function for the source range. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function for the destination range. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the source range.

  • +
  • rng2 – Refers to the destination range.

  • +
  • pred – Specifies the binary predicate function (or function object) which will be invoked for comparison of the elements in the in two ranges projected by proj1 and proj2 respectively.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements in the source range as a projection operation before the actual predicate is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements in the destination range as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The starts_with algorithm returns a hpx::future<bool> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns bool otherwise. The starts_with algorithm returns a boolean with the value true if the second range matches the prefix of the first range, false otherwise.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::swap_ranges#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename InIter1, typename Sent1, typename InIter2, typename Sent2>
swap_ranges_result<InIter1, InIter2> swap_ranges(InIter1 first1, Sent1 last1, InIter2 first2, Sent2 last2)#
+

Exchanges elements between range [first1, last1) and another range starting at first2.

+

+The swap operations in the parallel swap_ranges algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first1 and last1

+
+
+
Template Parameters
+
    +
  • InIter1 – The type of the first range of iterators to swap (deduced).

  • +
  • Sent1 – The type of the first sentinel (deduced). This sentinel type must be a sentinel for InIter1.

  • +
  • InIter2 – The type of the second range of iterators to swap (deduced).

  • +
  • Sent2 – The type of the second sentinel (deduced). This sentinel type must be a sentinel for InIter2.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements for the first range.

  • +
  • last1 – Refers to sentinel value denoting the end of the sequence of elements for the first range.

  • +
  • first2 – Refers to the beginning of the sequence of elements for the second range.

  • +
  • last2 – Refers to sentinel value denoting the end of the sequence of elements for the second range.

  • +
+
+
Returns
+

The swap_ranges algorithm returns swap_ranges_result<InIter1, InIter2>. The swap_ranges algorithm returns in_in_result with the first element as the iterator to the element past the last element exchanged in range beginning with first1 and the second element as the iterator to the element past the last element exchanged in the range beginning with first2.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent1, typename FwdIter2, typename Sent2>
parallel::util::detail::algorithm_result<ExPolicy, swap_ranges_result<FwdIter1, FwdIter2>>::type swap_ranges(ExPolicy &&policy, FwdIter1 first1, Sent1 last1, FwdIter2 first2, Sent2 last2)#
+

Exchanges elements between range [first1, last1) and another range starting at first2.

+

+The swap operations in the parallel swap_ranges algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The swap operations in the parallel swap_ranges algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first1 and last1

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the first range of iterators to swap (deduced).

  • +
  • Sent1 – The type of the first sentinel (deduced). This sentinel type must be a sentinel for FwdIter1.

  • +
  • FwdIter2 – The type of the second range of iterators to swap (deduced).

  • +
  • Sent2 – The type of the second sentinel (deduced). This sentinel type must be a sentinel for FwdIter2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements for the first range.

  • +
  • last1 – Refers to sentinel value denoting the end of the sequence of elements for the first range.

  • +
  • first2 – Refers to the beginning of the sequence of elements for the second range.

  • +
  • last2 – Refers to sentinel value denoting the end of the sequence of elements for the second range.

  • +
+
+
Returns
+

The swap_ranges algorithm returns a hpx::future<swap_ranges_result<FwdIter1, FwdIter2>> if the execution policy is of type parallel_task_policy and returns FwdIter2 otherwise. The swap_ranges algorithm returns in_in_result with the first element as the iterator to the element past the last element exchanged in range beginning with first1 and the second element as the iterator to the element past the last element exchanged in the range beginning with first2.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2>
swap_ranges_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>> swap_ranges(Rng1 &&rng1, Rng2 &&rng2)#
+

Exchanges elements between range [first1, last1) and another range starting at first2.

+

+The swap operations in the parallel swap_ranges algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first1 and last1

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the sequence of elements of the first range.

  • +
  • rng2 – Refers to the sequence of elements of the second range.

  • +
+
+
Returns
+

The swap_ranges algorithm returns swap_ranges_result< hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng1>>. The swap_ranges algorithm returns in_in_result with the first element as the iterator to the element past the last element exchanged in range beginning with first1 and the second element as the iterator to the element past the last element exchanged in the range beginning with first2.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2>
parallel::util::detail::algorithm_result<ExPolicy, swap_ranges_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>>> swap_ranges(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2)#
+

Exchanges elements between range [first1, last1) and another range starting at first2.

+

+The swap operations in the parallel swap_ranges algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The swap operations in the parallel swap_ranges algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first1 and last1

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the sequence of elements of the first range.

  • +
  • rng2 – Refers to the sequence of elements of the second range.

  • +
+
+
Returns
+

The swap_ranges algorithm returns a hpx::future<swap_ranges_result< hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng1>>> if the execution policy is of type parallel_task_policy and returns swap_ranges_result< hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng1>>. otherwise. The swap_ranges algorithm returns in_in_result with the first element as the iterator to the element past the last element exchanged in range beginning with first1 and the second element as the iterator to the element past the last element exchanged in the range beginning with first2.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::transform#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename Sent1, typename FwdIter2, typename F, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, ranges::unary_transform_result<FwdIter1, FwdIter2>>::type transform(ExPolicy &&policy, FwdIter1 first, Sent1 last, FwdIter2 dest, F &&f, Proj &&proj = Proj())#
+

Applies the given function f to the given range rng and stores the result in another range, beginning at dest.

+

+The invocations of f in the parallel transform algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The invocations of f in the parallel transform algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly size(rng) applications of f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the invocations of f.

  • +
  • FwdIter1 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of a sentinel for FwdIter1.

  • +
  • FwdIter2 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type Ret must be such that an object of type FwdIter2 can be dereferenced and assigned a value of type Ret.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The transform algorithm returns a hpx::future<ranges::unary_transform_result<FwdIter1, FwdIter2> > if the execution policy is of type parallel_task_policy and returns ranges::unary_transform_result<FwdIter1, FwdIter2> otherwise. The transform algorithm returns a tuple holding an iterator referring to the first element after the input sequence and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename FwdIter, typename F, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, ranges::unary_transform_result<hpx::traits::range_iterator_t<Rng>, FwdIter>> transform(ExPolicy &&policy, Rng &&rng, FwdIter dest, F &&f, Proj &&proj = Proj())#
+

Applies the given function f to the given range rng and stores the result in another range, beginning at dest.

+

+The invocations of f in the parallel transform algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The invocations of f in the parallel transform algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly size(rng) applications of f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the invocations of f.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type range_iterator<Rng>::type can be dereferenced and then implicitly converted to Type. The type Ret must be such that an object of type OutIter can be dereferenced and assigned a value of type Ret.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The transform algorithm returns a hpx::future<ranges::unary_transform_result<range_iterator<Rng>::type, FwdIter>> if the execution policy is of type parallel_task_policy and returns ranges::unary_transform_result<range_iterator<Rng>::type, FwdIter> otherwise. The transform algorithm returns a tuple holding an iterator referring to the first element after the input sequence and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent1, typename FwdIter2, typename Sent2, typename FwdIter3, typename F, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, ranges::binary_transform_result<FwdIter1, FwdIter2, FwdIter3>>::type transform(ExPolicy &&policy, FwdIter1 first1, Sent1 last1, FwdIter2 first2, Sent2 last2, FwdIter3 dest, F &&f, Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Applies the given function f to pairs of elements from two ranges: one defined by rng and the other beginning at first2, and stores the result in another range, beginning at dest.

+

+The invocations of f in the parallel transform algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The invocations of f in the parallel transform algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly size(rng) applications of f

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the invocations of f.

  • +
  • FwdIter1 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of a sentinel for FwdIter1.

  • +
  • FwdIter2 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of a sentinel for FwdIter2.

  • +
  • FwdIter3 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
  • Proj1 – The type of an optional projection function to be used for elements of the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function to be used for elements of the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively. The type Ret must be such that an object of type FwdIter3 can be dereferenced and assigned a value of type Ret.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate f is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The transform algorithm returns A hpx::future<ranges::binary_transform_result<FwdIter1, FwdIter2, FwdIter3>> if the execution policy is of type parallel_task_policy and returns ranges::binary_transform_result<FwdIter1, FwdIter2, FwdIter3> otherwise. The transform algorithm returns a tuple holding an iterator referring to the first element after the first input sequence, an iterator referring to the first element after the second input sequence, and the output iterator referring to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2, typename FwdIter, typename F, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, ranges::binary_transform_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, FwdIter>> transform_t(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2, FwdIter dest, F &&f, Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Applies the given function f to pairs of elements from two ranges: one defined by [first1, last1) and the other beginning at first2, and stores the result in another range, beginning at dest.

+

+The invocations of f in the parallel transform algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The invocations of f in the parallel transform algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Exactly min(last2-first2, last1-first1) applications of f

+
+
+

Note

+

The algorithm will invoke the binary predicate until it reaches the end of the shorter of the two given input sequences

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the invocations of f.

  • +
  • Rng1 – The type of the first source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the second source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
  • Proj1 – The type of an optional projection function to be used for elements of the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function to be used for elements of the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 and Type2 must be such that objects of types range_iterator<Rng1>::type and range_iterator<Rng2>::type can be dereferenced and then implicitly converted to Type1 and Type2 respectively. The type Ret must be such that an object of type FwdIter can be dereferenced and assigned a value of type Ret.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate f is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The transform algorithm returns a hpx::future<ranges::binary_transform_result< hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, FwdIter> > if the execution policy is of type parallel_task_policy and returns ranges::binary_transform_result< hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, FwdIter> otherwise. The transform algorithm returns a tuple holding an iterator referring to the first element after the first input sequence, an iterator referring to the first element after the second input sequence, and the output iterator referring to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename Sent1, typename FwdIter2, typename F, typename Proj = hpx::identity>
ranges::unary_transform_result<FwdIter1, FwdIter2> transform(FwdIter1 first, Sent1 last, FwdIter2 dest, F &&f, Proj &&proj = Proj())#
+

Applies the given function f to the given range rng and stores the result in another range, beginning at dest.

+
+

Note

+

Complexity: Exactly size(rng) applications of f

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of a sentinel for FwdIter1.

  • +
  • FwdIter2 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to the end of the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type Ret must be such that an object of type FwdIter2 can be dereferenced and assigned a value of type Ret.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The transform algorithm returns ranges::unary_transform_result<FwdIter1, FwdIter2>. The transform algorithm returns a tuple holding an iterator referring to the first element after the input sequence and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename FwdIter, typename F, typename Proj = hpx::identity>
ranges::unary_transform_result<hpx::traits::range_iterator_t<Rng>, FwdIter> transform(Rng &&rng, FwdIter dest, F &&f, Proj &&proj = Proj())#
+

Applies the given function f to the given range rng and stores the result in another range, beginning at dest.

+
+

Note

+

Complexity: Exactly size(rng) applications of f

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is an unary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type &a);
    +
    +
    + + The signature does not need to have const&. The type Type must be such that an object of type range_iterator<Rng>::type can be dereferenced and then implicitly converted to Type. The type Ret must be such that an object of type OutIter can be dereferenced and assigned a value of type Ret.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The transform algorithm returns ranges::unary_transform_result<range_iterator<Rng>::type, FwdIter>. The transform algorithm returns a tuple holding an iterator referring to the first element after the input sequence and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename FwdIter1, typename Sent1, typename FwdIter2, typename Sent2, typename FwdIter3, typename F, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
ranges::binary_transform_result<FwdIter1, FwdIter2, FwdIter3> transform(FwdIter1 first1, Sent1 last1, FwdIter2 first2, Sent2 last2, FwdIter3 dest, F &&f, Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Applies the given function f to pairs of elements from two ranges: one defined by rng and the other beginning at first2, and stores the result in another range, beginning at dest.

+
+

Note

+

Complexity: Exactly size(rng) applications of f

+
+
+
Template Parameters
+
    +
  • FwdIter1 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent1 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of a sentinel for FwdIter1.

  • +
  • FwdIter2 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the end source iterators used (deduced). This iterator type must meet the requirements of a sentinel for FwdIter2.

  • +
  • FwdIter3 – The type of the source iterators for the first range used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
  • Proj1 – The type of an optional projection function to be used for elements of the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function to be used for elements of the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the first sequence of elements the algorithm will be applied to.

  • +
  • last1 – Refers to the end of the first sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the algorithm will be applied to.

  • +
  • last2 – Refers to the end of the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 and Type2 must be such that objects of types FwdIter1 and FwdIter2 can be dereferenced and then implicitly converted to Type1 and Type2 respectively. The type Ret must be such that an object of type FwdIter3 can be dereferenced and assigned a value of type Ret.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate f is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The transform algorithm returns ranges::binary_transform_result<FwdIter1, FwdIter2, FwdIter3>. The transform algorithm returns a tuple holding an iterator referring to the first element after the first input sequence, an iterator referring to the first element after the second input sequence, and the output iterator referring to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2, typename FwdIter, typename F, typename Proj1 = hpx::identity, typename Proj2 = hpx::identity>
ranges::binary_transform_result<hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, FwdIter> transform(Rng1 &&rng1, Rng2 &&rng2, FwdIter dest, F &&f, Proj1 &&proj1 = Proj1(), Proj2 &&proj2 = Proj2())#
+

Applies the given function f to pairs of elements from two ranges: one defined by [first1, last1) and the other beginning at first2, and stores the result in another range, beginning at dest.

+
+

Note

+

Complexity: Exactly min(last2-first2, last1-first1) applications of f

+
+
+

Note

+

The algorithm will invoke the binary predicate until it reaches the end of the shorter of the two given input sequences

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the first source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the second source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • F – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of transform requires F to meet the requirements of CopyConstructible.

  • +
  • Proj1 – The type of an optional projection function to be used for elements of the first sequence. This defaults to hpx::identity

  • +
  • Proj2 – The type of an optional projection function to be used for elements of the second sequence. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the first sequence of elements the algorithm will be applied to.

  • +
  • rng2 – Refers to the second sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • f – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last).This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&. The types Type1 and Type2 must be such that objects of types range_iterator<Rng1>::type and range_iterator<Rng2>::type can be dereferenced and then implicitly converted to Type1 and Type2 respectively. The type Ret must be such that an object of type FwdIter can be dereferenced and assigned a value of type Ret.

  • +
  • proj1 – Specifies the function (or function object) which will be invoked for each of the elements of the first sequence as a projection operation before the actual predicate f is invoked.

  • +
  • proj2 – Specifies the function (or function object) which will be invoked for each of the elements of the second sequence as a projection operation before the actual predicate f is invoked.

  • +
+
+
Returns
+

The transform algorithm returns ranges::binary_transform_result< hpx::traits::range_iterator_t<Rng1>, hpx::traits::range_iterator_t<Rng2>, FwdIter>. The transform algorithm returns a tuple holding an iterator referring to the first element after the first input sequence, an iterator referring to the first element after the second input sequence, and the output iterator referring to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::transform_exclusive_scan#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename InIter, typename Sent, typename OutIter, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<InIter>::value_type>
transform_exclusive_scan_result<InIter, OutIter> transform_exclusive_scan(InIter first, Sent last, OutIter dest, T init, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, conv(*first), …, conv(*(first + (i - result) - 1))).

+

+The reduce operations in the parallel transform_exclusive_scan algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_exclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_exclusive_scan algorithm returns transform_exclusive_scan_result<InIter, OutIter>. The transform_exclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<FwdIter1>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, transform_exclusive_result<FwdIter1, FwdIter2>>::type transform_exclusive_scan(ExPolicy &&policy, FwdIter1 first, Sent last, FwdIter2 dest, T init, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, conv(*first), …, conv(*(first + (i - result) - 1))).

+

+The reduce operations in the parallel transform_exclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_exclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_exclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_exclusive_scan algorithm returns a hpx::future<transform_exclusive_result<FwdIter1, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns transform_exclusive_result<FwdIter1, FwdIter2> otherwise. The transform_exclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename O, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
transform_exclusive_scan_result<hpx::traits::range_iterator_t<Rng>, O> transform_exclusive_scan(Rng &&rng, O dest, T init, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, conv(*first), …, conv(*(first + (i - result) - 1))).

+

+The reduce operations in the parallel transform_exclusive_scan algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_exclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced).

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_exclusive_scan algorithm returns a returns transform_exclusive_scan_result< traits::range_iterator_t<Rng>, O>. The transform_exclusive_scan algorithm returns an input iterator to one past the end of the range and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename O, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, transform_exclusive_scan_result<hpx::traits::range_iterator_t<Rng>, O>>::type transform_exclusive_scan(ExPolicy &&policy, Rng &&rng, O dest, T init, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, conv(*first), …, conv(*(first + (i - result) - 1))).

+

+The reduce operations in the parallel transform_exclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_exclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_exclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator. This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • init – The initial value for the generalized sum.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_exclusive_scan algorithm returns a hpx::future<transform_exclusive_scan_result< traits::range_iterator_t<Rng>, O>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns transform_exclusive_scan_result< traits::range_iterator_t<Rng>, O> otherwise. The transform_exclusive_scan algorithm returns an input iterator to one past the end of the range and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::transform_inclusive_scan#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename InIter, typename Sent, typename OutIter, typename BinOp, typename UnOp>
transform_inclusive_scan_result<InIter, OutIter> transform_inclusive_scan(InIter first, Sent last, OutIter dest, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, conv(*first), …, conv(*(first + (i - result)))).

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_inclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns transform_inclusive_scan_result<InIter, OutIter>. The transform_inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2, typename BinOp, typename UnOp>
parallel::util::detail::algorithm_result<ExPolicy, transform_inclusive_result<FwdIter1, FwdIter2>>::type transform_inclusive_scan(ExPolicy &&policy, FwdIter1 first, Sent last, FwdIter2 dest, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, conv(*first), …, conv(*(first + (i - result)))).

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_inclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns a hpx::future<transform_inclusive_result<FwdIter1, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns transform_inclusive_result<FwdIter1, FwdIter2> otherwise. The transform_inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename O, typename BinOp, typename UnOp>
transform_inclusive_scan_result<hpx::traits::range_iterator_t<Rng>, O> transform_inclusive_scan(Rng &&rng, O dest, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, conv(*first), …, conv(*(first + (i - result)))).

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_inclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced).

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns a returns transform_inclusive_scan_result< traits::range_iterator_t<Rng>, O>. The transform_inclusive_scan algorithm returns an input iterator to one past the end of the range and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename O, typename BinOp, typename UnOp>
parallel::util::detail::algorithm_result<ExPolicy, transform_inclusive_scan_result<hpx::traits::range_iterator_t<Rng>, O>>::type transform_inclusive_scan(ExPolicy &&policy, Rng &&rng, O dest, BinOp &&binary_op, UnOp &&unary_op)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(op, conv(*first), …, conv(*(first + (i - result)))).

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_inclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator. This iterator type must meet the requirements of an forward iterator.

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns a hpx::future<transform_inclusive_scan_result< traits::range_iterator_t<Rng>, O>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns transform_inclusive_scan_result< traits::range_iterator_t<Rng>, O> otherwise. The transform_inclusive_scan algorithm returns an input iterator to one past the end of the range and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename InIter, typename Sent, typename OutIter, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<InIter>::value_type>
transform_inclusive_scan_result<InIter, OutIter> transform_inclusive_scan(InIter first, Sent last, OutIter dest, BinOp &&binary_op, UnOp &&unary_op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, conv(*first), …, conv(*(first + (i - result)))).

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_inclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • OutIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an output iterator.

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns transform_inclusive_scan_result<InIter, OutIter>. The transform_inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent, typename FwdIter2, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<FwdIter1>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, transform_inclusive_result<FwdIter1, FwdIter2>>::type transform_inclusive_scan(ExPolicy &&policy, FwdIter1 first, Sent last, FwdIter2 dest, BinOp &&binary_op, UnOp &&unary_op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, conv(*first), …, conv(*(first + (i - result)))).

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_inclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns a hpx::future<transform_inclusive_result<FwdIter1, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns transform_inclusive_result<FwdIter1, FwdIter2> otherwise. The transform_inclusive_scan algorithm returns an input iterator to the point denoted by the sentinel and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename O, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
transform_inclusive_scan_result<hpx::traits::range_iterator_t<Rng>, O> transform_inclusive_scan(Rng &&rng, O dest, BinOp &&binary_op, UnOp &&unary_op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, conv(*first), …, conv(*(first + (i - result)))).

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_inclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced).

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns a returns transform_inclusive_scan_result< traits::range_iterator_t<Rng>, O>. The transform_inclusive_scan algorithm returns an input iterator to one past the end of the range and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename O, typename BinOp, typename UnOp, typename T = typename std::iterator_traits<hpx::traits::range_iterator_t<Rng>>::value_type>
parallel::util::detail::algorithm_result<ExPolicy, transform_inclusive_scan_result<hpx::traits::range_iterator_t<Rng>, O>>::type transform_inclusive_scan(ExPolicy &&policy, Rng &&rng, O dest, BinOp &&binary_op, UnOp &&unary_op, T init)#
+

Assigns through each iterator i in [result, result + (last - first)) the value of GENERALIZED_NONCOMMUTATIVE_SUM(binary_op, init, conv(*first), …, conv(*(first + (i - result)))).

+

+The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_inclusive_scan algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+Neither conv nor op shall invalidate iterators or sub-ranges, or modify elements in the ranges [first,last) or [result,result + (last - first)).

+

The behavior of transform_inclusive_scan may be non-deterministic for a non-associative predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates op and conv.

+
+
+

Note

+

GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aN) is defined as:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_NONCOMMUTATIVE_SUM(op, a1, …, aK), GENERALIZED_NONCOMMUTATIVE_SUM(op, aM, …, aN) where 1 < K+1 = M <= N.

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of an forward iterator. This iterator type must meet the requirements of an forward iterator.

  • +
  • BinOp – The type of the binary function object used for the reduction operation.

  • +
  • UnOp – The type of the unary function object used for the conversion operation.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • binary_op – Specifies the function (or function object) which will be invoked for each of the values of the input sequence. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Ret must be such that an object of a type as given by the input sequence can be implicitly converted to any of those types.

  • +
  • unary_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The transform_inclusive_scan algorithm returns a hpx::future<transform_inclusive_scan_result< traits::range_iterator_t<Rng>, O>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns transform_inclusive_scan_result< traits::range_iterator_t<Rng>, O> otherwise. The transform_inclusive_scan algorithm returns an input iterator to one past the end of the range and an output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::transform_reduce#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ExPolicy, typename Iter, typename Sent, typename T, typename Reduce, typename Convert>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> transform_reduce(ExPolicy &&policy, Iter first, Sent last, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns GENERALIZED_SUM(red_op, init, conv_op(*first), …, conv_op(*(first + (last - first) - 1))).

+

+The reduce operations in the parallel transform_reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_reduce algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between transform_reduce and accumulate is that the behavior of transform_reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates red_op and conv_op.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the reduction operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the first sorted range the algorithm will be applied to.

  • +
  • last – Refers to the end of the second sorted range the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for each of the values returned from the invocation of conv_op. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1, Type2, and Ret must be such that an object of a type as returned from conv_op can be implicitly converted to any of those types.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type Iter can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a hpx::future<T> if the execution policy is of type parallel_task_policy and returns T otherwise. The transform_reduce algorithm returns the result of the generalized sum over the values returned from conv_op when applied to the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename T, typename Reduce, typename Convert>
T transform_reduce(Iter first, Sent last, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns GENERALIZED_SUM(red_op, init, conv_op(*first), …, conv_op(*(first + (last - first) - 1))).

+

+The difference between transform_reduce and accumulate is that the behavior of transform_reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates red_op and conv_op.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the reduction operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the first sorted range the algorithm will be applied to.

  • +
  • last – Refers to the end of the second sorted range the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for each of the values returned from the invocation of conv_op. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1, Type2, and Ret must be such that an object of a type as returned from conv_op can be implicitly converted to any of those types.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type Iter can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_reduce algorithm returns T. The transform_reduce algorithm returns the result of the generalized sum over the values returned from conv_op when applied to the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Iter2, typename T>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> transform_reduce(ExPolicy &&policy, Iter first, Sent last, Iter2 first2, T init)#
+

Returns GENERALIZED_SUM(red_op, init, conv_op(*first), …, conv_op(*(first + (last - first) - 1))).

+

+The reduce operations in the parallel transform_reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_reduce algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between transform_reduce and accumulate is that the behavior of transform_reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates red_op and conv_op.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an random access iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the first sorted range the algorithm will be applied to.

  • +
  • last – Refers to the end of the second sorted range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a hpx::future<T> if the execution policy is of type parallel_task_policy and returns T otherwise. The transform_reduce algorithm returns the result of the generalized sum over the values returned from conv_op when applied to the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Iter2, typename T>
T transform_reduce(Iter first, Sent last, Iter2 first2, T init)#
+

Returns GENERALIZED_SUM(red_op, init, conv_op(*first), …, conv_op(*(first + (last - first) - 1))).

+

+The difference between transform_reduce and accumulate is that the behavior of transform_reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates red_op and conv_op.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an random access iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the first sorted range the algorithm will be applied to.

  • +
  • last – Refers to the end of the second sorted range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
+
+
Returns
+

The transform_reduce algorithm returns T. The transform_reduce algorithm returns the result of the generalized sum over the values returned from conv_op when applied to the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename Iter, typename Sent, typename Iter2, typename T, typename Reduce, typename Convert>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> transform_reduce(ExPolicy &&policy, Iter first, Sent last, Iter2 first2, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns GENERALIZED_SUM(red_op, init, conv_op(*first), …, conv_op(*(first + (last - first) - 1))).

+

+The reduce operations in the parallel transform_reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_reduce algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between transform_reduce and accumulate is that the behavior of transform_reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates red_op and conv_op.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an random access iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the reduction operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the first sorted range the algorithm will be applied to.

  • +
  • last – Refers to the end of the second sorted range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for each of the values returned from the invocation of conv_op. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1, Type2, and Ret must be such that an object of a type as returned from conv_op can be implicitly converted to any of those types.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type Iter can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a hpx::future<T> if the execution policy is of type parallel_task_policy and returns T otherwise. The transform_reduce algorithm returns the result of the generalized sum over the values returned from conv_op when applied to the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename Iter, typename Sent, typename Iter2, typename T, typename Reduce, typename Convert>
T transform_reduce(Iter first, Sent last, Iter2 first2, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns GENERALIZED_SUM(red_op, init, conv_op(*first), …, conv_op(*(first + (last - first) - 1))).

+

+The difference between transform_reduce and accumulate is that the behavior of transform_reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates red_op and conv_op.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • Iter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an random access iterator.

  • +
  • Sent – The type of the end source iterators used (deduced). This iterator type must meet the requirements of an sentinel for Iter.

  • +
  • Iter2 – The type of the source iterators used (deduced) representing the second sequence. This iterator type must meet the requirements of an random access iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the reduction operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the first sorted range the algorithm will be applied to.

  • +
  • last – Refers to the end of the second sorted range the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the sequence of elements of the second range the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for each of the values returned from the invocation of conv_op. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1, Type2, and Ret must be such that an object of a type as returned from conv_op can be implicitly converted to any of those types.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type Iter can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_reduce algorithm returns T. The transform_reduce algorithm returns the result of the generalized sum over the values returned from conv_op when applied to the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename T, typename Reduce, typename Convert>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> transform_reduce(ExPolicy &&policy, Rng &&rng, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns GENERALIZED_SUM(red_op, init, conv_op(*first), …, conv_op(*(first + (last - first) - 1))).

+

+The reduce operations in the parallel transform_reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The reduce operations in the parallel transform_reduce algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+

+The difference between transform_reduce and accumulate is that the behavior of transform_reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates red_op and conv_op.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the reduction operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for each of the values returned from the invocation of conv_op. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1, Type2, and Ret must be such that an object of a type as returned from conv_op can be implicitly converted to any of those types.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type Iter can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a hpx::future<T> if the execution policy is of type parallel_task_policy and returns T otherwise. The transform_reduce algorithm returns the result of the generalized sum over the values returned from conv_op when applied to the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename Rng, typename T, typename Reduce, typename Convert>
T transform_reduce(Rng &&rng, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns GENERALIZED_SUM(red_op, init, conv_op(*first), …, conv_op(*(first + (last - first) - 1))).

+

+The difference between transform_reduce and accumulate is that the behavior of transform_reduce may be non-deterministic for non-associative or non-commutative binary predicate.

+
+

Note

+

Complexity: O(last - first) applications of the predicates red_op and conv_op.

+
+
+

Note

+

GENERALIZED_SUM(op, a1, …, aN) is defined as follows:

    +
  • a1 when N is 1

  • +
  • op(GENERALIZED_SUM(op, b1, …, bK), GENERALIZED_SUM(op, bM, …, bN)), where:

      +
    • b1, …, bN may be any permutation of a1, …, aN and

    • +
    • 1 < K+1 = M <= N.

    • +
    +

  • +
+

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be used as initial (and intermediate) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the reduction operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • init – The initial value for the generalized sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for each of the values returned from the invocation of conv_op. This is a binary predicate. The signature of this predicate should be equivalent to:

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1, Type2, and Ret must be such that an object of a type as returned from conv_op can be implicitly converted to any of those types.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is a unary predicate. The signature of this predicate should be equivalent to:

    R fun(const Type &a);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type Iter can be dereferenced and then implicitly converted to Type. The type R must be such that an object of this type can be implicitly converted to T.

  • +
+
+
Returns
+

The transform_reduce algorithm returns T. The transform_reduce algorithm returns the result of the generalized sum over the values returned from conv_op when applied to the elements given by the input range [first, last).

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Iter2, typename T>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> transform_reduce(ExPolicy &&policy, Rng &&rng, Iter2 first2, T init)#
+

Returns the result of accumulating init with the inner products of the pairs formed by the elements of two ranges starting at first1 and first2.

+

+The operations in the parallel transform_reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The operations in the parallel transform_reduce algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op2.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter2 – The type of the second source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as return) values (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the result will be calculated with.

  • +
  • init – The initial value for the sum.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise.

+
+
+
+ +
+
+template<typename Rng, typename Iter2, typename T>
T transform_reduce(Rng &&rng, Iter2 first2, T init)#
+

Returns the result of accumulating init with the inner products of the pairs formed by the elements of two ranges starting at first1 and first2.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op2.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter2 – The type of the second source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as return) values (deduced).

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the result will be calculated with.

  • +
  • init – The initial value for the sum.

  • +
+
+
Returns
+

The transform_reduce algorithm returns T.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Iter2, typename T, typename Reduce, typename Convert>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, T> transform_reduce(ExPolicy &&policy, Rng &&rng, Iter2 first2, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns the result of accumulating init with the inner products of the pairs formed by the elements of two ranges starting at first1 and first2.

+

+The operations in the parallel transform_reduce algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The operations in the parallel transform_reduce algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op2.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter2 – The type of the second source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as return) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the multiplication operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the result will be calculated with.

  • +
  • init – The initial value for the sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for the initial value and each of the return values of op2. This is a binary predicate. The signature of this predicate should be equivalent to should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Ret must be such that it can be implicitly converted to a type of T.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the input values of the sequence. This is a binary predicate. The signature of this predicate should be equivalent to

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Ret must be such that it can be implicitly converted to an object for the second argument type of op1.

  • +
+
+
Returns
+

The transform_reduce algorithm returns a hpx::future<T> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns T otherwise.

+
+
+
+ +
+
+template<typename Rng, typename Iter2, typename T, typename Reduce, typename Convert>
T transform_reduce(Rng &&rng, Iter2 first2, T init, Reduce &&red_op, Convert &&conv_op)#
+

Returns the result of accumulating init with the inner products of the pairs formed by the elements of two ranges starting at first1 and first2.

+
+

Note

+

Complexity: O(last - first) applications of the predicate op2.

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Iter2 – The type of the second source iterators used (deduced). This iterator type must meet the requirements of an forward iterator.

  • +
  • T – The type of the value to be used as return) values (deduced).

  • +
  • Reduce – The type of the binary function object used for the multiplication operation.

  • +
  • Convert – The type of the unary function object used to transform the elements of the input sequence before invoking the reduce function.

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the second sequence of elements the result will be calculated with.

  • +
  • init – The initial value for the sum.

  • +
  • red_op – Specifies the function (or function object) which will be invoked for the initial value and each of the return values of op2. This is a binary predicate. The signature of this predicate should be equivalent to should be equivalent to:

    Ret fun(const Type1 &a, const Type1 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Ret must be such that it can be implicitly converted to a type of T.

  • +
  • conv_op – Specifies the function (or function object) which will be invoked for each of the input values of the sequence. This is a binary predicate. The signature of this predicate should be equivalent to

    Ret fun(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Ret must be such that it can be implicitly converted to an object for the second argument type of op1.

  • +
+
+
Returns
+

The transform_reduce algorithm returns T.

+
+
+
+ +
+
+ +
+
+
hpx::ranges::uninitialized_copy, hpx::ranges::uninitialized_copy_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename InIter, typename Sent1, typename FwdIter, typename Sent2>
hpx::parallel::util::in_out_result<InIter, FwdIter> uninitialized_copy(InIter first1, Sent1 last1, FwdIter first2, Sent2 last2)#
+

Copies the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the copy operation, the function has no effects.

+

+The assignments in the parallel uninitialized_copy algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent1 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter2.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements that will be copied from

  • +
  • last1 – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Refers to sentinel value denoting the end of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_copy algorithm returns an in_out_result<InIter, FwdIter>. The uninitialized_copy algorithm returns an input iterator to one past the last element copied from and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent1, typename FwdIter2, typename Sent2>
parallel::util::detail::algorithm_result<ExPolicy, parallel::util::in_out_result<FwdIter1, FwdIter2>>::type uninitialized_copy(ExPolicy &&policy, FwdIter1 first1, Sent1 last1, FwdIter2 first2, Sent2 last2)#
+

Copies the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the copy operation, the function has no effects.

+

+The assignments in the parallel uninitialized_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent1 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements that will be copied from

  • +
  • last1 – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Refers to sentinel value denoting the end of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_copy algorithm returns a hpx::future<in_out_result<InIter, FwdIter>>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns in_out_result<InIter, FwdIter> otherwise. The uninitialized_copy algorithm returns an input iterator to one past the last element copied from and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2>
hpx::parallel::util::in_out_result<typename hpx::traits::range_traits<Rng1>::iterator_type, typename hpx::traits::range_traits<Rng2>::iterator_type> uninitialized_copy(Rng1 &&rng1, Rng2 &&rng2)#
+

Copies the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the copy operation, the function has no effects.

+

+The assignments in the parallel uninitialized_copy algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the range from which the elements will be copied from

  • +
  • rng2 – Refers to the range to which the elements will be copied to

  • +
+
+
Returns
+

The uninitialized_copy algorithm returns an in_out_result<typename hpx::traits::range_traits<Rng1>::iterator_type, typename hpx::traits::range_traits<Rng2>::iterator_type>. The uninitialized_copy algorithm returns an input iterator to one past the last element copied from and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2>
parallel::util::detail::algorithm_result<ExPolicy, hpx::parallel::util::in_out_result<typename hpx::traits::range_traits<Rng1>::iterator_type, typename hpx::traits::range_traits<Rng2>::iterator_type>>::type uninitialized_copy(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2)#
+

Copies the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the copy operation, the function has no effects.

+

+The assignments in the parallel uninitialized_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the range from which the elements will be copied from

  • +
  • rng2 – Refers to the range to which the elements will be copied to

  • +
+
+
Returns
+

The uninitialized_copy algorithm returns a hpx::future<in_out_result<InIter, FwdIter>>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns in_out_result< typename hpx::traits::range_traits<Rng1>::iterator_type , typename hpx::traits::range_traits<Rng2>::iterator_type> otherwise. The uninitialized_copy algorithm returns the input iterator to one past the last element copied from and the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename InIter, typename Size, typename FwdIter, typename Sent2>
hpx::parallel::util::in_out_result<InIter, FwdIter> uninitialized_copy_n(InIter first1, Size count, FwdIter first2, Sent2 last2)#
+

Copies the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest. If an exception is thrown during the copy operation, the function has no effects.

+

+The assignments in the parallel uninitialized_copy_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements that will be copied from

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Refers to sentinel value denoting the end of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_copy_n algorithm returns in_out_result<InIter, FwdIter>. The uninitialized_copy_n algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Size, typename FwdIter2, typename Sent2>
parallel::util::detail::algorithm_result<ExPolicy, parallel::util::in_out_result<FwdIter1, FwdIter2>>::type uninitialized_copy_n(ExPolicy &&policy, FwdIter1 first1, Size count, FwdIter2 first2, Sent2 last2)#
+

Copies the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest. If an exception is thrown during the copy operation, the function has no effects.

+

+The assignments in the parallel uninitialized_copy_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_copy_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements that will be copied from

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Refers to sentinel value denoting the end of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_copy_n algorithm returns a hpx::future<in_out_result<FwdIter1, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The uninitialized_copy_n algorithm returns the output iterator to the element in the destination range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::uninitialized_default_construct, hpx::ranges::uninitialized_default_construct_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent>
FwdIter uninitialized_default_construct(FwdIter first, Sent last)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range by default-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_default_construct algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
+
+
Returns
+

The uninitialized_default_construct algorithm returns a returns FwdIter. The uninitialized_default_construct algorithm returns the output iterator to the element in the range, one past the last element constructed.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> uninitialized_default_construct(ExPolicy &&policy, FwdIter first, Sent last)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range by default-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_default_construct algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_default_construct algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
+
+
Returns
+

The uninitialized_default_construct algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The uninitialized_default_construct algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+template<typename Rng>
hpx::traits::range_traits<Rng>::iterator_type uninitialized_default_construct(Rng &&rng)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range by default-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_default_construct algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+

Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

+
+
Parameters
+

rng – Refers to the range to which will be default constructed.

+
+
Returns
+

The uninitialized_default_construct algorithm returns a returns hpx::traits::range_traits<Rng>::iterator_type. The uninitialized_default_construct algorithm returns the output iterator to the element in the range, one past the last element constructed.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng>
parallel::util::detail::algorithm_result<ExPolicy, typename hpx::traits::range_traits<Rng>::iterator_type>::type uninitialized_default_construct(ExPolicy &&policy, Rng &&rng)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range by default-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_default_construct algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_default_construct algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the range to which the value will be default constructed

  • +
+
+
Returns
+

The uninitialized_default_construct algorithm returns a hpx::future<typename hpx::traits::range_traits<Rng>::iterator_type>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns typename hpx::traits::range_traits<Rng>::iterator_type otherwise. The uninitialized_default_construct algorithm returns the output iterator to the element in the range, one past the last element constructed.

+
+
+
+ +
+
+template<typename FwdIter, typename Size>
FwdIter uninitialized_default_construct_n(FwdIter first, Size count)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range [first, first + count) by default-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_default_construct_n algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_default_construct_n algorithm returns a returns FwdIter. The uninitialized_default_construct_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter>::type uninitialized_default_construct_n(ExPolicy &&policy, FwdIter first, Size count)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range [first, first + count) by default-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_default_construct_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_default_construct_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_default_construct_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The uninitialized_default_construct_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::uninitialized_fill, hpx::ranges::uninitialized_fill_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent, typename T>
FwdIter uninitialized_fill(FwdIter first, Sent last, T const &value)#
+

Copies the given value to an uninitialized memory area, defined by the range [first, last). If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the ranges uninitialized_fill algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first and last

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The uninitialized_fill algorithm returns a returns FwdIter. The uninitialized_fill algorithm returns the output iterator to the element in the range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename T>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> uninitialized_fill(ExPolicy &&policy, FwdIter first, Sent last, T const &value)#
+

Copies the given value to an uninitialized memory area, defined by the range [first, last). If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_fill algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_fill algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The uninitialized_fill algorithm returns a returns FwdIter. The uninitialized_fill algorithm returns the output iterator to the element in the range, one past the last element copied.

+
+
+
+ +
+
+template<typename Rng, typename T>
hpx::traits::range_traits<Rng>::iterator_type uninitialized_fill(Rng &&rng, T const &value)#
+

Copies the given value to an uninitialized memory area, defined by the range [first, last). If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_fill algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Linear in the distance between first and last

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • rng – Refers to the range to which the value will be filled

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The uninitialized_fill algorithm returns a returns hpx::traits::range_traits<Rng>::iterator_type. The uninitialized_fill algorithm returns the output iterator to the element in the range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename T>
parallel::util::detail::algorithm_result<ExPolicy, typename hpx::traits::range_traits<Rng1>::iterator_type>::type uninitialized_fill(ExPolicy &&policy, Rng &&rng, T const &value)#
+

Copies the given value to an uninitialized memory area, defined by the range [first, last). If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_fill algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_fill algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Linear in the distance between first and last

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the range to which the value will be filled

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The uninitialized_fill algorithm returns a hpx::future<typename hpx::traits::range_traits<Rng>::iterator_type>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns typename hpx::traits::range_traits<Rng>::iterator_type otherwise. The uninitialized_fill algorithm returns the iterator to one past the last element filled in the range.

+
+
+
+ +
+
+template<typename FwdIter, typename Size, typename T>
FwdIter uninitialized_fill_n(FwdIter first, Size count, T const &value)#
+

Copies the given value value to the first count elements in an uninitialized memory area beginning at first. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_fill_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The uninitialized_fill_n algorithm returns a returns FwdIter. The uninitialized_fill_n algorithm returns the output iterator to the element in the range, one past the last element copied.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size, typename T>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> uninitialized_fill_n(ExPolicy &&policy, FwdIter first, Size count, T const &value)#
+

Copies the given value value to the first count elements in an uninitialized memory area beginning at first. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_fill_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_fill_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • T – The type of the value to be assigned (deduced).

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • value – The value to be assigned.

  • +
+
+
Returns
+

The uninitialized_fill_n algorithm returns a hpx::future<FwdIter>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The uninitialized_fill_n algorithm returns the output iterator to the element in the range, one past the last element copied.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::uninitialized_move, hpx::ranges::uninitialized_move_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename InIter, typename Sent1, typename FwdIter, typename Sent2>
hpx::parallel::util::in_out_result<InIter, FwdIter> uninitialized_move(InIter first1, Sent1 last1, FwdIter first2, Sent2 last2)#
+

Moves the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the initialization, some objects in [first, last) are left in a valid but unspecified state.

+

+The assignments in the parallel uninitialized_move algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent1 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter2.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements that will be moved from

  • +
  • last1 – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Refers to sentinel value denoting the end of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_move algorithm returns an in_out_result<InIter, FwdIter>. The uninitialized_move algorithm returns an input iterator to one past the last element moved from and the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Sent1, typename FwdIter2, typename Sent2>
parallel::util::detail::algorithm_result<ExPolicy, parallel::util::in_out_result<FwdIter1, FwdIter2>>::type uninitialized_move(ExPolicy &&policy, FwdIter1 first1, Sent1 last1, FwdIter2 first2, Sent2 last2)#
+

Moves the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the initialization, some objects in [first, last) are left in a valid but unspecified state.

+

+The assignments in the parallel uninitialized_move algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_move algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent1 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements that will be moved from

  • +
  • last1 – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Refers to sentinel value denoting the end of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_move algorithm returns a hpx::future<in_out_result<InIter, FwdIter>>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns in_out_result<InIter, FwdIter> otherwise. The uninitialized_move algorithm returns an input iterator to one past the last element moved from and the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename Rng1, typename Rng2>
hpx::parallel::util::in_out_result<typename hpx::traits::range_traits<Rng1>::iterator_type, typename hpx::traits::range_traits<Rng2>::iterator_type> uninitialized_move(Rng1 &&rng1, Rng2 &&rng2)#
+

Moves the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the initialization, some objects in [first, last) are left in a valid but unspecified state.

+

+The assignments in the parallel uninitialized_move algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • rng1 – Refers to the range from which the elements will be moved from

  • +
  • rng2 – Refers to the range to which the elements will be moved to

  • +
+
+
Returns
+

The uninitialized_move algorithm returns an in_out_result<typename hpx::traits::range_traits<Rng1>::iterator_type, typename hpx::traits::range_traits<Rng2>::iterator_type>. The uninitialized_move algorithm returns an input iterator to one past the last element moved from and the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng1, typename Rng2>
parallel::util::detail::algorithm_result<ExPolicy, hpx::parallel::util::in_out_result<typename hpx::traits::range_traits<Rng1>::iterator_type, typename hpx::traits::range_traits<Rng2>::iterator_type>>::type uninitialized_move(ExPolicy &&policy, Rng1 &&rng1, Rng2 &&rng2)#
+

Moves the elements in the range, defined by [first, last), to an uninitialized memory area beginning at dest. If an exception is thrown during the initialization, some objects in [first, last) are left in a valid but unspecified state.

+

+The assignments in the parallel uninitialized_move algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_move algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng1 – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
  • Rng2 – The type of the destination range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng1 – Refers to the range from which the elements will be moved from

  • +
  • rng2 – Refers to the range to which the elements will be moved to

  • +
+
+
Returns
+

The uninitialized_move algorithm returns a hpx::future<in_out_result<InIter, FwdIter>>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns in_out_result< typename hpx::traits::range_traits<Rng1>::iterator_type , typename hpx::traits::range_traits<Rng2>::iterator_type> otherwise. The uninitialized_move algorithm returns the input iterator to one past the last element moved from and the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename InIter, typename Size, typename FwdIter, typename Sent2>
hpx::parallel::util::in_out_result<InIter, FwdIter> uninitialized_move_n(InIter first1, Size count, FwdIter first2, Sent2 last2)#
+

Moves the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest. If an exception is thrown during the initialization, some objects in [first, first + count) are left in a valid but unspecified state.

+

+The assignments in the parallel uninitialized_move_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly count movements, if count > 0, no move operations otherwise.

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
+
+
Parameters
+
    +
  • first1 – Refers to the beginning of the sequence of elements that will be moved from

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Refers to sentinel value denoting the end of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_move_n algorithm returns in_out_result<InIter, FwdIter>. The uninitialized_move_n algorithm returns the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename Size, typename FwdIter2, typename Sent2>
parallel::util::detail::algorithm_result<ExPolicy, parallel::util::in_out_result<FwdIter1, FwdIter2>>::type uninitialized_move_n(ExPolicy &&policy, FwdIter1 first1, Size count, FwdIter2 first2, Sent2 last2)#
+

Moves the elements in the range [first, first + count), starting from first and proceeding to first + count - 1., to another range beginning at dest. If an exception is thrown during the initialization, some objects in [first, first + count) are left in a valid but unspecified state.

+

+The assignments in the parallel uninitialized_move_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_move_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count movements, if count > 0, no move operations otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter1 – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
  • FwdIter2 – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent2 – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter2.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first1 – Refers to the beginning of the sequence of elements that will be moved from

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
  • first2 – Refers to the beginning of the destination range.

  • +
  • last2 – Refers to sentinel value denoting the end of the second range the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_move_n algorithm returns a hpx::future<in_out_result<FwdIter1, FwdIter2>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter2 otherwise. The uninitialized_move_n algorithm returns the output iterator to the element in the destination range, one past the last element moved.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::uninitialized_value_construct, hpx::ranges::uninitialized_value_construct_n#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent>
FwdIter uninitialized_value_construct(FwdIter first, Sent last)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range by value-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_value_construct algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
+
+
Returns
+

The uninitialized_value_construct algorithm returns a returns FwdIter. The uninitialized_value_construct algorithm returns the output iterator to the element in the range, one past the last element constructed.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> uninitialized_value_construct(ExPolicy &&policy, FwdIter first, Sent last)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range by value-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_value_construct algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_value_construct algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
+
+
Returns
+

The uninitialized_value_construct algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The uninitialized_value_construct algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+template<typename Rng>
hpx::traits::range_traits<Rng>::iterator_type uninitialized_value_construct(Rng &&rng)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range by value-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_value_construct algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+

Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

+
+
Parameters
+

rng – Refers to the range to which will be value constructed.

+
+
Returns
+

The uninitialized_value_construct algorithm returns a returns hpx::traits::range_traits<Rng>::iterator_type. The uninitialized_value_construct algorithm returns the output iterator to the element in the range, one past the last element constructed.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng>
parallel::util::detail::algorithm_result<ExPolicy, typename hpx::traits::range_traits<Rng>::iterator_type>::type uninitialized_value_construct(ExPolicy &&policy, Rng &&rng)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range by value-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_value_construct algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_value_construct algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly last - first assignments.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an input iterator.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the range to which the value will be value consutrcted

  • +
+
+
Returns
+

The uninitialized_value_construct algorithm returns a hpx::future<typename hpx::traits::range_traits<Rng>::iterator_type>, if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns typename hpx::traits::range_traits<Rng>::iterator_type otherwise. The uninitialized_value_construct algorithm returns the output iterator to the element in the range, one past the last element constructed.

+
+
+
+ +
+
+template<typename FwdIter, typename Size>
FwdIter uninitialized_value_construct_n(FwdIter first, Size count)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range [first, first + count) by value-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_value_construct_n algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_value_construct_n algorithm returns a returns FwdIter. The uninitialized_value_construct_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Size>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter> uninitialized_value_construct_n(ExPolicy &&policy, FwdIter first, Size count)#
+

Constructs objects of type typename iterator_traits<ForwardIt>::value_type in the uninitialized storage designated by the range [first, first + count) by value-initialization. If an exception is thrown during the initialization, the function has no effects.

+

+The assignments in the parallel uninitialized_value_construct_n algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel uninitialized_value_construct_n algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs exactly count assignments, if count > 0, no assignments otherwise.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Size – The type of the argument specifying the number of elements to apply f to.

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • count – Refers to the number of elements starting at first the algorithm will be applied to.

  • +
+
+
Returns
+

The uninitialized_value_construct_n algorithm returns a hpx::future<FwdIter> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns FwdIter otherwise. The uninitialized_value_construct_n algorithm returns the iterator to the element in the source range, one past the last element constructed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::ranges::unique, hpx::ranges::unique_copy#
+

Defined in header hpx/algorithm.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace ranges
+
+

Functions

+
+
+template<typename FwdIter, typename Sent, typename Pred = ranges::equal_to, typename Proj = hpx::identity>
subrange_t<FwdIter, Sent> unique(FwdIter first, Sent last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Eliminates all but the first element from every consecutive group of equivalent elements from the range [first, last) and returns a past-the-end iterator for the new logical end of the range.

+

+The assignments in the parallel unique algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first - 1 applications of the predicate pred and no more than twice as many applications of the projection proj.

+
+
+
Template Parameters
+
    +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The unique algorithm returns subrange_t<FwdIter, Sent>. The unique algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename Pred = ranges::equal_to, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<FwdIter, Sent>>::type unique(ExPolicy &&policy, FwdIter first, Sent last, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Eliminates all but the first element from every consecutive group of equivalent elements from the range [first, last) and returns a past-the-end iterator for the new logical end of the range.

+

+The assignments in the parallel unique algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel unique algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first - 1 applications of the predicate pred and no more than twice as many applications of the projection proj.

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type1 &a, const Type2 &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The types Type1 and Type2 must be such that objects of types FwdIter can be dereferenced and then implicitly converted to both Type1 and Type2

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The unique algorithm returns subrange_t<FwdIter, Sent>. The unique algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange.

+
+
+
+ +
+
+template<typename Rng, typename Pred = ranges::equal_to, typename Proj = hpx::identity>
subrange_t<hpx::traits::range_iterator_t<Rng>, hpx::traits::range_iterator_t<Rng>> unique(Rng &&rng, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Eliminates all but the first element from every consecutive group of equivalent elements from the range rng and returns a past-the-end iterator for the new logical end of the range.

+

+The assignments in the parallel unique algorithm invoked without an execution policy object execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than N assignments, exactly N - 1 applications of the predicate pred and no more than twice as many applications of the projection proj, where N = std::distance(begin(rng), end(rng)).

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The unique algorithm returns subrange_t<hpx::traits::range_iterator_t<Rng>, hpx::traits::range_iterator_t<Rng>>. The unique algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename Pred = ranges::equal_to, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, subrange_t<hpx::traits::range_iterator_t<Rng>, hpx::traits::range_iterator_t<Rng>>> unique(ExPolicy &&policy, Rng &&rng, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Eliminates all but the first element from every consecutive group of equivalent elements from the range rng and returns a past-the-end iterator for the new logical end of the range.

+

+The assignments in the parallel unique algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel unique algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than N assignments, exactly N - 1 applications of the predicate pred and no more than twice as many applications of the projection proj, where N = std::distance(begin(rng), end(rng)).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The unique algorithm returns a hpx::future <subrange_t<hpx::traits::range_iterator_t<Rng>, hpx::traits::range_iterator_t<Rng>>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns subrange_t<hpx::traits::range_iterator_t<Rng>, hpx::traits::range_iterator_t<Rng>> otherwise. The unique algorithm returns an object {ret, last}, where ret is a past-the-end iterator for a new subrange.

+
+
+
+ +
+
+template<typename InIter, typename Sent, typename O, typename Pred = ranges::equal_to, typename Proj = hpx::identity>
unique_copy_result<InIter, O> unique_copy(InIter first, Sent last, O dest, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Copies the elements from the range [first, last), to another range beginning at dest in such a way that there are no consecutive equal elements. Only the first element of each group of equal elements is copied.

+

+The assignments in the parallel unique_copy algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first - 1 applications of the predicate pred and no more than twice as many applications of the projection proj

+
+
+
Template Parameters
+
    +
  • InIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of an input iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for InIter.

  • +
  • O – The type of the iterator representing the destination range (deduced).

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique_copy requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type InIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The unique_copy algorithm returns a returns unique_copy_result<InIter, O>. The unique_copy algorithm returns an in_out_result with the source iterator to one past the last element and out containing the destination iterator to the end of the dest range.

+
+
+
+ +
+
+template<typename ExPolicy, typename FwdIter, typename Sent, typename O, typename Pred = ranges::equal_to, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, unique_copy_result<FwdIter, O>>::type unique_copy(ExPolicy &&policy, FwdIter first, Sent last, O dest, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Copies the elements from the range [first, last), to another range beginning at dest in such a way that there are no consecutive equal elements. Only the first element of each group of equal elements is copied.

+

+The assignments in the parallel unique_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel unique_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than last - first assignments, exactly last - first - 1 applications of the predicate pred and no more than twice as many applications of the projection proj

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • FwdIter – The type of the source iterators used (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Sent – The type of the source sentinel (deduced). This sentinel type must be a sentinel for FwdIter1.

  • +
  • O – The type of the iterator representing the destination range (deduced).

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique_copy requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • first – Refers to the beginning of the sequence of elements the algorithm will be applied to.

  • +
  • last – Refers to sentinel value denoting the end of the sequence of elements the algorithm will be applied.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by [first, last). This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The unique_copy algorithm returns returns a hpx::future< unique_copy_result<FwdIter, O>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns unique_copy_result<FwdIter, O> otherwise. The unique_copy algorithm returns an in_out_result with the source iterator to one past the last element and out containing the destination iterator to the end of the dest range.

+
+
+
+ +
+
+template<typename Rng, typename O, typename Pred = ranges::equal_to, typename Proj = hpx::identity>
unique_copy_result<hpx::traits::range_iterator_t<Rng>, O> unique_copy(Rng &&rng, O dest, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Copies the elements from the range rng, to another range beginning at dest in such a way that there are no consecutive equal elements. Only the first element of each group of equal elements is copied.

+

+The assignments in the parallel unique_copy algorithm invoked without an execution policy object will execute in sequential order in the calling thread.

+
+

Note

+

Complexity: Performs not more than N assignments, exactly N - 1 applications of the predicate pred, where N = std::distance(begin(rng), end(rng)).

+
+
+
Template Parameters
+
    +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique_copy requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by the range rng. This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The unique_copy algorithm returns unique_copy_result< hpx::traits::range_iterator_t<Rng>, O>. The unique_copy algorithm returns the pair of the source iterator to last, and the destination iterator to the end of the dest range.

+
+
+
+ +
+
+template<typename ExPolicy, typename Rng, typename O, typename Pred = ranges::equal_to, typename Proj = hpx::identity>
parallel::util::detail::algorithm_result<ExPolicy, unique_copy_result<hpx::traits::range_iterator_t<Rng>, O>> unique_copy(ExPolicy &&policy, Rng &&rng, O dest, Pred &&pred = Pred(), Proj &&proj = Proj())#
+

Copies the elements from the range rng, to another range beginning at dest in such a way that there are no consecutive equal elements. Only the first element of each group of equal elements is copied.

+

+The assignments in the parallel unique_copy algorithm invoked with an execution policy object of type sequenced_policy execute in sequential order in the calling thread.

+

The assignments in the parallel unique_copy algorithm invoked with an execution policy object of type parallel_policy or parallel_task_policy are permitted to execute in an unordered fashion in unspecified threads, and indeterminately sequenced within each thread.

+
+

Note

+

Complexity: Performs not more than N assignments, exactly N - 1 applications of the predicate pred, where N = std::distance(begin(rng), end(rng)).

+
+
+
Template Parameters
+
    +
  • ExPolicy – The type of the execution policy to use (deduced). It describes the manner in which the execution of the algorithm may be parallelized and the manner in which it executes the assignments.

  • +
  • Rng – The type of the source range used (deduced). The iterators extracted from this range type must meet the requirements of an forward iterator.

  • +
  • O – The type of the iterator representing the destination range (deduced). This iterator type must meet the requirements of a forward iterator.

  • +
  • Pred – The type of the function/function object to use (deduced). Unlike its sequential form, the parallel overload of unique_copy requires Pred to meet the requirements of CopyConstructible. This defaults to std::equal_to<>

  • +
  • Proj – The type of an optional projection function. This defaults to hpx::identity

  • +
+
+
Parameters
+
    +
  • policy – The execution policy to use for the scheduling of the iterations.

  • +
  • rng – Refers to the sequence of elements the algorithm will be applied to.

  • +
  • dest – Refers to the beginning of the destination range.

  • +
  • pred – Specifies the function (or function object) which will be invoked for each of the elements in the sequence specified by the range rng. This is an binary predicate which returns true for the required elements. The signature of this predicate should be equivalent to:

    bool pred(const Type &a, const Type &b);
    +
    +
    + + The signature does not need to have const&, but the function must not modify the objects passed to it. The type Type must be such that an object of type FwdIter1 can be dereferenced and then implicitly converted to Type.

  • +
  • proj – Specifies the function (or function object) which will be invoked for each of the elements as a projection operation before the actual predicate is invoked.

  • +
+
+
Returns
+

The unique_copy algorithm returns a hpx::future<unique_copy_result< hpx::traits::range_iterator_t<Rng>, O>> if the execution policy is of type sequenced_task_policy or parallel_task_policy and returns unique_copy_result< hpx::traits::range_iterator_t<Rng>, O> otherwise. The unique_copy algorithm returns the pair of the source iterator to last, and the destination iterator to the end of the dest range.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/parallel/util/range.hpp#
+

Defined in header hpx/parallel/util/range.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace util#
+
+

Typedefs

+
+
+template<typename Iterator, typename Sentinel = Iterator>
using range = hpx::util::iterator_range<Iterator, Sentinel>#
+
+ +
+
+

Functions

+
+
+template<typename Iter, typename Sent>
range<Iter, Sent> concat(range<Iter, Sent> const &it1, range<Iter, Sent> const &it2)#
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2>
range<Iter2, Iter2> init_move(range<Iter2, Sent2> const &dest, range<Iter1, Sent1> const &src)#
+

Move objects from the range src to dest.

+
+
Parameters
+
    +
  • dest[in] : range where move the objects

  • +
  • src[in] : range from where move the objects

  • +
+
+
Returns
+

range with the objects moved and the size adjusted

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2>
range<Iter2, Sent2> uninit_move(range<Iter2, Sent2> const &dest, range<Iter1, Sent1> const &src)#
+

Move objects from the range src creating them in dest.

+
+
Parameters
+
    +
  • dest[in] : range where move and create the objects

  • +
  • src[in] : range from where move the objects

  • +
+
+
Returns
+

range with the objects moved and the size adjusted

+
+
+
+ +
+
+template<typename Iter, typename Sent>
void destroy_range(range<Iter, Sent> r)#
+

destroy a range of objects

+
+
Parameters
+

r[in] : range to destroy

+
+
+
+ +
+
+template<typename Iter, typename Sent>
range<Iter, Sent> init(range<Iter, Sent> const &r, typename std::iterator_traits<Iter>::value_type &val)#
+

initialize a range of objects with the object val moving across them

+
+
Parameters
+
    +
  • r[in] : range of elements not initialized

  • +
  • val[in] : object used for the initialization

  • +
+
+
Returns
+

range initialized

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Compare>
bool is_mergeable(range<Iter1, Sent1> const &src1, range<Iter2, Sent2> const &src2, Compare comp)#
+

: indicate if two ranges have a possible merge

+

+

Remark

+

+
+

+
+
Parameters
+
    +
  • src1[in] : first range

  • +
  • src2[in] : second range

  • +
  • comp[in] : object for to compare elements

  • +
+
+
Returns
+

true : they can be merged false : they can’t be merged

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Sent3, typename Compare>
range<Iter3, Sent3> full_merge(range<Iter3, Sent3> const &dest, range<Iter1, Sent1> const &src1, range<Iter2, Sent2> const &src2, Compare comp)#
+

Merge two contiguous ranges src1 and src2 , and put the result in the range dest, returning the range merged.

+
+
Parameters
+
    +
  • dest[in] : range where locate the elements merged. the size of dest must be greater or equal than the sum of the sizes of src1 and src2

  • +
  • src1[in] : first range to merge

  • +
  • src2[in] : second range to merge

  • +
  • comp[in] : comparison object

  • +
+
+
Returns
+

range with the elements merged and the size adjusted

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Value, typename Compare>
range<Value*> uninit_full_merge(range<Value*> const &dest, range<Iter1, Sent1> const &src1, range<Iter2, Sent2> const &src2, Compare comp)#
+

Merge two contiguous ranges src1 and src2 , and create and move the result in the uninitialized range dest, returning the range merged.

+
+
Parameters
+
    +
  • dest[in] : range where locate the elements merged. the size of dest must be greater or equal than the sum of the sizes of src1 and src2. Initially is un-initialize memory

  • +
  • src1[in] : first range to merge

  • +
  • src2[in] : second range to merge

  • +
  • comp[in] : comparison object

  • +
+
+
Returns
+

range with the elements merged and the size adjusted

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Compare>
range<Iter2, Sent2> half_merge(range<Iter2, Sent2> const &dest, range<Iter1, Sent1> const &src1, range<Iter2, Sent2> const &src2, Compare comp)#
+

: Merge two buffers. The first buffer is in a separate memory

+
+
Parameters
+
    +
  • dest[in] : range where finish the two buffers merged

  • +
  • src1[in] : first range to merge in a separate memory

  • +
  • src2[in] : second range to merge, in the final part of the range where deposit the final results

  • +
  • comp[in] : object for compare two elements of the type pointed by the Iter1 and Iter2

  • +
+
+
Returns
+

: range with the two buffers merged

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Iter3, typename Sent3, typename Compare>
bool in_place_merge_uncontiguous(range<Iter1, Sent1> const &src1, range<Iter2, Sent2> const &src2, range<Iter3, Sent3> &aux, Compare comp)#
+

: merge two non contiguous buffers src1 , src2, using the range aux as auxiliary memory

+

+

Remark

+

+
+

+
+
Parameters
+
    +
  • src1[in] : first range to merge

  • +
  • src2[in] : second range to merge

  • +
  • aux[in] : auxiliary range used in the merge

  • +
  • comp[in] : object for to compare elements

  • +
+
+
Returns
+

true : not changes done false : changes in the buffers

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Compare>
range<Iter1, Sent1> in_place_merge(range<Iter1, Sent1> const &src1, range<Iter1, Sent1> const &src2, range<Iter2, Sent2> &buf, Compare comp)#
+

: merge two contiguous buffers ( src1, src2) using buf as auxiliary memory

+

+

Remark

+

+
+

+
+
Parameters
+
    +
  • src1[in] : first range to merge

  • +
  • src2[in] : second range to merge

  • +
  • buf[in] : auxiliary memory used in the merge

  • +
  • comp[in] : object for to compare elements

  • +
+
+
Returns
+

true : not changes done false : changes in the buffers

+
+
+
+ +
+
+template<typename Iter1, typename Sent1, typename Iter2, typename Sent2, typename Compare>
void merge_flow(range<Iter1, Sent1> rng1, range<Iter2, Sent2> rbuf, range<Iter1, Sent1> rng2, Compare cmp)#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
asio#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/asio/asio_util.hpp#
+

Defined in header hpx/asio/asio_util.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util#
+
+

Typedefs

+
+
+using endpoint_iterator_type = asio::ip::tcp::resolver::iterator#
+
+ +
+
+

Functions

+
+
+bool get_endpoint(std::string const &addr, std::uint16_t port, asio::ip::tcp::endpoint &ep, bool force_ipv4 = false)#
+
+ +
+
+std::string get_endpoint_name(asio::ip::tcp::endpoint const &ep)#
+
+ +
+
+asio::ip::tcp::endpoint resolve_hostname(std::string const &hostname, std::uint16_t port, asio::io_context &io_service, bool force_ipv4 = false)#
+
+ +
+
+std::string resolve_public_ip_address()#
+
+ +
+
+std::string cleanup_ip_address(std::string const &addr)#
+
+ +
+
+endpoint_iterator_type connect_begin(std::string const &address, std::uint16_t port, asio::io_context &io_service)#
+
+ +
+
+template<typename Locality>
endpoint_iterator_type connect_begin(Locality const &loc, asio::io_context &io_service)#
+

Returns an iterator which when dereferenced will give an endpoint suitable for a call to connect() related to this locality.

+
+ +
+
+inline endpoint_iterator_type connect_end()#
+
+ +
+
+endpoint_iterator_type accept_begin(std::string const &address, std::uint16_t port, asio::io_context &io_service)#
+
+ +
+
+template<typename Locality>
endpoint_iterator_type accept_begin(Locality const &loc, asio::io_context &io_service)#
+

Returns an iterator which when dereferenced will give an endpoint suitable for a call to accept() related to this locality.

+
+ +
+
+inline endpoint_iterator_type accept_end()#
+
+ +
+
+bool split_ip_address(std::string const &v, std::string &host, std::uint16_t &port)#
+
+ +
+
+ +
+ +
+
+
+
+
assertion#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/assertion/evaluate_assert.hpp#
+

Defined in header hpx/assertion/evaluate_assert.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace assertion
+
+ +
+ +
+
+
HPX_CURRENT_SOURCE_LOCATION, hpx::source_location#
+

Defined in header hpx/source_location.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_CURRENT_SOURCE_LOCATION()#
+
+ +
+
+
+namespace hpx
+
+

Functions

+
+
+std::ostream &operator<<(std::ostream &os, source_location const &loc)#
+
+ +
+
+
+struct source_location#
+
+#include <source_location.hpp>
+

This contains the location information where HPX_ASSERT has been called The source_location class represents certain information about the source code, such as file names, line numbers, and function names. Previously, functions that desire to obtain this information about the call site (for logging, testing, or debugging purposes) must use macros so that predefined macros like and are expanded in the context of the caller. The source_location class provides a better alternative. source_location meets the DefaultConstructible, CopyConstructible, CopyAssignable and Destructible requirements. Lvalue of source_location meets the Swappable requirement. Additionally, the following conditions are true:

    +
  • std::is_nothrow_move_constructible_v<std::source_location> 
    +
    +
    +

  • +
  • std::is_nothrow_move_assignable_v<std::source_location> 
    +
    +
    +

  • +
  • std::is_nothrow_swappable_v<std::source_location> 
    +
    +
    + It is intended that source_location has a small size and can be copied efficiently. It is unspecified whether the copy/move constructors and the copy/move assignment operators of source_location are trivial and/or constexpr.

  • +
+

+
+

Public Functions

+
+
+inline constexpr std::uint_least32_t line() const noexcept#
+

return the line number represented by this object

+
+ +
+
+inline constexpr char const *file_name() const noexcept#
+

return the file name represented by this object

+
+ +
+
+inline constexpr char const *function_name() const noexcept#
+

return the name of the function represented by this object, if any

+
+ +
+
+

Public Members

+
+
+char const *filename#
+
+ +
+
+std::uint_least32_t line_number#
+
+ +
+
+char const *functionname#
+
+ +
+
+

Public Static Functions

+
+
+static inline constexpr std::uint_least32_t column() noexcept#
+

return the column number represented by this object

+
+ +
+
+ +
+
+namespace assertion
+
+

Typedefs

+
+
+using instead = hpx::source_location#
+
+ +
+
+ +
+ +
+
+
HPX_ASSERT, HPX_ASSERT_MSG#
+

Defined in header hpx/assert.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_ASSERT(expr)#
+

This macro asserts that expr evaluates to true.

+

+If expr evaluates to false, The source location and msg is being printed along with the expression and additional. Afterwards the program is being aborted. The assertion handler can be customized by calling hpx::assertion::set_assertion_handler().

+

Asserts are enabled if HPX_DEBUG is set. This is the default for CMAKE_BUILD_TYPE=Debug

+
+
Parameters
+
    +
  • expr – The expression to assert on. This can either be an expression that’s convertible to bool or a callable which returns bool

  • +
  • msg – The optional message that is used to give further information if the assert fails. This should be convertible to a std::string

  • +
+
+
+
+ +
+
+HPX_ASSERT_MSG(expr, msg)#
+

+

See also

+

HPX_ASSERT

+
+

+
+ +
+
+
+namespace hpx
+
+
+namespace assertion#
+
+

Typedefs

+
+
+using assertion_handler = void (*)(hpx::source_location const &loc, const char *expr, std::string const &msg)#
+

The signature for an assertion handler.

+
+ +
+
+

Functions

+
+
+void set_assertion_handler(assertion_handler handler)#
+

Set the assertion handler to be used within a program. If the handler has been set already once, the call to this function will be ignored.

+
+

Note

+

This function is not thread safe

+
+
+ +
+
+ +
+ +
+
+
+
+
async_base#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::async#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename F, typename ...Ts>
decltype(auto) async(F &&f, Ts&&... ts)#
+

The function template async runs the function f asynchronously (potentially in a separate thread which might be a part of a thread pool) and returns an hpx::future that will eventually hold the result of that function call. If no policy is defined, async behaves as if it is called with policy being hpx::launch::async | hpx::launch::deferred. Otherwise, it calls a function f with arguments ts according to a specific launch policy.

    +
  • If the async flag is set (i.e. (policy & hpx::launch::async) != 0), then async executes the callable object f on a new thread of execution (with all thread-locals initialized) as if spawned by hpx::thread(std::forward<F>(f), std::forward<Ts>(ts)…), except that if the function f returns a value or throws an exception, it is stored in the shared state accessible through the hpx::future that async returns to the caller.

  • +
  • If the deferred flag is set (i.e. (policy & hpx::launch::deferred) != 0), then async converts f and ts… the same way as by hpx::thread constructor, but does not spawn a new thread of execution. Instead, lazy evaluation is performed: the first call to a non-timed wait function on the hpx::future that async returned to the caller will cause the copy of f to be invoked (as an rvalue) with the copies of ts… (also passed as rvalues) in the current thread (which does not have to be the thread that originally called hpx::async). The result or exception is placed in the shared state associated with the future and only then it is made ready. All further accesses to the same hpx::future will return the result immediately.

  • +
  • If neither hpx::launch::async nor hpx::launch::deferred, nor any implementation-defined policy flag is set in policy, the behavior is undefined.

  • +
+

+

If more than one flag is set, it is implementation-defined which policy is selected. For the default (both the hpx::launch::async and hpx::launch::deferred flags are set in policy), standard recommends (but doesn’t require) utilizing available concurrency, and deferring any additional tasks.

+

In any case, the call to hpx::async synchronizes-with (as defined in std::memory_order) the call to f, and the completion of f is sequenced-before making the shared state ready. If the async policy is chosen, the associated thread completion synchronizes-with the successful return from the first function that is waiting on the shared state, or with the return of the last function that releases the shared state, whichever comes first. If std::decay<Function>::type or each type in std::decay<Ts>::type is not constructible from its corresponding argument, the program is ill-formed.

+
+
Parameters
+
    +
  • f – Callable object to call

  • +
  • ts – parameters to pass to f

  • +
+
+
Returns
+

hpx::future referring to the shared state created by this call to hpx::async.

+
+
+
+ +
+
+ +
+
+
hpx::dataflow#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename F, typename ...Ts>
decltype(auto) dataflow(F &&f, Ts&&... ts)#
+

The function template dataflow runs the function f asynchronously (potentially in a separate thread which might be a part of a thread pool) and returns a hpx::future that will eventually hold the result of that function call. Its behavior is similar to hpx::async with the exception that if one of the arguments is a future, then hpx::dataflow will wait for the future to be ready to launch the thread. Hence, the operation is delayed until all the arguments are ready.

+
+ +
+
+ +
+
+
hpx::launch#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+struct launch : public detail::policy_holder<>#
+
+#include <launch_policy.hpp>
+

Launch policies for hpx::async etc.

+
+

Public Functions

+
+
+inline constexpr launch() noexcept#
+

Default constructor. This creates a launch policy representing all possible launch modes

+
+ +
+
+inline constexpr launch(detail::async_policy p) noexcept#
+

Create a launch policy representing asynchronous execution.

+
+ +
+
+inline constexpr launch(detail::fork_policy p) noexcept#
+

Create a launch policy representing asynchronous execution. The new thread is executed in a preferred way

+
+ +
+
+inline constexpr launch(detail::sync_policy p) noexcept#
+

Create a launch policy representing synchronous execution.

+
+ +
+
+inline constexpr launch(detail::deferred_policy p) noexcept#
+

Create a launch policy representing deferred execution.

+
+ +
+
+inline constexpr launch(detail::apply_policy p) noexcept#
+

Create a launch policy representing fire and forget execution.

+
+ +
+
+template<typename F>
inline constexpr launch(detail::select_policy<F> const &p) noexcept#
+

Create a launch policy representing fire and forget execution.

+
+ +
+
+template<typename Launch, typename Enable = std::enable_if_t<hpx::traits::is_launch_policy_v<Launch>>>
inline constexpr launch(Launch l, threads::thread_priority priority, threads::thread_stacksize stacksize, threads::thread_schedule_hint hint) noexcept#
+
+ +
+
+

Public Static Attributes

+
+
+static const detail::async_policy async#
+

Predefined launch policy representing asynchronous execution.

+
+ +
+
+static const detail::fork_policy fork#
+

Predefined launch policy representing asynchronous execution.The new thread is executed in a preferred way

+
+ +
+
+static const detail::sync_policy sync#
+

Predefined launch policy representing synchronous execution.

+
+ +
+
+static const detail::deferred_policy deferred#
+

Predefined launch policy representing deferred execution.

+
+ +
+
+static const detail::apply_policy apply#
+

Predefined launch policy representing fire and forget execution.

+
+ +
+
+static const detail::select_policy_generator select#
+

Predefined launch policy representing delayed policy selection.

+
+ +
+
+

Friends

+
+
+inline friend launch tag_invoke(hpx::execution::experimental::with_priority_t, launch const &policy, threads::thread_priority priority) noexcept#
+
+ +
+
+inline friend constexpr friend hpx::threads::thread_priority tag_invoke (hpx::execution::experimental::get_priority_t, launch const &policy) noexcept
+
+ +
+
+inline friend launch tag_invoke(hpx::execution::experimental::with_stacksize_t, launch const &policy, threads::thread_stacksize stacksize) noexcept#
+
+ +
+
+inline friend constexpr friend hpx::threads::thread_stacksize tag_invoke (hpx::execution::experimental::get_stacksize_t, launch const &policy) noexcept
+
+ +
+
+inline friend launch tag_invoke(hpx::execution::experimental::with_hint_t, launch const &policy, threads::thread_schedule_hint hint) noexcept#
+
+ +
+
+inline friend constexpr friend hpx::threads::thread_schedule_hint tag_invoke (hpx::execution::experimental::get_hint_t, launch const &policy) noexcept
+
+ +
+
+ +
+ +
+
+
hpx::post#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename F, typename ...Ts>
bool post(F &&f, Ts&&... ts)#
+

Runs the function f asynchronously (potentially in a separate thread which might be a part of a thread pool). This is done in a fire-and-forget manner, meaning there is no return value or way to synchronize with the function execution (it does not return an hpx::future that would hold the result of that function call).

+

hpx::post is particularly useful when synchronization mechanisms as heavyweight as futures are not desired, and instead, more lightweight mechanisms like latches or atomic variables are preferred. Essentially, the post function enables the launch of a new thread without the overhead of creating a future.

+
+

Note

+

hpx::post is similar to hpx::async but does not return a future. This is why there is no way of finding out the result/failure of the execution of this function.

+
+
+ +
+
+ +
+
+
hpx::sync#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename F, typename ...Ts>
decltype(auto) sync(F &&f, Ts&&... ts)#
+

The function template sync runs the function f synchronously and returns an hpx::future that will eventually hold the result of that function call.

+
+ +
+
+ +
+
+
+
+
async_combinators#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/async_combinators/split_future.hpp#
+

Defined in header hpx/async_combinators/split_future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename ...Ts>
inline tuple<future<Ts>...> split_future(future<tuple<Ts...>> &&f)#
+

The function split_future is an operator allowing to split a given future of a sequence of values (any tuple, std::pair, or std::array) into an equivalent container of futures where each future represents one of the values from the original future. In some sense this function provides the inverse operation of when_all.

+
+

Note

+

The following cases are special:

tuple<future<void> > split_future(future<tuple<> > && f);
+array<future<void>, 1> split_future(future<array<T, 0> > && f);
+
+
+ here the returned futures are directly representing the futures which were passed to the function.

+
+
+
Parameters
+

f – [in] A future holding an arbitrary sequence of values stored in a tuple-like container. This facility supports hpx::tuple<>, std::pair<T1, T2>, and std::array<T, N>

+
+
Returns
+

Returns an equivalent container (same container type as passed as the argument) of futures, where each future refers to the corresponding value in the input parameter. All of the returned futures become ready once the input future has become ready. If the input future is exceptional, all output futures will be exceptional as well.

+
+
+
+ +
+
+template<typename T>
inline std::vector<future<T>> split_future(future<std::vector<T>> &&f, std::size_t size)#
+

The function split_future is an operator allowing to split a given future of a sequence of values (any std::vector) into a std::vector of futures where each future represents one of the values from the original std::vector. In some sense this function provides the inverse operation of when_all.

+
+
Parameters
+
    +
  • f – [in] A future holding an arbitrary sequence of values stored in a std::vector.

  • +
  • size – [in] The number of elements the vector will hold once the input future has become ready

  • +
+
+
Returns
+

Returns a std::vector of futures, where each future refers to the corresponding value in the input parameter. All of the returned futures become ready once the input future has become ready. If the input future is exceptional, all output futures will be exceptional as well.

+
+
+
+ +
+
+ +
+
+
hpx::wait_all#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename InputIter>
void wait_all(InputIter first, InputIter last)#
+

The function wait_all is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns after they finished executing.

+
+

Note

+

The function wait_all returns after all futures have become ready. All input futures are still valid after wait_all returns.

+
+
+

Note

+

The function wait_all will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_all_nothrow instead.

+
+
+
Parameters
+
    +
  • first – The iterator pointing to the first element of a sequence of future or shared_future objects for which wait_all should wait.

  • +
  • last – The iterator pointing to the last element of a sequence of future or shared_future objects for which wait_all should wait.

  • +
+
+
+
+ +
+
+template<typename R>
void wait_all(std::vector<future<R>> &&futures)#
+

The function wait_all is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns after they finished executing.

+
+

Note

+

The function wait_all returns after all futures have become ready. All input futures are still valid after wait_all returns.

+
+
+

Note

+

The function wait_all will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_all_nothrow instead.

+
+
+
Parameters
+

futures – A vector or array holding an arbitrary amount of future or shared_future objects for which wait_all should wait.

+
+
+
+ +
+
+template<typename R, std::size_t N>
void wait_all(std::array<future<R>, N> &&futures)#
+

The function wait_all is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns after they finished executing.

+
+

Note

+

The function wait_all returns after all futures have become ready. All input futures are still valid after wait_all returns.

+
+
+

Note

+

The function wait_all will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_all_nothrow instead.

+
+
+
Parameters
+

futures – A vector or array holding an arbitrary amount of future or shared_future objects for which wait_all should wait.

+
+
+
+ +
+
+template<typename T>
void wait_all(hpx::future<T> const &f)#
+

The function wait_all is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns after they finished executing.

+
+

Note

+

The function wait_all returns after the future has become ready. The input future is still valid after wait_all returns.

+
+
+

Note

+

The function wait_all will rethrow any exceptions captured by the future while becoming ready. If this behavior is undesirable, use wait_all_nothrow instead.

+
+
+
Parameters
+

f – A future or shared_future for which wait_all should wait.

+
+
+
+ +
+
+template<typename ...T>
void wait_all(T&&... futures)#
+

The function wait_all is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns after they finished executing.

+
+

Note

+

The function wait_all returns after all futures have become ready. All input futures are still valid after wait_all returns.

+
+
+

Note

+

The function wait_all will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_all_nothrow instead.

+
+
+
Parameters
+

futures – An arbitrary number of future or shared_future objects, possibly holding different types for which wait_all should wait.

+
+
+
+ +
+
+template<typename InputIter>
void wait_all_n(InputIter begin, std::size_t count)#
+

The function wait_all_n is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns after they finished executing.

+
+

Note

+

The function wait_all_n returns after all futures have become ready. All input futures are still valid after wait_all_n returns.

+
+
+

Note

+

The function wait_all_n will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_all_n_nothrow instead.

+
+
+
Parameters
+
    +
  • begin – The iterator pointing to the first element of a sequence of future or shared_future objects for which wait_all_n should wait.

  • +
  • count – The number of elements in the sequence starting at first.

  • +
+
+
Returns
+

The function wait_all_n will return an iterator referring to the first element in the input sequence after the last processed element.

+
+
+
+ +
+
+ +
+
+
hpx::wait_any#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename InputIter>
void wait_any(InputIter first, InputIter last)#
+

The function wait_any is a non-deterministic choice operator. It OR-composes all future objects given and returns after one future of that list finishes execution.

+
+

Note

+

The function wait_any returns after at least one future has become ready. All input futures are still valid after wait_any returns.

+
+
+

Note

+

The function wait_any will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_any_nothrow instead.

+
+
+
Parameters
+
    +
  • first – [in] The iterator pointing to the first element of a sequence of future or shared_future objects for which wait_any should wait.

  • +
  • last – [in] The iterator pointing to the last element of a sequence of future or shared_future objects for which wait_any should wait.

  • +
+
+
+
+ +
+
+template<typename R>
void wait_any(std::vector<future<R>> &futures)#
+

The function wait_any is a non-deterministic choice operator. It OR-composes all future objects given and returns after one future of that list finishes execution.

+
+

Note

+

The function wait_any returns after at least one future has become ready. All input futures are still valid after wait_any returns.

+
+
+

Note

+

The function wait_any will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_any_nothrow instead.

+
+
+
Parameters
+

futures – [in] A vector holding an arbitrary amount of future or shared_future objects for which wait_any should wait.

+
+
+
+ +
+
+template<typename R, std::size_t N>
void wait_any(std::array<future<R>, N> &futures)#
+

The function wait_any is a non-deterministic choice operator. It OR-composes all future objects given and returns after one future of that list finishes execution.

+
+

Note

+

The function wait_any returns after at least one future has become ready. All input futures are still valid after wait_any returns.

+
+
+

Note

+

The function wait_any will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_any_nothrow instead.

+
+
+
Parameters
+

futures – [in] Amn array holding an arbitrary amount of future or shared_future objects for which wait_any should wait.

+
+
+
+ +
+
+template<typename ...T>
void wait_any(T&&... futures)#
+

The function wait_any is a non-deterministic choice operator. It OR-composes all future objects given and returns after one future of that list finishes execution.

+
+

Note

+

The function wait_any returns after at least one future has become ready. All input futures are still valid after wait_any returns.

+
+
+

Note

+

The function wait_any will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_any_nothrow instead.

+
+
+
Parameters
+

futures – [in] An arbitrary number of future or shared_future objects, possibly holding different types for which wait_any should wait.

+
+
+
+ +
+
+template<typename InputIter>
void wait_any_n(InputIter first, std::size_t count)#
+

The function wait_any_n is a non-deterministic choice operator. It OR-composes all future objects given and returns after one future of that list finishes execution.

+
+

Note

+

The function wait_any_n returns after at least one future has become ready. All input futures are still valid after wait_any_n returns.

+
+
+

Note

+

The function wait_any_n will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_any_n_nothrow instead.

+
+
+
Parameters
+
    +
  • first – [in] The iterator pointing to the first element of a sequence of future or shared_future objects for which wait_any_n should wait.

  • +
  • count – [in] The number of elements in the sequence starting at first.

  • +
+
+
+
+ +
+
+ +
+
+
hpx::wait_each#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename F, typename Future>
void wait_each(F &&f, std::vector<Future> &&futures)#
+

The function wait_each is an operator allowing to join on the results of all given futures. It AND-composes all future objects given and returns after they finished executing. Additionally, the supplied function is called for each of the passed futures as soon as the future has become ready. wait_each returns after all futures have been become ready.

+
+

Note

+

This function consumes the futures as they are passed on to the supplied function. The callback should take one or two parameters, namely either a future to be processed or a type that std::size_t is implicitly convertible to as the first parameter and the future as the second parameter. The first parameter will correspond to the index of the current future in the collection.

+
+
+
Parameters
+
    +
  • f – The function which will be called for each of the input futures once the future has become ready.

  • +
  • futures – A vector holding an arbitrary amount of future or shared_future objects for which wait_each should wait.

  • +
+
+
+
+ +
+
+template<typename F, typename Iterator>
void wait_each(F &&f, Iterator begin, Iterator end)#
+

The function wait_each is an operator allowing to join on the results of all given futures. It AND-composes all future objects given and returns after they finished executing. Additionally, the supplied function is called for each of the passed futures as soon as the future has become ready. wait_each returns after all futures have been become ready.

+
+

Note

+

This function consumes the futures as they are passed on to the supplied function. The callback should take one or two parameters, namely either a future to be processed or a type that std::size_t is implicitly convertible to as the first parameter and the future as the second parameter. The first parameter will correspond to the index of the current future in the collection.

+
+
+
Parameters
+
    +
  • f – The function which will be called for each of the input futures once the future has become ready.

  • +
  • begin – The iterator pointing to the first element of a sequence of future or shared_future objects for which wait_each should wait.

  • +
  • end – The iterator pointing to the last element of a sequence of future or shared_future objects for which wait_each should wait.

  • +
+
+
+
+ +
+
+template<typename F, typename ...T>
void wait_each(F &&f, T&&... futures)#
+

The function wait_each is an operator allowing to join on the results of all given futures. It AND-composes all future objects given and returns after they finished executing. Additionally, the supplied function is called for each of the passed futures as soon as the future has become ready. wait_each returns after all futures have been become ready.

+
+

Note

+

This function consumes the futures as they are passed on to the supplied function. The callback should take one or two parameters, namely either a future to be processed or a type that std::size_t is implicitly convertible to as the first parameter and the future as the second parameter. The first parameter will correspond to the index of the current future in the collection.

+
+
+
Parameters
+
    +
  • f – The function which will be called for each of the input futures once the future has become ready.

  • +
  • futures – An arbitrary number of future or shared_future objects, possibly holding different types for which wait_each should wait.

  • +
+
+
+
+ +
+
+template<typename F, typename Iterator>
void wait_each_n(F &&f, Iterator begin, std::size_t count)#
+

The function wait_each is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns after they finished executing. Additionally, the supplied function is called for each of the passed futures as soon as the future has become ready.

+
+

Note

+

This function consumes the futures as they are passed on to the supplied function. The callback should take one or two parameters, namely either a future to be processed or a type that std::size_t is implicitly convertible to as the first parameter and the future as the second parameter. The first parameter will correspond to the index of the current future in the collection.

+
+
+
Parameters
+
    +
  • f – The function which will be called for each of the input futures once the future has become ready.

  • +
  • begin – The iterator pointing to the first element of a sequence of future or shared_future objects for which wait_each_n should wait.

  • +
  • count – The number of elements in the sequence starting at first.

  • +
+
+
+
+ +
+
+ +
+
+
hpx::wait_some#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename InputIter>
void wait_some(std::size_t n, InputIter first, InputIter last)#
+

The function wait_some is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns a new future object representing the same list of futures after n of them finished executing.

+
+

Note

+

The function wait_some returns after n futures have become ready. All input futures are still valid after wait_some returns.

+
+
+

Note

+

The function wait_some will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_some_nothrow instead.

+
+
+
Parameters
+
    +
  • n – [in] The number of futures out of the arguments which have to become ready in order for the function to return.

  • +
  • first – [in] The iterator pointing to the first element of a sequence of future or shared_future objects for which when_all should wait.

  • +
  • last – [in] The iterator pointing to the last element of a sequence of future or shared_future objects for which when_all should wait.

  • +
+
+
+
+ +
+
+template<typename R>
void wait_some(std::size_t n, std::vector<future<R>> &&futures)#
+

The function wait_some is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns a new future object representing the same list of futures after n of them finished executing.

+
+

Note

+

The function wait_some returns after n futures have become ready. All input futures are still valid after wait_some returns.

+
+
+

Note

+

The function wait_some will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_some_nothrow instead.

+
+
+
Parameters
+
    +
  • n – [in] The number of futures out of the arguments which have to become ready in order for the returned future to get ready.

  • +
  • futures – [in] A vector holding an arbitrary amount of future or shared_future objects for which wait_some should wait.

  • +
+
+
+
+ +
+
+template<typename R, std::size_t N>
void wait_some(std::size_t n, std::array<future<R>, N> &&futures)#
+

The function wait_some is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns a new future object representing the same list of futures after n of them finished executing.

+
+

Note

+

The function wait_some returns after n futures have become ready. All input futures are still valid after wait_some returns.

+
+
+

Note

+

The function wait_some will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_some_nothrow instead.

+
+
+
Parameters
+
    +
  • n – [in] The number of futures out of the arguments which have to become ready in order for the returned future to get ready.

  • +
  • futures – [in] An array holding an arbitrary amount of future or shared_future objects for which wait_some should wait.

  • +
+
+
+
+ +
+
+template<typename ...T>
void wait_some(std::size_t n, T&&... futures)#
+

The function wait_some is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns a new future object representing the same list of futures after n of them finished executing.

+
+

Note

+

The function wait_all returns after n futures have become ready. All input futures are still valid after wait_some returns.

+
+
+

Note

+

The function wait_some will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_some_nothrow instead.

+
+
+
Parameters
+
    +
  • n – [in] The number of futures out of the arguments which have to become ready in order for the returned future to get ready.

  • +
  • futures – [in] An arbitrary number of future or shared_future objects, possibly holding different types for which wait_some should wait.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+template<typename InputIter>
void wait_some_n(std::size_t n, InputIter first, std::size_t count)#
+

The function wait_some_n is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns a new future object representing the same list of futures after n of them finished executing.

+
+

Note

+

The function wait_some_n returns after n futures have become ready. All input futures are still valid after wait_some_n returns.

+
+
+

Note

+

The function wait_some_n will rethrow any exceptions captured by the futures while becoming ready. If this behavior is undesirable, use wait_some_n_nothrow instead.

+
+
+
Parameters
+
    +
  • n – [in] The number of futures out of the arguments which have to become ready in order for the returned future to get ready.

  • +
  • first – [in] The iterator pointing to the first element of a sequence of future or shared_future objects for which when_all should wait.

  • +
  • count – [in] The number of elements in the sequence starting at first.

  • +
+
+
+
+ +
+
+ +
+
+
hpx::when_all#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename InputIter, typename Container = vector<future<typename std::iterator_traits<InputIter>::value_type>>>
hpx::future<Container> when_all(InputIter first, InputIter last)#
+

function when_all creates a future object that becomes ready when all elements in a set of future and shared_future objects become ready. It is an operator allowing to join on the result of all given futures. It AND-composes all given future objects and returns a new future object representing the same list of futures after they finished executing.

+
+

Note

+

Calling this version of when_all where first == last, returns a future with an empty container that is immediately ready. Each future and shared_future is waited upon and then copied into the collection of the output (returned) future, maintaining the order of the futures in the input collection. The future returned by when_all will not throw an exception, but the futures held in the output collection may.

+
+
+
Parameters
+
    +
  • first – [in] The iterator pointing to the first element of a sequence of future or shared_future objects for which when_all should wait.

  • +
  • last – [in] The iterator pointing to the last element of a sequence of future or shared_future objects for which when_all should wait.

  • +
+
+
Returns
+

Returns a future holding the same list of futures as has been passed to when_all.

    +
  • future<Container<future<R>>>: If the input cardinality is unknown at compile time and the futures are all of the same type. The order of the futures in the output container will be the same as given by the input iterator.

  • +
+

+
+
+
+ +
+
+template<typename Range>
hpx::future<Range> when_all(Range &&values)#
+

function when_all creates a future object that becomes ready when all elements in a set of future and shared_future objects become ready. It is an operator allowing to join on the result of all given futures. It AND-composes all given future objects and returns a new future object representing the same list of futures after they finished executing.

+
+

Note

+

Calling this version of when_all where the input container is empty, returns a future with an empty container that is immediately ready. Each future and shared_future is waited upon and then copied into the collection of the output (returned) future, maintaining the order of the futures in the input collection. The future returned by when_all will not throw an exception, but the futures held in the output collection may.

+
+
+
Parameters
+

values – [in] A range holding an arbitrary amount of future or shared_future objects for which when_all should wait.

+
+
Returns
+

Returns a future holding the same list of futures as has been passed to when_all.

    +
  • future<Container<future<R>>>: If the input cardinality is unknown at compile time and the futures are all of the same type.

  • +
+

+
+
+
+ +
+
+template<typename ...T>
hpx::future<hpx::tuple<hpx::future<T>...>> when_all(T&&... futures)#
+

function when_all creates a future object that becomes ready when all elements in a set of future and shared_future objects become ready. It is an operator allowing to join on the result of all given futures. It AND-composes all given future objects and returns a new future object representing the same list of futures after they finished executing.

+
+

Note

+

Each future and shared_future is waited upon and then copied into the collection of the output (returned) future, maintaining the order of the futures in the input collection. The future returned by when_all will not throw an exception, but the futures held in the output collection may.

+
+
+
Parameters
+

futures – [in] An arbitrary number of future or shared_future objects, possibly holding different types for which when_all should wait.

+
+
Returns
+

Returns a future holding the same list of futures as has been passed to when_all.

    +
  • future<tuple<future<T0>, future<T1>, future<T2>…>>: If inputs are fixed in number and are of heterogeneous types. The inputs can be any arbitrary number of future objects.

  • +
  • future<tuple<>> if when_all is called with zero arguments. The returned future will be initially ready.

  • +
+

+
+
+
+ +
+
+template<typename InputIter, typename Container = vector<future<typename std::iterator_traits<InputIter>::value_type>>>
hpx::future<Container> when_all_n(InputIter begin, std::size_t count)#
+

function when_all creates a future object that becomes ready when all elements in a set of future and shared_future objects become ready. It is an operator allowing to join on the result of all given futures. It AND-composes all given future objects and returns a new future object representing the same list of futures after they finished executing.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

None of the futures in the input sequence are invalidated.

+
+
+
Parameters
+
    +
  • begin – [in] The iterator pointing to the first element of a sequence of future or shared_future objects for which wait_all_n should wait.

  • +
  • count – [in] The number of elements in the sequence starting at first.

  • +
+
+
Throws
+

This – function will throw errors which are encountered while setting up the requested operation only. Errors encountered while executing the operations delivering the results to be stored in the futures are reported through the futures themselves.

+
+
Returns
+

Returns a future holding the same list of futures as has been passed to when_all_n.

    +
  • future<Container<future<R>>>: If the input cardinality is unknown at compile time and the futures are all of the same type. The order of the futures in the output vector will be the same as given by the input iterator.

  • +
+

+
+
+
+ +
+
+ +
+
+
hpx::when_any#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename InputIter, typename Container = vector<future<typename std::iterator_traits<InputIter>::value_type>>>
future<when_any_result<Container>> when_any(InputIter first, InputIter last)#
+

function when_any creates a future object that becomes when at least one element in a set of future and shared_future objects becomes ready. It is a non-deterministic choice operator. It OR-composes all given future objects and returns a new future object representing the same list of futures after one future of that list finishes execution.

+
+
Parameters
+
    +
  • first – [in] The iterator pointing to the first element of a sequence of future or shared_future objects for which when_any should wait.

  • +
  • last – [in] The iterator pointing to the last element of a sequence of future or shared_future objects for which when_any should wait.

  • +
+
+
Returns
+

Returns a when_any_result holding the same list of futures as has been passed to when_any and an index pointing to a ready future.

    +
  • future<when_any_result<Container<future<R>>>>: If the input cardinality is unknown at compile time and the futures are all of the same type. The order of the futures in the output container will be the same as given by the input iterator.

  • +
+

+
+
+
+ +
+
+template<typename Range>
future<when_any_result<Range>> when_any(Range &values)#
+

function when_any creates a future object that becomes when at least one element in a set of future and shared_future objects becomes ready. It is a non-deterministic choice operator. It OR-composes all given future objects and returns a new future object representing the same list of futures after one future of that list finishes execution.

+
+
Parameters
+

values – [in] A range holding an arbitrary amount of futures or shared_future objects for which when_any should wait.

+
+
Returns
+

Returns a when_any_result holding the same list of futures as has been passed to when_any and an index pointing to a ready future.

    +
  • future<when_any_result<Container<future<R>>>>: If the input cardinality is unknown at compile time and the futures are all of the same type. The order of the futures in the output container will be the same as given by the input iterator.

  • +
+

+
+
+
+ +
+
+template<typename ...T>
future<when_any_result<tuple<future<T>...>>> when_any(T&&... futures)#
+

function when_any creates a future object that becomes when at least one element in a set of future and shared_future objects becomes ready. It is a non-deterministic choice operator. It OR-composes all given future objects and returns a new future object representing the same list of futures after one future of that list finishes execution.

+
+
Parameters
+

futures – [in] An arbitrary number of future or shared_future objects, possibly holding different types for which when_any should wait.

+
+
Returns
+

Returns a when_any_result holding the same list of futures as has been passed to when_any and an index pointing to a ready future..

    +
  • future<when_any_result<tuple<future<T0>, future<T1>…>>>: If inputs are fixed in number and are of heterogeneous types. The inputs can be any arbitrary number of future objects.

  • +
  • future<when_any_result<tuple<>>> if when_any is called with zero arguments. The returned future will be initially ready.

  • +
+

+
+
+
+ +
+
+template<typename InputIter, typename Container = vector<future<typename std::iterator_traits<InputIter>::value_type>>>
future<when_any_result<Container>> when_any_n(InputIter first, std::size_t count)#
+

function when_any_n creates a future object that becomes when at least one element in a set of future and shared_future objects becomes ready. It is a non-deterministic choice operator. It OR-composes all given future objects and returns a new future object representing the same list of futures after one future of that list finishes execution.

+
+

Note

+

None of the futures in the input sequence are invalidated.

+
+
+
Parameters
+
    +
  • first – [in] The iterator pointing to the first element of a sequence of future or shared_future objects for which when_any_n should wait.

  • +
  • count – [in] The number of elements in the sequence starting at first.

  • +
+
+
Returns
+

Returns a when_any_result holding the same list of futures as has been passed to when_any and an index pointing to a ready future.

    +
  • future<when_any_result<Container<future<R>>>>: If the input cardinality is unknown at compile time and the futures are all of the same type. The order of the futures in the output container will be the same as given by the input iterator.

  • +
+

+
+
+
+ +
+
+
+template<typename Sequence>
struct when_any_result#
+
+#include <when_any.hpp>
+

Result type for when_any, contains a sequence of futures and an index pointing to a ready future.

+
+

Public Members

+
+
+std::size_t index#
+

The index of a future which has become ready.

+
+ +
+
+Sequence futures#
+

The sequence of futures as passed to hpx::when_any

+
+ +
+
+ +
+ +
+
+
hpx::when_each#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename F, typename Future>
future<void> when_each(F &&f, std::vector<Future> &&futures)#
+

The function when_each is an operator allowing to join on the results of all given futures. It AND-composes all future objects given and returns a new future object representing the event of all those futures having finished executing. It also calls the supplied callback for each of the futures which becomes ready.

+
+

Note

+

This function consumes the futures as they are passed on to the supplied function. The callback should take one or two parameters, namely either a future to be processed or a type that std::size_t is implicitly convertible to as the first parameter and the future as the second parameter. The first parameter will correspond to the index of the current future in the collection.

+
+
+
Parameters
+
    +
  • f – The function which will be called for each of the input futures once the future has become ready.

  • +
  • futures – A vector holding an arbitrary amount of future or shared_future objects for which wait_each should wait.

  • +
+
+
Returns
+

Returns a future representing the event of all input futures being ready.

+
+
+
+ +
+
+template<typename F, typename Iterator>
future<Iterator> when_each(F &&f, Iterator begin, Iterator end)#
+

The function when_each is an operator allowing to join on the results of all given futures. It AND-composes all future objects given and returns a new future object representing the event of all those futures having finished executing. It also calls the supplied callback for each of the futures which becomes ready.

+
+

Note

+

This function consumes the futures as they are passed on to the supplied function. The callback should take one or two parameters, namely either a future to be processed or a type that std::size_t is implicitly convertible to as the first parameter and the future as the second parameter. The first parameter will correspond to the index of the current future in the collection.

+
+
+
Parameters
+
    +
  • f – The function which will be called for each of the input futures once the future has become ready.

  • +
  • begin – The iterator pointing to the first element of a sequence of future or shared_future objects for which wait_each should wait.

  • +
  • end – The iterator pointing to the last element of a sequence of future or shared_future objects for which wait_each should wait.

  • +
+
+
Returns
+

Returns a future representing the event of all input futures being ready.

+
+
+
+ +
+
+template<typename F, typename ...Ts>
future<void> when_each(F &&f, Ts&&... futures)#
+

The function when_each is an operator allowing to join on the results of all given futures. It AND-composes all future objects given and returns a new future object representing the event of all those futures having finished executing. It also calls the supplied callback for each of the futures which becomes ready.

+
+

Note

+

This function consumes the futures as they are passed on to the supplied function. The callback should take one or two parameters, namely either a future to be processed or a type that std::size_t is implicitly convertible to as the first parameter and the future as the second parameter. The first parameter will correspond to the index of the current future in the collection.

+
+
+
Parameters
+
    +
  • f – The function which will be called for each of the input futures once the future has become ready.

  • +
  • futures – An arbitrary number of future or shared_future objects, possibly holding different types for which wait_each should wait.

  • +
+
+
Returns
+

Returns a future representing the event of all input futures being ready.

+
+
+
+ +
+
+template<typename F, typename Iterator>
future<Iterator> when_each_n(F &&f, Iterator begin, std::size_t count)#
+

The function when_each is an operator allowing to join on the results of all given futures. It AND-composes all future objects given and returns a new future object representing the event of all those futures having finished executing. It also calls the supplied callback for each of the futures which becomes ready.

+
+

Note

+

This function consumes the futures as they are passed on to the supplied function. The callback should take one or two parameters, namely either a future to be processed or a type that std::size_t is implicitly convertible to as the first parameter and the future as the second parameter. The first parameter will correspond to the index of the current future in the collection.

+
+
+
Parameters
+
    +
  • f – The function which will be called for each of the input futures once the future has become ready.

  • +
  • begin – The iterator pointing to the first element of a sequence of future or shared_future objects for which wait_each_n should wait.

  • +
  • count – The number of elements in the sequence starting at first.

  • +
+
+
Returns
+

Returns a future holding the iterator pointing to the first element after the last one.

+
+
+
+ +
+
+ +
+
+
hpx::when_some#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename InputIter, typename Container = vector<future<typename std::iterator_traits<InputIter>::value_type>>>
future<when_some_result<Container>> when_some(std::size_t n, Iterator first, Iterator last)#
+

The function when_some is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns a new future object representing the same list of futures after n of them finished executing.

+
+

Note

+

The future returned by the function when_some becomes ready when at least n argument futures have become ready.

+
+
+

Note

+

Calling this version of when_some where first == last, returns a future with an empty container that is immediately ready. Each future and shared_future is waited upon and then copied into the collection of the output (returned) future, maintaining the order of the futures in the input collection. The future returned by when_some will not throw an exception, but the futures held in the output collection may.

+
+
+
Parameters
+
    +
  • n – [in] The number of futures out of the arguments which have to become ready in order for the returned future to get ready.

  • +
  • first – [in] The iterator pointing to the first element of a sequence of future or shared_future objects for which when_all should wait.

  • +
  • last – [in] The iterator pointing to the last element of a sequence of future or shared_future objects for which when_all should wait.

  • +
+
+
Returns
+

Returns a when_some_result holding the same list of futures as has been passed to when_some and indices pointing to ready futures.

    +
  • future<when_some_result<Container<future<R>>>>: If the input cardinality is unknown at compile time and the futures are all of the same type. The order of the futures in the output container will be the same as given by the input iterator.

  • +
+

+
+
+
+ +
+
+template<typename Range>
future<when_some_result<Range>> when_some(std::size_t n, Range &&futures)#
+

The function when_some is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns a new future object representing the same list of futures after n of them finished executing.

+
+

Note

+

The future returned by the function when_some becomes ready when at least n argument futures have become ready.

+
+
+

Note

+

Each future and shared_future is waited upon and then copied into the collection of the output (returned) future, maintaining the order of the futures in the input collection. The future returned by when_some will not throw an exception, but the futures held in the output collection may.

+
+
+
Parameters
+
    +
  • n – [in] The number of futures out of the arguments which have to become ready in order for the returned future to get ready.

  • +
  • futures – [in] A container holding an arbitrary amount of future or shared_future objects for which when_some should wait.

  • +
+
+
Returns
+

Returns a when_some_result holding the same list of futures as has been passed to when_some and indices pointing to ready futures.

    +
  • future<when_some_result<Container<future<R>>>>: If the input cardinality is unknown at compile time and the futures are all of the same type. The order of the futures in the output container will be the same as given by the input iterator.

  • +
+

+
+
+
+ +
+
+template<typename ...Ts>
future<when_some_result<tuple<future<T>...>>> when_some(std::size_t n, Ts&&... futures)#
+

The function when_some is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns a new future object representing the same list of futures after n of them finished executing.

+
+

Note

+

The future returned by the function when_some becomes ready when at least n argument futures have become ready.

+
+
+

Note

+

Each future and shared_future is waited upon and then copied into the collection of the output (returned) future, maintaining the order of the futures in the input collection. The future returned by when_some will not throw an exception, but the futures held in the output collection may.

+
+
+
Parameters
+
    +
  • n – [in] The number of futures out of the arguments which have to become ready in order for the returned future to get ready.

  • +
  • futures – [in] An arbitrary number of future or shared_future objects, possibly holding different types for which when_some should wait.

  • +
+
+
Returns
+

Returns a when_some_result holding the same list of futures as has been passed to when_some and an index pointing to a ready future..

    +
  • future<when_some_result<tuple<future<T0>, future<T1>…>>>: If inputs are fixed in number and are of heterogeneous types. The inputs can be any arbitrary number of future objects.

  • +
  • future<when_some_result<tuple<>>> if when_some is called with zero arguments. The returned future will be initially ready.

  • +
+

+
+
+
+ +
+
+template<typename InputIter, typename Container = vector<future<typename std::iterator_traits<InputIter>::value_type>>>
future<when_some_result<Container>> when_some_n(std::size_t n, Iterator first, std::size_t count)#
+

The function when_some_n is an operator allowing to join on the result of all given futures. It AND-composes all future objects given and returns a new future object representing the same list of futures after n of them finished executing.

+
+

Note

+

The future returned by the function when_some_n becomes ready when at least n argument futures have become ready.

+
+
+

Note

+

Calling this version of when_some_n where count == 0, returns a future with the same elements as the arguments that is immediately ready. Possibly none of the futures in that container are ready. Each future and shared_future is waited upon and then copied into the collection of the output (returned) future, maintaining the order of the futures in the input collection. The future returned by when_some_n will not throw an exception, but the futures held in the output collection may.

+
+
+
Parameters
+
    +
  • n – [in] The number of futures out of the arguments which have to become ready in order for the returned future to get ready.

  • +
  • first – [in] The iterator pointing to the first element of a sequence of future or shared_future objects for which when_all should wait.

  • +
  • count – [in] The number of elements in the sequence starting at first.

  • +
+
+
Returns
+

Returns a when_some_result holding the same list of futures as has been passed to when_some and indices pointing to ready futures.

    +
  • future<when_some_result<Container<future<R>>>>: If the input cardinality is unknown at compile time and the futures are all of the same type. The order of the futures in the output container will be the same as given by the input iterator.

  • +
+

+
+
+
+ +
+
+
+template<typename Sequence>
struct when_some_result#
+
+#include <when_some.hpp>
+

Result type for when_some, contains a sequence of futures and indices pointing to ready futures.

+
+

Public Members

+
+
+std::vector<std::size_t> indices#
+

List of indices of futures that have become ready.

+
+ +
+
+Sequence futures#
+

The sequence of futures as passed to hpx::when_some.

+
+ +
+
+ +
+ +
+
+
+
+
async_cuda#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/async_cuda/cublas_executor.hpp#
+

Defined in header hpx/async_cuda/cublas_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/async_cuda/cuda_executor.hpp#
+

Defined in header hpx/async_cuda/cuda_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace cuda#
+
+
+namespace experimental#
+
+
+struct cuda_executor : public hpx::cuda::experimental::cuda_executor_base#
+
+

Public Functions

+
+
+inline explicit cuda_executor(std::size_t device, bool event_mode = true)#
+
+ +
+
+inline ~cuda_executor()#
+
+ +
+
+template<typename F, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::post_t, cuda_executor const &exec, F &&f, Ts&&... ts)#
+
+ +
+
+template<typename F, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::async_execute_t, cuda_executor const &exec, F &&f, Ts&&... ts)#
+
+ +
+
+

Protected Functions

+
+
+template<typename R, typename ...Params, typename ...Args>
inline void post(R (*cuda_function)(Params...), Args&&... args) const#
+
+ +
+
+template<typename R, typename ...Params, typename ...Args>
inline hpx::future<void> async(R (*cuda_kernel)(Params...), Args&&... args) const#
+
+ +
+
+ +
+
+struct cuda_executor_base#
+

Subclassed by hpx::cuda::experimental::cuda_executor

+
+

Public Types

+
+
+using future_type = hpx::future<void>#
+
+ +
+
+

Public Functions

+
+
+inline cuda_executor_base(std::size_t device, bool event_mode)#
+
+ +
+
+inline future_type get_future() const#
+
+ +
+
+

Protected Attributes

+
+
+int device_#
+
+ +
+
+bool event_mode_#
+
+ +
+
+cudaStream_t stream_#
+
+ +
+
+std::shared_ptr<hpx::cuda::experimental::target> target_#
+
+ +
+
+ +
+ +
+ +
+
+namespace parallel
+
+
+namespace execution#
+
+ +
+ +
+ +
+
+
+
+
async_mpi#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/async_mpi/mpi_executor.hpp#
+

Defined in header hpx/async_mpi/mpi_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace mpi#
+
+
+namespace experimental#
+
+
+struct executor#
+
+

Public Types

+
+
+using execution_category = hpx::execution::parallel_execution_tag#
+
+ +
+
+using executor_parameters_type = hpx::execution::experimental::default_parameters#
+
+ +
+
+

Public Functions

+
+
+inline explicit constexpr executor(MPI_Comm communicator = MPI_COMM_WORLD)#
+
+ +
+
+template<typename F, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::async_execute_t, executor const &exec, F &&f, Ts&&... ts)#
+
+ +
+
+inline std::size_t in_flight_estimate() const#
+
+ +
+
+

Private Members

+
+
+MPI_Comm communicator_#
+
+ +
+
+ +
+ +
+ +
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
hpx/async_mpi/transform_mpi.hpp#
+

Defined in header hpx/async_mpi/transform_mpi.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace mpi
+
+
+namespace experimental
+
+

Variables

+
+
+hpx::mpi::experimental::transform_mpi_t transform_mpi#
+
+ +
+
+
+struct transform_mpi_t : public hpx::functional::detail::tag_fallback<transform_mpi_t>#
+
+

Friends

+
+
+template<typename Sender, typename F> inline friend constexpr friend auto tag_fallback_invoke (transform_mpi_t, Sender &&s, F &&f)
+
+ +
+
+template<typename F> inline friend constexpr friend auto tag_fallback_invoke (transform_mpi_t, F &&f)
+
+ +
+
+ +
+ +
+ +
+ +
+
+
+
+
async_sycl#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/async_sycl/sycl_executor.hpp#
+

Defined in header hpx/async_sycl/sycl_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename Executor, typename ...Ts>
decltype(auto) async(Executor &&exec, hpx::sycl::experimental::sycl_executor::queue_function_ptr_t<Ts...> &&f, Ts&&... ts)#
+

hpx::async overload for launching sycl queue member functions with an sycl executor

+
+ +
+
+template<typename Executor, typename ...Ts>
bool apply(Executor &&exec, hpx::sycl::experimental::sycl_executor::queue_function_ptr_t<Ts...> &&f, Ts&&... ts)#
+

hpx::apply overload for launching sycl queue member functions with an sycl executor

+
+ +
+
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+
+namespace sycl#
+
+
+namespace experimental#
+
+
+struct sycl_executor#
+
+

Public Types

+
+
+using future_type = hpx::future<void>#
+
+ +
+
+template<typename ...Params>
using queue_function_ptr_t = cl::sycl::event (cl::sycl::queue::*)(std::conditional_t<std::is_trivial_v<std::remove_reference_t<Params>>, std::decay_t<Params>, Params>...)#
+

Default Implementation without the extra intel code_location parameter. Removes the reference for trivial types to make the function matching easier (see sycl_stream.cpp test)

+
+ +
+
+

Public Functions

+
+
+inline explicit sycl_executor(cl::sycl::default_selector selector)#
+

Create a SYCL executor (based on a sycl queue)

+
+ +
+
+~sycl_executor() = default#
+
+ +
+
+inline future_type get_future()#
+

Get future for this command_queue (NOTE will be more efficient if an event is provided &#8212; otherwise a dummy kernel must be submitted to get an event)

+
+ +
+
+inline future_type get_future(cl::sycl::event event)#
+

Get future for that becomes ready when the given event completes.

+
+ +
+
+template<typename ...Params>
inline void post(queue_function_ptr_t<Params...> &&queue_member_function, Params&&... args)#
+

Invoke queue member function given queue and parameters &#8212; do not use event to return a hpx::future (One way)

+
+ +
+
+template<typename ...Params>
inline hpx::future<void> async_execute(queue_function_ptr_t<Params...> &&queue_member_function, Params&&... args)#
+

Invoke queue member function given queue and parameters &#8212; hpx::future tied to the sycl event / (two way)

+
+ +
+
+template<typename F, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::post_t, sycl_executor &exec, F &&f, Ts&&... ts)#
+
+ +
+
+template<typename F, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::async_execute_t, sycl_executor &exec, F &&f, Ts&&... ts)#
+
+ +
+
+inline cl::sycl::device get_device() const#
+

Return the device used by the underlying SYCL queue.

+
+ +
+
+inline cl::sycl::context get_context() const#
+

Return the context used by the underlying SYCL queue.

+
+ +
+
+

Protected Attributes

+
+
+cl::sycl::queue command_queue#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
+
+
cache#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/cache/local_cache.hpp#
+

Defined in header hpx/cache/local_cache.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+
+namespace cache
+
+
+template<typename Key, typename Entry, typename UpdatePolicy = std::less<Entry>, typename InsertPolicy = policies::always<Entry>, typename CacheStorage = std::map<Key, Entry>, typename Statistics = statistics::no_statistics>
class local_cache#
+
+#include <hpx/cache/local_cache.hpp>
+

The local_cache implements the basic functionality needed for a local (non-distributed) cache.

+
+
Template Parameters
+
    +
  • Key – The type of the keys to use to identify the entries stored in the cache

  • +
  • Entry – The type of the items to be held in the cache, must model the CacheEntry concept

  • +
  • UpdatePolicy – A (optional) type specifying a (binary) function object used to sort the cache entries based on their ‘age’. The ‘oldest’ entries (according to this sorting criteria) will be discarded first if the maximum capacity of the cache is reached. The default is std::less<Entry>. The function object will be invoked using 2 entry instances of the type Entry. This type must model the UpdatePolicy model.

  • +
  • InsertPolicy – A (optional) type specifying a (unary) function object used to allow global decisions whether a particular entry should be added to the cache or not. The default is policies::always, imposing no global insert related criteria on the cache. The function object will be invoked using the entry instance to be inserted into the cache. This type must model the InsertPolicy model.

  • +
  • CacheStorage – A (optional) container type used to store the cache items. The container must be an associative and STL compatible container.The default is a std::map<Key, Entry>.

  • +
  • Statistics – A (optional) type allowing to collect some basic statistics about the operation of the cache instance. The type must conform to the CacheStatistics concept. The default value is the type statistics::no_statistics which does not collect any numbers, but provides empty stubs allowing the code to compile.

  • +
+
+
+
+

Public Types

+
+
+using key_type = Key#
+
+ +
+
+using entry_type = Entry#
+
+ +
+
+using update_policy_type = UpdatePolicy#
+
+ +
+
+using insert_policy_type = InsertPolicy#
+
+ +
+
+using storage_type = CacheStorage#
+
+ +
+
+using statistics_type = Statistics#
+
+ +
+
+using value_type = typename entry_type::value_type#
+
+ +
+
+using size_type = typename storage_type::size_type#
+
+ +
+
+using storage_value_type = typename storage_type::value_type#
+
+ +
+
+

Public Functions

+
+
+inline explicit local_cache(size_type max_size = 0, update_policy_type const &up = update_policy_type(), insert_policy_type const &ip = insert_policy_type())#
+

Construct an instance of a local_cache.

+
+
Parameters
+
    +
  • max_size – [in] The maximal size this cache is allowed to reach any time. The default is zero (no size limitation). The unit of this value is usually determined by the unit of the values returned by the entry’s get_size function.

  • +
  • up – [in] An instance of the UpdatePolicy to use for this cache. The default is to use a default constructed instance of the type as defined by the UpdatePolicy template parameter.

  • +
  • ip – [in] An instance of the InsertPolicy to use for this cache. The default is to use a default constructed instance of the type as defined by the InsertPolicy template parameter.

  • +
+
+
+
+ +
+
+local_cache(local_cache const &other) = default#
+
+ +
+
+local_cache(local_cache &&other) = default#
+
+ +
+
+local_cache &operator=(local_cache const &other) = default#
+
+ +
+
+local_cache &operator=(local_cache &&other) = default#
+
+ +
+
+~local_cache() = default#
+
+ +
+
+inline constexpr size_type size() const noexcept#
+

Return current size of the cache.

+
+
Returns
+

The current size of this cache instance.

+
+
+
+ +
+
+inline constexpr size_type capacity() const noexcept#
+

Access the maximum size the cache is allowed to grow to.

+
+

Note

+

The unit of this value is usually determined by the unit of the return values of the entry’s function entry::get_size.

+
+
+
Returns
+

The maximum size this cache instance is currently allowed to reach. If this number is zero the cache has no limitation with regard to a maximum size.

+
+
+
+ +
+
+inline bool reserve(size_type max_size)#
+

Change the maximum size this cache can grow to.

+
+
Parameters
+

max_size – [in] The new maximum size this cache will be allowed to grow to.

+
+
Returns
+

This function returns true if successful. It returns false if the new max_size is smaller than the current limit and the cache could not be shrunk to the new maximum size.

+
+
+
+ +
+
+inline bool holds_key(key_type const &k) const#
+

Check whether the cache currently holds an entry identified by the given key.

+
+

Note

+

This function does not call the entry’s function entry::touch. It just checks if the cache contains an entry corresponding to the given key.

+
+
+
Parameters
+

k – [in] The key for the entry which should be looked up in the cache.

+
+
Returns
+

This function returns true if the cache holds the referenced entry, otherwise it returns false.

+
+
+
+ +
+
+inline bool get_entry(key_type const &k, key_type &realkey, entry_type &val)#
+

Get a specific entry identified by the given key.

+
+

Note

+

The function will call the entry’s entry::touch function if the value corresponding to the provided key is found in the cache.

+
+
+
Parameters
+
    +
  • k – [in] The key for the entry which should be retrieved from the cache.

  • +
  • realkey[out] – Return the full real key found in the cache

  • +
  • val – [out] If the entry indexed by the key is found in the cache this value on successful return will be a copy of the corresponding entry.

  • +
+
+
Returns
+

This function returns true if the cache holds the referenced entry, otherwise it returns false.

+
+
+
+ +
+
+inline bool get_entry(key_type const &k, entry_type &val)#
+

Get a specific entry identified by the given key.

+
+

Note

+

The function will call the entry’s entry::touch function if the value corresponding to the provided key is found in the cache.

+
+
+
Parameters
+
    +
  • k – [in] The key for the entry which should be retrieved from the cache.

  • +
  • val – [out] If the entry indexed by the key is found in the cache this value on successful return will be a copy of the corresponding entry.

  • +
+
+
Returns
+

This function returns true if the cache holds the referenced entry, otherwise it returns false.

+
+
+
+ +
+
+inline bool get_entry(key_type const &k, value_type &val)#
+

Get a specific entry identified by the given key.

+
+

Note

+

The function will call the entry’s entry::touch function if the value corresponding to the provided is found in the cache.

+
+
+
Parameters
+
    +
  • k – [in] The key for the entry which should be retrieved from the cache

  • +
  • val – [out] If the entry indexed by the key is found in the cache this value on successful return will be a copy of the corresponding value.

  • +
+
+
Returns
+

This function returns true if the cache holds the referenced entry, otherwise it returns false.

+
+
+
+ +
+
+inline bool insert(key_type const &k, value_type const &val)#
+

Insert a new element into this cache.

+
+

Note

+

This function invokes both, the insert policy as provided to the constructor and the function entry::insert of the newly constructed entry instance. If either of these functions returns false the key/value pair doesn’t get inserted into the cache and the insert function will return false. Other reasons for this function to fail (return false) are a) the key/value pair is already held in the cache or b) inserting the new value into the cache maxed out its capacity and it was not possible to free any of the existing entries.

+
+
+
Parameters
+
    +
  • k – [in] The key for the entry which should be added to the cache.

  • +
  • val – [in] The value which should be added to the cache.

  • +
+
+
Returns
+

This function returns true if the entry has been successfully added to the cache, otherwise it returns false.

+
+
+
+ +
+
+inline bool insert(key_type const &k, value_type &&val)#
+
+ +
+
+template<typename Entry_, std::enable_if_t<std::is_convertible_v<std::decay_t<Entry_>, entry_type>, int> = 0>
inline bool insert(key_type const &k, Entry_ &&e)#
+

Insert a new entry into this cache.

+
+

Note

+

This function invokes both, the insert policy as provided to the constructor and the function entry::insert of the provided entry instance. If either of these functions returns false the key/value pair doesn’t get inserted into the cache and the insert function will return false. Other reasons for this function to fail (return false) are a) the key/value pair is already held in the cache or b) inserting the new value into the cache maxed out its capacity and it was not possible to free any of the existing entries.

+
+
+
Parameters
+
    +
  • k – [in] The key for the entry which should be added to the cache.

  • +
  • e – [in] The entry which should be added to the cache.

  • +
+
+
Returns
+

This function returns true if the entry has been successfully added to the cache, otherwise it returns false.

+
+
+
+ +
+
+template<typename Value, std::enable_if_t<std::is_convertible_v<std::decay_t<Value>, value_type>, int> = 0>
inline bool update(key_type const &k, Value &&val)#
+

Update an existing element in this cache.

+
+

Note

+

The function will call the entry’s entry::touch function if the indexed value is found in the cache.

+
+
+

Note

+

The difference to the other overload of the insert function is that this overload replaces the cached value only, while the other overload replaces the whole cache entry, updating the cache entry properties.

+
+
+
Parameters
+
    +
  • k – [in] The key for the value which should be updated in the cache.

  • +
  • val – [in] The value which should be used as a replacement for the existing value in the cache. Any existing cache entry is not changed except for its value.

  • +
+
+
Returns
+

This function returns true if the entry has been successfully updated, otherwise it returns false. If the entry currently is not held by the cache it is added and the return value reflects the outcome of the corresponding insert operation.

+
+
+
+ +
+
+template<typename F, typename Value, typename = std::enable_if_t<std::is_convertible_v<std::decay_t<Value>, value_type>>>
inline bool update_if(key_type const &k, Value &&val, F &&f)#
+

Update an existing element in this cache.

+
+

Note

+

The function will call the entry’s entry::touch function if the indexed value is found in the cache.

+
+
+

Note

+

The difference to the other overload of the insert function is that this overload replaces the cached value only, while the other overload replaces the whole cache entry, updating the cache entry properties.

+
+
+
Parameters
+
    +
  • k – [in] The key for the value which should be updated in the cache.

  • +
  • val – [in] The value which should be used as a replacement for the existing value in the cache. Any existing cache entry is not changed except for its value.

  • +
  • f – [in] A callable taking two arguments, k and the key found in the cache (in that order). If f returns true, then the update will continue. If f returns false, then the update will not succeed.

  • +
+
+
Returns
+

This function returns true if the entry has been successfully updated, otherwise it returns false. If the entry currently is not held by the cache it is added and the return value reflects the outcome of the corresponding insert operation.

+
+
+
+ +
+
+template<typename Entry_, std::enable_if_t<std::is_convertible_v<std::decay_t<Entry_>, entry_type>, int> = 0>
inline bool update(key_type const &k, Entry_ &&e)#
+

Update an existing entry in this cache.

+
+

Note

+

The function will call the entry’s entry::touch function if the indexed value is found in the cache.

+
+
+

Note

+

The difference to the other overload of the insert function is that this overload replaces the whole cache entry, while the other overload retplaces the cached value only, leaving the cache entry properties untouched.

+
+
+
Parameters
+
    +
  • k – [in] The key for the entry which should be updated in the cache.

  • +
  • e – [in] The entry which should be used as a replacement for the existing entry in the cache. Any existing entry is first removed and then this entry is added.

  • +
+
+
Returns
+

This function returns true if the entry has been successfully updated, otherwise it returns false. If the entry currently is not held by the cache it is added and the return value reflects the outcome of the corresponding insert operation.

+
+
+
+ +
+
+template<typename Func = policies::always<storage_value_type>>
inline size_type erase(Func &&ep = Func())#
+

Remove stored entries from the cache for which the supplied function object returns true.

+
+
Parameters
+

ep – [in] This parameter has to be a (unary) function object. It is invoked for each of the entries currently held in the cache. An entry is considered for removal from the cache whenever the value returned from this invocation is true. Even then the entry might not be removed from the cache as its entry::remove function might return false.

+
+
Returns
+

This function returns the overall size of the removed entries (which is the sum of the values returned by the entry::get_size functions of the removed entries).

+
+
+
+ +
+
+inline size_type erase()#
+

Remove all stored entries from the cache.

+
+

Note

+

All entries are considered for removal, but in the end an entry might not be removed from the cache as its entry::remove function might return false. This function is very useful for instance in conjunction with an entry’s entry::remove function enforcing additional criteria like entry expiration, etc.

+
+
+
Returns
+

This function returns the overall size of the removed entries (which is the sum of the values returned by the entry::get_size functions of the removed entries).

+
+
+
+ +
+
+inline void clear()#
+

Clear the cache.

+

Unconditionally removes all stored entries from the cache.

+
+ +
+
+inline constexpr statistics_type const &get_statistics() const noexcept#
+

Allow to access the embedded statistics instance.

+
+
Returns
+

This function returns a reference to the statistics instance embedded inside this cache

+
+
+
+ +
+
+inline statistics_type &get_statistics() noexcept#
+
+ +
+
+

Protected Functions

+
+
+inline bool free_space(long num_free)#
+
+ +
+
+

Private Types

+
+
+using iterator = typename storage_type::iterator#
+
+ +
+
+using const_iterator = typename storage_type::const_iterator#
+
+ +
+
+using heap_type = std::deque<iterator>#
+
+ +
+
+using heap_iterator = typename heap_type::iterator#
+
+ +
+
+using adapted_update_policy_type = adapt<UpdatePolicy, iterator>#
+
+ +
+
+using update_on_exit = typename statistics_type::update_on_exit#
+
+ +
+
+

Private Members

+
+
+size_type max_size_#
+
+ +
+
+size_type current_size_#
+
+ +
+
+storage_type store_#
+
+ +
+
+heap_type entry_heap_#
+
+ +
+
+adapted_update_policy_type update_policy_#
+
+ +
+
+insert_policy_type insert_policy_#
+
+ +
+
+statistics_type statistics_#
+
+ +
+
+
+template<typename Func, typename Iterator>
struct adapt#
+
+

Public Functions

+
+
+inline explicit adapt(Func const &f)#
+
+ +
+
+inline explicit adapt(Func &&f) noexcept#
+
+ +
+
+inline bool operator()(Iterator const &lhs, Iterator const &rhs) const#
+
+ +
+
+

Public Members

+
+
+Func f_#
+
+ +
+
+ +
+ +
+ +
+ +
+ +
+
+
hpx/cache/lru_cache.hpp#
+

Defined in header hpx/cache/lru_cache.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+
+namespace cache
+
+
+template<typename Key, typename Entry, typename Statistics = statistics::no_statistics>
class lru_cache#
+
+#include <hpx/cache/lru_cache.hpp>
+

The lru_cache implements the basic functionality needed for a local (non-distributed) LRU cache.

+
+
Template Parameters
+
    +
  • Key – The type of the keys to use to identify the entries stored in the cache

  • +
  • Entry – The type of the items to be held in the cache.

  • +
  • Statistics – A (optional) type allowing to collect some basic statistics about the operation of the cache instance. The type must conform to the CacheStatistics concept. The default value is the type statistics::no_statistics which does not collect any numbers, but provides empty stubs allowing the code to compile.

  • +
+
+
+
+

Public Types

+
+
+using key_type = Key#
+
+ +
+
+using entry_type = Entry#
+
+ +
+
+using statistics_type = Statistics#
+
+ +
+
+using entry_pair = std::pair<key_type, entry_type>#
+
+ +
+
+using storage_type = std::list<entry_pair>#
+
+ +
+
+using map_type = std::map<Key, typename storage_type::iterator>#
+
+ +
+
+using size_type = std::size_t#
+
+ +
+
+

Public Functions

+
+
+inline explicit lru_cache(size_type max_size = 0)#
+

Construct an instance of a lru_cache.

+
+
Parameters
+

max_size – [in] The maximal size this cache is allowed to reach any time. The default is zero (no size limitation). The unit of this value is usually determined by the unit of the values returned by the entry’s get_size function.

+
+
+
+ +
+
+lru_cache(lru_cache const &other) = default#
+
+ +
+
+lru_cache(lru_cache &&other) = default#
+
+ +
+
+lru_cache &operator=(lru_cache const &other) = default#
+
+ +
+
+lru_cache &operator=(lru_cache &&other) = default#
+
+ +
+
+~lru_cache() = default#
+
+ +
+
+inline constexpr size_type size() const noexcept#
+

Return current size of the cache.

+
+
Returns
+

The current size of this cache instance.

+
+
+
+ +
+
+inline constexpr size_type capacity() const noexcept#
+

Access the maximum size the cache is allowed to grow to.

+
+

Note

+

The unit of this value is usually determined by the unit of the return values of the entry’s function entry::get_size.

+
+
+
Returns
+

The maximum size this cache instance is currently allowed to reach. If this number is zero the cache has no limitation with regard to a maximum size.

+
+
+
+ +
+
+inline void reserve(size_type max_size)#
+

Change the maximum size this cache can grow to.

+
+
Parameters
+

max_size – [in] The new maximum size this cache will be allowed to grow to.

+
+
+
+ +
+
+inline bool holds_key(key_type const &key) const#
+

Check whether the cache currently holds an entry identified by the given key.

+
+

Note

+

This function does not call the entry’s function entry::touch. It just checks if the cache contains an entry corresponding to the given key.

+
+
+
Parameters
+

key – [in] The key for the entry which should be looked up in the cache.

+
+
Returns
+

This function returns true if the cache holds the referenced entry, otherwise it returns false.

+
+
+
+ +
+
+inline bool get_entry(key_type const &key, key_type &realkey, entry_type &entry)#
+

Get a specific entry identified by the given key.

+
+

Note

+

The function will “touch” the entry and mark it as recently used if the key was found in the cache.

+
+
+
Parameters
+
    +
  • key – [in] The key for the entry which should be retrieved from the cache.

  • +
  • realkey[out] – Return the full real key found in the cache

  • +
  • entry – [out] If the entry indexed by the key is found in the cache this value on successful return will be a copy of the corresponding entry.

  • +
+
+
Returns
+

This function returns true if the cache holds the referenced entry, otherwise it returns false.

+
+
+
+ +
+
+inline bool get_entry(key_type const &key, entry_type const &entry)#
+

Get a specific entry identified by the given key.

+
+

Note

+

The function will “touch” the entry and mark it as recently used if the key was found in the cache.

+
+
+
Parameters
+
    +
  • key – [in] The key for the entry which should be retrieved from the cache.

  • +
  • entry – [out] If the entry indexed by the key is found in the cache this value on successful return will be a copy of the corresponding entry.

  • +
+
+
Returns
+

This function returns true if the cache holds the referenced entry, otherwise it returns false.

+
+
+
+ +
+
+template<typename Entry_, typename = std::enable_if_t<std::is_convertible_v<std::decay_t<Entry_>, entry_type>>>
inline bool insert(key_type const &key, Entry_ &&entry)#
+

Insert a new entry into this cache.

+
+

Note

+

This function assumes that the entry is not in the cache already. Inserting an already existing entry is considered undefined behavior

+
+
+
Parameters
+
    +
  • key – [in] The key for the entry which should be added to the cache.

  • +
  • entry – [in] The entry which should be added to the cache.

  • +
+
+
+
+ +
+
+template<typename Entry_, typename = std::enable_if_t<std::is_convertible_v<std::decay_t<Entry_>, entry_type>>>
inline void update(key_type const &key, Entry_ &&entry)#
+

Update an existing element in this cache.

+
+

Note

+

The function will “touch” the entry and mark it as recently used if the key was found in the cache.

+
+
+

Note

+

The difference to the other overload of the insert function is that this overload replaces the cached value only, while the other overload replaces the whole cache entry, updating the cache entry properties.

+
+
+
Parameters
+
    +
  • key – [in] The key for the value which should be updated in the cache.

  • +
  • entry – [in] The entry which should be used as a replacement for the existing value in the cache. Any existing cache entry is not changed except for its value.

  • +
+
+
+
+ +
+
+template<typename F, typename Entry_, std::enable_if_t<std::is_convertible_v<std::decay_t<Entry_>, entry_type>, int> = 0>
inline bool update_if(key_type const &key, Entry_ &&entry, F &&f)#
+

Update an existing element in this cache.

+
+

Note

+

The function will “touch” the entry and mark it as recently used if the key was found in the cache.

+
+
+

Note

+

The difference to the other overload of the insert function is that this overload replaces the cached value only, while the other overload replaces the whole cache entry, updating the cache entry properties.

+
+
+
Parameters
+
    +
  • key – [in] The key for the value which should be updated in the cache.

  • +
  • entry – [in] The value which should be used as a replacement for the existing value in the cache. Any existing cache entry is not changed except for its value.

  • +
  • f – [in] A callable taking two arguments, k and the key found in the cache (in that order). If f returns true, then the update will continue. If f returns false, then the update will not succeed.

  • +
+
+
Returns
+

This function returns true if the entry has been successfully updated, otherwise it returns false. If the entry currently is not held by the cache it is added and the return value reflects the outcome of the corresponding insert operation.

+
+
+
+ +
+
+template<typename Func>
inline size_type erase(Func const &ep)#
+

Remove stored entries from the cache for which the supplied function object returns true.

+
+
Parameters
+

ep – [in] This parameter has to be a (unary) function object. It is invoked for each of the entries currently held in the cache. An entry is considered for removal from the cache whenever the value returned from this invocation is true.

+
+
Returns
+

This function returns the overall size of the removed entries (which is the sum of the values returned by the entry::get_size functions of the removed entries).

+
+
+
+ +
+
+inline size_type erase()#
+

Remove all stored entries from the cache.

+
+
Returns
+

This function returns the overall size of the removed entries (which is the sum of the values returned by the entry::get_size functions of the removed entries).

+
+
+
+ +
+
+inline size_type clear()#
+

Clear the cache.

+

Unconditionally removes all stored entries from the cache.

+
+ +
+
+inline constexpr statistics_type const &get_statistics() const noexcept#
+

Allow to access the embedded statistics instance.

+
+
Returns
+

This function returns a reference to the statistics instance embedded inside this cache

+
+
+
+ +
+
+inline statistics_type &get_statistics() noexcept#
+
+ +
+
+

Private Types

+
+
+using update_on_exit = typename statistics_type::update_on_exit#
+
+ +
+
+

Private Functions

+
+
+template<typename Entry_, typename = std::enable_if_t<std::is_convertible_v<std::decay_t<Entry_>, entry_type>>>
inline void insert_nonexist(key_type const &key, Entry_ &&entry)#
+
+ +
+
+inline void touch(typename storage_type::iterator it)#
+
+ +
+
+inline void evict()#
+
+ +
+
+

Private Members

+
+
+size_type max_size_#
+
+ +
+
+size_type current_size_ = 0#
+
+ +
+
+storage_type storage_#
+
+ +
+
+map_type map_#
+
+ +
+
+statistics_type statistics_#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/cache/entries/entry.hpp#
+

Defined in header hpx/cache/entries/entry.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+
+namespace cache#
+
+
+namespace entries#
+
+
+class entry#
+
+#include <hpx/cache/entries/entry.hpp>
+
+
Template Parameters
+
    +
  • Value – The data type to be stored in a cache. It has to be default constructible, copy constructible and less_than_comparable.

  • +
  • Derived – The (optional) type for which this type is used as a base class.

  • +
+
+
+
+

Public Types

+
+
+using value_type = Value#
+
+ +
+
+

Public Functions

+
+
+entry() = default#
+

Any cache entry has to be default constructible.

+
+ +
+
+inline explicit entry(value_type const &val) noexcept(std::is_nothrow_copy_constructible_v<value_type>)#
+

Construct a new instance of a cache entry holding the given value.

+
+ +
+
+inline explicit entry(value_type &&val) noexcept#
+

Construct a new instance of a cache entry holding the given value.

+
+ +
+
+inline value_type &get() noexcept#
+

Get a reference to the stored data value.

+
+

Note

+

This function is part of the CacheEntry concept

+
+
+ +
+
+inline constexpr value_type const &get() const noexcept#
+
+ +
+
+

Public Static Functions

+
+
+static inline constexpr bool touch() noexcept#
+

The function touch is called by a cache holding this instance whenever it has been requested (touched).

+
+

Note

+

It is possible to change the entry in a way influencing the sort criteria mandated by the UpdatePolicy. In this case the function should return true to indicate this to the cache, forcing to reorder the cache entries.

+
+
+

Note

+

This function is part of the CacheEntry concept

+
+
+
Returns
+

This function should return true if the cache needs to update it’s internal heap. Usually this is needed if the entry has been changed by touch() in a way influencing the sort order as mandated by the cache’s UpdatePolicy

+
+
+
+ +
+
+static inline constexpr bool insert() noexcept#
+

The function insert is called by a cache whenever it is about to be inserted into the cache.

+
+

Note

+

This function is part of the CacheEntry concept

+
+
+
Returns
+

This function should return true if the entry should be added to the cache, otherwise it should return false.

+
+
+
+ +
+
+static inline constexpr bool remove() noexcept#
+

The function remove is called by a cache holding this instance whenever it is about to be removed from the cache.

+
+

Note

+

This function is part of the CacheEntry concept

+
+
+
Returns
+

The return value can be used to avoid removing this instance from the cache. If the value is true it is ok to remove the entry, other wise it will stay in the cache.

+
+
+
+ +
+
+static inline constexpr std::size_t get_size() noexcept#
+

Return the ‘size’ of this entry. By default the size of each entry is just one (1), which is sensible if the cache has a limit (capacity) measured in number of entries.

+
+ +
+
+

Private Members

+
+
+value_type value_#
+
+ +
+
+

Friends

+
+
+inline friend bool operator<(entry const &lhs, entry const &rhs) noexcept(noexcept(std::declval<value_type const&>() < std::declval<value_type const&>()))#
+

Forwarding operator< allowing to compare entries instead of the values.

+
+ +
+
+ +
+ +
+ +
+ +
+ +
+
+
hpx/cache/entries/fifo_entry.hpp#
+

Defined in header hpx/cache/entries/fifo_entry.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+
+namespace cache
+
+
+namespace entries
+
+
+template<typename Value>
class fifo_entry : public hpx::util::cache::entries::entry<Value, fifo_entry<Value>>#
+
+#include <hpx/cache/entries/fifo_entry.hpp>
+

The fifo_entry type can be used to store arbitrary values in a cache. Using this type as the cache’s entry type makes sure that the least recently inserted entries are discarded from the cache first.

+
+

Note

+

The fifo_entry conforms to the CacheEntry concept.

+
+
+

Note

+

This type can be used to model a ‘last in first out’ cache policy if it is used with a std::greater as the caches’ UpdatePolicy (instead of the default std::less).

+
+
+
Template Parameters
+

Value – The data type to be stored in a cache. It has to be default constructible, copy constructible and less_than_comparable.

+
+
+
+

Public Functions

+
+
+fifo_entry() = default#
+

Any cache entry has to be default constructible.

+
+ +
+
+inline explicit fifo_entry(Value const &val) noexcept(std::is_nothrow_constructible_v<base_type, Value const&>)#
+

Construct a new instance of a cache entry holding the given value.

+
+ +
+
+inline explicit fifo_entry(Value &&val) noexcept#
+

Construct a new instance of a cache entry holding the given value.

+
+ +
+
+inline constexpr bool insert()#
+

The function insert is called by a cache whenever it is about to be inserted into the cache.

+
+

Note

+

This function is part of the CacheEntry concept

+
+
+
Returns
+

This function should return true if the entry should be added to the cache, otherwise it should return false.

+
+
+
+ +
+
+inline constexpr time_point const &get_creation_time() const noexcept#
+
+ +
+
+

Private Types

+
+
+using base_type = entry<Value, fifo_entry<Value>>#
+
+ +
+
+using time_point = std::chrono::steady_clock::time_point#
+
+ +
+
+

Private Members

+
+
+time_point insertion_time_#
+
+ +
+
+

Friends

+
+
+inline friend bool operator<(fifo_entry const &lhs, fifo_entry const &rhs) noexcept(noexcept(std::declval<time_point const&>() < std::declval<time_point const&>()))#
+

Compare the ‘age’ of two entries. An entry is ‘older’ than another entry if it has been created earlier (FIFO).

+
+ +
+
+ +
+ +
+ +
+ +
+ +
+
+
hpx/cache/entries/lfu_entry.hpp#
+

Defined in header hpx/cache/entries/lfu_entry.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+
+namespace cache
+
+
+namespace entries
+
+
+template<typename Value>
class lfu_entry : public hpx::util::cache::entries::entry<Value, lfu_entry<Value>>#
+
+#include <hpx/cache/entries/lfu_entry.hpp>
+

The lfu_entry type can be used to store arbitrary values in a cache. Using this type as the cache’s entry type makes sure that the least frequently used entries are discarded from the cache first.

+
+

Note

+

The lfu_entry conforms to the CacheEntry concept.

+
+
+

Note

+

This type can be used to model a ‘most frequently used’ cache policy if it is used with a std::greater as the caches’ UpdatePolicy (instead of the default std::less).

+
+
+
Template Parameters
+

Value – The data type to be stored in a cache. It has to be default constructible, copy constructible and less_than_comparable.

+
+
+
+

Public Functions

+
+
+lfu_entry() = default#
+

Any cache entry has to be default constructible.

+
+ +
+
+inline explicit lfu_entry(Value const &val) noexcept(std::is_nothrow_constructible_v<base_type, Value const&>)#
+

Construct a new instance of a cache entry holding the given value.

+
+ +
+
+inline explicit lfu_entry(Value &&val) noexcept#
+

Construct a new instance of a cache entry holding the given value.

+
+ +
+
+inline bool touch() noexcept#
+

The function touch is called by a cache holding this instance whenever it has been requested (touched).

+

In the case of the LFU entry we store the reference count tracking the number of times this entry has been requested. This which will be used to compare the age of an entry during the invocation of the operator<().

+
+
Returns
+

This function should return true if the cache needs to update it’s internal heap. Usually this is needed if the entry has been changed by touch() in a way influencing the sort order as mandated by the cache’s UpdatePolicy

+
+
+
+ +
+
+inline constexpr unsigned long const &get_access_count() const noexcept#
+
+ +
+
+

Private Types

+
+
+using base_type = entry<Value, lfu_entry<Value>>#
+
+ +
+
+

Private Members

+
+
+unsigned long ref_count_ = 0#
+
+ +
+
+

Friends

+
+
+inline friend bool operator<(lfu_entry const &lhs, lfu_entry const &rhs) noexcept#
+

Compare the ‘age’ of two entries. An entry is ‘older’ than another entry if it has been accessed less frequently (LFU).

+
+ +
+
+ +
+ +
+ +
+ +
+ +
+
+
hpx/cache/entries/lru_entry.hpp#
+

Defined in header hpx/cache/entries/lru_entry.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+
+namespace cache
+
+
+namespace entries
+
+
+template<typename Value>
class lru_entry : public hpx::util::cache::entries::entry<Value, lru_entry<Value>>#
+
+#include <hpx/cache/entries/lru_entry.hpp>
+

The lru_entry type can be used to store arbitrary values in a cache. Using this type as the cache’s entry type makes sure that the least recently used entries are discarded from the cache first.

+
+

Note

+

The lru_entry conforms to the CacheEntry concept.

+
+
+

Note

+

This type can be used to model a ‘most recently used’ cache policy if it is used with a std::greater as the caches’ UpdatePolicy (instead of the default std::less).

+
+
+
Template Parameters
+

Value – The data type to be stored in a cache. It has to be default constructible, copy constructible and less_than_comparable.

+
+
+
+

Public Functions

+
+
+inline lru_entry()#
+

Any cache entry has to be default constructible.

+
+ +
+
+inline explicit lru_entry(Value const &val) noexcept(std::is_nothrow_constructible_v<base_type, Value const&>)#
+

Construct a new instance of a cache entry holding the given value.

+
+ +
+
+inline explicit lru_entry(Value &&val) noexcept#
+

Construct a new instance of a cache entry holding the given value.

+
+ +
+
+inline bool touch()#
+

The function touch is called by a cache holding this instance whenever it has been requested (touched).

+

In the case of the LRU entry we store the time of the last access which will be used to compare the age of an entry during the invocation of the operator<().

+
+
Returns
+

This function should return true if the cache needs to update it’s internal heap. Usually this is needed if the entry has been changed by touch() in a way influencing the sort order as mandated by the cache’s UpdatePolicy

+
+
+
+ +
+
+inline constexpr time_point const &get_access_time() const noexcept#
+

Returns the last access time of the entry.

+
+ +
+
+

Private Types

+
+
+using base_type = entry<Value, lru_entry<Value>>#
+
+ +
+
+using time_point = std::chrono::steady_clock::time_point#
+
+ +
+
+

Private Members

+
+
+time_point access_time_#
+
+ +
+
+

Friends

+
+
+inline friend bool operator<(lru_entry const &lhs, lru_entry const &rhs) noexcept(noexcept(std::declval<time_point const&>() < std::declval<time_point const&>()))#
+

Compare the ‘age’ of two entries. An entry is ‘older’ than another entry if it has been accessed less recently (LRU).

+
+ +
+
+ +
+ +
+ +
+ +
+ +
+
+
hpx/cache/entries/size_entry.hpp#
+

Defined in header hpx/cache/entries/size_entry.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+
+namespace cache
+
+
+namespace entries
+
+
+class size_entry#
+
+#include <hpx/cache/entries/size_entry.hpp>
+

The size_entry type can be used to store values in a cache which have a size associated (such as files, etc.). Using this type as the cache’s entry type makes sure that the entries with the biggest size are discarded from the cache first.

+
+

Note

+

The size_entry conforms to the CacheEntry concept.

+
+
+

Note

+

This type can be used to model a ‘discard smallest first’ cache policy if it is used with a std::greater as the caches’ UpdatePolicy (instead of the default std::less).

+
+
+
Template Parameters
+
    +
  • Value – The data type to be stored in a cache. It has to be default constructible, copy constructible and less_than_comparable.

  • +
  • Derived – The (optional) type for which this type is used as a base class.

  • +
+
+
+
+

Public Functions

+
+
+size_entry() = default#
+

Any cache entry has to be default constructible.

+
+ +
+
+inline explicit size_entry(Value const &val, std::size_t size = 0) noexcept(std::is_nothrow_constructible_v<base_type, Value const&>)#
+

Construct a new instance of a cache entry holding the given value.

+
+ +
+
+inline explicit size_entry(Value &&val, std::size_t size = 0) noexcept#
+

Construct a new instance of a cache entry holding the given value.

+
+ +
+
+inline constexpr std::size_t get_size() const noexcept#
+

Return the ‘size’ of this entry.

+
+ +
+
+

Private Types

+
+
+using derived_type = typename detail::size_derived<Value, Derived>::type#
+
+ +
+
+using base_type = entry<Value, derived_type>#
+
+ +
+
+

Private Members

+
+
+std::size_t size_ = 0#
+
+ +
+
+

Friends

+
+
+inline friend constexpr friend bool operator< (size_entry const &lhs, size_entry const &rhs) noexcept
+

Compare the ‘age’ of two entries. An entry is ‘older’ than another entry if it has a bigger size.

+
+ +
+
+ +
+ +
+ +
+ +
+ +
+
+
hpx/cache/statistics/local_statistics.hpp#
+

Defined in header hpx/cache/statistics/local_statistics.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+
+namespace cache
+
+
+namespace statistics#
+
+
+class local_statistics : public hpx::util::cache::statistics::no_statistics#
+
+

Public Functions

+
+
+local_statistics() = default#
+
+ +
+
+inline constexpr std::size_t hits() const noexcept#
+
+ +
+
+inline constexpr std::size_t misses() const noexcept#
+
+ +
+
+inline constexpr std::size_t insertions() const noexcept#
+
+ +
+
+inline constexpr std::size_t evictions() const noexcept#
+
+ +
+
+inline std::size_t hits(bool reset) noexcept#
+
+ +
+
+inline std::size_t misses(bool reset) noexcept#
+
+ +
+
+inline std::size_t insertions(bool reset) noexcept#
+
+ +
+
+inline std::size_t evictions(bool reset) noexcept#
+
+ +
+
+inline void got_hit() noexcept#
+

The function got_hit will be called by a cache instance whenever a entry got touched.

+
+ +
+
+inline void got_miss() noexcept#
+

The function got_miss will be called by a cache instance whenever a requested entry has not been found in the cache.

+
+ +
+
+inline void got_insertion() noexcept#
+

The function got_insertion will be called by a cache instance whenever a new entry has been inserted.

+
+ +
+
+inline void got_eviction() noexcept#
+

The function got_eviction will be called by a cache instance whenever an entry has been removed from the cache because a new inserted entry let the cache grow beyond its capacity.

+
+ +
+
+inline void clear() noexcept#
+

Reset all statistics.

+
+ +
+
+

Private Members

+
+
+std::size_t hits_ = 0#
+
+ +
+
+std::size_t misses_ = 0#
+
+ +
+
+std::size_t insertions_ = 0#
+
+ +
+
+std::size_t evictions_ = 0#
+
+ +
+
+

Private Static Functions

+
+
+static inline std::size_t get_and_reset(std::size_t &value, bool reset) noexcept#
+
+ +
+
+ +
+ +
+ +
+ +
+ +
+
+
hpx/cache/statistics/no_statistics.hpp#
+

Defined in header hpx/cache/statistics/no_statistics.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_CACHE_METHOD_UNSCOPED_ENUM_DEPRECATION_MSG#
+
+ +
+
+
+namespace hpx
+
+
+namespace util
+
+
+namespace cache
+
+
+namespace statistics
+
+

Enums

+
+
+enum class method#
+

Values:

+
+
+enumerator get_entry#
+
+ +
+
+enumerator insert_entry#
+
+ +
+
+enumerator update_entry#
+
+ +
+
+enumerator erase_entry#
+
+ +
+ +
+
+

Variables

+
+
+constexpr method method_get_entry = method::get_entry#
+
+ +
+
+constexpr method method_insert_entry = method::insert_entry#
+
+ +
+
+constexpr method method_update_entry = method::update_entry#
+
+ +
+
+constexpr method method_erase_entry = method::erase_entry#
+
+ +
+
+
+class no_statistics#
+

Subclassed by hpx::util::cache::statistics::local_statistics

+
+

Public Static Functions

+
+
+static inline constexpr void got_hit() noexcept#
+

The function got_hit will be called by a cache instance whenever a entry got touched.

+
+ +
+
+static inline constexpr void got_miss() noexcept#
+

The function got_miss will be called by a cache instance whenever a requested entry has not been found in the cache.

+
+ +
+
+static inline constexpr void got_insertion() noexcept#
+

The function got_insertion will be called by a cache instance whenever a new entry has been inserted.

+
+ +
+
+static inline constexpr void got_eviction() noexcept#
+

The function got_eviction will be called by a cache instance whenever an entry has been removed from the cache because a new inserted entry let the cache grow beyond its capacity.

+
+ +
+
+static inline constexpr void clear() noexcept#
+

Reset all statistics.

+
+ +
+
+static inline constexpr std::int64_t get_get_entry_count(bool) noexcept#
+

The function get_get_entry_count returns the number of invocations of the get_entry() API function of the cache.

+
+ +
+
+static inline constexpr std::int64_t get_insert_entry_count(bool) noexcept#
+

The function get_insert_entry_count returns the number of invocations of the insert_entry() API function of the cache.

+
+ +
+
+static inline constexpr std::int64_t get_update_entry_count(bool) noexcept#
+

The function get_update_entry_count returns the number of invocations of the update_entry() API function of the cache.

+
+ +
+
+static inline constexpr std::int64_t get_erase_entry_count(bool) noexcept#
+

The function get_erase_entry_count returns the number of invocations of the erase() API function of the cache.

+
+ +
+
+static inline constexpr std::int64_t get_get_entry_time(bool) noexcept#
+

The function get_get_entry_time returns the overall time spent executing of the get_entry() API function of the cache.

+
+ +
+
+static inline constexpr std::int64_t get_insert_entry_time(bool) noexcept#
+

The function get_insert_entry_time returns the overall time spent executing of the insert_entry() API function of the cache.

+
+ +
+
+static inline constexpr std::int64_t get_update_entry_time(bool) noexcept#
+

The function get_update_entry_time returns the overall time spent executing of the update_entry() API function of the cache.

+
+ +
+
+static inline constexpr std::int64_t get_erase_entry_time(bool) noexcept#
+

The function get_erase_entry_time returns the overall time spent executing of the erase() API function of the cache.

+
+ +
+
+
+struct update_on_exit#
+
+#include <no_statistics.hpp>
+

Helper class to update timings and counts on function exit.

+
+

Public Functions

+
+
+inline constexpr update_on_exit(no_statistics const&, method) noexcept#
+
+ +
+
+ +
+ +
+ +
+ +
+ +
+ +
+
+
+
+
compute_local#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/compute_local/vector.hpp#
+

Defined in header hpx/compute_local/vector.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace compute
+
+

Functions

+
+
+template<typename T, typename Allocator>
void swap(vector<T, Allocator> &x, vector<T, Allocator> &y) noexcept#
+

Effects: x.swap(y);.

+
+ +
+
+
+template<typename T, typename Allocator = std::allocator<T>>
class vector#
+
+

Public Types

+
+
+using value_type = T#
+

Member types (FIXME: add reference to std.

+
+ +
+
+using allocator_type = Allocator#
+
+ +
+
+using access_target = typename alloc_traits::access_target#
+
+ +
+
+using size_type = std::size_t#
+
+ +
+
+using difference_type = std::ptrdiff_t#
+
+ +
+
+using reference = typename alloc_traits::reference#
+
+ +
+
+using const_reference = typename alloc_traits::const_reference#
+
+ +
+
+using pointer = typename alloc_traits::pointer#
+
+ +
+
+using const_pointer = typename alloc_traits::const_pointer#
+
+ +
+
+using iterator = detail::iterator<T, Allocator>#
+
+ +
+
+using const_iterator = detail::iterator<T const, Allocator>#
+
+ +
+
+using reverse_iterator = detail::reverse_iterator<T, Allocator>#
+
+ +
+
+using const_reverse_iterator = detail::const_reverse_iterator<T, Allocator>#
+
+ +
+
+

Public Functions

+
+
+inline explicit vector(Allocator const &alloc = Allocator())#
+
+ +
+
+inline vector(size_type count, T const &value, Allocator const &alloc = Allocator())#
+
+ +
+
+inline explicit vector(size_type count, Allocator const &alloc = Allocator())#
+
+ +
+
+template<typename InIter, typename Enable = typename std::enable_if<hpx::traits::is_input_iterator<InIter>::value>::type>
inline vector(InIter first, InIter last, Allocator const &alloc)#
+
+ +
+
+inline vector(vector const &other)#
+
+ +
+
+inline vector(vector const &other, Allocator const &alloc)#
+
+ +
+
+inline vector(vector &&other) noexcept#
+
+ +
+
+inline vector(vector &&other, Allocator const &alloc)#
+
+ +
+
+inline vector(std::initializer_list<T> init, Allocator const &alloc)#
+
+ +
+
+inline ~vector()#
+
+ +
+
+inline vector &operator=(vector const &other)#
+
+ +
+
+inline vector &operator=(vector &&other) noexcept#
+
+ +
+
+inline allocator_type get_allocator() const noexcept#
+

Returns the allocator associated with the container.

+
+ +
+
+inline reference operator[](size_type pos)#
+
+ +
+
+inline const_reference operator[](size_type pos) const#
+
+ +
+
+inline pointer data() noexcept#
+

Returns pointer to the underlying array serving as element storage. The pointer is such that range [data(); data() + size()) is always a valid range, even if the container is empty (data() is not dereference-able in that case).

+
+ +
+
+inline const_pointer data() const noexcept#
+

Returns pointer to the underlying array serving as element storage. The pointer is such that range [data(); data() + size()) is always a valid range, even if the container is empty (data() is not dereference-able in that case).

+
+ +
+
+inline T *device_data() const noexcept#
+

Returns a raw pointer corresponding to the address of the data allocated on the device.

+
+ +
+
+inline std::size_t size() const noexcept#
+
+ +
+
+inline std::size_t capacity() const noexcept#
+
+ +
+
+inline bool empty() const noexcept#
+

Returns: size() == 0.

+
+ +
+
+inline void resize(size_type, T const&)#
+

Effects: If size <= size(), equivalent to calling pop_back() size() - size times. If size() < size, appends size - size() copies of val to the sequence.

+

Requires: T shall be CopyInsertable into *this.

+

Remarks: If an exception is thrown there are no effects.

+
+ +
+
+inline iterator begin() noexcept#
+
+ +
+
+inline iterator end() noexcept#
+
+ +
+
+inline const_iterator cbegin() const noexcept#
+
+ +
+
+inline const_iterator cend() const noexcept#
+
+ +
+
+inline const_iterator begin() const noexcept#
+
+ +
+
+inline const_iterator end() const noexcept#
+
+ +
+
+inline void swap(vector &other) noexcept#
+

Effects: Exchanges the contents and capacity() of *this with that of x.

+

Complexity: Constant time.

+
+ +
+
+inline void clear() noexcept#
+

Effects: Erases all elements in the range [begin(),end()). Destroys all elements in ‘a’. Invalidates all references, pointers, and iterators referring to the elements of a and may invalidate the past-the-end iterator.

+

Post: a.empty() returns true.

+

Complexity: Linear.

+
+ +
+
+

Public Static Functions

+
+
+static inline void resize(size_type)#
+

Effects: If size <= size(), equivalent to calling pop_back() size()

    +
  • size times. If size() < size, appends size - size() default-inserted elements to the sequence.

  • +
+

+

Requires: T shall be MoveInsertable and DefaultInsertable into *this.

+

Remarks: If an exception is thrown other than by the move constructor of a non-CopyInsertable T there are no effects.

+
+ +
+
+

Private Types

+
+
+using alloc_traits = traits::allocator_traits<Allocator>#
+
+ +
+
+

Private Members

+
+
+size_type size_#
+
+ +
+
+size_type capacity_#
+
+ +
+
+allocator_type alloc_#
+
+ +
+
+pointer data_#
+
+ +
+
+ +
+ +
+ +
+
+
hpx/compute_local/host/block_executor.hpp#
+

Defined in header hpx/compute_local/host/block_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<typename Executor>
struct hpx::parallel::execution::executor_execution_category<compute::host::block_executor<Executor>>#
+
+

Public Types

+
+
+using type = hpx::execution::parallel_execution_tag#
+
+ +
+
+ +
+
+template<typename Executor>
struct is_one_way_executor<compute::host::block_executor<Executor>> : public true_type#
+
+ +
+
+template<typename Executor>
struct is_two_way_executor<compute::host::block_executor<Executor>> : public true_type#
+
+ +
+
+template<typename Executor>
struct is_bulk_one_way_executor<compute::host::block_executor<Executor>> : public true_type#
+
+ +
+
+template<typename Executor>
struct is_bulk_two_way_executor<compute::host::block_executor<Executor>> : public true_type#
+
+ +
+
+namespace hpx
+
+
+namespace compute#
+
+
+namespace host#
+
+
+template<typename Executor = hpx::parallel::execution::restricted_thread_pool_executor>
struct block_executor#
+
+#include <block_executor.hpp>
+

The block executor can be used to build NUMA aware programs. It will distribute work evenly across the passed targets

+
+
Template Parameters
+

Executor – The underlying executor to use

+
+
+
+

Public Types

+
+
+using executor_parameters_type = hpx::execution::experimental::default_parameters#
+
+ +
+
+

Public Functions

+
+
+inline explicit block_executor(std::vector<host::target> const &targets, threads::thread_priority priority = threads::thread_priority::high, threads::thread_stacksize stacksize = threads::thread_stacksize::default_, threads::thread_schedule_hint schedulehint = {})#
+
+ +
+
+inline explicit block_executor(std::vector<host::target> &&targets)#
+
+ +
+
+inline block_executor(block_executor const &other)#
+
+ +
+
+inline block_executor(block_executor &&other) noexcept#
+
+ +
+
+inline block_executor &operator=(block_executor const &other)#
+
+ +
+
+inline block_executor &operator=(block_executor &&other) noexcept#
+
+ +
+
+inline std::vector<host::target> const &targets() const noexcept#
+
+ +
+
+

Private Functions

+
+
+inline auto get_next_executor() const#
+
+ +
+
+template<typename F, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::post_t, block_executor const &exec, F &&f, Ts&&... ts)#
+
+ +
+
+template<typename F, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::async_execute_t, block_executor const &exec, F &&f, Ts&&... ts)#
+
+ +
+
+template<typename F, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::sync_execute_t, block_executor const &exec, F &&f, Ts&&... ts)#
+
+ +
+
+template<typename F, typename Shape, typename ...Ts>
inline decltype(auto) bulk_async_execute_impl(F &&f, Shape const &shape, Ts&&... ts) const#
+
+ +
+
+template<typename F, typename Shape, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::bulk_async_execute_t, block_executor const &exec, F &&f, Shape const &shape, Ts&&... ts)#
+
+ +
+
+template<typename F, typename Shape, typename ...Ts>
inline decltype(auto) bulk_sync_execute_impl(F &&f, Shape const &shape, Ts&&... ts) const#
+
+ +
+
+template<typename F, typename Shape, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::bulk_sync_execute_t, block_executor const &exec, F &&f, Shape const &shape, Ts&&... ts)#
+
+ +
+
+inline void init_executors()#
+
+ +
+
+

Private Members

+
+
+std::vector<host::target> targets_#
+
+ +
+
+mutable std::atomic<std::size_t> current_#
+
+ +
+
+std::vector<Executor> executors_#
+
+ +
+
+threads::thread_priority priority_ = threads::thread_priority::high#
+
+ +
+
+threads::thread_stacksize stacksize_ = threads::thread_stacksize::default_#
+
+ +
+
+threads::thread_schedule_hint schedulehint_ = {}#
+
+ +
+
+ +
+ +
+ +
+
+namespace parallel
+
+
+namespace execution
+
+
+template<typename Executor> block_executor< Executor > >
+
+

Public Types

+
+
+using type = hpx::execution::parallel_execution_tag#
+
+ +
+
+ +
+
+template<typename Executor> block_executor< Executor > > : public true_type
+
+ +
+
+template<typename Executor> block_executor< Executor > > : public true_type
+
+ +
+
+template<typename Executor> block_executor< Executor > > : public true_type
+
+ +
+
+template<typename Executor> block_executor< Executor > > : public true_type
+
+ +
+ +
+ +
+ +
+
+
hpx/compute_local/host/block_fork_join_executor.hpp#
+

Defined in header hpx/compute_local/host/block_fork_join_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+
+class block_fork_join_executor#
+
+#include <block_fork_join_executor.hpp>
+

An executor with fork-join (blocking) semantics.

+

The block_fork_join_executor creates on construction a set of worker threads that are kept alive for the duration of the executor. Copying the executor has reference semantics, i.e. copies of a fork_join_executor hold a reference to the worker threads of the original instance. Scheduling work through the executor concurrently from different threads is undefined behaviour.

+

The executor keeps a set of worker threads alive for the lifetime of the executor, meaning other work will not be executed while the executor is busy or waiting for work. The executor has a customizable delay after which it will yield to other work. Since starting and resuming the worker threads is a slow operation the executor should be reused whenever possible for multiple adjacent parallel algorithms or invocations of bulk_(a)sync_execute.

+

This behaviour is similar to the plain fork_join_executor except that the block_fork_join_executor creates a hierarchy of fork_join_executors, one for each target used to initialize it.

+
+

Public Functions

+
+
+inline explicit block_fork_join_executor(threads::thread_priority priority = threads::thread_priority::bound, threads::thread_stacksize stacksize = threads::thread_stacksize::small_, fork_join_executor::loop_schedule const schedule = fork_join_executor::loop_schedule::static_, std::chrono::nanoseconds yield_delay = std::chrono::milliseconds(1))#
+

Construct a block_fork_join_executor.

+
+

Note

+

This constructor will create one fork_join_executor for each numa domain

+
+
+
Parameters
+
    +
  • priority – The priority of the worker threads.

  • +
  • stacksize – The stacksize of the worker threads. Must not be nostack.

  • +
  • schedule – The loop schedule of the parallel regions.

  • +
  • yield_delay – The time after which the executor yields to other work if it has not received any new work for execution.

  • +
+
+
+
+ +
+
+inline explicit block_fork_join_executor(std::vector<compute::host::target> const &targets, threads::thread_priority priority = threads::thread_priority::bound, threads::thread_stacksize stacksize = threads::thread_stacksize::small_, fork_join_executor::loop_schedule const schedule = fork_join_executor::loop_schedule::static_, std::chrono::nanoseconds yield_delay = std::chrono::milliseconds(1))#
+

Construct a block_fork_join_executor.

+
+

Note

+

This constructor will create one fork_join_executor for each given target

+
+
+
Parameters
+
    +
  • targets – The list of targets to use for thread placement

  • +
  • priority – The priority of the worker threads.

  • +
  • stacksize – The stacksize of the worker threads. Must not be nostack.

  • +
  • schedule – The loop schedule of the parallel regions.

  • +
  • yield_delay – The time after which the executor yields to other work if it has not received any new work for execution.

  • +
+
+
+
+ +
+
+template<typename F, typename S, typename ...Ts>
inline void bulk_sync_execute_helper(F &&f, S const &shape, Ts&&... ts)#
+
+ +
+
+template<typename F, typename S, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::bulk_async_execute_t, block_fork_join_executor &exec, F &&f, S const &shape, Ts&&... ts)#
+
+ +
+
+template<typename ...Fs>
inline void sync_invoke_helper(Fs&&... fs) const#
+
+ +
+
+template<typename F, typename ...Fs>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::sync_invoke_t, block_fork_join_executor const &exec, F &&f, Fs&&... fs)#
+
+ +
+
+template<typename F, typename ...Fs>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::async_invoke_t, block_fork_join_executor const &exec, F &&f, Fs&&... fs)#
+
+ +
+
+template<typename Tag>
inline decltype(auto) friend tag_invoke(Tag tag, block_fork_join_executor const &exec) noexcept#
+
+ +
+
+

Private Members

+
+
+fork_join_executor exec_#
+
+ +
+
+std::vector<fork_join_executor> block_execs_#
+
+ +
+
+

Private Static Functions

+
+
+static inline hpx::threads::mask_type cores_for_targets(std::vector<compute::host::target> const &targets)#
+
+ +
+
+

Friends

+
+
+template<typename F, typename S, typename ...Ts>
inline friend void tag_invoke(hpx::parallel::execution::bulk_sync_execute_t, block_fork_join_executor &exec, F &&f, S const &shape, Ts&&... ts)#
+
+ +
+
+template<typename Tag, typename Property>
inline friend block_fork_join_executor tag_invoke(Tag tag, block_fork_join_executor const &exec, Property &&prop) noexcept#
+
+ +
+
+ +
+ +
+ +
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
+
+
config#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/config/endian.hpp#
+

Defined in header hpx/config/endian.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
+
+
coroutines#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/coroutines/thread_enums.hpp#
+

Defined in header hpx/coroutines/thread_enums.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace threads#
+
+

Enums

+
+
+enum class thread_schedule_state : std::int8_t#
+

The thread_schedule_state enumerator encodes the current state of a thread instance

+

Values:

+
+
+enumerator unknown#
+
+ +
+
+enumerator active#
+

thread is currently active (running, has resources)

+
+ +
+
+enumerator pending#
+

thread is pending (ready to run, but no hardware resource available)

+
+ +
+
+enumerator suspended#
+

thread has been suspended (waiting for synchronization event, but still known and under control of the thread-manager)

+
+ +
+
+enumerator depleted#
+

thread has been depleted (deeply suspended, it is not known to the thread-manager)

+
+ +
+
+enumerator terminated#
+

thread has been stopped an may be garbage collected

+
+ +
+
+enumerator staged#
+

this is not a real thread state, but allows to reference staged task descriptions, which eventually will be converted into thread objects

+
+ +
+
+enumerator pending_do_not_schedule#
+

this is not a real thread state, but allows to create a thread in pending state without scheduling it (internal, do not use)

+
+ +
+
+enumerator pending_boost#
+

this is not a real thread state, but allows to suspend a thread in pending state without high priority rescheduling

+
+ +
+
+enumerator deleted#
+

thread has been stopped and was deleted

+
+ +
+ +
+
+enum class thread_priority : std::int8_t#
+

This enumeration lists all possible thread-priorities for HPX threads.

+

Values:

+
+
+enumerator unknown#
+
+ +
+
+enumerator default_#
+

Will assign the priority of the task to the default (normal) priority.

+
+ +
+
+enumerator low#
+

Task goes onto a special low priority queue and will not be executed until all high/normal priority tasks are done, even if they are added after the low priority task.

+
+ +
+
+enumerator normal#
+

Task will be executed when it is taken from the normal priority queue, this is usually a first in-first-out ordering of tasks (depending on scheduler choice). This is the default priority.

+
+ +
+
+enumerator high_recursive#
+

The task is a high priority task and any child tasks spawned by this task will be made high priority as well - unless they are specifically flagged as non default priority.

+
+ +
+
+enumerator boost#
+

Same as thread_priority_high except that the thread will fall back to thread_priority_normal if resumed after being suspended.

+
+ +
+
+enumerator high#
+

Task goes onto a special high priority queue and will be executed before normal/low priority tasks are taken (some schedulers modify the behavior slightly and the documentation for those should be consulted).

+
+ +
+
+enumerator bound#
+

Task goes onto a special high priority queue and will never be stolen by another thread after initial assignment. This should be used for thread placement tasks such as OpenMP type for loops.

+
+ +
+ +
+
+enum class thread_restart_state : std::int8_t#
+

The thread_restart_state enumerator encodes the reason why a thread is being restarted

+

Values:

+
+
+enumerator unknown#
+
+ +
+
+enumerator signaled#
+

The thread has been signaled.

+
+ +
+
+enumerator timeout#
+

The thread has been reactivated after a timeout.

+
+ +
+
+enumerator terminate#
+

The thread needs to be terminated.

+
+ +
+
+enumerator abort#
+

The thread needs to be aborted.

+
+ +
+ +
+
+enum class thread_stacksize : std::int8_t#
+

A thread_stacksize references any of the possible stack-sizes for HPX threads.

+

Values:

+
+
+enumerator unknown#
+
+ +
+
+enumerator small_#
+

use small stack size (the underscore is to work around ‘small’ being defined to char on Windows)

+
+ +
+
+enumerator medium#
+

use medium sized stack size

+
+ +
+
+enumerator large#
+

use large stack size

+
+ +
+
+enumerator huge#
+

use very large stack size

+
+ +
+
+enumerator nostack#
+

this thread does not suspend (does not need a stack)

+
+ +
+
+enumerator current#
+

use size of current thread’s stack

+
+ +
+
+enumerator default_#
+

use default stack size

+
+ +
+
+enumerator minimal#
+

use minimally stack size

+
+ +
+
+enumerator maximal#
+

use maximally stack size

+
+ +
+ +
+
+enum class thread_schedule_hint_mode : std::int8_t#
+

The type of hint given when creating new tasks.

+

Values:

+
+
+enumerator none#
+

A hint that leaves the choice of scheduling entirely up to the scheduler.

+
+ +
+
+enumerator thread#
+

A hint that tells the scheduler to prefer scheduling a task on the local thread number associated with this hint. Local thread numbers are indexed from zero. It is up to the scheduler to decide how to interpret thread numbers that are larger than the number of threads available to the scheduler. Typically thread numbers will wrap around when too large.

+
+ +
+
+enumerator numa#
+

A hint that tells the scheduler to prefer scheduling a task on the NUMA domain associated with this hint. NUMA domains are indexed from zero. It is up to the scheduler to decide how to interpret NUMA domain indices that are larger than the number of available NUMA domains to the scheduler. Typically indices will wrap around when too large.

+
+ +
+ +
+
+enum class thread_placement_hint : std::int8_t#
+

The type of hint given to the scheduler related to thread placement

+

The type of hint given to the scheduler related running a thread as a child directly in the context of the parent thread

+

Values:

+
+
+enumerator none#
+

No hint is specified. The implementation is free to chose what placement methods to use.

+
+ +
+
+enumerator depth_first#
+

A hint that tells the scheduler to prefer spreading thread placement on a depth-first basis (i.e. consecutively scheduled threads are placed on the same core).

+
+ +
+
+enumerator breadth_first#
+

A hint that tells the scheduler to prefer spreading thread placement on a breadth-first basis (i.e. consecutively scheduled threads are placed on the neighboring cores).

+
+ +
+
+enumerator depth_first_reverse#
+

A hint that tells the scheduler to prefer spreading thread placement on a depth-first basis (i.e. consecutively scheduled threads are placed on the same core). Threads are being scheduled in reverse order.

+
+ +
+
+enumerator breadth_first_reverse#
+

A hint that tells the scheduler to prefer spreading thread placement on a breadth-first basis (i.e. consecutively scheduled threads are placed on the neighboring cores). Threads are being scheduled in reverse order.

+
+ +
+ +
+
+enum class thread_sharing_hint : std::int8_t#
+

The type of hint given to the scheduler related to whether it is ok to share the invoked function object between threads

+

Values:

+
+
+enumerator none#
+

No hint is specified. The implementation is free to chose what sharing methods to use.

+
+ +
+
+enumerator do_not_share_function#
+

A hint that tells the scheduler to avoid sharing the given function (object) between threads.

+
+ +
+
+enumerator do_not_combine_tasks#
+

A hint that tells the scheduler to avoid combining tasks on the same thread. This is important for tasks that may synchronize between each other, which could lead to deadlocks if those tasks are combined running by the same thread.

+
+ +
+ +
+
+enum class thread_execution_hint : std::int8_t#
+

Values:

+
+
+enumerator none#
+

No hint is specified. Always run the thread in its own execution environment.

+
+ +
+
+enumerator run_as_child#
+

Attempt to run the thread in the execution context of the parent thread.

+
+ +
+ +
+
+

Functions

+
+
+std::ostream &operator<<(std::ostream &os, thread_schedule_state t)#
+
+ +
+
+char const *get_thread_state_name(thread_schedule_state state) noexcept#
+

Returns the name of the given state.

+

Get the readable string representing the name of the given thread_state constant.

+
+
Parameters
+

state – this represents the thread state.

+
+
+
+ +
+
+std::ostream &operator<<(std::ostream &os, thread_priority t)#
+
+ +
+
+char const *get_thread_priority_name(thread_priority priority) noexcept#
+

Return the thread priority name.

+

Get the readable string representing the name of the given thread_priority constant.

+
+
Parameters
+

priority – this represents the thread priority.

+
+
+
+ +
+
+std::ostream &operator<<(std::ostream &os, thread_restart_state t)#
+
+ +
+
+char const *get_thread_state_ex_name(thread_restart_state state) noexcept#
+

Get the readable string representing the name of the given thread_restart_state constant.

+
+ +
+
+char const *get_thread_state_name(thread_state state) noexcept#
+

Get the readable string representing the name of the given thread_state constant.

+
+ +
+
+std::ostream &operator<<(std::ostream &os, thread_stacksize t)#
+
+ +
+
+char const *get_stack_size_enum_name(thread_stacksize size) noexcept#
+

Returns the stack size name.

+

Get the readable string representing the given stack size constant.

+
+
Parameters
+

size – this represents the stack size

+
+
+
+ +
+
+constexpr bool do_not_share_function(thread_sharing_hint hint) noexcept#
+
+ +
+
+constexpr bool do_not_combine_tasks(thread_sharing_hint hint) noexcept#
+
+ +
+
+constexpr thread_sharing_hint operator|(thread_sharing_hint lhs, thread_sharing_hint rhs) noexcept#
+
+ +
+
+constexpr bool run_as_child(thread_execution_hint hint) noexcept#
+
+ +
+
+

Variables

+
+
+constexpr thread_execution_hint default_runs_as_child_hint = thread_execution_hint::none#
+

Default value to use for runs-as-child mode (if true, then futures will attempt to execute associated threads directly if they have not started running).

+
+ +
+
+
+struct thread_schedule_hint#
+
+#include <thread_enums.hpp>
+

A hint given to a scheduler to guide where a task should be scheduled.

+

A scheduler is free to ignore the hint, or modify the hint to suit the resources available to the scheduler.

+
+

Public Functions

+
+
+inline constexpr thread_schedule_hint() noexcept#
+

Construct a default hint with mode thread_schedule_hint_mode::none.

+
+ +
+
+inline explicit constexpr thread_schedule_hint(std::int16_t thread_hint, thread_placement_hint placement = thread_placement_hint::none, thread_execution_hint runs_as_child = default_runs_as_child_hint, thread_sharing_hint sharing = thread_sharing_hint::none) noexcept#
+

Construct a hint with mode thread_schedule_hint_mode::thread and the given hint as the local thread number.

+
+ +
+
+inline constexpr thread_schedule_hint(thread_schedule_hint_mode mode, std::int16_t hint, thread_placement_hint placement = thread_placement_hint::none, thread_execution_hint runs_as_child = default_runs_as_child_hint, thread_sharing_hint sharing = thread_sharing_hint::none) noexcept#
+

Construct a hint with the given mode and hint. The numerical hint is unused when the mode is thread_schedule_hint_mode::none.

+
+ +
+
+inline constexpr thread_placement_hint placement_mode() const noexcept#
+
+ +
+
+inline void placement_mode(thread_placement_hint bits) noexcept#
+
+ +
+
+inline constexpr thread_sharing_hint sharing_mode() const noexcept#
+
+ +
+
+inline void sharing_mode(thread_sharing_hint bits) noexcept#
+
+ +
+
+inline constexpr thread_execution_hint runs_as_child_mode() const noexcept#
+
+ +
+
+inline void runs_as_child_mode(thread_execution_hint bits) noexcept#
+
+ +
+
+

Public Members

+
+
+std::int16_t hint = -1#
+

The hint associated with the mode. The interpretation of this hint depends on the given mode.

+
+ +
+
+thread_schedule_hint_mode mode = thread_schedule_hint_mode::none#
+

The mode of the scheduling hint.

+
+ +
+
+std::uint8_t placement_mode_bits#
+

The mode of the desired thread placement.

+
+ +
+
+std::uint8_t sharing_mode_bits#
+

The mode of the desired sharing hint.

+
+ +
+
+std::uint8_t runs_as_child_mode_bits#
+

The thread will run as a child directly in the context of the current thread

+
+ +
+
+ +
+ +
+ +
+
+
hpx/coroutines/thread_id_type.hpp#
+

Defined in header hpx/coroutines/thread_id_type.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<>
struct std::hash<::hpx::threads::thread_id>#
+
+

Public Functions

+
+
+inline std::size_t operator()(::hpx::threads::thread_id const &v) const noexcept#
+
+ +
+
+ +
+
+template<>
struct std::hash<::hpx::threads::thread_id_ref>#
+
+

Public Functions

+
+
+inline std::size_t operator()(::hpx::threads::thread_id_ref const &v) const noexcept#
+
+ +
+
+ +
+
+namespace hpx
+
+
+namespace threads
+
+

Enums

+
+
+enum class thread_id_addref#
+

Values:

+
+
+enumerator yes#
+
+ +
+
+enumerator no#
+
+ +
+ +
+
+

Variables

+
+
+constexpr const thread_id invalid_thread_id#
+
+ +
+
+
+struct thread_id#
+
+

Public Functions

+
+
+constexpr thread_id() noexcept = default#
+
+ +
+
+thread_id(thread_id const&) = default#
+
+ +
+
+thread_id &operator=(thread_id const&) = default#
+
+ +
+
+~thread_id() = default#
+
+ +
+
+inline constexpr thread_id(thread_id &&rhs) noexcept#
+
+ +
+
+inline constexpr thread_id &operator=(thread_id &&rhs) noexcept#
+
+ +
+
+inline explicit constexpr thread_id(thread_id_repr thrd) noexcept#
+
+ +
+
+inline constexpr thread_id &operator=(thread_id_repr rhs) noexcept#
+
+ +
+
+inline explicit constexpr operator bool() const noexcept#
+
+ +
+
+inline constexpr thread_id_repr get() const noexcept#
+
+ +
+
+inline constexpr void reset() noexcept#
+
+ +
+
+

Private Types

+
+
+using thread_id_repr = void*#
+
+ +
+
+

Private Members

+
+
+thread_id_repr thrd_ = nullptr#
+
+ +
+
+

Friends

+
+
+inline friend constexpr friend bool operator== (std::nullptr_t, thread_id const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator!= (std::nullptr_t, thread_id const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator== (thread_id const &lhs, std::nullptr_t) noexcept
+
+ +
+
+inline friend constexpr friend bool operator!= (thread_id const &lhs, std::nullptr_t) noexcept
+
+ +
+
+inline friend constexpr friend bool operator== (thread_id const &lhs, thread_id const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator!= (thread_id const &lhs, thread_id const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator< (thread_id const &lhs, thread_id const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator> (thread_id const &lhs, thread_id const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator<= (thread_id const &lhs, thread_id const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator>= (thread_id const &lhs, thread_id const &rhs) noexcept
+
+ +
+
+friend std::ostream &operator<<(std::ostream &os, thread_id const &id)#
+
+ +
+
+friend void format_value(std::ostream &os, std::string_view spec, thread_id const &id)#
+
+ +
+
+ +
+
+struct thread_id_ref#
+
+

Public Types

+
+
+using thread_repr = detail::thread_data_reference_counting#
+
+ +
+
+

Public Functions

+
+
+thread_id_ref() noexcept = default#
+
+ +
+
+thread_id_ref(thread_id_ref const&) = default#
+
+ +
+
+thread_id_ref &operator=(thread_id_ref const&) = default#
+
+ +
+
+thread_id_ref(thread_id_ref &&rhs) noexcept = default#
+
+ +
+
+thread_id_ref &operator=(thread_id_ref &&rhs) noexcept = default#
+
+ +
+
+~thread_id_ref() = default#
+
+ +
+
+inline explicit thread_id_ref(thread_id_repr const &thrd) noexcept#
+
+ +
+
+inline explicit thread_id_ref(thread_id_repr &&thrd) noexcept#
+
+ +
+
+inline thread_id_ref &operator=(thread_id_repr const &rhs) noexcept#
+
+ +
+
+inline thread_id_ref &operator=(thread_id_repr &&rhs) noexcept#
+
+ +
+
+inline explicit thread_id_ref(thread_repr *thrd, thread_id_addref addref = thread_id_addref::yes) noexcept#
+
+ +
+
+inline thread_id_ref &operator=(thread_repr *rhs) noexcept#
+
+ +
+
+inline thread_id_ref(thread_id const &noref)#
+
+ +
+
+inline thread_id_ref(thread_id &&noref) noexcept#
+
+ +
+
+inline thread_id_ref &operator=(thread_id const &noref)#
+
+ +
+
+inline thread_id_ref &operator=(thread_id &&noref) noexcept#
+
+ +
+
+inline explicit constexpr operator bool() const noexcept#
+
+ +
+
+inline constexpr thread_id noref() const noexcept#
+
+ +
+
+inline constexpr thread_id_repr &get() & noexcept#
+
+ +
+
+inline thread_id_repr &&get() && noexcept#
+
+ +
+
+inline constexpr thread_id_repr const &get() const & noexcept#
+
+ +
+
+inline void reset() noexcept#
+
+ +
+
+inline void reset(thread_repr *thrd, bool add_ref = true) noexcept#
+
+ +
+
+inline constexpr thread_repr *detach() noexcept#
+
+ +
+
+

Private Types

+
+
+using thread_id_repr = hpx::intrusive_ptr<detail::thread_data_reference_counting>#
+
+ +
+
+

Private Members

+
+
+thread_id_repr thrd_#
+
+ +
+
+

Friends

+
+
+inline friend constexpr friend bool operator== (std::nullptr_t, thread_id_ref const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator!= (std::nullptr_t, thread_id_ref const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator== (thread_id_ref const &lhs, std::nullptr_t) noexcept
+
+ +
+
+inline friend constexpr friend bool operator!= (thread_id_ref const &lhs, std::nullptr_t) noexcept
+
+ +
+
+inline friend constexpr friend bool operator== (thread_id_ref const &lhs, thread_id_ref const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator!= (thread_id_ref const &lhs, thread_id_ref const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator< (thread_id_ref const &lhs, thread_id_ref const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator> (thread_id_ref const &lhs, thread_id_ref const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator<= (thread_id_ref const &lhs, thread_id_ref const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator>= (thread_id_ref const &lhs, thread_id_ref const &rhs) noexcept
+
+ +
+
+friend std::ostream &operator<<(std::ostream &os, thread_id_ref const &id)#
+
+ +
+
+friend void format_value(std::ostream &os, std::string_view spec, thread_id_ref const &id)#
+
+ +
+
+ +
+ +
+ +
+
+namespace std#
+
+
+template<> thread_id >
+
+

Public Functions

+
+
+inline std::size_t operator()(::hpx::threads::thread_id const &v) const noexcept#
+
+ +
+
+ +
+
+template<> thread_id_ref >
+
+

Public Functions

+
+
+inline std::size_t operator()(::hpx::threads::thread_id_ref const &v) const noexcept#
+
+ +
+
+ +
+ +
+
+
+
+
datastructures#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::any_nonser. hpx::bad_any_cast, hpx::unique_any_nonser, hpx::any_cast, hpx::make_any_nonser, hpx::make_unique_any_nonser#
+

Defined in header hpx/any.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<>
class hpx::util::basic_any<void, void, void, std::true_type>#
+
+

Public Functions

+
+
+inline constexpr basic_any() noexcept#
+
+ +
+
+inline basic_any(basic_any const &x)#
+
+ +
+
+inline basic_any(basic_any &&x) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>>>>
inline explicit basic_any(T &&x, std::enable_if_t<std::is_copy_constructible_v<std::decay_t<T>>>* = nullptr)#
+
+ +
+
+template<typename T, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, Ts&&... ts)#
+
+ +
+
+template<typename T, typename U, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+inline ~basic_any()#
+
+ +
+
+inline basic_any &operator=(basic_any const &x)#
+
+ +
+
+inline basic_any &operator=(basic_any &&rhs) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline basic_any &operator=(T &&rhs)#
+
+ +
+
+inline basic_any &swap(basic_any &x) noexcept#
+
+ +
+
+inline std::type_info const &type() const#
+
+ +
+
+template<typename T>
inline T const &cast() const#
+
+ +
+
+inline bool has_value() const noexcept#
+
+ +
+
+inline void reset()#
+
+ +
+
+

Private Functions

+
+
+inline basic_any &assign(basic_any const &x)#
+
+ +
+
+

Private Members

+
+
+detail::any::fxn_ptr_table<void, void, void, std::true_type> *table#
+
+ +
+
+void *object#
+
+ +
+
+

Private Static Functions

+
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::true_type, Ts&&... ts)#
+
+ +
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::false_type, Ts&&... ts)#
+
+ +
+
+ +
+
+template<typename Char>
class hpx::util::basic_any<void, void, Char, std::true_type>#
+
+

Public Functions

+
+
+inline constexpr basic_any() noexcept#
+
+ +
+
+inline basic_any(basic_any const &x)#
+
+ +
+
+inline basic_any(basic_any &&x) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>>>>
inline explicit basic_any(T &&x, std::enable_if_t<std::is_copy_constructible_v<std::decay_t<T>>>* = nullptr)#
+
+ +
+
+template<typename T, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, Ts&&... ts)#
+
+ +
+
+template<typename T, typename U, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+inline ~basic_any()#
+
+ +
+
+inline basic_any &operator=(basic_any const &x)#
+
+ +
+
+inline basic_any &operator=(basic_any &&rhs) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline basic_any &operator=(T &&rhs) noexcept#
+
+ +
+
+inline basic_any &swap(basic_any &x) noexcept#
+
+ +
+
+inline std::type_info const &type() const#
+
+ +
+
+template<typename T>
inline T const &cast() const#
+
+ +
+
+inline bool has_value() const noexcept#
+
+ +
+
+inline void reset()#
+
+ +
+
+

Private Functions

+
+
+inline basic_any &assign(basic_any const &x)#
+
+ +
+
+

Private Members

+
+
+detail::any::fxn_ptr_table<void, void, Char, std::true_type> *table#
+
+ +
+
+void *object#
+
+ +
+
+

Private Static Functions

+
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::true_type, Ts&&... ts)#
+
+ +
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::false_type, Ts&&... ts)#
+
+ +
+
+ +
+
+template<>
class hpx::util::basic_any<void, void, void, std::false_type>#
+
+

Public Functions

+
+
+inline constexpr basic_any() noexcept#
+
+ +
+
+inline basic_any(basic_any &&x) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>>>>
inline explicit basic_any(T &&x, std::enable_if_t<std::is_move_constructible_v<std::decay_t<T>>>* = nullptr)#
+
+ +
+
+template<typename T, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, Ts&&... ts)#
+
+ +
+
+template<typename T, typename U, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+basic_any(basic_any const &x) = delete#
+
+ +
+
+basic_any &operator=(basic_any const &x) = delete#
+
+ +
+
+inline ~basic_any()#
+
+ +
+
+inline basic_any &operator=(basic_any &&rhs) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>> && std::is_move_constructible_v<std::decay_t<T>>>>
inline basic_any &operator=(T &&rhs)#
+
+ +
+
+inline basic_any &swap(basic_any &x) noexcept#
+
+ +
+
+inline std::type_info const &type() const#
+
+ +
+
+template<typename T>
inline T const &cast() const#
+
+ +
+
+inline bool has_value() const noexcept#
+
+ +
+
+inline void reset()#
+
+ +
+
+

Private Members

+
+
+detail::any::fxn_ptr_table<void, void, void, std::false_type> *table#
+
+ +
+
+void *object#
+
+ +
+
+

Private Static Functions

+
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::true_type, Ts&&... ts)#
+
+ +
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::false_type, Ts&&... ts)#
+
+ +
+
+ +
+
+template<typename Char>
class hpx::util::basic_any<void, void, Char, std::false_type>#
+
+

Public Functions

+
+
+inline constexpr basic_any() noexcept#
+
+ +
+
+inline basic_any(basic_any &&x) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>>>>
inline explicit basic_any(T &&x, std::enable_if_t<std::is_move_constructible_v<std::decay_t<T>>>* = nullptr)#
+
+ +
+
+template<typename T, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, Ts&&... ts)#
+
+ +
+
+template<typename T, typename U, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+basic_any(basic_any const &x) = delete#
+
+ +
+
+basic_any &operator=(basic_any const &x) = delete#
+
+ +
+
+inline ~basic_any()#
+
+ +
+
+inline basic_any &operator=(basic_any &&rhs) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>> && std::is_move_constructible_v<std::decay_t<T>>>>
inline basic_any &operator=(T &&rhs) noexcept#
+
+ +
+
+inline basic_any &swap(basic_any &x) noexcept#
+
+ +
+
+inline std::type_info const &type() const#
+
+ +
+
+template<typename T>
inline T const &cast() const#
+
+ +
+
+inline bool has_value() const noexcept#
+
+ +
+
+inline void reset()#
+
+ +
+
+

Private Members

+
+
+detail::any::fxn_ptr_table<void, void, Char, std::false_type> *table#
+
+ +
+
+void *object#
+
+ +
+
+

Private Static Functions

+
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::true_type, Ts&&... ts)#
+
+ +
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::false_type, Ts&&... ts)#
+
+ +
+
+ +
+
+namespace hpx
+

Top level HPX namespace.

+
+

Typedefs

+
+
+using any_nonser = util::basic_any<void, void, void, std::true_type>#
+
+ +
+
+using unique_any_nonser = util::basic_any<void, void, void, std::false_type>#
+
+ +
+
+

Functions

+
+
+template<typename T, typename ...Ts>
util::basic_any<void, void, void, std::true_type> make_any_nonser(Ts&&... ts)#
+
+ +
+
+template<typename T, typename U, typename ...Ts>
util::basic_any<void, void, void, std::true_type> make_any_nonser(std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+template<typename T, typename ...Ts>
util::basic_any<void, void, void, std::false_type> make_unique_any_nonser(Ts&&... ts)#
+
+ +
+
+template<typename T, typename U, typename ...Ts>
util::basic_any<void, void, void, std::false_type> make_unique_any_nonser(std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+template<typename T>
util::basic_any<void, void, void, std::true_type> make_any_nonser(T &&t)#
+
+ +
+
+template<typename T>
util::basic_any<void, void, void, std::false_type> make_unique_any_nonser(T &&t)#
+
+ +
+
+template<typename T, typename IArch, typename OArch, typename Char, typename Copyable>
T *any_cast(util::basic_any<IArch, OArch, Char, Copyable> *operand) noexcept#
+

Performs type-safe access to the contained object.

+
+
Parameters
+

operand – target any object

+
+
Returns
+

If operand is not a null pointer, and the typeid of the requested T matches that of the contents of operand, a pointer to the value contained by operand, otherwise a null pointer.

+
+
+
+ +
+
+template<typename T, typename IArch, typename OArch, typename Char, typename Copyable>
T const *any_cast(util::basic_any<IArch, OArch, Char, Copyable> const *operand) noexcept#
+

Performs type-safe access to the contained object.

+
+
Parameters
+

operand – target any object

+
+
Returns
+

If operand is not a null pointer, and the typeid of the requested T matches that of the contents of operand, a pointer to the value contained by operand, otherwise a null pointer.

+
+
+
+ +
+
+template<typename T, typename IArch, typename OArch, typename Char, typename Copyable>
T any_cast(util::basic_any<IArch, OArch, Char, Copyable> &operand)#
+

Performs type-safe access to the contained object. Let U be std::remove_cv_t<std::remove_reference_t<T>> The program is ill-formed if std::is_constructible_v<T, U&> is false.

+
+
Parameters
+

operand – target any object

+
+
Returns
+

static_cast<T>(*std::any_cast<U>(&operand))

+
+
+
+ +
+
+template<typename T, typename IArch, typename OArch, typename Char, typename Copyable>
T const &any_cast(util::basic_any<IArch, OArch, Char, Copyable> const &operand)#
+

Performs type-safe access to the contained object. Let U be std::remove_cv_t<std::remove_reference_t<T>> The program is ill-formed if std::is_constructible_v<T, const U&> is false.

+
+
Parameters
+

operand – target any object

+
+
Returns
+

static_cast<T>(*std::any_cast<U>(&operand))

+
+
+
+ +
+
+
+struct bad_any_cast : public bad_cast#
+
+#include <any.hpp>
+

Defines a type of object to be thrown by the value-returning forms of hpx::any_cast on failure.

+
+

Public Functions

+
+
+inline bad_any_cast(std::type_info const &src, std::type_info const &dest)#
+

Constructs a new bad_any_cast object with an implementation-defined null-terminated byte string which is accessible through what().

+
+ +
+
+inline char const *what() const noexcept override#
+

Returns the explanatory string.

+
+

Note

+

Implementations are allowed but not required to override what().

+
+
+
Returns
+

Pointer to a null-terminated string with explanatory information. The string is suitable for conversion and display as a std::wstring. The pointer is guaranteed to be valid at least until the exception object from which it is obtained is destroyed, or until a non-const member function (e.g. copy assignment operator) on the exception object is called.

+
+
+
+ +
+
+

Public Members

+
+
+char const *from#
+
+ +
+
+char const *to#
+
+ +
+
+ +
+
+namespace util
+
+

Typedefs

+
+
+using streamable_any_nonser = basic_any<void, void, char, std::true_type>#
+
+ +
+
+using streamable_wany_nonser = basic_any<void, void, wchar_t, std::true_type>#
+
+ +
+
+using streamable_unique_any_nonser = basic_any<void, void, char, std::false_type>#
+
+ +
+
+using streamable_unique_wany_nonser = basic_any<void, void, wchar_t, std::false_type>#
+
+ +
+
+

Functions

+
+
+template<typename IArch, typename OArch, typename Char, typename Copyable, typename Enable = std::enable_if_t<!std::is_void_v<Char>>>
std::basic_istream<Char> &operator>>(std::basic_istream<Char> &i, basic_any<IArch, OArch, Char, Copyable> &obj)#
+
+ +
+
+template<typename IArch, typename OArch, typename Char, typename Copyable, typename Enable = std::enable_if_t<!std::is_void_v<Char>>>
std::basic_ostream<Char> &operator<<(std::basic_ostream<Char> &o, basic_any<IArch, OArch, Char, Copyable> const &obj)#
+
+ +
+
+template<typename IArch, typename OArch, typename Char, typename Copyable>
void swap(basic_any<IArch, OArch, Char, Copyable> &lhs, basic_any<IArch, OArch, Char, Copyable> &rhs) noexcept#
+
+ +
+
+template<typename T, typename Char, typename ...Ts>
basic_any<void, void, Char, std::true_type> make_streamable_any_nonser(Ts&&... ts)#
+
+ +
+
+template<typename T, typename Char, typename U, typename ...Ts>
basic_any<void, void, Char, std::true_type> make_streamable_any_nonser(std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+template<typename T, typename Char, typename ...Ts>
basic_any<void, void, Char, std::false_type> make_streamable_unique_any_nonser(Ts&&... ts)#
+
+ +
+
+template<typename T, typename Char, typename U, typename ...Ts>
basic_any<void, void, Char, std::false_type> make_streamable_unique_any_nonser(std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+template<typename T, typename Char>
basic_any<void, void, Char, std::true_type> make_streamable_any_nonser(T &&t)#
+
+ +
+
+template<typename T, typename Char>
basic_any<void, void, Char, std::false_type> make_streamable_unique_any_nonser(T &&t)#
+
+ +
+
+
+template<typename IArch, typename OArch, typename Char = char, typename Copyable = std::true_type>
class basic_any#
+
+ +
+
+template<typename Char> false_type >
+
+

Public Functions

+
+
+inline constexpr basic_any() noexcept#
+
+ +
+
+inline basic_any(basic_any &&x) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>>>>
inline explicit basic_any(T &&x, std::enable_if_t<std::is_move_constructible_v<std::decay_t<T>>>* = nullptr)#
+
+ +
+
+template<typename T, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, Ts&&... ts)#
+
+ +
+
+template<typename T, typename U, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+basic_any(basic_any const &x) = delete#
+
+ +
+
+basic_any &operator=(basic_any const &x) = delete#
+
+ +
+
+inline ~basic_any()#
+
+ +
+
+inline basic_any &operator=(basic_any &&rhs) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>> && std::is_move_constructible_v<std::decay_t<T>>>>
inline basic_any &operator=(T &&rhs) noexcept#
+
+ +
+
+inline basic_any &swap(basic_any &x) noexcept#
+
+ +
+
+inline std::type_info const &type() const#
+
+ +
+
+template<typename T>
inline T const &cast() const#
+
+ +
+
+inline bool has_value() const noexcept#
+
+ +
+
+inline void reset()#
+
+ +
+
+

Private Members

+
+
+detail::any::fxn_ptr_table<void, void, Char, std::false_type> *table#
+
+ +
+
+void *object#
+
+ +
+
+

Private Static Functions

+
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::true_type, Ts&&... ts)#
+
+ +
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::false_type, Ts&&... ts)#
+
+ +
+
+ +
+
+template<typename Char> true_type >
+
+

Public Functions

+
+
+inline constexpr basic_any() noexcept
+
+ +
+
+inline basic_any(basic_any const &x)
+
+ +
+
+inline basic_any(basic_any &&x) noexcept
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>>>>
inline explicit basic_any(T &&x, std::enable_if_t<std::is_copy_constructible_v<std::decay_t<T>>>* = nullptr)#
+
+ +
+
+template<typename T, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, Ts&&... ts)
+
+ +
+
+template<typename T, typename U, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, std::initializer_list<U> il, Ts&&... ts)
+
+ +
+
+inline ~basic_any()
+
+ +
+
+inline basic_any &operator=(basic_any const &x)
+
+ +
+
+inline basic_any &operator=(basic_any &&rhs) noexcept
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline basic_any &operator=(T &&rhs) noexcept
+
+ +
+
+inline basic_any &swap(basic_any &x) noexcept
+
+ +
+
+inline std::type_info const &type() const
+
+ +
+
+template<typename T>
inline T const &cast() const
+
+ +
+
+inline bool has_value() const noexcept
+
+ +
+
+inline void reset()
+
+ +
+
+

Private Functions

+
+
+inline basic_any &assign(basic_any const &x)#
+
+ +
+
+

Private Members

+
+
+detail::any::fxn_ptr_table<void, void, Char, std::true_type> *table
+
+ +
+
+void *object
+
+ +
+
+

Private Static Functions

+
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::true_type, Ts&&... ts)
+
+ +
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::false_type, Ts&&... ts)
+
+ +
+
+ +
+
+template<> false_type >
+
+

Public Functions

+
+
+inline constexpr basic_any() noexcept
+
+ +
+
+inline basic_any(basic_any &&x) noexcept
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>>>>
inline explicit basic_any(T &&x, std::enable_if_t<std::is_move_constructible_v<std::decay_t<T>>>* = nullptr)
+
+ +
+
+template<typename T, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, Ts&&... ts)
+
+ +
+
+template<typename T, typename U, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, std::initializer_list<U> il, Ts&&... ts)
+
+ +
+
+basic_any(basic_any const &x) = delete
+
+ +
+
+basic_any &operator=(basic_any const &x) = delete
+
+ +
+
+inline ~basic_any()
+
+ +
+
+inline basic_any &operator=(basic_any &&rhs) noexcept
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>> && std::is_move_constructible_v<std::decay_t<T>>>>
inline basic_any &operator=(T &&rhs)
+
+ +
+
+inline basic_any &swap(basic_any &x) noexcept
+
+ +
+
+inline std::type_info const &type() const
+
+ +
+
+template<typename T>
inline T const &cast() const
+
+ +
+
+inline bool has_value() const noexcept
+
+ +
+
+inline void reset()
+
+ +
+
+

Private Members

+
+
+detail::any::fxn_ptr_table<void, void, void, std::false_type> *table
+
+ +
+
+void *object
+
+ +
+
+

Private Static Functions

+
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::true_type, Ts&&... ts)
+
+ +
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::false_type, Ts&&... ts)
+
+ +
+
+ +
+
+template<> true_type >
+
+

Public Functions

+
+
+inline constexpr basic_any() noexcept
+
+ +
+
+inline basic_any(basic_any const &x)
+
+ +
+
+inline basic_any(basic_any &&x) noexcept
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>>>>
inline explicit basic_any(T &&x, std::enable_if_t<std::is_copy_constructible_v<std::decay_t<T>>>* = nullptr)
+
+ +
+
+template<typename T, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, Ts&&... ts)
+
+ +
+
+template<typename T, typename U, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, std::initializer_list<U> il, Ts&&... ts)
+
+ +
+
+inline ~basic_any()
+
+ +
+
+inline basic_any &operator=(basic_any const &x)
+
+ +
+
+inline basic_any &operator=(basic_any &&rhs) noexcept
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline basic_any &operator=(T &&rhs)
+
+ +
+
+inline basic_any &swap(basic_any &x) noexcept
+
+ +
+
+inline std::type_info const &type() const
+
+ +
+
+template<typename T>
inline T const &cast() const
+
+ +
+
+inline bool has_value() const noexcept
+
+ +
+
+inline void reset()
+
+ +
+
+

Private Functions

+
+
+inline basic_any &assign(basic_any const &x)
+
+ +
+
+

Private Members

+
+
+detail::any::fxn_ptr_table<void, void, void, std::true_type> *table
+
+ +
+
+void *object
+
+ +
+
+

Private Static Functions

+
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::true_type, Ts&&... ts)
+
+ +
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::false_type, Ts&&... ts)
+
+ +
+
+ +
+ +
+ +
+
+
hpx::ignore, hpx::tuple, hpx::tuple_size, hpx::tuple_element, hpx::make_tuple, hpx::tie, hpx::forward_as_tuple, hpx::tuple_cat, hpx::get#
+

Defined in header hpx/tuple.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename ...Ts>
constexpr tuple<util::decay_unwrap_t<Ts>...> make_tuple(Ts&&... ts)#
+

Provides compile-time indexed access to the types of the elements of the tuple.

+
+ +
+
+template<typename ...Ts>
constexpr tuple<Ts&&...> forward_as_tuple(Ts&&... ts)#
+

Constructs a tuple of references to the arguments in args suitable for forwarding as an argument to a function. The tuple has rvalue reference data members when rvalues are used as arguments, and otherwise has lvalue reference data members.

+
+
Parameters
+

ts – zero or more arguments to construct the tuple from

+
+
Returns
+

hpx::tuple object created as if by

hpx::tuple<Ts&&...>(HPX_FORWARD(Ts, ts)...) 
+
+
+

+
+
+
+ +
+
+template<typename ...Ts>
constexpr tuple<Ts&...> tie(Ts&... ts)#
+

Creates a tuple of lvalue references to its arguments or instances of hpx::ignore.

+
+
Parameters
+

ts – zero or more lvalue arguments to construct the tuple from.

+
+
Returns
+

hpx::tuple object containing lvalue references.

+
+
+
+ +
+
+template<typename ...Tuples>
constexpr auto tuple_cat(Tuples&&... tuples)#
+

Constructs a tuple that is a concatenation of all tuples in tuples. The behavior is undefined if any type in std::decay_t<Tuples>… is not a specialization of hpx::tuple. However, an implementation may choose to support types (such as std::array and std::pair) that follow the tuple-like protocol.

+
+
Parameters
+

tuples – - zero or more tuples to concatenate

+
+
Returns
+

hpx::tuple object composed of all elements of all argument tuples constructed from hpx::get<Is>(HPX_FORWARD(UTuple,t) for each individual element.

+
+
+
+ +
+
+template<std::size_t I>
util::at_index<I, Ts...>::type &get() noexcept#
+

Extracts the Ith element from the tuple. I must be an integer value in [0, sizeof…(Ts)).

+
+ +
+
+template<std::size_t I>
util::at_index<I, Ts...>::type const &get() const noexcept#
+

Extracts the Ith element from the tuple. I must be an integer value in [0, sizeof…(Ts)).

+
+ +
+
+

Variables

+
+
+constexpr hpx::detail::ignore_type ignore = {}#
+

An object of unspecified type such that any value can be assigned to it with no effect. Intended for use with hpx::tie when unpacking a hpx::tuple, as a placeholder for the arguments that are not used. While the behavior of hpx::ignore outside of hpx::tie is not formally specified, some code guides recommend using hpx::ignore to avoid warnings from unused return values of [[nodiscard]] functions.

+
+ +
+
+
+template<typename ...Ts>
class tuple#
+
+#include <tuple.hpp>
+

Class template hpx::tuple is a fixed-size collection of heterogeneous values. It is a generalization of hpx::pair. If std::is_trivially_destructible<Ti>::value is true for every Ti in Ts, the destructor of tuple is trivial.

+
+
Param Ts…
+

the types of the elements that the tuple stores.

+
+
+
+ +
+
+template<std::size_t I, typename T, typename Enable = void>
struct tuple_element#
+
+#include <tuple.hpp>
+

Provides compile-time indexed access to the types of the elements of a tuple-like type.

+

The primary template is not defined. An explicit (full) or partial specialization is required to make a type tuple-like.

+
+ +
+
+template<typename T>
struct tuple_size#
+
+#include <tuple.hpp>
+

Provides access to the number of elements in a tuple-like type as a compile-time constant expression.

+

The primary template is not defined. An explicit (full) or partial specialization is required to make a type tuple-like.

+
+ +
+ +
+
+
hpx::any, hpx::make_any#
+

Defined in header hpx/any.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<typename IArch, typename OArch, typename Char>
class hpx::util::basic_any<IArch, OArch, Char, std::true_type>#
+
+

Public Functions

+
+
+inline constexpr basic_any() noexcept#
+
+ +
+
+inline basic_any(basic_any const &x)#
+
+ +
+
+inline basic_any(basic_any &&x) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>>>>
inline basic_any(T &&x, std::enable_if_t<std::is_copy_constructible_v<std::decay_t<T>>>* = nullptr)#
+
+ +
+
+template<typename T, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, Ts&&... ts)#
+
+ +
+
+template<typename T, typename U, typename ...Ts, typename Enable = std::enable_if<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+inline ~basic_any()#
+
+ +
+
+inline basic_any &operator=(basic_any const &x)#
+
+ +
+
+inline basic_any &operator=(basic_any &&rhs) noexcept#
+
+ +
+
+template<typename T, typename Enable = std::enable_if<!std::is_same_v<basic_any, std::decay_t<T>> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline basic_any &operator=(T &&rhs)#
+
+ +
+
+inline basic_any &swap(basic_any &x) noexcept#
+
+ +
+
+inline std::type_info const &type() const#
+
+ +
+
+template<typename T>
inline T const &cast() const#
+
+ +
+
+inline bool has_value() const noexcept#
+
+ +
+
+inline void reset()#
+
+ +
+
+inline bool equal_to(basic_any const &rhs) const noexcept#
+
+ +
+
+

Private Functions

+
+
+inline basic_any &assign(basic_any const &x)#
+
+ +
+
+inline void load(IArch &ar, unsigned const version)#
+
+ +
+
+inline void save(OArch &ar, unsigned const version) const#
+
+ +
+
+

Private Members

+
+
+detail::any::fxn_ptr_table<IArch, OArch, Char, std::true_type> *table#
+
+ +
+
+void *object#
+
+ +
+
+

Private Static Functions

+
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::true_type, Ts&&... ts)#
+
+ +
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::false_type, Ts&&... ts)#
+
+ +
+
+

Friends

+
+
+friend class hpx::serialization::access
+
+ +
+
+ +
+
+namespace hpx
+

Top level HPX namespace.

+
+

Typedefs

+
+
+using any = util::basic_any<serialization::input_archive, serialization::output_archive, char, std::true_type>#
+
+ +
+
+

Functions

+
+
+template<typename T, typename Char>
util::basic_any<serialization::input_archive, serialization::output_archive, Char> make_any(T &&t)#
+

Constructs an any object containing an object of type T, passing the provided arguments to T’s constructor. Equivalent to:

return std::any(std::in_place_type<T>, std::forward<Args>(args)...);
+
+
+

+
+ +
+
+
+namespace util
+
+

Typedefs

+
+
+using wany = basic_any<serialization::input_archive, serialization::output_archive, wchar_t, std::true_type>#
+
+ +
+
+

Functions

+
+
+template<typename T, typename Char, typename ...Ts>
basic_any<serialization::input_archive, serialization::output_archive, Char> make_any(Ts&&... ts)#
+
+ +
+
+template<typename T, typename Char, typename U, typename ...Ts>
basic_any<serialization::input_archive, serialization::output_archive, Char> make_any(std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+
+template<typename IArch, typename OArch, typename Char> true_type >
+
+

Public Functions

+
+
+inline constexpr basic_any() noexcept
+
+ +
+
+inline basic_any(basic_any const &x)
+
+ +
+
+inline basic_any(basic_any &&x) noexcept
+
+ +
+
+template<typename T, typename Enable = std::enable_if_t<!std::is_same_v<basic_any, std::decay_t<T>>>>
inline basic_any(T &&x, std::enable_if_t<std::is_copy_constructible_v<std::decay_t<T>>>* = nullptr)
+
+ +
+
+template<typename T, typename ...Ts, typename Enable = std::enable_if_t<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, Ts&&... ts)
+
+ +
+
+template<typename T, typename U, typename ...Ts, typename Enable = std::enable_if<std::is_constructible_v<std::decay_t<T>, Ts...> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline explicit basic_any(std::in_place_type_t<T>, std::initializer_list<U> il, Ts&&... ts)#
+
+ +
+
+inline ~basic_any()
+
+ +
+
+inline basic_any &operator=(basic_any const &x)
+
+ +
+
+inline basic_any &operator=(basic_any &&rhs) noexcept
+
+ +
+
+template<typename T, typename Enable = std::enable_if<!std::is_same_v<basic_any, std::decay_t<T>> && std::is_copy_constructible_v<std::decay_t<T>>>>
inline basic_any &operator=(T &&rhs)#
+
+ +
+
+inline basic_any &swap(basic_any &x) noexcept
+
+ +
+
+inline std::type_info const &type() const
+
+ +
+
+template<typename T>
inline T const &cast() const
+
+ +
+
+inline bool has_value() const noexcept
+
+ +
+
+inline void reset()
+
+ +
+
+inline bool equal_to(basic_any const &rhs) const noexcept#
+
+ +
+
+

Private Functions

+
+
+inline basic_any &assign(basic_any const &x)
+
+ +
+
+inline void load(IArch &ar, unsigned const version)#
+
+ +
+
+inline void save(OArch &ar, unsigned const version) const#
+
+ +
+
+

Private Members

+
+
+detail::any::fxn_ptr_table<IArch, OArch, Char, std::true_type> *table
+
+ +
+
+void *object
+
+ +
+
+

Private Static Functions

+
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::true_type, Ts&&... ts)
+
+ +
+
+template<typename T, typename ...Ts>
static inline void new_object(void *&object, std::false_type, Ts&&... ts)
+
+ +
+
+

Friends

+
+
+friend class hpx::serialization::access
+
+ +
+
+ +
+
+struct hash_any#
+
+

Public Functions

+
+
+template<typename Char>
std::size_t operator()(basic_any<serialization::input_archive, serialization::output_archive, Char, std::true_type> const &elem) const#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
debugging#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/debugging/print.hpp#
+

Defined in header hpx/debugging/print.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_DP_LAZY(Expr, printer)#
+
+ +
+
+
+
+
+
errors#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/errors/error.hpp#
+

Defined in header hpx/errors/error.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_ERROR_UNSCOPED_ENUM_DEPRECATION_MSG#
+
+ +
+
+
+namespace hpx
+
+

Enums

+
+
+enum class error : std::int16_t#
+

Possible error conditions.

+

This enumeration lists all possible error conditions which can be reported from any of the API functions.

+

Values:

+
+
+enumerator success#
+

The operation was successful.

+
+ +
+
+enumerator no_success#
+

The operation did failed, but not in an unexpected manner.

+
+ +
+
+enumerator not_implemented#
+

The operation is not implemented.

+
+ +
+
+enumerator out_of_memory#
+

The operation caused an out of memory condition.

+
+ +
+
+enumerator bad_action_code#
+
+ +
+
+enumerator bad_component_type#
+

The specified component type is not known or otherwise invalid.

+
+ +
+
+enumerator network_error#
+

A generic network error occurred.

+
+ +
+
+enumerator version_too_new#
+

The version of the network representation for this object is too new.

+
+ +
+
+enumerator version_too_old#
+

The version of the network representation for this object is too old.

+
+ +
+
+enumerator version_unknown#
+

The version of the network representation for this object is unknown.

+
+ +
+
+enumerator unknown_component_address#
+
+ +
+
+enumerator duplicate_component_address#
+

The given global id has already been registered.

+
+ +
+
+enumerator invalid_status#
+

The operation was executed in an invalid status.

+
+ +
+
+enumerator bad_parameter#
+

One of the supplied parameters is invalid.

+
+ +
+
+enumerator internal_server_error#
+
+ +
+
+enumerator service_unavailable#
+
+ +
+
+enumerator bad_request#
+
+ +
+
+enumerator repeated_request#
+
+ +
+
+enumerator lock_error#
+
+ +
+
+enumerator duplicate_console#
+

There is more than one console locality.

+
+ +
+
+enumerator no_registered_console#
+

There is no registered console locality available.

+
+ +
+
+enumerator startup_timed_out#
+
+ +
+
+enumerator uninitialized_value#
+
+ +
+
+enumerator bad_response_type#
+
+ +
+
+enumerator deadlock#
+
+ +
+
+enumerator assertion_failure#
+
+ +
+
+enumerator null_thread_id#
+

Attempt to invoke an API function from a non-HPX thread.

+
+ +
+
+enumerator invalid_data#
+
+ +
+
+enumerator yield_aborted#
+

The yield operation was aborted.

+
+ +
+ +
+ +
+
+enumerator commandline_option_error#
+

One of the options given on the command line is erroneous.

+
+ +
+
+enumerator serialization_error#
+

There was an error during serialization of this object.

+
+ +
+
+enumerator unhandled_exception#
+

An unhandled exception has been caught.

+
+ +
+
+enumerator kernel_error#
+

The OS kernel reported an error.

+
+ +
+
+enumerator broken_task#
+

The task associated with this future object is not available anymore.

+
+ +
+
+enumerator task_moved#
+

The task associated with this future object has been moved.

+
+ +
+
+enumerator task_already_started#
+

The task associated with this future object has already been started.

+
+ +
+
+enumerator future_already_retrieved#
+

The future object has already been retrieved.

+
+ +
+
+enumerator promise_already_satisfied#
+

The value for this future object has already been set.

+
+ +
+
+enumerator future_does_not_support_cancellation#
+

The future object does not support cancellation.

+
+ +
+
+enumerator future_can_not_be_cancelled#
+

The future can’t be canceled at this time.

+
+ +
+
+enumerator no_state#
+

The future object has no valid shared state.

+
+ +
+
+enumerator broken_promise#
+

The promise has been deleted.

+
+ +
+
+enumerator thread_resource_error#
+
+ +
+
+enumerator future_cancelled#
+
+ +
+
+enumerator thread_cancelled#
+
+ +
+
+enumerator thread_not_interruptable#
+
+ +
+
+enumerator duplicate_component_id#
+

The component type has already been registered.

+
+ +
+
+enumerator unknown_error#
+

An unknown error occurred.

+
+ +
+
+enumerator bad_plugin_type#
+

The specified plugin type is not known or otherwise invalid.

+
+ +
+
+enumerator filesystem_error#
+

The specified file does not exist or other filesystem related error.

+
+ +
+
+enumerator bad_function_call#
+

equivalent of std::bad_function_call

+
+ +
+
+enumerator task_canceled_exception#
+

parallel::task_canceled_exception

+
+ +
+
+enumerator task_block_not_active#
+

task_region is not active

+
+ +
+
+enumerator out_of_range#
+

Equivalent to std::out_of_range.

+
+ +
+
+enumerator length_error#
+

Equivalent to std::length_error.

+
+ +
+
+enumerator migration_needs_retry#
+

migration failed because of global race, retry

+
+ +
+ +
+
+

Functions

+
+
+inline constexpr bool operator==(int lhs, error rhs) noexcept#
+
+ +
+
+inline constexpr bool operator==(error lhs, int rhs) noexcept#
+
+ +
+
+inline constexpr bool operator!=(int lhs, error rhs) noexcept#
+
+ +
+
+inline constexpr bool operator!=(error lhs, int rhs) noexcept#
+
+ +
+
+inline constexpr bool operator<(int lhs, error rhs) noexcept#
+
+ +
+
+inline constexpr bool operator>=(int lhs, error rhs) noexcept#
+
+ +
+
+inline constexpr int operator&(error lhs, error rhs) noexcept#
+
+ +
+
+inline constexpr int operator&(int lhs, error rhs) noexcept#
+
+ +
+
+inline constexpr int operator|=(int &lhs, error rhs) noexcept#
+
+ +
+
+char const *get_error_name(error e) noexcept#
+
+ +
+
+

Variables

+
+
+constexpr error success = error::success#
+
+ +
+
+constexpr error no_success = error::no_success#
+
+ +
+
+constexpr error not_implemented = error::not_implemented#
+
+ +
+
+constexpr error out_of_memory = error::out_of_memory#
+
+ +
+
+constexpr error bad_action_code = error::bad_action_code#
+
+ +
+
+constexpr error bad_component_type = error::bad_component_type#
+
+ +
+
+constexpr error network_error = error::network_error#
+
+ +
+
+constexpr error version_too_new = error::version_too_new#
+
+ +
+
+constexpr error version_too_old = error::version_too_old#
+
+ +
+
+constexpr error version_unknown = error::version_unknown#
+
+ +
+
+constexpr error unknown_component_address = error::unknown_component_address#
+
+ +
+
+constexpr error duplicate_component_address = error::duplicate_component_address#
+
+ +
+
+constexpr error invalid_status = error::invalid_status#
+
+ +
+
+constexpr error bad_parameter = error::bad_parameter#
+
+ +
+
+constexpr error internal_server_error = error::internal_server_error#
+
+ +
+
+constexpr error service_unavailable = error::service_unavailable#
+
+ +
+
+constexpr error bad_request = error::bad_request#
+
+ +
+
+constexpr error repeated_request = error::repeated_request#
+
+ +
+
+constexpr error lock_error = error::lock_error#
+
+ +
+
+constexpr error duplicate_console = error::duplicate_console#
+
+ +
+
+constexpr error no_registered_console = error::no_registered_console#
+
+ +
+
+constexpr error startup_timed_out = error::startup_timed_out#
+
+ +
+
+constexpr error uninitialized_value = error::uninitialized_value#
+
+ +
+
+constexpr error bad_response_type = error::bad_response_type#
+
+ +
+
+constexpr error deadlock = error::deadlock#
+
+ +
+
+constexpr error assertion_failure = error::assertion_failure#
+
+ +
+
+constexpr error null_thread_id = error::null_thread_id#
+
+ +
+
+constexpr error invalid_data = error::invalid_data#
+
+ +
+
+constexpr error yield_aborted = error::yield_aborted#
+
+ +
+ +
+ +
+
+constexpr error commandline_option_error = error::commandline_option_error#
+
+ +
+
+constexpr error serialization_error = error::serialization_error#
+
+ +
+
+constexpr error unhandled_exception = error::unhandled_exception#
+
+ +
+
+constexpr error kernel_error = error::kernel_error#
+
+ +
+
+constexpr error broken_task = error::broken_task#
+
+ +
+
+constexpr error task_moved = error::task_moved#
+
+ +
+
+constexpr error task_already_started = error::task_already_started#
+
+ +
+
+constexpr error future_already_retrieved = error::future_already_retrieved#
+
+ +
+
+constexpr error promise_already_satisfied = error::promise_already_satisfied#
+
+ +
+
+constexpr error future_does_not_support_cancellation = error::future_does_not_support_cancellation#
+
+ +
+
+constexpr error future_can_not_be_cancelled = error::future_can_not_be_cancelled#
+
+ +
+
+constexpr error no_state = error::no_state#
+
+ +
+
+constexpr error broken_promise = error::broken_promise#
+
+ +
+
+constexpr error thread_resource_error = error::thread_resource_error#
+
+ +
+
+constexpr error future_cancelled = error::future_cancelled#
+
+ +
+
+constexpr error thread_cancelled = error::thread_cancelled#
+
+ +
+
+constexpr error thread_not_interruptable = error::thread_not_interruptable#
+
+ +
+
+constexpr error duplicate_component_id = error::duplicate_component_id#
+
+ +
+
+constexpr error unknown_error = error::unknown_error#
+
+ +
+
+constexpr error bad_plugin_type = error::bad_plugin_type#
+
+ +
+
+constexpr error filesystem_error = error::filesystem_error#
+
+ +
+
+constexpr error bad_function_call = error::bad_function_call#
+
+ +
+
+constexpr error task_canceled_exception = error::task_canceled_exception#
+
+ +
+
+constexpr error task_block_not_active = error::task_block_not_active#
+
+ +
+
+constexpr error out_of_range = error::out_of_range#
+
+ +
+
+constexpr error length_error = error::length_error#
+
+ +
+
+constexpr error migration_needs_retry = error::migration_needs_retry#
+
+ +
+
+ +
+
+
hpx::error_code#
+

Defined in header hpx/system_error.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Unnamed Group

+
+
+inline error_code make_error_code(error e, throwmode mode = throwmode::plain)#
+

Returns a new error_code constructed from the given parameters.

+
+ +
+
+inline error_code make_error_code(error e, char const *func, char const *file, long line, throwmode mode = throwmode::plain)#
+
+ +
+
+inline error_code make_error_code(error e, char const *msg, throwmode mode = throwmode::plain)#
+

Returns error_code(e, msg, mode).

+
+ +
+
+inline error_code make_error_code(error e, char const *msg, char const *func, char const *file, long line, throwmode mode = throwmode::plain)#
+
+ +
+
+inline error_code make_error_code(error e, std::string const &msg, throwmode mode = throwmode::plain)#
+

Returns error_code(e, msg, mode).

+
+ +
+
+inline error_code make_error_code(error e, std::string const &msg, char const *func, char const *file, long line, throwmode mode = throwmode::plain)#
+
+ +
+
+inline error_code make_error_code(std::exception_ptr const &e)#
+
+ +
+
+

Functions

+
+
+std::error_category const &get_hpx_category() noexcept#
+

Returns generic HPX error category used for new errors.

+
+ +
+
+std::error_category const &get_hpx_rethrow_category() noexcept#
+

Returns generic HPX error category used for errors re-thrown after the exception has been de-serialized.

+
+ +
+
+inline error_code make_success_code(throwmode mode = throwmode::plain)#
+

Returns error_code(hpx::error::success, “success”, mode).

+
+ +
+
+
+class error_code : public error_code#
+
+#include <error_code.hpp>
+

A hpx::error_code represents an arbitrary error condition.

+

The class hpx::error_code describes an object used to hold error code values, such as those originating from the operating system or other low-level application program interfaces.

+
+

Note

+

Class hpx::error_code is an adjunct to error reporting by exception

+
+
+

Public Functions

+
+
+inline explicit error_code(throwmode mode = throwmode::plain)#
+

Construct an object of type error_code.

+
+
Parameters
+

mode – The parameter mode specifies whether the constructed hpx::error_code belongs to the error category hpx_category (if mode is plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

+
+
Throws
+

nothing

+
+
+
+ +
+
+explicit error_code(error e, throwmode mode = throwmode::plain)#
+

Construct an object of type error_code.

+
+
Parameters
+
    +
  • e – The parameter e holds the hpx::error code the new exception should encapsulate.

  • +
  • mode – The parameter mode specifies whether the constructed hpx::error_code belongs to the error category hpx_category (if mode is plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

  • +
+
+
Throws
+

nothing

+
+
+
+ +
+
+error_code(error e, char const *func, char const *file, long line, throwmode mode = throwmode::plain)#
+

Construct an object of type error_code.

+
+
Parameters
+
    +
  • e – The parameter e holds the hpx::error code the new exception should encapsulate.

  • +
  • func – The name of the function where the error was raised.

  • +
  • file – The file name of the code where the error was raised.

  • +
  • line – The line number of the code line where the error was raised.

  • +
  • mode – The parameter mode specifies whether the constructed hpx::error_code belongs to the error category hpx_category (if mode is plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

  • +
+
+
Throws
+

nothing

+
+
+
+ +
+
+error_code(error e, char const *msg, throwmode mode = throwmode::plain)#
+

Construct an object of type error_code.

+
+
Parameters
+
    +
  • e – The parameter e holds the hpx::error code the new exception should encapsulate.

  • +
  • msg – The parameter msg holds the error message the new exception should encapsulate.

  • +
  • mode – The parameter mode specifies whether the constructed hpx::error_code belongs to the error category hpx_category (if mode is plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

  • +
+
+
Throws
+

std::bad_alloc – (if allocation of a copy of the passed string fails).

+
+
+
+ +
+
+error_code(error e, char const *msg, char const *func, char const *file, long line, throwmode mode = throwmode::plain)#
+

Construct an object of type error_code.

+
+
Parameters
+
    +
  • e – The parameter e holds the hpx::error code the new exception should encapsulate.

  • +
  • msg – The parameter msg holds the error message the new exception should encapsulate.

  • +
  • func – The name of the function where the error was raised.

  • +
  • file – The file name of the code where the error was raised.

  • +
  • line – The line number of the code line where the error was raised.

  • +
  • mode – The parameter mode specifies whether the constructed hpx::error_code belongs to the error category hpx_category (if mode is plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

  • +
+
+
Throws
+

std::bad_alloc – (if allocation of a copy of the passed string fails).

+
+
+
+ +
+
+error_code(error e, std::string const &msg, throwmode mode = throwmode::plain)#
+

Construct an object of type error_code.

+
+
Parameters
+
    +
  • e – The parameter e holds the hpx::error code the new exception should encapsulate.

  • +
  • msg – The parameter msg holds the error message the new exception should encapsulate.

  • +
  • mode – The parameter mode specifies whether the constructed hpx::error_code belongs to the error category hpx_category (if mode is plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

  • +
+
+
Throws
+

std::bad_alloc – (if allocation of a copy of the passed string fails).

+
+
+
+ +
+
+error_code(error e, std::string const &msg, char const *func, char const *file, long line, throwmode mode = throwmode::plain)#
+

Construct an object of type error_code.

+
+
Parameters
+
    +
  • e – The parameter e holds the hpx::error code the new exception should encapsulate.

  • +
  • msg – The parameter msg holds the error message the new exception should encapsulate.

  • +
  • func – The name of the function where the error was raised.

  • +
  • file – The file name of the code where the error was raised.

  • +
  • line – The line number of the code line where the error was raised.

  • +
  • mode – The parameter mode specifies whether the constructed hpx::error_code belongs to the error category hpx_category (if mode is plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

  • +
+
+
Throws
+

std::bad_alloc – (if allocation of a copy of the passed string fails).

+
+
+
+ +
+
+std::string get_message() const#
+

Return a reference to the error message stored in the hpx::error_code.

+
+
Throws
+

nothing

+
+
+
+ +
+
+inline void clear()#
+

Clear this error_code object. The postconditions of invoking this method are.

+

+

+
+ +
+
+error_code(error_code const &rhs)#
+

Copy constructor for error_code

+
+

Note

+

This function maintains the error category of the left hand side if the right hand side is a success code.

+
+
+ +
+
+error_code &operator=(error_code const &rhs)#
+

Assignment operator for error_code

+
+

Note

+

This function maintains the error category of the left hand side if the right hand side is a success code.

+
+
+ +
+
+

Private Functions

+
+
+error_code(int err, hpx::exception const &e)#
+
+ +
+
+explicit error_code(std::exception_ptr const &e)#
+
+ +
+
+

Private Members

+
+
+std::exception_ptr exception_#
+
+ +
+
+

Friends

+
+
+friend class exception
+
+ +
+
+friend error_code make_error_code(std::exception_ptr const&)#
+
+ +
+
+ +
+ +
+
+
hpx::exception#
+

Defined in header hpx/exception.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Typedefs

+
+
+using custom_exception_info_handler_type = std::function<hpx::exception_info(std::string const&, std::string const&, long, std::string const&)>#
+
+ +
+
+using pre_exception_handler_type = std::function<void()>#
+
+ +
+
+

Functions

+
+
+void set_custom_exception_info_handler(custom_exception_info_handler_type f)#
+
+ +
+
+void set_pre_exception_handler(pre_exception_handler_type f)#
+
+ +
+
+std::string get_error_what(exception_info const &xi)#
+

Return the error message of the thrown exception.

+

The function hpx::get_error_what can be used to extract the diagnostic information element representing the error message as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error() hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

std::bad_alloc – (if one of the required allocations fails)

+
+
Returns
+

The error message stored in the exception If the exception instance does not hold this information, the function will return an empty string.

+
+
+
+ +
+
+error get_error(hpx::exception const &e)#
+

Return the error code value of the exception thrown.

+

The function hpx::get_error can be used to extract the diagnostic information element representing the error value code as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

e – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception, hpx::error_code, or std::exception_ptr.

+
+
Throws
+

nothing

+
+
Returns
+

The error value code of the locality where the exception was thrown. If the exception instance does not hold this information, the function will return hpx::naming::invalid_locality_id.

+
+
+
+ +
+
+error get_error(hpx::error_code const &e)#
+
+ +
+
+std::string get_error_function_name(hpx::exception_info const &xi)#
+

Return the function name from which the exception was thrown.

+

The function hpx::get_error_function_name can be used to extract the diagnostic information element representing the name of the function as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id() hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

std::bad_alloc – (if one of the required allocations fails)

+
+
Returns
+

The name of the function from which the exception was thrown. If the exception instance does not hold this information, the function will return an empty string.

+
+
+
+ +
+
+std::string get_error_file_name(hpx::exception_info const &xi)#
+

Return the (source code) file name of the function from which the exception was thrown.

+

The function hpx::get_error_file_name can be used to extract the diagnostic information element representing the name of the source file as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

std::bad_alloc – (if one of the required allocations fails)

+
+
Returns
+

The name of the source file of the function from which the exception was thrown. If the exception instance does not hold this information, the function will return an empty string.

+
+
+
+ +
+
+long get_error_line_number(hpx::exception_info const &xi)#
+

Return the line number in the (source code) file of the function from which the exception was thrown.

+

The function hpx::get_error_line_number can be used to extract the diagnostic information element representing the line number as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name() hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

nothing

+
+
Returns
+

The line number of the place where the exception was thrown. If the exception instance does not hold this information, the function will return -1.

+
+
+
+ +
+
+
+class bad_alloc_exception : public hpx::exception, public bad_alloc#
+
+

Public Functions

+
+
+bad_alloc_exception()#
+

Construct a hpx::bad_alloc_exception.

+
+ +
+
+error_code get_error_code(throwmode mode = throwmode::plain) const noexcept#
+

The function get_error_code() returns a hpx::error_code which represents the same error condition as this hpx::exception instance.

+
+
Parameters
+

mode – The parameter mode specifies whether the returned hpx::error_code belongs to the error category hpx_category (if mode is throwmode::plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

+
+
+
+ +
+
+

Public Static Functions

+
+
+static inline constexpr error get_error() noexcept#
+

The function get_error() returns hpx::error::out_of_memory

+
+
Throws
+

nothing

+
+
+
+ +
+
+ +
+
+class exception : public system_error#
+
+#include <exception.hpp>
+

A hpx::exception is the main exception type used by HPX to report errors.

+

The hpx::exception type is the main exception type used by HPX to report errors. Any exceptions thrown by functions in the HPX library are either of this type or of a type derived from it. This implies that it is always safe to use this type only in catch statements guarding HPX library calls.

+

Subclassed by hpx::bad_alloc_exception, hpx::exception_list

+
+

Public Functions

+
+
+explicit exception(error e = hpx::error::success)#
+

Construct a hpx::exception from a hpx::error.

+
+
Parameters
+

e – The parameter e holds the hpx::error code the new exception should encapsulate.

+
+
+
+ +
+
+explicit exception(std::system_error const &e)#
+

Construct a hpx::exception from a boost::system_error.

+
+ +
+
+explicit exception(std::error_code const &e)#
+

Construct a hpx::exception from a boost::system::error_code (this is new for Boost V1.69). This constructor is required to compensate for the changes introduced as a resolution to LWG3162 (https://cplusplus.github.io/LWG/issue3162).

+
+ +
+
+exception(error e, char const *msg, throwmode mode = throwmode::plain)#
+

Construct a hpx::exception from a hpx::error and an error message.

+
+
Parameters
+
    +
  • e – The parameter e holds the hpx::error code the new exception should encapsulate.

  • +
  • msg – The parameter msg holds the error message the new exception should encapsulate.

  • +
  • mode – The parameter mode specifies whether the returned hpx::error_code belongs to the error category hpx_category (if mode is plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

  • +
+
+
+
+ +
+
+exception(error e, std::string const &msg, throwmode mode = throwmode::plain)#
+

Construct a hpx::exception from a hpx::error and an error message.

+
+
Parameters
+
    +
  • e – The parameter e holds the hpx::error code the new exception should encapsulate.

  • +
  • msg – The parameter msg holds the error message the new exception should encapsulate.

  • +
  • mode – The parameter mode specifies whether the returned hpx::error_code belongs to the error category hpx_category (if mode is plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

  • +
+
+
+
+ +
+
+~exception() override#
+

Destruct a hpx::exception

+
+
Throws
+

nothing

+
+
+
+ +
+
+error get_error() const noexcept#
+

The function get_error() returns the hpx::error code stored in the referenced instance of a hpx::exception. It returns the hpx::error code this exception instance was constructed from.

+
+
Throws
+

nothing

+
+
+
+ +
+
+error_code get_error_code(throwmode mode = throwmode::plain) const noexcept#
+

The function get_error_code() returns a hpx::error_code which represents the same error condition as this hpx::exception instance.

+
+
Parameters
+

mode – The parameter mode specifies whether the returned hpx::error_code belongs to the error category hpx_category (if mode is throwmode::plain, this is the default) or to the category hpx_category_rethrow (if mode is rethrow).

+
+
+
+ +
+
+ +
+
+struct thread_interrupted : public exception#
+
+#include <exception.hpp>
+

A hpx::thread_interrupted is the exception type used by HPX to interrupt a running HPX thread.

+

The hpx::thread_interrupted type is the exception type used by HPX to interrupt a running thread.

+

A running thread can be interrupted by invoking the interrupt() member function of the corresponding hpx::thread object. When the interrupted thread next executes one of the specified interruption points (or if it is currently blocked whilst executing one) with interruption enabled, then a hpx::thread_interrupted exception will be thrown in the interrupted thread. If not caught, this will cause the execution of the interrupted thread to terminate. As with any other exception, the stack will be unwound, and destructors for objects of automatic storage duration will be executed.

+

If a thread wishes to avoid being interrupted, it can create an instance of hpx::this_thread::disable_interruption. Objects of this class disable interruption for the thread that created them on construction, and restore the interruption state to whatever it was before on destruction.

+

void f()
+{
+    // interruption enabled here
+    {
+        hpx::this_thread::disable_interruption di;
+        // interruption disabled
+        {
+            hpx::this_thread::disable_interruption di2;
+            // interruption still disabled
+        } // di2 destroyed, interruption state restored
+        // interruption still disabled
+    } // di destroyed, interruption state restored
+    // interruption now enabled
+}
+
+
+

+

The effects of an instance of hpx::this_thread::disable_interruption can be temporarily reversed by constructing an instance of hpx::this_thread::restore_interruption, passing in the hpx::this_thread::disable_interruption object in question. This will restore the interruption state to what it was when the hpx::this_thread::disable_interruption object was constructed, and then disable interruption again when the hpx::this_thread::restore_interruption object is destroyed.

+

void g()
+{
+    // interruption enabled here
+    {
+        hpx::this_thread::disable_interruption di;
+        // interruption disabled
+        {
+            hpx::this_thread::restore_interruption ri(di);
+            // interruption now enabled
+        } // ri destroyed, interruption disable again
+    } // di destroyed, interruption state restored
+    // interruption now enabled
+}
+
+
+

+

At any point, the interruption state for the current thread can be queried by calling hpx::this_thread::interruption_enabled().

+
+ +
+ +
+
+
hpx/errors/exception_fwd.hpp#
+

Defined in header hpx/errors/exception_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_THROWMODE_UNSCOPED_ENUM_DEPRECATION_MSG#
+
+ +
+
+
+namespace hpx
+
+

Enums

+
+
+enum class throwmode : std::uint8_t#
+

Encode error category for new error_code.

+

Values:

+
+
+enumerator plain#
+
+ +
+
+enumerator rethrow#
+
+ +
+
+enumerator lightweight#
+
+ +
+ +
+
+

Functions

+
+
+constexpr bool operator&(throwmode lhs, throwmode rhs) noexcept#
+
+ +
+
+

Variables

+
+
+constexpr throwmode plain = throwmode::plain#
+
+ +
+
+constexpr throwmode rethrow = throwmode::rethrow#
+
+ +
+
+constexpr throwmode lightweight = throwmode::lightweight#
+
+ +
+
+constexpr throwmode lightweight_rethrow = throwmode::lightweight_rethrow#
+
+ +
+
+error_code throws#
+

Predefined error_code object used as “throw on error” tag.

+

The predefined hpx::error_code object hpx::throws is supplied for use as a “throw on error” tag.

+

Functions that specify an argument in the form ‘error_code& ec=throws’ (with appropriate namespace qualifiers), have the following error handling semantics:

+

If &ec != &throws and an error occurred: ec.value() returns the implementation specific error number for the particular error that occurred and ec.category() returns the error_category for ec.value().

+

If &ec != &throws and an error did not occur, ec.clear().

+

If an error occurs and &ec == &throws, the function throws an exception of type hpx::exception or of a type derived from it. The exception’s get_errorcode() member function returns a reference to an hpx::error_code object with the behavior as specified above.

+
+ +
+
+ +
+
+
hpx/errors/exception_list.hpp#
+

Defined in header hpx/errors/exception_list.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+class exception_list : public hpx::exception#
+
+#include <exception_list.hpp>
+

The class exception_list is a container of exception_ptr objects parallel algorithms may use to communicate uncaught exceptions encountered during parallel execution to the caller of the algorithm

+

The type exception_list::const_iterator fulfills the requirements of a forward iterator.

+
+

Public Types

+
+
+using iterator = exception_list_type::const_iterator#
+

bidirectional iterator

+
+ +
+
+

Public Functions

+
+
+inline std::size_t size() const noexcept#
+

The number of exception_ptr objects contained within the exception_list.

+
+

Note

+

Complexity: Constant time.

+
+
+ +
+
+inline exception_list_type::const_iterator begin() const noexcept#
+

An iterator referring to the first exception_ptr object contained within the exception_list.

+
+ +
+
+inline exception_list_type::const_iterator end() const noexcept#
+

An iterator which is the past-the-end value for the exception_list.

+
+ +
+
+ +
+ +
+
+
HPX_THROW_EXCEPTION, HPX_THROW_BAD_ALLOC, HPX_THROWS_IF#
+

Defined in header hpx/exception.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_THROW_EXCEPTION(errcode, f, ...)#
+

Throw a hpx::exception initialized from the given parameters.

+

The macro HPX_THROW_EXCEPTION can be used to throw a hpx::exception. The purpose of this macro is to prepend the source file name and line number of the position where the exception is thrown to the error message. Moreover, this associates additional diagnostic information with the exception, such as file name and line number, locality id and thread id, and stack backtrace from the point where the exception was thrown.

+

The parameter errcode holds the hpx::error code the new exception should encapsulate. The parameter f is expected to hold the name of the function exception is thrown from and the parameter msg holds the error message the new exception should encapsulate.

+

void raise_exception()
+{
+    // Throw a hpx::exception initialized from the given parameters.
+    // Additionally associate with this exception some detailed
+    // diagnostic information about the throw-site.
+    HPX_THROW_EXCEPTION(hpx::error::no_success, "raise_exception",
+       "simulated error");
+}
+
+
+
+
Example:

+
+
+

+
+ +
+
+HPX_THROW_BAD_ALLOC(f)#
+

Throw a hpx::bad_alloc_exception initialized from the given parameters.

+

The macro HPX_THROW_BAD_ALLOC can be used to throw a hpx::exception. The purpose of this macro is to prepend the source file name and line number of the position where the exception is thrown to the error message. Moreover, this associates additional diagnostic information with the exception, such as file name and line number, locality id and thread id, and stack backtrace from the point where the exception was thrown.

+

The parameter errcode holds the hpx::error code the new exception should encapsulate. The parameter f is expected to hold the name of the function exception is thrown from and the parameter msg holds the error message the new exception should encapsulate.

+

void raise_exception()
+{
+    // Throw a hpx::exception initialized from the given parameters.
+    // Additionally associate with this exception some detailed
+    // diagnostic information about the throw-site.
+    HPX_THROW_BAD_ALLOC("raise_exception", "simulated error");
+}
+
+
+
+
Example:

+
+
+

+
+ +
+
+HPX_THROWS_IF(ec, errcode, f, ...)#
+

Either throw a hpx::exception or initialize hpx::error_code from the given parameters.

+

The macro HPX_THROWS_IF can be used to either throw a hpx::exception or to initialize a hpx::error_code from the given parameters. If &ec == &hpx::throws, the semantics of this macro are equivalent to HPX_THROW_EXCEPTION. If &ec != &hpx::throws, the hpx::error_code instance ec is initialized instead.

+

The parameter errcode holds the hpx::error code from which the new exception should be initialized. The parameter f is expected to hold the name of the function exception is thrown from and the parameter msg holds the error message the new exception should encapsulate.

+
+ +
+
+HPX_THROWS_BAD_ALLOC_IF(ec, f)#
+

Either throw a hpx::bad_alloc_exception or hpx::error_code to out_of_memory.

+

The macro HPX_THROWS_BAD_ALLOC_IF can be used to either throw a hpx::bad_alloc_exception or to initialize a hpx::error_code to hpx::error::out_of_memory. If &ec == &hpx::throws, the semantics of this macro are equivalent to HPX_THROW_BAD_ALLOC. If &ec != &hpx::throws, the hpx::error_code instance ec is initialized instead.

+
+ +
+
+
+namespace hpx
+
+ +
+
+
+
+
execution#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/execution/executors/adaptive_static_chunk_size.hpp#
+

Defined in header hpx/execution/executors/adaptive_static_chunk_size.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+

Typedefs

+
+
+typedef hpx::execution::experimental::adaptive_static_chunk_size instead#
+
+ +
+
+
+namespace experimental
+
+
+struct adaptive_static_chunk_size#
+
+#include <adaptive_static_chunk_size.hpp>
+

Loop iterations are divided into pieces of size chunk_size and then assigned to threads. If chunk_size is not specified, the iterations are evenly (if possible) divided contiguously among the threads.

+
+

Note

+

This executor parameters type is equivalent to OpenMP’s STATIC scheduling directive.

+
+
+

Public Functions

+
+
+adaptive_static_chunk_size() = default#
+

Construct a adaptive_static_chunk_size executor parameters object

+
+

Note

+

By default the number of loop iterations is determined from the number of available cores and the overall number of loop iterations to schedule.

+
+
+ +
+
+inline explicit constexpr adaptive_static_chunk_size(std::size_t chunk_size) noexcept#
+

Construct a adaptive_static_chunk_size executor parameters object

+
+
Parameters
+

chunk_size – [in] The optional chunk size to use as the number of loop iterations to run on a single thread.

+
+
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx::execution::experimental::auto_chunk_size#
+

Defined in header hpx/execution.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+
+struct auto_chunk_size#
+
+#include <auto_chunk_size.hpp>
+

Loop iterations are divided into pieces and then assigned to threads. The number of loop iterations combined is determined based on measurements of how long the execution of 1% of the overall number of iterations takes. This executor parameters type makes sure that as many loop iterations are combined as necessary to run for the amount of time specified.

+
+

Public Functions

+
+
+inline explicit constexpr auto_chunk_size(std::uint64_t num_iters_for_timing = 0) noexcept#
+

Construct an auto_chunk_size executor parameters object

+
+

Note

+

Default constructed auto_chunk_size executor parameter types will use 80 microseconds as the minimal time for which any of the scheduled chunks should run.

+
+
+ +
+
+inline explicit auto_chunk_size(hpx::chrono::steady_duration const &rel_time, std::uint64_t num_iters_for_timing = 0) noexcept#
+

Construct an auto_chunk_size executor parameters object

+
+
Parameters
+
    +
  • rel_time – [in] The time duration to use as the minimum to decide how many loop iterations should be combined.

  • +
  • num_iters_for_timing – [in] The number of iterations to use for the timing operation

  • +
+
+
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/execution/executors/default_parameters.hpp#
+

Defined in header hpx/execution/executors/default_parameters.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+
+struct default_parameters#
+
+#include <default_parameters.hpp>
+

Loop iterations are divided into pieces of size chunk_size and then assigned to threads. If chunk_size is not specified, the iterations are evenly (if possible) divided contiguously among the threads.

+
+

Note

+

This executor parameters type is equivalent to OpenMP’s STATIC scheduling directive.

+
+
+

Public Functions

+
+
+default_parameters() = default#
+

Construct a default_parameters executor parameters object

+
+

Note

+

By default the number of loop iterations is determined from the number of available cores and the overall number of loop iterations to schedule.

+
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx::execution::experimental::dynamic_chunk_size#
+

Defined in header hpx/execution.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+
+struct dynamic_chunk_size#
+
+#include <dynamic_chunk_size.hpp>
+

Loop iterations are divided into pieces of size chunk_size and then dynamically scheduled among the threads; when a thread finishes one chunk, it is dynamically assigned another If chunk_size is not specified, the default chunk size is 1.

+
+

Note

+

This executor parameters type is equivalent to OpenMP’s DYNAMIC scheduling directive.

+
+
+

Public Functions

+
+
+dynamic_chunk_size() = default#
+

Construct an dynamic_chunk_size executor parameters object

+
+

Note

+

Default constructed dynamic_chunk_size executor parameter types will use a chunk size of ‘1’.

+
+
+ +
+
+inline explicit constexpr dynamic_chunk_size(std::size_t chunk_size) noexcept#
+

Construct a dynamic_chunk_size executor parameters object

+
+
Parameters
+

chunk_size – [in] The optional chunk size to use as the number of loop iterations to schedule together. The default chunk size is 1.

+
+
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/execution/executors/execution.hpp#
+

Defined in header hpx/execution/executors/execution.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
hpx/execution/executors/execution_information.hpp#
+

Defined in header hpx/execution/executors/execution_information.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Variables

+
+
+hpx::parallel::execution::has_pending_closures_t has_pending_closures#
+
+ +
+
+hpx::parallel::execution::get_pu_mask_t get_pu_mask#
+
+ +
+
+hpx::parallel::execution::set_scheduler_mode_t set_scheduler_mode#
+
+ +
+
+
+struct get_pu_mask_t : public hpx::functional::detail::tag_fallback<get_pu_mask_t>#
+
+#include <execution_information.hpp>
+

Retrieve the bitmask describing the processing units the given thread is allowed to run on

+

All threads::executors invoke sched.get_pu_mask().

+
+

Note

+

If the executor does not support this operation, this call will always invoke hpx::threads::get_pu_mask()

+
+
+
Param exec
+

[in] The executor object to use for querying the number of pending tasks.

+
+
Param topo
+

[in] The topology object to use to extract the requested information.

+
+
Param thream_num
+

[in] The sequence number of the thread to retrieve information for.

+
+
+
+

Private Functions

+
+
+template<typename Executor>
inline decltype(auto) friend tag_fallback_invoke(get_pu_mask_t, Executor&&, threads::topology &topo, std::size_t thread_num)#
+
+ +
+
+template<typename Executor>
inline decltype(auto) friend tag_invoke(get_pu_mask_t, Executor &&exec, threads::topology &topo, std::size_t thread_num)#
+
+ +
+
+ +
+
+struct has_pending_closures_t : public hpx::functional::detail::tag_fallback<has_pending_closures_t>#
+
+#include <execution_information.hpp>
+

Retrieve whether this executor has operations pending or not.

+
+

Note

+

If the executor does not expose this information, this call will always return false

+
+
+
Param exec
+

[in] The executor object to use to extract the requested information for.

+
+
+
+

Private Functions

+
+
+template<typename Executor>
inline decltype(auto) friend tag_fallback_invoke(has_pending_closures_t, Executor&&)#
+
+ +
+
+template<typename Executor>
inline decltype(auto) friend tag_invoke(has_pending_closures_t, Executor &&exec)#
+
+ +
+
+ +
+
+struct set_scheduler_mode_t : public hpx::functional::detail::tag_fallback<set_scheduler_mode_t>#
+
+#include <execution_information.hpp>
+

Set various modes of operation on the scheduler underneath the given executor.

+
+

Note

+

This calls exec.set_scheduler_mode(mode) if it exists; otherwise it does nothing.

+
+
+
Param exec
+

[in] The executor object to use.

+
+
Param mode
+

[in] The new mode for the scheduler to pick up

+
+
+
+

Friends

+
+
+template<typename Executor, typename Mode>
inline friend void tag_fallback_invoke(set_scheduler_mode_t, Executor&&, Mode const&)#
+
+ +
+
+template<typename Executor, typename Mode>
inline friend void tag_invoke(set_scheduler_mode_t, Executor &&exec, Mode const &mode)#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/execution/executors/execution_parameters.hpp#
+

Defined in header hpx/execution/executors/execution_parameters.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Functions

+
+
+template<typename ...Params>
constexpr executor_parameters_join<Params...>::type join_executor_parameters(Params&&... params)#
+
+ +
+
+template<typename Param>
constexpr Param &&join_executor_parameters(Param &&param) noexcept#
+
+ +
+
+
+template<typename ...Params>
struct executor_parameters_join#
+
+

Public Types

+
+
+using type = detail::executor_parameters<std::decay_t<Params>...>#
+
+ +
+
+ +
+
+template<typename Param>
struct executor_parameters_join<Param>#
+
+

Public Types

+
+
+using type = Param#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/execution/executors/execution_parameters_fwd.hpp#
+

Defined in header hpx/execution/executors/execution_parameters_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<>
struct is_scheduling_property<hpx::parallel::execution::with_processing_units_count_t> : public true_type#
+
+ +
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Variables

+
+
+constexpr struct hpx::parallel::execution::null_parameters_t null_parameters#
+
+ +
+
+hpx::parallel::execution::get_chunk_size_t get_chunk_size#
+
+ +
+
+hpx::parallel::execution::measure_iteration_t measure_iteration#
+
+ +
+
+hpx::parallel::execution::maximal_number_of_chunks_t maximal_number_of_chunks#
+
+ +
+
+hpx::parallel::execution::reset_thread_distribution_t reset_thread_distribution#
+
+ +
+
+hpx::parallel::execution::processing_units_count_t processing_units_count#
+
+ +
+
+hpx::parallel::execution::with_processing_units_count_t with_processing_units_count#
+
+ +
+
+hpx::parallel::execution::mark_begin_execution_t mark_begin_execution#
+
+ +
+
+hpx::parallel::execution::mark_end_of_scheduling_t mark_end_of_scheduling#
+
+ +
+
+hpx::parallel::execution::mark_end_execution_t mark_end_execution#
+
+ +
+
+
+struct get_chunk_size_t : public hpx::functional::detail::tag_priority<get_chunk_size_t>#
+
+#include <execution_parameters_fwd.hpp>
+

Return the number of invocations of the given function f which should be combined into a single task

+
+
Param params
+

[in] The executor parameters object to use for determining the chunk size for the given number of tasks num_tasks.

+
+
Param exec
+

[in] The executor object which will be used for scheduling of the loop iterations.

+
+
Param iteration_duration
+

[in] The time one of the tasks require to be executed.

+
+
Param cores
+

[in] The number of cores the number of chunks should be determined for.

+
+
Param num_tasks
+

[in] The number of tasks the chunk size should be determined for

+
+
Return
+

The size of the chunks (number of iterations per chunk) that should be used for parallel execution.

+
+
+
+

Private Functions

+
+
+template<typename Parameters, typename Executor>
inline decltype(auto) friend tag_fallback_invoke(get_chunk_size_t, Parameters &&params, Executor &&exec, hpx::chrono::steady_duration const &iteration_duration, std::size_t cores, std::size_t num_tasks)#
+
+ +
+
+template<typename Parameters, typename Executor>
inline decltype(auto) friend tag_fallback_invoke(get_chunk_size_t tag, Parameters &&params, Executor &&exec, std::size_t cores, std::size_t num_tasks)#
+
+ +
+
+ +
+
+struct mark_begin_execution_t : public hpx::functional::detail::tag_priority<mark_begin_execution_t>#
+
+#include <execution_parameters_fwd.hpp>
+

Mark the begin of a parallel algorithm execution

+
+

Note

+

This calls params.mark_begin_execution(exec) if it exists; otherwise it does nothing.

+
+
+
Param params
+

[in] The executor parameters object to use as a fallback if the executor does not expose

+
+
+
+

Private Functions

+
+
+template<typename Parameters, typename Executor>
inline decltype(auto) friend tag_fallback_invoke(mark_begin_execution_t, Parameters &&params, Executor &&exec)#
+
+ +
+
+ +
+
+struct mark_end_execution_t : public hpx::functional::detail::tag_priority<mark_end_execution_t>#
+
+#include <execution_parameters_fwd.hpp>
+

Mark the end of a parallel algorithm execution

+
+

Note

+

This calls params.mark_end_execution(exec) if it exists; otherwise it does nothing.

+
+
+
Param params
+

[in] The executor parameters object to use as a fallback if the executor does not expose

+
+
+
+

Private Functions

+
+
+template<typename Parameters, typename Executor>
inline decltype(auto) friend tag_fallback_invoke(mark_end_execution_t, Parameters &&params, Executor &&exec)#
+
+ +
+
+ +
+
+struct mark_end_of_scheduling_t : public hpx::functional::detail::tag_priority<mark_end_of_scheduling_t>#
+
+#include <execution_parameters_fwd.hpp>
+

Mark the end of scheduling tasks during parallel algorithm execution

+
+

Note

+

This calls params.mark_begin_execution(exec) if it exists; otherwise it does nothing.

+
+
+
Param params
+

[in] The executor parameters object to use as a fallback if the executor does not expose

+
+
+
+

Private Functions

+
+
+template<typename Parameters, typename Executor>
inline decltype(auto) friend tag_fallback_invoke(mark_end_of_scheduling_t, Parameters &&params, Executor &&exec)#
+
+ +
+
+ +
+
+struct maximal_number_of_chunks_t : public hpx::functional::detail::tag_priority<maximal_number_of_chunks_t>#
+
+#include <execution_parameters_fwd.hpp>
+

Return the largest reasonable number of chunks to create for a single algorithm invocation.

+
+
Param params
+

[in] The executor parameters object to use for determining the number of chunks for the given number of cores.

+
+
Param exec
+

[in] The executor object which will be used for scheduling of the loop iterations.

+
+
Param cores
+

[in] The number of cores the number of chunks should be determined for.

+
+
Param num_tasks
+

[in] The number of tasks the chunk size should be determined for

+
+
+
+

Private Functions

+
+
+template<typename Parameters, typename Executor>
inline decltype(auto) friend tag_fallback_invoke(maximal_number_of_chunks_t, Parameters &&params, Executor &&exec, std::size_t cores, std::size_t num_tasks)#
+
+ +
+
+ +
+
+struct measure_iteration_t : public hpx::functional::detail::tag_priority<measure_iteration_t>#
+
+#include <execution_parameters_fwd.hpp>
+

Return the measured execution time for one iteration based on running the given function.

+
+

Note

+

The parameter f is expected to be a nullary function returning a std::size_t representing the number of iteration the function has already executed (i.e. which don’t have to be scheduled anymore).

+
+
+
Param params
+

[in] The executor parameters object to use for determining the chunk size for the given number of tasks num_tasks.

+
+
Param exec
+

[in] The executor object which will be used for scheduling of the loop iterations.

+
+
Param f
+

[in] The function which will be optionally scheduled using the given executor.

+
+
Param num_tasks
+

[in] The number of tasks the chunk size should be determined for

+
+
Return
+

The execution time for one of the tasks.

+
+
+
+

Private Functions

+
+
+template<typename Parameters, typename Executor, typename F>
inline decltype(auto) friend tag_fallback_invoke(measure_iteration_t, Parameters &&params, Executor &&exec, F &&f, std::size_t num_tasks)#
+
+ +
+
+ +
+
+struct null_parameters_t#
+
+ +
+
+struct processing_units_count_t : public hpx::functional::detail::tag_priority<processing_units_count_t>#
+
+#include <execution_parameters_fwd.hpp>
+

Retrieve the number of (kernel-)threads used by the associated executor.

+
+

Note

+

This calls params.processing_units_count(Executor&&) if it exists; otherwise it forwards the request to the executor parameters object.

+
+
+
Param params
+

[in] The executor parameters object to use as a fallback if the executor does not expose

+
+
Param iteration_duration
+

[in] The time one of the tasks require to be executed.

+
+
Param num_tasks
+

[in] The number of tasks the number of cores should be determined for

+
+
Return
+

The number of cores to use

+
+
+
+

Private Functions

+
+
+template<typename Parameters, typename Executor>
inline decltype(auto) friend tag_fallback_invoke(processing_units_count_t, Parameters &&params, Executor &&exec, hpx::chrono::steady_duration const &iteration_duration, std::size_t num_tasks)#
+
+ +
+
+template<typename Parameters, typename Executor>
inline decltype(auto) friend tag_fallback_invoke(processing_units_count_t tag, Parameters &&params, Executor &&exec, std::size_t num_tasks = 0)#
+
+ +
+
+template<typename Executor>
inline decltype(auto) friend tag_fallback_invoke(processing_units_count_t, Executor &&exec, hpx::chrono::steady_duration const &iteration_duration, std::size_t num_tasks)#
+
+ +
+
+template<typename Executor>
inline decltype(auto) friend tag_fallback_invoke(processing_units_count_t tag, Executor &&exec, std::size_t num_tasks = 0)#
+
+ +
+
+ +
+
+struct reset_thread_distribution_t : public hpx::functional::detail::tag_priority<reset_thread_distribution_t>#
+
+#include <execution_parameters_fwd.hpp>
+

Reset the internal round robin thread distribution scheme for the given executor.

+
+

Note

+

This calls params.reset_thread_distribution(exec) if it exists; otherwise it does nothing.

+
+
+
Param params
+

[in] The executor parameters object to use for resetting the thread distribution scheme.

+
+
Param exec
+

[in] The executor object to use.

+
+
+
+

Private Functions

+
+
+template<typename Parameters, typename Executor>
inline decltype(auto) friend tag_fallback_invoke(reset_thread_distribution_t, Parameters &&params, Executor &&exec)#
+
+ +
+
+ +
+
+struct with_processing_units_count_t : public hpx::functional::detail::tag_priority<with_processing_units_count_t>#
+
+#include <execution_parameters_fwd.hpp>
+

Generate a policy that supports setting the number of cores for execution.

+
+ +
+ +
+ +
+ +
+
+
hpx::execution::experimental::guided_chunk_size#
+

Defined in header hpx/execution.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+
+struct guided_chunk_size#
+
+#include <guided_chunk_size.hpp>
+

Iterations are dynamically assigned to threads in blocks as threads request those until no blocks remain to be assigned. Similar to dynamic_chunk_size except that the block size decreases each time a number of loop iterations is given to a thread. The size of the initial block is proportional to number_of_iterations / number_of_cores. Subsequent blocks are proportional to number_of_iterations_remaining / number_of_cores. The optional chunk size parameter defines the minimum block size. The default chunk size is 1.

+
+

Note

+

This executor parameters type is equivalent to OpenMP’s GUIDED scheduling directive.

+
+
+

Public Functions

+
+
+guided_chunk_size() = default#
+

Construct an dynamic_chunk_size executor parameters object

+
+

Note

+

Default constructed dynamic_chunk_size executor parameter types will use a chunk size of ‘1’.

+
+
+ +
+
+inline explicit constexpr guided_chunk_size(std::size_t min_chunk_size) noexcept#
+

Construct a guided_chunk_size executor parameters object

+
+
Parameters
+

min_chunk_size – [in] The optional minimal chunk size to use as the minimal number of loop iterations to schedule together. The default minimal chunk size is 1.

+
+
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx::execution::experimental::num_cores#
+

Defined in header hpx/execution.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+
+struct num_cores#
+
+#include <num_cores.hpp>
+

Control number of cores in executors which need a functionality for setting the number of cores to be used by an algorithm directly

+
+

Public Functions

+
+
+inline explicit constexpr num_cores(std::size_t cores = 1) noexcept#
+

Construct a num_cores executor parameters object

+
+

Note

+

make sure the minimal number of cores is and the maximum number of cores is what’s available to HPX

+
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx::execution::experimental::persistent_auto_chunk_size#
+

Defined in header hpx/execution.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+
+struct persistent_auto_chunk_size#
+
+#include <persistent_auto_chunk_size.hpp>
+

Loop iterations are divided into pieces and then assigned to threads. The number of loop iterations combined is determined based on measurements of how long the execution of 1% of the overall number of iterations takes. This executor parameters type makes sure that as many loop iterations are combined as necessary to run for the amount of time specified.

+
+

Public Functions

+
+
+inline explicit constexpr persistent_auto_chunk_size(std::uint64_t num_iters_for_timing = 0) noexcept#
+

Construct an persistent_auto_chunk_size executor parameters object

+
+

Note

+

Default constructed persistent_auto_chunk_size executor parameter types will use 0 microseconds as the execution time for each chunk and 80 microseconds as the minimal time for which any of the scheduled chunks should run.

+
+
+ +
+
+inline explicit persistent_auto_chunk_size(hpx::chrono::steady_duration const &time_cs, std::uint64_t num_iters_for_timing = 0) noexcept#
+

Construct an persistent_auto_chunk_size executor parameters object

+
+
Parameters
+
    +
  • time_cs – The execution time for each chunk.

  • +
  • num_iters_for_timing – [in] The number of iterations to use for measuring the execution time of one iteration

  • +
+
+
+
+ +
+
+inline persistent_auto_chunk_size(hpx::chrono::steady_duration const &time_cs, hpx::chrono::steady_duration const &rel_time, std::uint64_t num_iters_for_timing = 0) noexcept#
+

Construct an persistent_auto_chunk_size executor parameters object

+
+
Parameters
+
    +
  • rel_time – [in] The time duration to use as the minimum to decide how many loop iterations should be combined.

  • +
  • time_cs – The execution time for each chunk.

  • +
  • num_iters_for_timing – [in] The number of iterations to use for measuring the execution time of one iteration

  • +
+
+
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/execution/executors/polymorphic_executor.hpp#
+

Defined in header hpx/execution/executors/polymorphic_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+
+template<typename Sig>
class polymorphic_executor#
+
+ +
+
+template<typename R, typename ...Ts>
class polymorphic_executor<R(Ts...)> : private hpx::parallel::execution::detail::polymorphic_executor_base#
+
+

Public Types

+
+
+template<typename>
using future_type = hpx::future<R>#
+
+ +
+
+

Public Functions

+
+
+inline constexpr polymorphic_executor() noexcept#
+
+ +
+
+inline polymorphic_executor(polymorphic_executor const &other)#
+
+ +
+
+inline polymorphic_executor(polymorphic_executor &&other) noexcept#
+
+ +
+
+inline polymorphic_executor &operator=(polymorphic_executor const &other)#
+
+ +
+
+inline polymorphic_executor &operator=(polymorphic_executor &&other) noexcept#
+
+ +
+
+template<typename Exec, typename PE = std::decay_t<Exec>, typename Enable = std::enable_if_t<!std::is_same_v<PE, polymorphic_executor>>>
inline polymorphic_executor(Exec &&exec)#
+
+ +
+
+template<typename Exec, typename PE = std::decay_t<Exec>, typename Enable = std::enable_if_t<!std::is_same_v<PE, polymorphic_executor>>>
inline polymorphic_executor &operator=(Exec &&exec)#
+
+ +
+
+inline void reset() noexcept#
+
+ +
+
+

Private Types

+
+
+using base_type = detail::polymorphic_executor_base#
+
+ +
+
+using vtable = detail::polymorphic_executor_vtable<R(Ts...)>#
+
+ +
+
+

Private Functions

+
+
+inline void assign(std::nullptr_t) noexcept#
+
+ +
+
+template<typename Exec>
inline void assign(Exec &&exec)#
+
+ +
+
+

Private Static Functions

+
+
+static inline constexpr vtable const *get_empty_vtable() noexcept#
+
+ +
+
+template<typename T>
static inline constexpr vtable const *get_vtable() noexcept#
+
+ +
+
+

Friends

+
+
+template<typename F>
inline friend void tag_invoke(hpx::parallel::execution::post_t, polymorphic_executor const &exec, F &&f, Ts... ts)#
+
+ +
+
+template<typename F>
inline friend R tag_invoke(hpx::parallel::execution::sync_execute_t, polymorphic_executor const &exec, F &&f, Ts... ts)#
+
+ +
+
+template<typename F>
inline friend hpx::future<R> tag_invoke(hpx::parallel::execution::async_execute_t, polymorphic_executor const &exec, F &&f, Ts... ts)#
+
+ +
+
+template<typename F, typename Future>
inline friend hpx::future<R> tag_invoke(hpx::parallel::execution::then_execute_t, polymorphic_executor const &exec, F &&f, Future &&predecessor, Ts&&... ts)#
+
+ +
+
+template<typename F, typename Shape>
inline friend std::vector<R> tag_invoke(hpx::parallel::execution::bulk_sync_execute_t, polymorphic_executor const &exec, F &&f, Shape const &s, Ts&&... ts)#
+
+ +
+
+template<typename F, typename Shape>
inline friend std::vector<hpx::future<R>> tag_invoke(hpx::parallel::execution::bulk_async_execute_t, polymorphic_executor const &exec, F &&f, Shape const &s, Ts&&... ts)#
+
+ +
+
+template<typename F, typename Shape>
inline friend hpx::future<std::vector<R>> tag_invoke(hpx::parallel::execution::bulk_then_execute_t, polymorphic_executor const &exec, F &&f, Shape const &s, hpx::shared_future<void> const &predecessor, Ts&&... ts)#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/execution/executors/rebind_executor.hpp#
+

Defined in header hpx/execution/executors/rebind_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Typedefs

+
+
+template<typename ExPolicy, typename Executor, typename Parameters>
using rebind_executor_t = typename rebind_executor<ExPolicy, Executor, Parameters>::type#
+
+ +
+
+

Variables

+
+
+constexpr struct hpx::parallel::execution::create_rebound_policy_t create_rebound_policy#
+
+ +
+
+
+struct create_rebound_policy_t#
+
+

Public Functions

+
+
+template<typename ExPolicy, typename Executor, typename Parameters>
inline constexpr decltype(auto) operator()(ExPolicy&&, Executor &&exec, Parameters &&parameters) const#
+
+ +
+
+ +
+
+template<typename ExPolicy, typename Executor, typename Parameters>
struct rebind_executor#
+
+#include <rebind_executor.hpp>
+

Rebind the type of executor used by an execution policy. The execution category of Executor shall not be weaker than that of ExecutionPolicy.

+
+

Public Types

+
+
+using type = typename policy_type::template rebind<executor_type, parameters_type>::type#
+

The type of the rebound execution policy.

+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx::execution::experimental::static_chunk_size#
+

Defined in header hpx/execution.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+
+struct static_chunk_size#
+
+#include <static_chunk_size.hpp>
+

Loop iterations are divided into pieces of size chunk_size and then assigned to threads. If chunk_size is not specified, the iterations are evenly (if possible) divided contiguously among the threads.

+
+

Note

+

This executor parameters type is equivalent to OpenMP’s STATIC scheduling directive.

+
+
+

Public Functions

+
+
+static_chunk_size() = default#
+

Construct a static_chunk_size executor parameters object

+
+

Note

+

By default the number of loop iterations is determined from the number of available cores and the overall number of loop iterations to schedule.

+
+
+ +
+
+inline explicit constexpr static_chunk_size(std::size_t chunk_size) noexcept#
+

Construct a static_chunk_size executor parameters object

+
+
Parameters
+

chunk_size – [in] The optional chunk size to use as the number of loop iterations to run on a single thread.

+
+
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/execution/traits/is_execution_policy.hpp#
+

Defined in header hpx/execution/traits/is_execution_policy.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Variables

+
+
+template<typename T>
constexpr bool is_execution_policy_v = is_execution_policy<T>::value#
+
+ +
+
+template<typename T>
constexpr bool is_parallel_execution_policy_v = is_parallel_execution_policy<T>::value#
+
+ +
+
+template<typename T>
constexpr bool is_sequenced_execution_policy_v = is_sequenced_execution_policy<T>::value#
+
+ +
+
+template<typename T>
constexpr bool is_async_execution_policy_v = is_async_execution_policy<T>::value#
+
+ +
+
+
+template<typename T>
struct is_async_execution_policy : public hpx::detail::is_async_execution_policy<std::decay_t<T>>#
+
+#include <is_execution_policy.hpp>
+

Extension: Detect whether given execution policy makes algorithms asynchronous

+

    +
  1. The type is_async_execution_policy can be used to detect asynchronous execution policies for the purpose of excluding function signatures from otherwise ambiguous overload resolution participation.

  2. +
  3. If T is the type of a standard or implementation-defined execution policy, is_async_execution_policy<T> shall be publicly derived from integral_constant<bool, true>, otherwise from integral_constant<bool, false>.

  4. +
  5. The behavior of a program that adds specializations for is_async_execution_policy is undefined.

  6. +
+

+
+ +
+
+template<typename T>
struct is_execution_policy : public hpx::detail::is_execution_policy<std::decay_t<T>>#
+
+#include <is_execution_policy.hpp>
+

    +
  1. The type is_execution_policy can be used to detect execution policies for the purpose of excluding function signatures from otherwise ambiguous overload resolution participation.

  2. +
  3. If T is the type of a standard or implementation-defined execution policy, is_execution_policy<T> shall be publicly derived from integral_constant<bool, true>, otherwise from integral_constant<bool, false>.

  4. +
  5. The behavior of a program that adds specializations for is_execution_policy is undefined.

  6. +
+

+
+ +
+
+template<typename T>
struct is_parallel_execution_policy : public hpx::detail::is_parallel_execution_policy<std::decay_t<T>>#
+
+#include <is_execution_policy.hpp>
+

Extension: Detect whether given execution policy enables parallelization

+

    +
  1. The type is_parallel_execution_policy can be used to detect parallel execution policies for the purpose of excluding function signatures from otherwise ambiguous overload resolution participation.

  2. +
  3. If T is the type of a standard or implementation-defined execution policy, is_parallel_execution_policy<T> shall be publicly derived from integral_constant<bool, true>, otherwise from integral_constant<bool, false>.

  4. +
  5. The behavior of a program that adds specializations for is_parallel_execution_policy is undefined.

  6. +
+

+
+ +
+
+template<typename T>
struct is_sequenced_execution_policy : public hpx::detail::is_sequenced_execution_policy<std::decay_t<T>>#
+
+#include <is_execution_policy.hpp>
+

Extension: Detect whether given execution policy does not enable parallelization

+

    +
  1. The type is_sequenced_execution_policy can be used to detect non-parallel execution policies for the purpose of excluding function signatures from otherwise ambiguous overload resolution participation.

  2. +
  3. If T is the type of a standard or implementation-defined execution policy, is_sequenced_execution_policy<T> shall be publicly derived from integral_constant<bool, true>, otherwise from integral_constant<bool, false>.

  4. +
  5. The behavior of a program that adds specializations for is_sequenced_execution_policy is undefined.

  6. +
+

+
+ +
+ +
+
+
+
+
execution_base#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/execution_base/execution.hpp#
+

Defined in header hpx/execution_base/execution.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+struct parallel_execution_tag#
+
+#include <execution.hpp>
+

Function invocations executed by a group of parallel execution agents execute in unordered fashion. Any such invocations executing in the same thread are indeterminately sequenced with respect to each other.

+ +
+ +
+
+struct sequenced_execution_tag#
+
+#include <execution.hpp>
+

Function invocations executed by a group of sequential execution agents execute in sequential order.

+
+ +
+
+struct unsequenced_execution_tag#
+
+#include <execution.hpp>
+

Function invocations executed by a group of vector execution agents are permitted to execute in unordered fashion when executed in different threads, and un-sequenced with respect to one another when executed in the same thread.

+ +
+ +
+ +
+
+namespace parallel
+
+
+namespace execution
+
+

Variables

+
+
+hpx::parallel::execution::sync_execute_t sync_execute#
+
+ +
+
+hpx::parallel::execution::async_execute_t async_execute#
+
+ +
+
+hpx::parallel::execution::then_execute_t then_execute#
+
+ +
+
+hpx::parallel::execution::post_t post#
+
+ +
+
+hpx::parallel::execution::bulk_sync_execute_t bulk_sync_execute#
+
+ +
+
+hpx::parallel::execution::bulk_async_execute_t bulk_async_execute#
+
+ +
+
+hpx::parallel::execution::bulk_then_execute_t bulk_then_execute#
+
+ +
+
+hpx::parallel::execution::async_invoke_t async_invoke#
+
+ +
+
+hpx::parallel::execution::sync_invoke_t sync_invoke#
+
+ +
+
+
+struct async_execute_t : public hpx::functional::detail::tag_fallback<async_execute_t>#
+
+#include <execution.hpp>
+

Customization point for asynchronous execution agent creation.

+

This asynchronously creates a single function invocation f() using the associated executor.

+
+

Note

+

Executors have to implement only async_execute(). All other functions will be emulated by this or other customization points in terms of this single basic primitive. However, some executors will naturally specialize all operations for maximum efficiency.

+
+
+

Note

+

This is valid for one way executors (calls make_ready_future(exec.sync_execute(f, ts…) if it exists) and for two way executors (calls exec.async_execute(f, ts…) if it exists).

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param ts
+

[in] Additional arguments to use to invoke f.

+
+
Return
+

f(ts…)’s result through a future

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(async_execute_t, Executor &&exec, F &&f, Ts&&... ts)#
+
+ +
+
+ +
+
+struct async_invoke_t : public hpx::functional::detail::tag_fallback<async_invoke_t>#
+
+#include <execution.hpp>
+

Asynchronously invoke the given set of nullary functions, each on its own execution agent

+

This creates a group of function invocations whose ordering is given by the execution_category associated with the executor.

+

All exceptions thrown by invocations of the functions are reported in a manner consistent with parallel algorithm execution through the returned future.

+
+

Note

+

This calls exec.async_invoke(fs…) if it exists; otherwise it executes async_execute(fs) for each fs.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the functions fs.

+
+
Param fs
+

[in] The functions which will be scheduled using the given executor.

+
+
Return
+

The return type of executor_type::async_invoke if defined by executor_type. Otherwise a future<void> representing finishing the execution of all functions fs.

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Fs>
inline decltype(auto) friend tag_fallback_invoke(async_invoke_t, Executor &&exec, F &&f, Fs&&... fs)#
+
+ +
+
+ +
+
+struct bulk_async_execute_t : public hpx::functional::detail::tag_fallback<bulk_async_execute_t>#
+
+#include <execution.hpp>
+

Bulk form of asynchronous execution agent creation.

+

+This asynchronously creates a group of function invocations f(i) whose ordering is given by the execution_category associated with the executor.

+

Here i takes on all values in the index space implied by shape. All exceptions thrown by invocations of f(i) are reported in a manner consistent with parallel algorithm execution through the returned future.

+
+

Note

+

This is deliberately different from the bulk_async_execute customization points specified in P0443.The bulk_async_execute customization point defined here is more generic and is used as the workhorse for implementing the specified APIs.

+
+
+

Note

+

This calls exec.bulk_async_execute(f, shape, ts…) if it exists; otherwise it executes async_execute(f, shape, ts…) as often as needed.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param shape
+

[in] The shape objects which defines the iteration boundaries for the arguments to be passed to f.

+
+
Param ts
+

[in] Additional arguments to use to invoke f.

+
+
Return
+

The return type of executor_type::bulk_async_execute if defined by executor_type. Otherwise a vector of futures holding the returned values of each invocation of f.

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename Shape, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(bulk_async_execute_t, Executor &&exec, F &&f, Shape const &shape, Ts&&... ts)#
+
+ +
+
+template<typename Executor, typename F, typename Shape, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(bulk_async_execute_t tag, Executor &&exec, F &&f, Shape const &shape, Ts&&... ts)
+
+ +
+
+ +
+
+struct bulk_sync_execute_t : public hpx::functional::detail::tag_fallback<bulk_sync_execute_t>#
+
+#include <execution.hpp>
+

Bulk form of synchronous execution agent creation.

+

+This synchronously creates a group of function invocations f(i) whose ordering is given by the execution_category associated with the executor. The function synchronizes the execution of all scheduled functions with the caller.

+

Here i takes on all values in the index space implied by shape. All exceptions thrown by invocations of f(i) are reported in a manner consistent with parallel algorithm execution through the returned future.

+
+

Note

+

This is deliberately different from the bulk_sync_execute customization points specified in P0443.The bulk_sync_execute customization point defined here is more generic and is used as the workhorse for implementing the specified APIs.

+
+
+

Note

+

This calls exec.bulk_sync_execute(f, shape, ts…) if it exists; otherwise it executes sync_execute(f, shape, ts…) as often as needed.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param shape
+

[in] The shape objects which defines the iteration boundaries for the arguments to be passed to f.

+
+
Param ts
+

[in] Additional arguments to use to invoke f.

+
+
Return
+

The return type of executor_type::bulk_sync_execute if defined by executor_type. Otherwise a vector holding the returned values of each invocation of f except when f returns void, which case void is returned.

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename Shape, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(bulk_sync_execute_t, Executor &&exec, F &&f, Shape const &shape, Ts&&... ts)#
+
+ +
+
+template<typename Executor, typename F, typename Shape, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(bulk_sync_execute_t tag, Executor &&exec, F &&f, Shape const &shape, Ts&&... ts)
+
+ +
+
+ +
+
+struct bulk_then_execute_t : public hpx::functional::detail::tag_fallback<bulk_then_execute_t>#
+
+#include <execution.hpp>
+

Bulk form of execution agent creation depending on a given future.

+

+This creates a group of function invocations f(i) whose ordering is given by the execution_category associated with the executor.

+

Here i takes on all values in the index space implied by shape. All exceptions thrown by invocations of f(i) are reported in a manner consistent with parallel algorithm execution through the returned future.

+
+

Note

+

This is deliberately different from the then_sync_execute customization points specified in P0443.The bulk_then_execute customization point defined here is more generic and is used as the workhorse for implementing the specified APIs.

+
+
+

Note

+

This calls exec.bulk_then_execute(f, shape, pred, ts…) if it exists; otherwise it executes sync_execute(f, shape, pred.share(), ts…) (if this executor is also an OneWayExecutor), or async_execute(f, shape, pred.share(), ts…) (if this executor is also a TwoWayExecutor) - as often as needed.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param shape
+

[in] The shape objects which defines the iteration boundaries for the arguments to be passed to f.

+
+
Param predecessor
+

[in] The future object the execution of the given function depends on.

+
+
Param ts
+

[in] Additional arguments to use to invoke f.

+
+
Return
+

The return type of executor_type::bulk_then_execute if defined by executor_type. Otherwise a vector holding the returned values of each invocation of f.

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename Shape, typename Future, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(bulk_then_execute_t, Executor &&exec, F &&f, Shape const &shape, Future &&predecessor, Ts&&... ts)#
+
+ +
+
+template<typename Executor, typename F, typename Shape, typename Future, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(bulk_then_execute_t tag, Executor &&exec, F &&f, Shape const &shape, Future &&predecessor, Ts&&... ts)
+
+ +
+
+ +
+
+struct post_t : public hpx::functional::detail::tag_fallback<post_t>#
+
+#include <execution.hpp>
+

Customization point for asynchronous fire & forget execution agent creation.

+

This asynchronously (fire & forget) creates a single function invocation f() using the associated executor.

+
+

Note

+

This is valid for two way executors (calls exec.post(f, ts…), if available, otherwise it calls exec.async_execute(f, ts…) while discarding the returned future), and for non-blocking two way executors (calls exec.post(f, ts…) if it exists).

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param ts
+

[in] Additional arguments to use to invoke f.

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(post_t, Executor &&exec, F &&f, Ts&&... ts)#
+
+ +
+
+ +
+
+struct sync_execute_t : public hpx::functional::detail::tag_fallback<sync_execute_t>#
+
+#include <execution.hpp>
+

Customization point for synchronous execution agent creation.

+

This synchronously creates a single function invocation f() using the associated executor. The execution of the supplied function synchronizes with the caller

+
+

Note

+

It will call tag_invoke(sync_execute_t, exec, f, ts…) if it exists. For two-way executors it will invoke asynch_execute_t and wait for the task’s completion before returning.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param ts
+

[in] Additional arguments to use to invoke f.

+
+
Return
+

f(ts…)’s result

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(sync_execute_t, Executor &&exec, F &&f, Ts&&... ts)#
+
+ +
+
+ +
+
+struct sync_invoke_t : public hpx::functional::detail::tag_fallback<sync_invoke_t>#
+
+#include <execution.hpp>
+

Synchronously invoke the given set of nullary functions, each on its own execution agent

+

This creates a group of function invocations whose ordering is given by the execution_category associated with the executor.

+

All exceptions thrown by invocations of the functions are reported in a manner consistent with parallel algorithm execution through the returned future.

+
+

Note

+

This calls exec.sync_invoke(fs…) if it exists; otherwise it executes sync_execute(fs) for each fs.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the functions fs.

+
+
Param fs
+

[in] The functions which will be scheduled using the given executor.

+
+
Return
+

The return type of executor_type::async_invoke if defined by executor_type.

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Fs>
inline decltype(auto) friend tag_fallback_invoke(sync_invoke_t, Executor &&exec, F &&f, Fs&&... fs)#
+
+ +
+
+ +
+
+struct then_execute_t : public hpx::functional::detail::tag_fallback<then_execute_t>#
+
+#include <execution.hpp>
+

Customization point for execution agent creation depending on a given future.

+

This creates a single function invocation f() using the associated executor after the given future object has become ready.

+
+

Note

+

This is valid for two way executors (calls exec.then_execute(f, predecessor, ts…) if it exists) and for one way executors (calls predecessor.then(bind(f, ts…))).

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param predecessor
+

[in] The future object the execution of the given function depends on.

+
+
Param ts
+

[in] Additional arguments to use to invoke f.

+
+
Return
+

f(ts…)’s result through a future

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename Future, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(then_execute_t, Executor &&exec, F &&f, Future &&predecessor, Ts&&... ts)#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/execution_base/receiver.hpp#
+

Defined in header hpx/execution_base/receiver.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+

Functions

+
+
+template<typename R, typename ...As>
void set_value(R &&r, As&&... as)#
+

set_value is a customization point object. The expression hpx::execution::set_value(r, as...) is equivalent to:

    +
  • r.set_value(as...), if that expression is valid. If the function selected does not send the value(s) as... to the Receiver r’s value channel, the program is ill-formed (no diagnostic required).

  • +
  • Otherwise, `set_value(r, as…), if that expression is valid, with overload resolution performed in a context that include the declaration void set_value();

  • +
  • Otherwise, the expression is ill-formed.

  • +
+

+

The customization is implemented in terms of hpx::functional::tag_invoke.

+
+ +
+
+template<typename R>
void set_stopped(R &&r)#
+

set_stopped is a customization point object. The expression hpx::execution::set_stopped(r) is equivalent to:

    +
  • r.set_stopped(), if that expression is valid. If the function selected does not signal the Receiver r’s done channel, the program is ill-formed (no diagnostic required).

  • +
  • Otherwise, `set_stopped(r), if that expression is valid, with overload resolution performed in a context that include the declaration void set_stopped();

  • +
  • Otherwise, the expression is ill-formed.

  • +
+

+

The customization is implemented in terms of hpx::functional::tag_invoke.

+
+ +
+
+template<typename R, typename E>
void set_error(R &&r, E &&e)#
+

set_error is a customization point object. The expression hpx::execution::set_error(r, e) is equivalent to:

    +
  • r.set_stopped(e), if that expression is valid. If the function selected does not send the error e the Receiver r’s error channel, the program is ill-formed (no diagnostic required).

  • +
  • Otherwise, `set_error(r, e), if that expression is valid, with overload resolution performed in a context that include the declaration void set_error();

  • +
  • Otherwise, the expression is ill-formed.

  • +
+

+

The customization is implemented in terms of hpx::functional::tag_invoke.

+
+ +
+
+

Variables

+
+
+hpx::execution::experimental::set_value_t set_value#
+
+ +
+
+hpx::execution::experimental::set_error_t set_error#
+
+ +
+
+hpx::execution::experimental::set_stopped_t set_stopped#
+
+ +
+
+template<typename T, typename E = std::exception_ptr>
constexpr bool is_receiver_v = is_receiver<T, E>::value#
+
+ +
+
+template<typename T, typename CS>
constexpr bool is_receiver_of_v = is_receiver_of<T, CS>::value#
+
+ +
+
+template<typename T, typename CS>
constexpr bool is_nothrow_receiver_of_v = is_nothrow_receiver_of<T, CS>::value#
+
+ +
+
+
+template<typename T, typename CS>
struct is_nothrow_receiver_of : public hpx::execution::experimental::detail::is_nothrow_receiver_of_impl<is_receiver_v<T> && is_receiver_of_v<T, CS>, T, CS>#
+
+ +
+
+template<typename T, typename E>
struct is_receiver#
+
+#include <receiver.hpp>
+

Receiving values from asynchronous computations is handled by the Receiver concept. A Receiver needs to be able to receive an error or be marked as being canceled. As such, the Receiver concept is defined by having the following two customization points defined, which form the completion-signal operations:

    +
  • hpx::execution::experimental::set_stopped * hpx::execution::experimental::set_error

  • +
+

+

Those two functions denote the completion-signal operations. The Receiver contract is as follows:

    +
  • None of a Receiver’s completion-signal operation shall be invoked before hpx::execution::experimental::start has been called on the operation state object that was returned by connecting a Receiver to a sender hpx::execution::experimental::connect.

  • +
  • Once hpx::execution::start has been called on the operation state object, exactly one of the Receiver’s completion-signal operation shall complete without an exception before the Receiver is destroyed

  • +
+

+

Once one of the Receiver’s completion-signal operation has been completed without throwing an exception, the Receiver contract has been satisfied. In other words: The asynchronous operation has been completed.

+

+

+
+ +
+
+template<typename T, typename CS>
struct is_receiver_of#
+
+#include <receiver.hpp>
+

The receiver_of concept is a refinement of the Receiver concept by requiring one additional completion-signal operation:

    +
  • hpx::execution::set_value

  • +
+

+

The receiver_of concept takes a receiver and an instance of the completion_signatures<> class template. The receiver_of concept, rather than accepting a receiver and some value types, is changed to take a receiver and an instance of the completion_signatures<> class template. A sender uses completion_signatures<> to describe the signals with which it completes. The receiver_of concept ensures that a particular receiver is capable of receiving those signals.

+

This completion-signal operation adds the following to the Receiver’s contract:

    +
  • If hpx::execution::set_value exits with an exception, it is still valid to call hpx::execution::set_error or hpx::execution::set_stopped

  • +
+

+

+

See also

+

hpx::execution::traits::is_receiver

+
+

+
+ +
+
+struct set_error_t : public hpx::functional::tag_noexcept<set_error_t>#
+
+ +
+
+struct set_stopped_t : public hpx::functional::tag_noexcept<set_stopped_t>#
+
+ +
+
+struct set_value_t : public hpx::functional::tag<set_value_t>#
+
+ +
+ +
+ +
+ +
+
+
hpx/execution_base/traits/is_executor_parameters.hpp#
+

Defined in header hpx/execution_base/traits/is_executor_parameters.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<typename Executor>
struct hpx::parallel::execution::extract_executor_parameters<Executor, std::void_t<typename Executor::executor_parameters_type>>#
+
+

Public Types

+
+
+using type = typename Executor::executor_parameters_type#
+
+ +
+
+ +
+
+template<typename Parameters>
struct extract_has_variable_chunk_size<Parameters, std::void_t<typename Parameters::has_variable_chunk_size>> : public true_type#
+
+ +
+
+template<typename Parameters>
struct extract_has_variable_chunk_size<::std::reference_wrapper<Parameters>> : public hpx::parallel::execution::extract_has_variable_chunk_size<Parameters>#
+
+ +
+
+template<typename Parameters>
struct extract_invokes_testing_function<::std::reference_wrapper<Parameters>> : public hpx::parallel::execution::extract_invokes_testing_function<Parameters>#
+
+ +
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Typedefs

+
+
+template<typename Executor>
using extract_executor_parameters_t = typename extract_executor_parameters<Executor>::type#
+
+ +
+
+

Variables

+
+
+template<typename Parameters>
constexpr bool extract_has_variable_chunk_size_v = extract_has_variable_chunk_size<Parameters>::value#
+
+ +
+
+template<typename Parameters>
constexpr bool extract_invokes_testing_function_v = extract_invokes_testing_function<Parameters>::value#
+
+ +
+
+template<typename T>
constexpr bool is_executor_parameters_v = is_executor_parameters<T>::value#
+
+ +
+
+
+template<typename Executor, typename Enable = void>
struct extract_executor_parameters#
+
+

Public Types

+
+
+using type = sequential_executor_parameters#
+
+ +
+
+ +
+
+template<typename Executor> executor_parameters_type > >
+
+

Public Types

+
+
+using type = typename Executor::executor_parameters_type
+
+ +
+
+ +
+
+template<typename Parameters, typename Enable = void>
struct extract_has_variable_chunk_size : public false_type#
+
+ +
+
+template<typename Parameters> has_variable_chunk_size > > : public true_type
+
+ +
+
+template<typename Parameters> reference_wrapper< Parameters > > : public hpx::parallel::execution::extract_has_variable_chunk_size< Parameters >
+
+ +
+
+template<typename Parameters, typename Enable = void>
struct extract_invokes_testing_function : public false_type#
+
+ +
+
+template<typename Parameters> reference_wrapper< Parameters > > : public hpx::parallel::execution::extract_invokes_testing_function< Parameters >
+
+ +
+
+template<typename T>
struct is_executor_parameters : public detail::is_executor_parameters<std::decay_t<T>>#
+
+ +
+
+struct sequential_executor_parameters#
+
+ +
+ +
+ +
+
+namespace traits#
+
+

Variables

+
+
+template<typename T>
constexpr bool is_executor_parameters_v = is_executor_parameters<T>::value#
+
+ +
+
+
+template<typename Parameters, typename Enable>
struct is_executor_parameters#
+
+ +
+ +
+ +
+
+
+
+
executors#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/executors/annotating_executor.hpp#
+

Defined in header hpx/executors/annotating_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+

Functions

+
+
+template<typename Tag, typename BaseExecutor, typename Property>
auto tag_invoke(Tag tag, annotating_executor<BaseExecutor> const &exec, Property &&prop) -> decltype(annotating_executor<BaseExecutor>(std::declval<Tag>()(std::declval<BaseExecutor>(), std::declval<Property>())))#
+
+ +
+
+template<typename Tag, typename BaseExecutor>
auto tag_invoke(Tag tag, annotating_executor<BaseExecutor> const &exec) -> decltype(std::declval<Tag>()(std::declval<BaseExecutor>()))#
+
+ +
+
+template<typename Executor>
constexpr auto tag_fallback_invoke(with_annotation_t, Executor &&exec, char const *annotation)#
+
+ +
+
+template<typename Executor>
auto tag_fallback_invoke(with_annotation_t, Executor &&exec, std::string annotation)#
+
+ +
+
+
+template<typename BaseExecutor>
struct annotating_executor#
+
+#include <annotating_executor.hpp>
+

A annotating_executor wraps any other executor and adds the capability to add annotations to the launched threads.

+
+

Public Functions

+
+
+template<typename Executor, typename Enable = std::enable_if_t<hpx::traits::is_executor_any_v<Executor> && !std::is_same_v<std::decay_t<Executor>, annotating_executor>>>
inline explicit constexpr annotating_executor(Executor &&exec, char const *annotation = nullptr)#
+
+ +
+
+template<typename Executor, typename Enable = std::enable_if_t<hpx::traits::is_executor_any_v<Executor>>>
inline explicit annotating_executor(Executor &&exec, std::string annotation)#
+
+ +
+
+ +
+ +
+ +
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
hpx/executors/current_executor.hpp#
+

Defined in header hpx/executors/current_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Typedefs

+
+
+typedef hpx::execution::parallel_executor instead#
+
+ +
+
+ +
+ +
+
+namespace this_thread#
+
+

Functions

+
+
+hpx::execution::parallel_executor get_executor(error_code &ec = throws)#
+

Returns a reference to the executor that was used to create the current thread.

+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+ +
+
+namespace threads
+
+

Functions

+
+
+hpx::execution::parallel_executor get_executor(thread_id_type const &id, error_code &ec = throws)#
+

Returns a reference to the executor that was used to create the given thread.

+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/executors/exception_list.hpp#
+

Defined in header hpx/executors/exception_list.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+ +
+
+
hpx::execution::seq, hpx::execution::par, hpx::execution::par_unseq, hpx::execution::task, hpx::execution::sequenced_policy, hpx::execution::parallel_policy, hpx::execution::parallel_unsequenced_policy, hpx::execution::sequenced_task_policy, hpx::execution::parallel_task_policy#
+

Defined in header hpx/execution.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+

Typedefs

+
+
+using sequenced_task_policy = detail::sequenced_task_policy_shim<sequenced_executor, hpx::traits::executor_parameters_type_t<sequenced_executor>>#
+

Extension: The class sequenced_task_policy is an execution policy type used as a unique type to disambiguate parallel algorithm overloading and indicate that a parallel algorithm’s execution may not be parallelized (has to run sequentially).

+

The algorithm returns a future representing the result of the corresponding algorithm when invoked with the sequenced_policy.

+
+ +
+
+using sequenced_policy = detail::sequenced_policy_shim<sequenced_executor, hpx::traits::executor_parameters_type_t<sequenced_executor>>#
+

The class sequenced_policy is an execution policy type used as a unique type to disambiguate parallel algorithm overloading and require that a parallel algorithm’s execution may not be parallelized.

+
+ +
+
+using parallel_task_policy = detail::parallel_task_policy_shim<parallel_executor, hpx::traits::executor_parameters_type_t<parallel_executor>>#
+

Extension: The class parallel_task_policy is an execution policy type used as a unique type to disambiguate parallel algorithm overloading and indicate that a parallel algorithm’s execution may be parallelized.

+

The algorithm returns a future representing the result of the corresponding algorithm when invoked with the parallel_policy.

+
+ +
+
+using parallel_policy = detail::parallel_policy_shim<parallel_executor, hpx::traits::executor_parameters_type_t<parallel_executor>>#
+

The class parallel_policy is an execution policy type used as a unique type to disambiguate parallel algorithm overloading and indicate that a parallel algorithm’s execution may be parallelized.

+
+ +
+
+using parallel_unsequenced_task_policy = detail::parallel_unsequenced_task_policy_shim<parallel_executor, hpx::traits::executor_parameters_type_t<parallel_executor>>#
+

The class parallel_unsequenced_task_policy is an execution policy type used as a unique type to disambiguate parallel algorithm overloading and indicate that a parallel algorithm’s execution may be parallelized and vectorized.

+
+ +
+
+using parallel_unsequenced_policy = detail::parallel_unsequenced_policy_shim<parallel_executor, hpx::traits::executor_parameters_type_t<parallel_executor>>#
+

The class parallel_unsequenced_policy is an execution policy type used as a unique type to disambiguate parallel algorithm overloading and indicate that a parallel algorithm’s execution may be parallelized and vectorized.

+
+ +
+
+using unsequenced_task_policy = detail::unsequenced_task_policy_shim<sequenced_executor, hpx::traits::executor_parameters_type_t<sequenced_executor>>#
+

The class unsequenced_task_policy is an execution policy type used as a unique type to disambiguate parallel algorithm overloading and indicate that a parallel algorithm’s execution may be vectorized.

+
+ +
+
+using unsequenced_policy = detail::unsequenced_policy_shim<sequenced_executor, hpx::traits::executor_parameters_type_t<sequenced_executor>>#
+

The class unsequenced_policy is an execution policy type used as a unique type to disambiguate parallel algorithm overloading and indicate that a parallel algorithm’s execution may be vectorized.

+
+ +
+
+

Variables

+
+
+constexpr task_policy_tag task = {}#
+
+ +
+
+constexpr non_task_policy_tag non_task = {}#
+
+ +
+
+constexpr sequenced_policy seq = {}#
+

Default sequential execution policy object.

+
+ +
+
+constexpr parallel_policy par = {}#
+

Default parallel execution policy object.

+
+ +
+
+constexpr parallel_unsequenced_policy par_unseq = {}#
+

Default vector execution policy object.

+
+ +
+
+constexpr unsequenced_policy unseq = {}#
+

Default vector execution policy object.

+
+ +
+
+
+struct non_task_policy_tag : public hpx::execution::experimental::to_non_task_t#
+
+ +
+
+struct task_policy_tag : public hpx::execution::experimental::to_task_t#
+
+ +
+
+namespace experimental
+
+
+template<>
struct is_execution_policy_mapping<non_task_policy_tag> : public true_type#
+
+ +
+
+template<>
struct is_execution_policy_mapping<task_policy_tag> : public true_type#
+
+ +
+ +
+ +
+ +
+
+
hpx/executors/execution_policy_annotation.hpp#
+

Defined in header hpx/executors/execution_policy_annotation.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+

Functions

+
+
+template<typename ExPolicy>
constexpr decltype(auto) tag_invoke(hpx::execution::experimental::with_annotation_t, ExPolicy &&policy, char const *annotation)#
+
+ +
+
+template<typename ExPolicy>
decltype(auto) tag_invoke(hpx::execution::experimental::with_annotation_t, ExPolicy &&policy, std::string annotation)#
+
+ +
+
+template<typename ExPolicy>
constexpr decltype(auto) tag_invoke(hpx::execution::experimental::get_annotation_t, ExPolicy &&policy)#
+
+ +
+
+ +
+ +
+ +
+
+
hpx/executors/execution_policy_mappings.hpp#
+

Defined in header hpx/executors/execution_policy_mappings.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+

Variables

+
+
+template<typename Tag>
constexpr bool is_execution_policy_mapping_v = is_execution_policy_mapping<Tag>::value#
+
+ +
+
+hpx::execution::experimental::to_non_par_t to_non_par#
+
+ +
+
+hpx::execution::experimental::to_par_t to_par#
+
+ +
+
+hpx::execution::experimental::to_non_task_t to_non_task#
+
+ +
+
+hpx::execution::experimental::to_task_t to_task#
+
+ +
+
+hpx::execution::experimental::to_non_unseq_t to_non_unseq#
+
+ +
+
+hpx::execution::experimental::to_unseq_t to_unseq#
+
+ +
+
+
+template<typename Tag>
struct is_execution_policy_mapping : public false_type#
+
+ +
+
+template<>
struct is_execution_policy_mapping<to_non_par_t> : public true_type#
+
+ +
+
+template<>
struct is_execution_policy_mapping<to_non_task_t> : public true_type#
+
+ +
+
+template<>
struct is_execution_policy_mapping<to_non_unseq_t> : public true_type#
+
+ +
+
+template<>
struct is_execution_policy_mapping<to_par_t> : public true_type#
+
+ +
+
+template<>
struct is_execution_policy_mapping<to_task_t> : public true_type#
+
+ +
+
+template<>
struct is_execution_policy_mapping<to_unseq_t> : public true_type#
+
+ +
+
+struct to_non_par_t : public hpx::functional::detail::tag_fallback<to_non_par_t>#
+
+

Private Functions

+
+
+template<typename ExPolicy>
inline constexpr decltype(auto) friend tag_fallback_invoke(to_non_par_t, ExPolicy &&policy) noexcept#
+
+ +
+
+ +
+
+struct to_non_task_t : public hpx::functional::detail::tag_fallback<to_non_task_t>#
+

Subclassed by hpx::execution::non_task_policy_tag

+
+

Private Functions

+
+
+template<typename ExPolicy>
inline constexpr decltype(auto) friend tag_fallback_invoke(to_non_task_t, ExPolicy &&policy) noexcept#
+
+ +
+
+ +
+
+struct to_non_unseq_t : public hpx::functional::detail::tag_fallback<to_non_unseq_t>#
+
+

Private Functions

+
+
+template<typename ExPolicy>
inline constexpr decltype(auto) friend tag_fallback_invoke(to_non_unseq_t, ExPolicy &&policy) noexcept#
+
+ +
+
+ +
+
+struct to_par_t : public hpx::functional::detail::tag_fallback<to_par_t>#
+
+

Private Functions

+
+
+template<typename ExPolicy>
inline constexpr decltype(auto) friend tag_fallback_invoke(to_par_t, ExPolicy &&policy) noexcept#
+
+ +
+
+ +
+
+struct to_task_t : public hpx::functional::detail::tag_fallback<to_task_t>#
+

Subclassed by hpx::execution::task_policy_tag

+
+

Private Functions

+
+
+template<typename ExPolicy>
inline constexpr decltype(auto) friend tag_fallback_invoke(to_task_t, ExPolicy &&policy) noexcept#
+
+ +
+
+ +
+
+struct to_unseq_t : public hpx::functional::detail::tag_fallback<to_unseq_t>#
+
+

Private Functions

+
+
+template<typename ExPolicy>
inline constexpr decltype(auto) friend tag_fallback_invoke(to_unseq_t, ExPolicy &&policy) noexcept#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/executors/execution_policy_parameters.hpp#
+

Defined in header hpx/executors/execution_policy_parameters.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Functions

+
+
+template<typename ExPolicy>
constexpr decltype(auto) tag_invoke(with_processing_units_count_t, ExPolicy &&policy, std::size_t num_cores)#
+
+ +
+
+template<typename ExPolicy, typename Params>
constexpr decltype(auto) tag_invoke(with_processing_units_count_t, ExPolicy &&policy, Params &&params)#
+
+ +
+
+template<typename ParametersProperty, typename ExPolicy, typename Params>
constexpr decltype(auto) tag_fallback_invoke(ParametersProperty, ExPolicy &&policy, Params &&params)#
+
+ +
+
+template<typename ParametersProperty, typename ExPolicy, typename ...Ts>
constexpr auto tag_fallback_invoke(ParametersProperty prop, ExPolicy &&policy, Ts&&... ts) -> decltype(std::declval<ParametersProperty>()(std::declval<typename std::decay_t<ExPolicy>::executor_type>(), std::declval<Ts>()...))#
+
+ +
+
+ +
+ +
+ +
+
+
hpx/executors/execution_policy_scheduling_property.hpp#
+

Defined in header hpx/executors/execution_policy_scheduling_property.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+

Functions

+
+
+template<typename Tag, typename ExPolicy, typename Property>
constexpr decltype(auto) tag_invoke(Tag tag, ExPolicy &&policy, Property prop)#
+
+ +
+
+template<typename Tag, typename ExPolicy>
constexpr decltype(auto) tag_invoke(Tag tag, ExPolicy &&policy)#
+
+ +
+
+ +
+ +
+ +
+
+
hpx/executors/explicit_scheduler_executor.hpp#
+

Defined in header hpx/executors/explicit_scheduler_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+

Functions

+
+
+template<typename BaseScheduler>
explicit explicit_scheduler_executor(BaseScheduler &&sched) -> explicit_scheduler_executor<std::decay_t<BaseScheduler>>#
+
+ +
+
+template<typename Tag, typename BaseScheduler, typename Property>
auto tag_invoke(Tag tag, explicit_scheduler_executor<BaseScheduler> const &exec, Property &&prop) -> decltype(explicit_scheduler_executor<BaseScheduler>(std::declval<Tag>()(std::declval<BaseScheduler>(), std::declval<Property>())))#
+
+ +
+
+template<typename Tag, typename BaseScheduler>
auto tag_invoke(Tag tag, explicit_scheduler_executor<BaseScheduler> const &exec) -> decltype(std::declval<Tag>()(std::declval<BaseScheduler>()))#
+
+ +
+
+
+template<typename BaseScheduler>
struct explicit_scheduler_executor
+
+ +
+ +
+ +
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
hpx/executors/fork_join_executor.hpp#
+

Defined in header hpx/executors/fork_join_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/executors/parallel_executor.hpp#
+

Defined in header hpx/executors/parallel_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+

Typedefs

+
+
+using parallel_executor = parallel_policy_executor<hpx::launch>#
+
+ +
+
+

Functions

+
+
+template<typename Tag, typename Policy, typename Property>
auto tag_invoke(Tag tag, parallel_policy_executor<Policy> const &exec, Property &&prop) -> decltype(std::declval<parallel_policy_executor<Policy>>().policy(std::declval<Tag>()(std::declval<Policy>(), std::declval<Property>())), parallel_policy_executor<Policy>())#
+
+ +
+
+template<typename Tag, typename Policy>
auto tag_invoke(Tag tag, parallel_policy_executor<Policy> const &exec) -> decltype(std::declval<Tag>()(std::declval<Policy>()))#
+
+ +
+
+
+template<typename Policy>
struct parallel_policy_executor#
+
+#include <parallel_executor.hpp>
+

A parallel_executor creates groups of parallel execution agents which execute in threads implicitly created by the executor. This executor prefers continuing with the creating thread first before executing newly created threads.

+

This executor conforms to the concepts of a TwoWayExecutor, and a BulkTwoWayExecutor

+
+

Public Types

+
+
+using execution_category = std::conditional_t<std::is_same_v<Policy, launch::sync_policy>, sequenced_execution_tag, parallel_execution_tag>#
+

Associate the parallel_execution_tag executor tag type as a default with this executor, except if the given launch policy is synch.

+
+ +
+
+using executor_parameters_type = experimental::default_parameters#
+

Associate the default_parameters executor parameters type as a default with this executor.

+
+ +
+
+

Public Functions

+
+
+inline explicit constexpr parallel_policy_executor(threads::thread_priority priority, threads::thread_stacksize stacksize = threads::thread_stacksize::default_, threads::thread_schedule_hint schedulehint = {}, Policy l = parallel::execution::detail::get_default_policy<Policy>::call(), std::size_t hierarchical_threshold = hierarchical_threshold_default_)#
+

Create a new parallel executor.

+
+ +
+
+inline explicit constexpr parallel_policy_executor(threads::thread_stacksize stacksize, threads::thread_schedule_hint schedulehint = {}, Policy l = parallel::execution::detail::get_default_policy<Policy>::call())#
+
+ +
+
+inline explicit constexpr parallel_policy_executor(threads::thread_schedule_hint schedulehint, Policy l = parallel::execution::detail::get_default_policy<Policy>::call())#
+
+ +
+
+inline explicit constexpr parallel_policy_executor(Policy l)#
+
+ +
+
+inline constexpr parallel_policy_executor()#
+
+ +
+
+inline explicit constexpr parallel_policy_executor(threads::thread_pool_base *pool, Policy l, std::size_t hierarchical_threshold = hierarchical_threshold_default_)#
+
+ +
+
+inline explicit constexpr parallel_policy_executor(threads::thread_pool_base *pool, threads::thread_priority priority = threads::thread_priority::default_, threads::thread_stacksize stacksize = threads::thread_stacksize::default_, threads::thread_schedule_hint schedulehint = {}, Policy l = parallel::execution::detail::get_default_policy<Policy>::call(), std::size_t hierarchical_threshold = hierarchical_threshold_default_)#
+
+ +
+
+inline constexpr void set_hierarchical_threshold(std::size_t threshold) noexcept#
+
+ +
+
+template<typename Parameters>
inline std::size_t processing_units_count(Parameters&&, hpx::chrono::steady_duration const& = hpx::chrono::null_duration, std::size_t = 0) const#
+
+ +
+
+

Friends

+
+
+template<typename Executor_> inline friend constexpr friend auto tag_invoke (hpx::parallel::execution::with_processing_units_count_t, Executor_ const &exec, std::size_t num_cores) noexcept
+
+ +
+
+template<typename Parameters> inline friend constexpr friend std::size_t tag_invoke (hpx::parallel::execution::processing_units_count_t, Parameters &&, parallel_policy_executor const &exec, hpx::chrono::steady_duration const &=hpx::chrono::null_duration, std::size_t=0)
+
+ +
+
+template<typename Executor_> inline friend constexpr friend auto tag_invoke (hpx::execution::experimental::with_first_core_t, Executor_ const &exec, std::size_t first_core) noexcept
+
+ +
+
+inline friend constexpr friend std::size_t tag_invoke (hpx::execution::experimental::get_first_core_t, parallel_policy_executor const &exec) noexcept
+
+ +
+
+inline friend auto tag_invoke(hpx::execution::experimental::get_processing_units_mask_t, parallel_policy_executor const &exec)#
+
+ +
+
+inline friend auto tag_invoke(hpx::execution::experimental::get_cores_mask_t, parallel_policy_executor const &exec)#
+
+ +
+
+ +
+ +
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
hpx/executors/parallel_executor_aggregated.hpp#
+

Defined in header hpx/executors/parallel_executor_aggregated.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
hpx/executors/restricted_thread_pool_executor.hpp#
+

Defined in header hpx/executors/restricted_thread_pool_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Typedefs

+
+
+using restricted_thread_pool_executor = restricted_policy_executor<hpx::launch>#
+
+ +
+
+
+template<typename Policy>
class restricted_policy_executor#
+
+

Public Types

+
+
+using execution_category = typename embedded_executor::execution_category#
+

Associate the parallel_execution_tag executor tag type as a default with this executor.

+
+ +
+
+using executor_parameters_type = typename embedded_executor::executor_parameters_type#
+
+ +
+
+

Public Functions

+
+
+inline explicit restricted_policy_executor(std::size_t first_thread = 0, std::size_t num_threads = 1, threads::thread_priority priority = threads::thread_priority::default_, threads::thread_stacksize stacksize = threads::thread_stacksize::default_, threads::thread_schedule_hint schedulehint = {}, std::size_t hierarchical_threshold = hierarchical_threshold_default_)#
+

Create a new parallel executor.

+
+ +
+
+inline restricted_policy_executor(restricted_policy_executor const &other)#
+
+ +
+
+inline restricted_policy_executor &operator=(restricted_policy_executor const &rhs)#
+
+ +
+
+

Private Types

+
+
+using embedded_executor = hpx::execution::parallel_policy_executor<Policy>#
+
+ +
+
+

Private Members

+
+
+std::uint16_t first_thread_#
+
+ +
+
+mutable std::atomic<std::size_t> os_thread_#
+
+ +
+
+embedded_executor exec_#
+
+ +
+
+

Private Static Attributes

+
+
+static constexpr std::size_t hierarchical_threshold_default_ = 6#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/executors/scheduler_executor.hpp#
+

Defined in header hpx/executors/scheduler_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+

Functions

+
+
+template<typename BaseScheduler>
explicit scheduler_executor(BaseScheduler &&sched) -> scheduler_executor<std::decay_t<BaseScheduler>>#
+
+ +
+
+template<typename Tag, typename BaseScheduler, typename Property>
auto tag_invoke(Tag tag, scheduler_executor<BaseScheduler> const &exec, Property &&prop) -> decltype(scheduler_executor<BaseScheduler>(std::declval<Tag>()(std::declval<BaseScheduler>(), std::declval<Property>())))#
+
+ +
+
+template<typename Tag, typename BaseScheduler>
auto tag_invoke(Tag tag, scheduler_executor<BaseScheduler> const &exec) -> decltype(std::declval<Tag>()(std::declval<BaseScheduler>()))#
+
+ +
+
+
+template<typename BaseScheduler>
struct scheduler_executor
+
+ +
+ +
+ +
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
hpx/executors/sequenced_executor.hpp#
+

Defined in header hpx/executors/sequenced_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+struct sequenced_executor#
+
+#include <sequenced_executor.hpp>
+

A sequential_executor creates groups of sequential execution agents which execute in the calling thread. The sequential order is given by the lexicographical order of indices in the index space.

+
+ +
+ +
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
hpx/executors/service_executors.hpp#
+

Defined in header hpx/executors/service_executors.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
hpx/executors/std_execution_policy.hpp#
+

Defined in header hpx/executors/std_execution_policy.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/executors/thread_pool_scheduler.hpp#
+

Defined in header hpx/executors/thread_pool_scheduler.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace execution
+
+
+namespace experimental
+
+

Typedefs

+
+
+using thread_pool_scheduler = thread_pool_policy_scheduler<hpx::launch>#
+
+ +
+
+

Functions

+
+
+template<typename Tag, typename Policy, typename Property>
auto tag_invoke(Tag tag, thread_pool_policy_scheduler<Policy> const &scheduler, Property &&prop) -> decltype(std::declval<thread_pool_policy_scheduler<Policy>>().policy(std::declval<Tag>()(std::declval<Policy>(), std::declval<Property>())), thread_pool_policy_scheduler<Policy>())#
+
+ +
+
+template<typename Tag, typename Policy>
auto tag_invoke(Tag tag, thread_pool_policy_scheduler<Policy> const &scheduler) -> decltype(std::declval<Tag>()(std::declval<Policy>()))#
+
+ +
+
+
+template<typename Policy>
struct thread_pool_policy_scheduler#
+
+

Public Types

+
+
+using execution_category = std::conditional_t<std::is_same_v<Policy, launch::sync_policy>, sequenced_execution_tag, parallel_execution_tag>#
+
+ +
+
+

Public Functions

+
+
+inline explicit constexpr thread_pool_policy_scheduler(Policy l = experimental::detail::get_default_scheduler_policy<Policy>::call())#
+
+ +
+
+inline explicit thread_pool_policy_scheduler(hpx::threads::thread_pool_base *pool, Policy l = experimental::detail::get_default_scheduler_policy<Policy>::call()) noexcept#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/executors/datapar/execution_policy.hpp#
+

Defined in header hpx/executors/datapar/execution_policy.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/executors/datapar/execution_policy_mappings.hpp#
+

Defined in header hpx/executors/datapar/execution_policy_mappings.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
+
+
filesystem#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/modules/filesystem.hpp#
+

Defined in header hpx/modules/filesystem.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+

This file provides a compatibility layer using Boost.Filesystem for the C++17 filesystem library. It is not intended to be a complete compatibility layer. It only contains functions required by the HPX codebase. It also provides some functions only available in Boost.Filesystem when using C++17 filesystem.

+
+
+namespace hpx
+
+
+namespace filesystem#
+
+

Functions

+
+
+inline path initial_path()#
+
+ +
+
+inline std::string basename(path const &p)#
+
+ +
+
+inline path canonical(path const &p, path const &base)#
+
+ +
+
+inline path canonical(path const &p, path const &base, std::error_code &ec)#
+
+ +
+
+ +
+ +
+
+namespace filesystem#
+
+ +
+
+
+
+
functional#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::bind, hpx::placeholders::_1, hpx::placeholders::_2, …, hpx::placeholders::_9#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+

Functions

+
+
+template<typename F, typename ...Ts, typename Enable = std::enable_if_t<!traits::is_action_v<std::decay_t<F>>>>
constexpr detail::bound<std::decay_t<F>, util::make_index_pack_t<sizeof...(Ts)>, util::decay_unwrap_t<Ts>...> bind(F &&f, Ts&&... vs)#
+

The function template bind generates a forwarding call wrapper for f. Calling this wrapper is equivalent to invoking f with some of its arguments bound to vs.

+
+
Parameters
+
    +
  • f – Callable object (function object, pointer to function, reference to function, pointer to member function, or pointer to data member) that will be bound to some arguments

  • +
  • vs – list of arguments to bind, with the unbound arguments replaced by the placeholders _1, _2, _3… of namespace hpx::placeholders

  • +
+
+
Returns
+

A function object of unspecified type T, for which

hpx::is_bind_expression<T>::value == true. 
+
+
+

+
+
+
+ +
+
+
+namespace placeholders#
+

The hpx::placeholders namespace contains the placeholder objects [_1, …, _N] where N is an implementation defined maximum number.

+

When used as an argument in a hpx::bind expression, the placeholder objects are stored in the generated function object, and when that function object is invoked with unbound arguments, each placeholder _N is replaced by the corresponding Nth unbound argument.

+

The types of the placeholder objects are DefaultConstructible and CopyConstructible, their default copy/move constructors do not throw exceptions, and for any placeholder _N, the type hpx::is_placeholder<decltype(_N)> is defined, where hpx::is_placeholder<decltype(_N)> is derived from std::integral_constant<int, N>.

+
+

Variables

+
+
+constexpr detail::placeholder<1> _1 = {}#
+
+ +
+
+constexpr detail::placeholder<2> _2 = {}#
+
+ +
+
+constexpr detail::placeholder<3> _3 = {}#
+
+ +
+
+constexpr detail::placeholder<4> _4 = {}#
+
+ +
+
+constexpr detail::placeholder<5> _5 = {}#
+
+ +
+
+constexpr detail::placeholder<6> _6 = {}#
+
+ +
+
+constexpr detail::placeholder<7> _7 = {}#
+
+ +
+
+constexpr detail::placeholder<8> _8 = {}#
+
+ +
+
+constexpr detail::placeholder<9> _9 = {}#
+
+ +
+
+ +
+
+namespace serialization#
+
+

Functions

+
+
+template<typename Archive, typename F, typename ...Ts>
void serialize(Archive &ar, ::hpx::detail::bound<F, Ts...> &bound, unsigned int const version = 0)#
+
+ +
+
+template<typename Archive, std::size_t I>
constexpr void serialize(Archive&, ::hpx::detail::placeholder<I>&, unsigned int const = 0) noexcept#
+
+ +
+
+ +
+
+namespace util
+
+

Functions

+
+
+template<typename F, typename... Ts>  HPX_DEPRECATED_V (1, 8, "hpx::util::bind is deprecated, use hpx::bind instead") const expr decltype(auto) bind(F &&f
+
+ +
+
+

Variables

+
+
+Ts && ts  {returnhpx::bind(HPX_FORWARD(F, f), HPX_FORWARD(Ts, ts)...)
+
+ +
+
+
+namespace placeholders#
+
+

Functions

+
+
+HPX_DEPRECATED_V (1, 8, "hpx::placeholders::_1 is deprecated, use hpx::placeholders::_1 " "instead") inline const expr hpx
+
+ +
+
+HPX_DEPRECATED_V (1, 8, "hpx::placeholders::_2 is deprecated, use hpx::placeholders::_2 " "instead") inline const expr hpx
+
+ +
+
+HPX_DEPRECATED_V (1, 8, "hpx::placeholders::_3 is deprecated, use hpx::placeholders::_3 " "instead") inline const expr hpx
+
+ +
+
+HPX_DEPRECATED_V (1, 8, "hpx::placeholders::_4 is deprecated, use hpx::placeholders::_4 " "instead") inline const expr hpx
+
+ +
+
+HPX_DEPRECATED_V (1, 8, "hpx::placeholders::_5 is deprecated, use hpx::placeholders::_5 " "instead") inline const expr hpx
+
+ +
+
+HPX_DEPRECATED_V (1, 8, "hpx::placeholders::_6 is deprecated, use hpx::placeholders::_6 " "instead") inline const expr hpx
+
+ +
+
+HPX_DEPRECATED_V (1, 8, "hpx::placeholders::_7 is deprecated, use hpx::placeholders::_7 " "instead") inline const expr hpx
+
+ +
+
+HPX_DEPRECATED_V (1, 8, "hpx::placeholders::_8 is deprecated, use hpx::placeholders::_8 " "instead") inline const expr hpx
+
+ +
+
+HPX_DEPRECATED_V (1, 8, "hpx::placeholders::_9 is deprecated, use hpx::placeholders::_9 " "instead") inline const expr hpx
+
+ +
+
+ +
+ +
+ +
+
+
hpx::bind_back#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+

Functions

+
+
+template<typename F, typename ...Ts>
constexpr hpx::detail::bound_back<std::decay_t<F>, util::make_index_pack_t<sizeof...(Ts)>, util::decay_unwrap_t<Ts>...> bind_back(F &&f, Ts&&... vs)#
+

Function templates bind_back generate a forwarding call wrapper for f. Calling this wrapper is equivalent to invoking f with its last sizeof…(Ts) parameters bound to vs.

+
+
Parameters
+
    +
  • f – Callable object (function object, pointer to function, reference to function, pointer to member function, or pointer to data member) that will be bound to some arguments

  • +
  • vs – list of the arguments to bind to the last sizeof…(Ts) parameters of f

  • +
+
+
Returns
+

A function object of type T that is unspecified, except that the types of objects returned by two calls to hpx::bind_back with the same arguments are the same.

+
+
+
+ +
+
+template<typename F>
constexpr std::decay_t<F> bind_back(F &&f)#
+
+ +
+
+
+namespace serialization
+
+

Functions

+
+
+template<typename Archive, typename F, typename ...Ts>
void serialize(Archive &ar, ::hpx::detail::bound_back<F, Ts...> &bound, unsigned int const version = 0)#
+
+ +
+
+ +
+
+namespace util
+
+

Functions

+
+
+template<typename F, typename... Ts>  HPX_DEPRECATED_V (1, 8, "hpx::util::bind_back is deprecated, use hpx::bind_back instead") const expr decltype(auto) bind_back(F &&f
+
+ +
+
+ +
+ +
+
+
hpx::bind_front#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+

Functions

+
+
+template<typename F, typename ...Ts>
constexpr detail::bound_front<std::decay_t<F>, util::make_index_pack_t<sizeof...(Ts)>, util::decay_unwrap_t<Ts>...> bind_front(F &&f, Ts&&... vs)#
+

Function template bind_front generates a forwarding call wrapper for f. Calling this wrapper is equivalent to invoking f with its first sizeof…(Ts) parameters bound to vs.

+
+
Parameters
+
    +
  • f – Callable object (function object, pointer to function, reference to function, pointer to member function, or pointer to data member) that will be bound to some arguments

  • +
  • vs – list of the arguments to bind to the first or sizeof…(Ts) parameters of f

  • +
+
+
Returns
+

A function object of type T that is unspecified, except that the types of objects returned by two calls to hpx::bind_front with the same arguments are the same.

+
+
+
+ +
+
+template<typename F>
constexpr std::decay_t<F> bind_front(F &&f)#
+
+ +
+
+
+namespace serialization
+
+

Functions

+
+
+template<typename Archive, typename F, typename ...Ts>
void serialize(Archive &ar, ::hpx::detail::bound_front<F, Ts...> &bound, unsigned int const version = 0)#
+
+ +
+
+ +
+
+namespace util
+
+

Functions

+
+
+template<typename F, typename... Ts>  HPX_DEPRECATED_V (1, 8, "hpx::util::bind_front is deprecated, use hpx::bind_front instead") const expr decltype(auto) bind_front(F &&f
+
+ +
+
+ +
+ +
+
+
hpx::function#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_UTIL_REGISTER_FUNCTION_DECLARATION(Sig, F, Name)#
+
+ +
+
+HPX_UTIL_REGISTER_FUNCTION(Sig, F, Name)#
+
+ +
+
+
+namespace hpx
+

Top level namespace.

+
+
+template<typename Sig, bool Serializable = false>
class function#
+
+#include <function.hpp>
+

Class template hpx::function is a general-purpose polymorphic function wrapper. Instances of hpx::function can store, copy, and invoke any CopyConstructible Callable target &#8212; functions, lambda expressions, bind expressions, or other function objects, as well as pointers to member functions and pointers to data members. The stored callable object is called the target of hpx::function. If an hpx::function contains no target, it is called empty. Invoking the target of an empty hpx::function results in hpx::error::bad_function_call exception being thrown. hpx::function satisfies the requirements of CopyConstructible and CopyAssignable.

+
+ +
+
+template<typename R, typename ...Ts, bool Serializable>
class function<R(Ts...), Serializable> : public util::detail::basic_function<R(Ts...), true, Serializable>#
+
+

Public Types

+
+
+using result_type = R#
+
+ +
+
+

Public Functions

+
+
+inline constexpr function(std::nullptr_t = nullptr) noexcept#
+
+ +
+
+function(function const&) = default#
+
+ +
+
+function(function&&) noexcept = default#
+
+ +
+
+function &operator=(function const&) = default#
+
+ +
+
+function &operator=(function&&) noexcept = default#
+
+ +
+
+~function() = default#
+
+ +
+
+template<typename F, typename FD = std::decay_t<F>, typename Enable1 = std::enable_if_t<!std::is_same_v<FD, function>>, typename Enable2 = std::enable_if_t<is_invocable_r_v<R, FD&, Ts...>>>
inline function(F &&f)#
+
+ +
+
+template<typename F, typename FD = std::decay_t<F>, typename Enable1 = std::enable_if_t<!std::is_same_v<FD, function>>, typename Enable2 = std::enable_if_t<is_invocable_r_v<R, FD&, Ts...>>>
inline function &operator=(F &&f)#
+
+ +
+
+

Private Types

+
+
+using base_type = util::detail::basic_function<R(Ts...), true, Serializable>#
+
+ +
+
+ +
+
+namespace distributed#
+
+

Typedefs

+
+
+template<typename Sig>
using function = hpx::function<Sig, true>#
+
+ +
+
+ +
+
+namespace util
+
+

Typedefs

+
+
+typedef hpx::function<Sig, Serializable> instead#
+
+ +
+
+ +
+ +
+
+
hpx::function_ref#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+
+template<typename Sig>
class function_ref#
+
+#include <function_ref.hpp>
+

function_ref class is a vocabulary type with reference semantics for passing entities to call.

+

An example use case that benefits from higher-order functions is retry(n,f) which attempts to call f up to n times synchronously until success. This example might model the real-world scenario of repeatedly querying a flaky web service.

using payload = std::optional< /* ... */ >;
+// Repeatedly invokes `action` up to `times` repetitions.
+// Immediately returns if `action` returns a valid `payload`.
+// Returns `std::nullopt` otherwise.
+payload retry(size_t times, /* ????? */ action);
+
+
+ The passed-in action should be a callable entity that takes no arguments and returns a payload. This can be done with function pointers, hpx::function or a template but it is much simpler with function_ref as seen below:
payload retry(size_t times, function_ref<payload()> action);
+
+
+

+
+ +
+
+template<typename R, typename ...Ts>
class function_ref<R(Ts...)>#
+
+

Public Functions

+
+
+template<typename F, typename FD = std::decay_t<F>, typename Enable = std::enable_if_t<!std::is_same_v<FD, function_ref> && is_invocable_r_v<R, F&, Ts...>>>
inline function_ref(F &&f)#
+
+ +
+
+inline function_ref(function_ref const &other) noexcept#
+
+ +
+
+template<typename F, typename FD = std::decay_t<F>, typename Enable = std::enable_if_t<!std::is_same_v<FD, function_ref> && is_invocable_r_v<R, F&, Ts...>>>
inline function_ref &operator=(F &&f)#
+
+ +
+
+inline function_ref &operator=(function_ref const &other) noexcept#
+
+ +
+
+template<typename F, typename T = std::remove_reference_t<F>, typename Enable = std::enable_if_t<!std::is_pointer_v<T>>>
inline void assign(F &&f)#
+
+ +
+
+template<typename T>
inline void assign(std::reference_wrapper<T> f_ref) noexcept#
+
+ +
+
+template<typename T>
inline void assign(T *f_ptr) noexcept#
+
+ +
+
+inline void swap(function_ref &f) noexcept#
+
+ +
+
+inline R operator()(Ts... vs) const#
+
+ +
+
+inline std::size_t get_function_address() const#
+
+ +
+
+inline char const *get_function_annotation() const#
+
+ +
+
+inline util::itt::string_handle get_function_annotation_itt() const#
+
+ +
+
+

Protected Attributes

+
+
+R (*vptr)(void*, Ts&&...)#
+
+ +
+
+void *object#
+
+ +
+
+

Private Types

+
+
+using VTable = util::detail::function_ref_vtable<R(Ts...)>#
+
+ +
+
+

Private Static Functions

+
+
+template<typename T>
static inline constexpr VTable const *get_vtable() noexcept#
+
+ +
+
+ +
+
+namespace util
+
+ +
+ +
+
+
hpx::invoke#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_INVOKE_R(R, F, ...)#
+
+ +
+
+
+namespace hpx
+

Top level namespace.

+
+

Functions

+
+
+template<typename F, typename ...Ts>
constexpr util::invoke_result_t<F, Ts&&...> invoke(F &&f, Ts&&... vs) noexcept(noexcept(HPX_INVOKE(HPX_FORWARD(F, f), HPX_FORWARD(Ts, vs)...)))#
+

Invokes the given callable object f with the content of the argument pack vs

+
+

Note

+

This function is similar to std::invoke (C++17)

+
+
+
Parameters
+
    +
  • f – Requires to be a callable object. If f is a member function pointer, the first argument in the pack will be treated as the callee (this object).

  • +
  • vs – An arbitrary pack of arguments

  • +
+
+
Throws
+

std::exception – like objects thrown by call to object f with the argument types vs.

+
+
Returns
+

The result of the callable object when it’s called with the given argument types.

+
+
+
+ +
+
+template<typename R, typename F, typename ...Ts>
constexpr R invoke_r(F &&f, Ts&&... vs) noexcept(noexcept(HPX_INVOKE(HPX_FORWARD(F, f), HPX_FORWARD(Ts, vs)...)))#
+

Invokes the given callable object f with the content of the argument pack vs

+
+

Note

+

This function is similar to std::invoke (C++17)

+
+
+
Parameters
+
    +
  • f – Requires to be a callable object. If f is a member function pointer, the first argument in the pack will be treated as the callee (this object).

  • +
  • vs – An arbitrary pack of arguments

  • +
+
+
Throws
+

std::exception – like objects thrown by call to object f with the argument types vs.

+
+
Template Parameters
+

R – The result type of the function when it’s called with the content of the given argument types vs.

+
+
Returns
+

The result of the callable object when it’s called with the given argument types.

+
+
+
+ +
+
+
+namespace functional#
+
+
+struct invoke#
+
+

Public Functions

+
+
+template<typename F, typename ...Ts>
inline constexpr util::invoke_result_t<F, Ts&&...> operator()(F &&f, Ts&&... vs) const noexcept(noexcept(HPX_INVOKE(HPX_FORWARD(F, f), HPX_FORWARD(Ts, vs)...)))#
+
+ +
+
+ +
+
+template<typename R>
struct invoke_r#
+
+

Public Functions

+
+
+template<typename F, typename ...Ts>
inline constexpr R operator()(F &&f, Ts&&... vs) const noexcept(noexcept(HPX_INVOKE(HPX_FORWARD(F, f), HPX_FORWARD(Ts, vs)...)))#
+
+ +
+
+ +
+ +
+ +
+
+
hpx::invoke_fused, hpx::invoke_fused_r#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+

Functions

+
+
+template<typename F, typename Tuple>
constexpr detail::invoke_fused_result_t<F, Tuple> invoke_fused(F &&f, Tuple &&t) noexcept(noexcept(detail::invoke_fused_impl(detail::fused_index_pack_t<Tuple>{}, HPX_FORWARD(F, f), HPX_FORWARD(Tuple, t))))#
+

Invokes the given callable object f with the content of the sequenced type t (tuples, pairs).

+
+

Note

+

This function is similar to std::apply (C++17). The difference between hpx::invoke and hpx::invoke_fused is that the later unpacks the tuples while the former cannot. Turning a tuple into a parameter pack is not a trivial operation which makes hpx::invoke_fused rather useful.

+
+
+
Parameters
+
    +
  • f – Must be a callable object. If f is a member function pointer, the first argument in the sequenced type will be treated as the callee (this object).

  • +
  • t – A type whose contents are accessible through a call to hpx::get.

  • +
+
+
Throws
+

std::exception – like objects thrown by call to object f with the arguments contained in the sequenceable type t.

+
+
Returns
+

The result of the callable object when it’s called with the content of the given sequenced type.

+
+
+
+ +
+
+template<typename R, typename F, typename Tuple>
constexpr R invoke_fused_r(F &&f, Tuple &&t) noexcept(noexcept(detail::invoke_fused_impl(detail::fused_index_pack_t<Tuple>{}, HPX_FORWARD(F, f), HPX_FORWARD(Tuple, t))))#
+

Invokes the given callable object f with the content of the sequenced type t (tuples, pairs).

+
+

Note

+

This function is similar to std::apply (C++17). The difference between hpx::invoke and hpx::invoke_fused is that the later unpacks the tuples while the former cannot. Turning a tuple into a parameter pack is not a trivial operation which makes hpx::invoke_fused rather useful.

+
+
+

Note

+

The difference between hpx::invoke_fused and hpx::invoke_fused_r is that the later allows to specify the return type as well.

+
+
+
Parameters
+
    +
  • f – Must be a callable object. If f is a member function pointer, the first argument in the sequenced type will be treated as the callee (this object).

  • +
  • t – A type whose contents are accessible through a call to hpx::get.

  • +
+
+
Throws
+

std::exception – like objects thrown by call to object f with the arguments contained in the sequenceable type t.

+
+
Template Parameters
+

R – The result type of the function when it’s called with the content of the given sequenced type.

+
+
Returns
+

The result of the callable object when it’s called with the content of the given sequenced type.

+
+
+
+ +
+
+ +
+
+
hpx::mem_fn#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+

Functions

+
+
+template<typename M, typename C>
constexpr detail::mem_fn<M C::*> mem_fn(M C::* pm) noexcept#
+

Function template hpx::mem_fn generates wrapper objects for pointers to members, which can store, copy, and invoke a pointer to member. Both references and pointers (including smart pointers) to an object can be used when invoking a hpx::mem_fn.

+
+
Parameters
+

pm – pointer to member that will be wrapped

+
+
Returns
+

a call wrapper of unspecified type with the following member:

template <typename... Ts>
+constexpr typename util::invoke_result<MemberPointer, Ts...>::type
+operator()(Ts&&... vs) noexcept;
+
+
+ Let fn be the call wrapper returned by a call to hpx::mem_fn with a pointer to member pm. Then the expression fn(t,a2,...,aN) is equivalent to HPX_INVOKE(pm,t,a2,...,aN). Thus, the return type of operator() is std::result_of<decltype(pm)(Ts&&...)>::type or equivalently std::invoke_result_t<decltype(pm),Ts&&...>, and the value in noexcept specifier is equal to std::is_nothrow_invocable_v<decltype(pm),Ts&&...>) . Each argument in vs is perfectly forwarded, as if by std::forward<Ts>(vs)… .

+
+
+
+ +
+
+template<typename R, typename C, typename ...Ps>
constexpr detail::mem_fn<R (C::*)(Ps...)> mem_fn(R (C::* pm)(Ps...)) noexcept#
+

Function template hpx::mem_fn generates wrapper objects for pointers to members, which can store, copy, and invoke a pointer to member. Both references and pointers (including smart pointers) to an object can be used when invoking a hpx::mem_fn.

+
+
Parameters
+

pm – pointer to member that will be wrapped

+
+
Returns
+

a call wrapper of unspecified type with the following member:

template <typename... Ts>
+constexpr typename util::invoke_result<MemberPointer, Ts...>::type
+operator()(Ts&&... vs) noexcept;
+
+
+ Let fn be the call wrapper returned by a call to hpx::mem_fn with a pointer to member pm. Then the expression fn(t,a2,...,aN) is equivalent to HPX_INVOKE(pm,t,a2,...,aN). Thus, the return type of operator() is std::result_of<decltype(pm)(Ts&&...)>::type or equivalently std::invoke_result_t<decltype(pm),Ts&&...>, and the value in noexcept specifier is equal to std::is_nothrow_invocable_v<decltype(pm),Ts&&...>) . Each argument in vs is perfectly forwarded, as if by std::forward<Ts>(vs)… .

+
+
+
+ +
+
+template<typename R, typename C, typename ...Ps>
constexpr detail::mem_fn<R (C::*)(Ps...) const> mem_fn(R (C::* pm)(Ps...) const) noexcept#
+

Function template hpx::mem_fn generates wrapper objects for pointers to members, which can store, copy, and invoke a pointer to member. Both references and pointers (including smart pointers) to an object can be used when invoking a hpx::mem_fn.

+
+
Parameters
+

pm – pointer to member that will be wrapped

+
+
Returns
+

a call wrapper of unspecified type with the following member:

template <typename... Ts>
+constexpr typename util::invoke_result<MemberPointer, Ts...>::type
+operator()(Ts&&... vs) noexcept;
+
+
+ Let fn be the call wrapper returned by a call to hpx::mem_fn with a pointer to member pm. Then the expression fn(t,a2,...,aN) is equivalent to HPX_INVOKE(pm,t,a2,...,aN). Thus, the return type of operator() is std::result_of<decltype(pm)(Ts&&...)>::type or equivalently std::invoke_result_t<decltype(pm),Ts&&...>, and the value in noexcept specifier is equal to std::is_nothrow_invocable_v<decltype(pm),Ts&&...>) . Each argument in vs is perfectly forwarded, as if by std::forward<Ts>(vs)… .

+
+
+
+ +
+
+ +
+
+
hpx::move_only_function#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_UTIL_REGISTER_UNIQUE_FUNCTION_DECLARATION(Sig, F, Name)#
+
+ +
+
+HPX_UTIL_REGISTER_UNIQUE_FUNCTION(Sig, F, Name)#
+
+ +
+
+
+namespace hpx
+

Top level namespace.

+
+
+template<typename Sig, bool Serializable = false>
class move_only_function#
+
+#include <move_only_function.hpp>
+

Class template hpx::move_only_function is a general-purpose polymorphic function wrapper. hpx::move_only_function objects can store and invoke any constructible (not required to be move constructible) Callable target &#8212; functions, lambda expressions, bind expressions, or other function objects, as well as pointers to member functions and pointers to member objects.

+

The stored callable object is called the target of hpx::move_only_function. If an hpx::move_only_function contains no target, it is called empty. Unlike hpx::function, invoking an empty hpx::move_only_function results in undefined behavior.

+

hpx::move_only_functions supports every possible combination of cv-qualifiers, ref-qualifiers, and noexcept-specifiers not including volatile provided in its template parameter. These qualifiers and specifier (if any) are added to its operator(). hpx::move_only_function satisfies the requirements of MoveConstructible and MoveAssignable, but does not satisfy CopyConstructible or CopyAssignable.

+
+ +
+
+template<typename R, typename ...Ts, bool Serializable>
class move_only_function<R(Ts...), Serializable> : public util::detail::basic_function<R(Ts...), false, Serializable>#
+
+

Public Types

+
+
+using result_type = R#
+
+ +
+
+

Public Functions

+
+
+inline constexpr move_only_function(std::nullptr_t = nullptr) noexcept#
+
+ +
+
+move_only_function(move_only_function const&) = delete#
+
+ +
+
+move_only_function(move_only_function&&) noexcept = default#
+
+ +
+
+move_only_function &operator=(move_only_function const&) = delete#
+
+ +
+
+move_only_function &operator=(move_only_function&&) noexcept = default#
+
+ +
+
+~move_only_function() = default#
+
+ +
+
+template<typename F, typename FD = std::decay_t<F>, typename Enable1 = std::enable_if_t<!std::is_same_v<FD, move_only_function>>, typename Enable2 = std::enable_if_t<is_invocable_r_v<R, FD&, Ts...>>>
inline move_only_function(F &&f)#
+
+ +
+
+template<typename F, typename FD = std::decay_t<F>, typename Enable1 = std::enable_if_t<!std::is_same_v<FD, move_only_function>>, typename Enable2 = std::enable_if_t<is_invocable_r_v<R, FD&, Ts...>>>
inline move_only_function &operator=(F &&f)#
+
+ +
+
+

Private Types

+
+
+using base_type = util::detail::basic_function<R(Ts...), false, Serializable>#
+
+ +
+
+ +
+
+namespace distributed
+
+

Typedefs

+
+
+template<typename Sig>
using move_only_function = hpx::move_only_function<Sig, true>#
+
+ +
+
+ +
+
+namespace util
+
+ +
+ +
+
+
hpx::experimental::scope_exit#
+

Defined in header hpx/experimental/scope.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+
+namespace experimental
+
+

Functions

+
+
+template<typename F>
auto scope_exit(F &&f)#
+

The class template scope_exit is a general-purpose scope guard intended to call its exit function when a scope is exited.

+
+
Template Parameters
+

F – type of stored exit function

+
+
Parameters
+

f – stored exit function

+
+
+
+ +
+
+ +
+ +
+
+
hpx::experimental::scope_fail#
+

Defined in header hpx/experimental/scope.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+
+namespace experimental
+
+

Functions

+
+
+template<typename F>
auto scope_fail(F &&f)#
+

The class template scope_fail is a general-purpose scope guard intended to call its exit function when a scope is exited via an exception.

+
+
Template Parameters
+

F – type of stored exit function

+
+
Parameters
+

f – stored exit function

+
+
+
+ +
+
+ +
+ +
+
+
hpx::experimental::scope_success#
+

Defined in header hpx/experimental/scope.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+
+namespace experimental
+
+

Functions

+
+
+template<typename F>
auto scope_success(F &&f)#
+

The class template scope_success is a general-purpose scope guard intended to call its exit function when a scope is normally exited.

+
+
Template Parameters
+

F – type of stored exit function

+
+
Parameters
+

f – stored exit function

+
+
+
+ +
+
+ +
+ +
+
+
hpx::is_bind_expression#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+

Variables

+
+
+template<typename T>
constexpr bool is_bind_expression_v = is_bind_expression<T>::value#
+
+ +
+
+
+template<typename T>
struct is_bind_expression : public std::is_bind_expression<T>#
+
+#include <is_bind_expression.hpp>
+

If T is the type produced by a call to hpx::bind, this template is derived from std::true_type. For any other type, this template is derived from std::false_type.

+

This template may be specialized for a user-defined type T to implement UnaryTypeTrait with base characteristic of std::true_type to indicate that T should be treated by hpx::bind as if it were the type of a bind subexpression: when a bind-generated function object is invoked, a bound argument of this type will be invoked as a function object and will be given all the unbound arguments passed to the bind-generated object.

+

Subclassed by hpx::is_bind_expression< T const >

+
+ +
+
+template<typename T>
struct is_bind_expression<T const> : public hpx::is_bind_expression<T>#
+
+ +
+
+namespace traits
+
+

Typedefs

+
+
+typedef hpx::is_bind_expression<T> instead#
+
+ +
+
+

Functions

+
+
+template<typename T>  HPX_DEPRECATED_V (1, 8, "hpx::traits::is_bind_expression_v is deprecated, use " "hpx::is_bind_expression_v instead") inline const expr bool is_bind_expression_v
+
+ +
+
+ +
+ +
+
+
hpx::is_placeholder#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level namespace.

+
+
+template<typename T>
struct is_placeholder#
+
+#include <is_placeholder.hpp>
+

If T is a standard, Boost, or HPX placeholder (_1, _2, _3, …) then this template is derived from std::integral_constant<int,1>, std::integral_constant<int,2>, std::integral_constant<int,3>, respectively. Otherwise, it is derived from std::integral_constant<int,0>.

+

The template may be specialized for any user-defined T type: the specialization must satisfy UnaryTypeTrait with base characteristic of std::integral_constant<int,N> with N>0 to indicate that T should be treated as N’th placeholder type. hpx::bind uses hpx::is_placeholder to detect placeholders for unbound arguments.

+
+ +
+
+namespace traits
+
+

Functions

+
+
+template<typename T>  HPX_DEPRECATED_V (1, 8, "hpx::traits::is_placeholder_v is deprecated, use " "hpx::is_placeholder_v instead") inline const expr bool is_placeholder_v
+
+ +
+
+ +
+ +
+
+
+
+
futures#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::future, hpx::shared_future, hpx::make_future, hpx::make_shared_future, hpx::make_ready_future, hpx::make_ready_future_alloc, hpx::make_ready_future_at, hpx::make_ready_future_after, hpx::make_exceptional_future#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_MAKE_EXCEPTIONAL_FUTURE(T, errorcode, f, msg)#
+
+ +
+
+
+namespace hpx
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename R, typename U>
hpx::future<R> make_future(hpx::future<U> &&f)#
+

Converts any future of type U to any other future of type R based on an existing conversion path from U to R.

+
+ +
+
+template<typename R, typename U, typename Conv>
hpx::future<R> make_future(hpx::future<U> &&f, Conv &&conv)#
+

Converts any future of type U to any other future of type R based on a given conversion function: R conv(U).

+
+ +
+
+template<typename R, typename U>
hpx::future<R> make_future(hpx::shared_future<U> f)#
+

Converts any shared_future of type U to any other future of type R based on an existing conversion path from U to R.

+
+ +
+
+template<typename R, typename U, typename Conv>
hpx::future<R> make_future(hpx::shared_future<U> f, Conv &&conv)#
+

Converts any future of type U to any other future of type R based on an existing conversion path from U to R.

+
+ +
+
+template<typename R>
hpx::shared_future<R> make_shared_future(hpx::future<R> &&f) noexcept#
+

Converts any future or shared_future of type T to a corresponding shared_future of type T.

+
+ +
+
+template<typename R>
hpx::shared_future<R> &make_shared_future(hpx::shared_future<R> &f) noexcept#
+

Converts any future or shared_future of type T to a corresponding shared_future of type T.

+
+ +
+
+template<typename R>
hpx::shared_future<R> &&make_shared_future(hpx::shared_future<R> &&f) noexcept#
+

Converts any future or shared_future of type T to a corresponding shared_future of type T.

+
+ +
+
+template<typename R>
hpx::shared_future<R> const &make_shared_future(hpx::shared_future<R> const &f) noexcept#
+

Converts any future or shared_future of type T to a corresponding shared_future of type T.

+
+ +
+
+template<typename T, typename Allocator, typename ...Ts>
std::enable_if_t<std::is_constructible_v<T, Ts&&...> || std::is_void_v<T>, future<T>> make_ready_future_alloc(Allocator const &a, Ts&&... ts)#
+

Creates a pre-initialized future object with allocator (extension)

+
+ +
+
+template<typename T, typename ...Ts>
std::enable_if_t<std::is_constructible_v<T, Ts&&...> || std::is_void_v<T>, future<T>> make_ready_future(Ts&&... ts)#
+

The function creates a shared state that is immediately ready and returns a future associated with that shared state. For the returned future, valid() == true and is_ready() == true.

+
+ +
+
+template<int DeductionGuard = 0, typename Allocator, typename T>
future<hpx::util::decay_unwrap_t<T>> make_ready_future_alloc(Allocator const &a, T &&init)#
+
+ +
+
+template<int DeductionGuard = 0, typename T>
future<hpx::util::decay_unwrap_t<T>> make_ready_future(T &&init)#
+

The function creates a shared state that is immediately ready and returns a future associated with that shared state. For the returned future, valid() == true and is_ready() == true.

+
+ +
+
+template<typename T>
future<T> make_exceptional_future(std::exception_ptr const &e)#
+

Creates a pre-initialized future object which holds the given error (extension)

+
+ +
+
+template<typename T, typename E>
future<T> make_exceptional_future(E e)#
+

Creates a pre-initialized future object which holds the given error (extension)

+
+ +
+
+template<int DeductionGuard = 0, typename T>
future<hpx::util::decay_unwrap_t<T>> make_ready_future_at(hpx::chrono::steady_time_point const &abs_time, T &&init)#
+

Creates a pre-initialized future object which gets ready at a given point in time (extension)

+
+ +
+
+template<int DeductionGuard = 0, typename T>
future<hpx::util::decay_unwrap_t<T>> make_ready_future_after(hpx::chrono::steady_duration const &rel_time, T &&init)#
+

Creates a pre-initialized future object which gets ready after a given point in time (extension)

+
+ +
+
+template<typename Allocator>
inline future<void> make_ready_future_alloc(Allocator const &a)#
+
+ +
+
+future<void> make_ready_future()#
+

The function creates a shared state that is immediately ready and returns a future associated with that shared state. For the returned future, valid() == true and is_ready() == true.

+
+ +
+
+inline future<void> make_ready_future_at(hpx::chrono::steady_time_point const &abs_time)#
+

Creates a pre-initialized future object which gets ready at a given point in time (extension)

+
+ +
+
+inline future<void> make_ready_future_after(hpx::chrono::steady_duration const &rel_time)#
+

Creates a pre-initialized future object which gets ready after a given point in time (extension)

+
+ +
+
+
+template<typename R>
class future : public hpx::lcos::detail::future_base<future<R>, R>#
+
+#include <future_fwd.hpp>
+

The class template hpx::future provides a mechanism to access the result of asynchronous operations:

    +
  • An asynchronous operation (created via hpx::async, hpx::packaged_task, or hpx::promise) can provide a hpx::future object to the creator of that asynchronous operation.

  • +
  • The creator of the asynchronous operation can then use a variety of methods to query, wait for, or extract a value from the hpx::future. These methods may block if the asynchronous operation has not yet provided a value.

  • +
  • When the asynchronous operation is ready to send a result to the creator, it can do so by modifying shared state (e.g. hpx::promise::set_value) that is linked to the creator’s hpx::future. Note that hpx::future references shared state that is not shared with any other asynchronous return objects (as opposed to hpx::shared_future).

  • +
+

+
+

Public Types

+
+
+using result_type = R#
+
+ +
+
+using shared_state_type = typename base_type::shared_state_type#
+
+ +
+
+

Public Functions

+
+
+constexpr future() noexcept = default#
+
+ +
+
+future(future &&other) noexcept = default#
+
+ +
+
+future(future const &other) noexcept = delete#
+
+ +
+
+inline future(future<future> &&other) noexcept#
+
+ +
+
+inline future(future<shared_future<R>> &&other) noexcept#
+
+ +
+
+template<typename T>
inline future(future<T> &&other, std::enable_if_t<std::is_void_v<R> && !traits::is_future_v<T>, T>* = nullptr) noexcept#
+
+ +
+
+~future() = default#
+
+ +
+
+future &operator=(future &&other) noexcept = default#
+
+ +
+
+future &operator=(future const &other) noexcept = delete#
+
+ +
+
+inline shared_future<R> share() noexcept#
+
+ +
+
+inline hpx::traits::future_traits<future>::result_type get()#
+
+ +
+
+inline hpx::traits::future_traits<future>::result_type get(error_code &ec)#
+
+ +
+
+template<typename F>
inline decltype(auto) then(F &&f, error_code &ec = throws)#
+

Attaches a continuation to *this. The behavior is undefined if *this has no associated shared state (i.e., valid()==false ).

+

In cases where decltype(func(*this)) is future<R>, the resulting type is future<R> instead of future<future<R>>. Effects:

    +
  • The continuation is called when the object’s shared state is ready (has a value or exception stored).

  • +
  • The continuation launches according to the specified launch policy or executor.

  • +
  • When the executor or launch policy is not provided the continuation inherits the parent’s launch policy or executor.

  • +
  • If the parent was created with std::promise or with a packaged_task (has no associated launch policy), the continuation behaves the same as the third overload with a policy argument of launch::async | launch::deferred and the same argument for func.

  • +
  • If the parent has a policy of launch::deferred and the continuation does not have a specified launch policy or scheduler, then the parent is filled by immediately calling .wait(), and the policy of the antecedent is launch::deferred

  • +
+

+
+

Note

+

Postcondition:

    +
  • The future object is moved to the parameter of the continuation function.

  • +
  • valid() == false on original future object immediately after it returns.

  • +
+

+
+
+
Template Parameters
+
    +
  • F – The type of the function/function object to use (deduced). F must meet requirements of MoveConstructible.

  • +
  • error_code – The type of error code.

  • +
+
+
Parameters
+
    +
  • f – A continuation to be attached.

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

An object of type future<decltype(func(*this))> that refers to the shared state created by the continuation.

+
+
+
+ +
+
+template<typename T0, typename F>
inline decltype(auto) then(T0 &&t0, F &&f, error_code &ec = throws)#
+

Attaches a continuation to *this. The behavior is undefined if *this has no associated shared state (i.e., valid()==false ). \copydetail hpx::future::then(F&& f, error_code& ec = throws)

+
+

Note

+

Postcondition:

    +
  • The future object is moved to the parameter of the continuation function.

  • +
  • valid() == false on original future object immediately after it returns.

  • +
+

+
+
+
Template Parameters
+
    +
  • T0 – The type of executor or launch policy.

  • +
  • F – The type of the function/function object to use (deduced). F must meet requirements of MoveConstructible.

  • +
  • error_code – The type of error code.

  • +
+
+
Parameters
+
    +
  • t0 – The executor or launch policy to be used.

  • +
  • f – A continuation to be attached.

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

An object of type future<decltype(func(*this))> that refers to the shared state created by the continuation.

+
+
+
+ +
+
+template<typename Allocator, typename F>
inline auto then_alloc(Allocator const &alloc, F &&f, error_code &ec = throws) -> decltype(base_type::then_alloc(alloc, HPX_MOVE(*this), HPX_FORWARD(F, f), ec))#
+
+ +
+
+

Private Types

+
+
+using base_type = lcos::detail::future_base<future<R>, R>#
+
+ +
+
+

Private Functions

+
+
+inline explicit future(hpx::intrusive_ptr<shared_state_type> const &state)#
+
+ +
+
+inline explicit future(hpx::intrusive_ptr<shared_state_type> &&state)#
+
+ +
+
+template<typename SharedState>
inline explicit future(hpx::intrusive_ptr<SharedState> const &state)#
+
+ +
+
+

Friends

+
+
+friend struct hpx::traits::future_access
+
+ +
+
+ +
+
+template<typename R>
class shared_future : public hpx::lcos::detail::future_base<shared_future<R>, R>#
+
+#include <future_fwd.hpp>
+

The class template hpx::shared_future provides a mechanism to access the result of asynchronous operations, similar to hpx::future, except that multiple threads are allowed to wait for the same shared state. Unlike hpx::future, which is only moveable (so only one instance can refer to any particular asynchronous result), hpx::shared_future is copyable and multiple shared future objects may refer to the same shared state. Access to the same shared state from multiple threads is safe if each thread does it through its own copy of a shared_future object.

+
+

Public Types

+
+
+using result_type = R#
+
+ +
+
+using shared_state_type = typename base_type::shared_state_type#
+
+ +
+
+

Public Functions

+
+
+constexpr shared_future() noexcept = default#
+
+ +
+
+shared_future(shared_future const &other) = default#
+
+ +
+
+shared_future(shared_future &&other) noexcept = default#
+
+ +
+
+inline shared_future(future<R> &&other) noexcept#
+
+ +
+
+inline shared_future(future<shared_future> &&other) noexcept#
+
+ +
+
+template<typename T>
inline shared_future(shared_future<T> const &other, std::enable_if_t<std::is_void_v<R> && !traits::is_future_v<T>, T>* = nullptr)#
+
+ +
+
+~shared_future() = default#
+
+ +
+
+shared_future &operator=(shared_future const &other) = default#
+
+ +
+
+shared_future &operator=(shared_future &&other) noexcept = default#
+
+ +
+
+inline hpx::traits::future_traits<shared_future>::result_type get() const#
+
+ +
+
+inline hpx::traits::future_traits<shared_future>::result_type get(error_code &ec) const#
+
+ +
+
+template<typename F>
inline decltype(auto) then(F &&f, error_code &ec = throws) const#
+

Attaches a continuation to *this. The behavior is undefined if *this has no associated shared state (i.e., valid()==false ).

+

In cases where decltype(func(*this)) is future<R>, the resulting type is future<R> instead of future<future<R>>. Effects:

    +
  • The continuation is called when the object’s shared state is ready (has a value or exception stored).

  • +
  • The continuation launches according to the specified launch policy or executor.

  • +
  • When the executor or launch policy is not provided the continuation inherits the parent’s launch policy or executor.

  • +
  • If the parent was created with std::promise or with a packaged_task (has no associated launch policy), the continuation behaves the same as the third overload with a policy argument of launch::async | launch::deferred and the same argument for func.

  • +
  • If the parent has a policy of launch::deferred and the continuation does not have a specified launch policy or scheduler, then the parent is filled by immediately calling .wait(), and the policy of the antecedent is launch::deferred

  • +
+

+
+

Note

+

Postcondition:

    +
  • The future object is moved to the parameter of the continuation function.

  • +
  • valid() == false on original future object immediately after it returns.

  • +
+

+
+
+
Template Parameters
+
    +
  • F – The type of the function/function object to use (deduced). F must meet requirements of MoveConstructible.

  • +
  • error_code – The type of error code.

  • +
+
+
Parameters
+
    +
  • f – A continuation to be attached.

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

An object of type future<decltype(func(*this))> that refers to the shared state created by the continuation.

+
+
+
+ +
+
+template<typename T0, typename F>
inline decltype(auto) then(T0 &&t0, F &&f, error_code &ec = throws) const#
+

Attaches a continuation to *this. The behavior is undefined if *this has no associated shared state (i.e., valid()==false ). \copydetail hpx::future::then(F&& f, error_code& ec = throws)

+
+

Note

+

Postcondition:

    +
  • The future object is moved to the parameter of the continuation function.

  • +
  • valid() == false on original future object immediately after it returns.

  • +
+

+
+
+
Template Parameters
+
    +
  • T0 – The type of executor or launch policy.

  • +
  • F – The type of the function/function object to use (deduced). F must meet requirements of MoveConstructible.

  • +
  • error_code – The type of error code.

  • +
+
+
Parameters
+
    +
  • t0 – The executor or launch policy to be used.

  • +
  • f – A continuation to be attached.

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

An object of type future<decltype(func(*this))> that refers to the shared state created by the continuation.

+
+
+
+ +
+
+template<typename Allocator, typename F>
inline auto then_alloc(Allocator const &alloc, F &&f, error_code &ec = throws) -> decltype(base_type::then_alloc(alloc, HPX_MOVE(*this), HPX_FORWARD(F, f), ec))#
+
+ +
+
+

Private Types

+
+
+using base_type = lcos::detail::future_base<shared_future<R>, R>#
+
+ +
+
+

Private Functions

+
+
+inline explicit shared_future(hpx::intrusive_ptr<shared_state_type> const &state)#
+
+ +
+
+inline explicit shared_future(hpx::intrusive_ptr<shared_state_type> &&state)#
+
+ +
+
+template<typename SharedState>
inline explicit shared_future(hpx::intrusive_ptr<SharedState> const &state)#
+
+ +
+
+

Friends

+
+
+friend struct hpx::traits::future_access
+
+ +
+
+ +
+
+namespace lcos#
+
+

Functions

+
+
+template<typename R, typename U>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_future is deprecated. Use hpx::make_future instead.") hpx
+
+ +
+
+template<typename R, typename U, typename Conv>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_future is deprecated. Use hpx::make_future instead.") hpx
+
+ +
+
+template<typename T, typename Allocator, typename... Ts>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_ready_future_alloc is deprecated. Use " "hpx::make_ready_future_alloc instead.") std
+
+ +
+
+template<typename T, typename... Ts>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_ready_future is deprecated. Use " "hpx::make_ready_future instead.") std
+
+ +
+
+template<typename T>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_exceptional_future is deprecated. Use " "hpx::make_exceptional_future instead.") hpx
+
+ +
+
+template<typename T, typename E>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_exceptional_future is deprecated. Use " "hpx::make_exceptional_future instead.") hpx
+
+ +
+
+template<int DeductionGuard = 0, typename T>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_ready_future_at is deprecated. Use " "hpx::make_ready_future_at instead.") hpx
+
+ +
+
+template<int DeductionGuard = 0, typename T>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_ready_future_after is deprecated. Use " "hpx::make_ready_future_after instead.") hpx
+
+ +
+
+template<typename Allocator>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_ready_future_alloc is deprecated. Use " "hpx::make_ready_future_alloc instead.") hpx
+
+ +
+
+template<typename T>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_ready_future is deprecated. Use " "hpx::make_ready_future instead.") std
+
+ +
+
+template<typename T>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_ready_future_at is deprecated. Use " "hpx::make_ready_future_at instead.") std
+
+ +
+
+template<typename T>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::make_ready_future_after is deprecated. Use " "hpx::make_ready_future_after instead.") std
+
+ +
+
+ +
+
+namespace serialization
+
+

Functions

+
+
+template<typename Archive, typename T>
void serialize(Archive &ar, ::hpx::future<T> &f, unsigned version)#
+
+ +
+
+template<typename Archive, typename T>
void serialize(Archive &ar, ::hpx::shared_future<T> &f, unsigned version)#
+
+ +
+
+ +
+ +
+
+
hpx/futures/future_fwd.hpp#
+

Defined in header hpx/futures/future_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+template<typename R>
class future : public hpx::lcos::detail::future_base<future<R>, R>
+
+#include <future_fwd.hpp>
+
+ +
+
+template<typename R>
class shared_future : public hpx::lcos::detail::future_base<shared_future<R>, R>
+
+#include <future_fwd.hpp>
+
+ +
+
+namespace lcos
+
+

Typedefs

+
+
+typedef hpx::future<R> instead#
+
+ +
+
+ +
+ +
+
+namespace lcos#
+
+ +
+
+
hpx::packaged_task#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<typename Sig, typename Allocator>
struct uses_allocator<hpx::packaged_task<Sig>, Allocator> : public true_type#
+
+ +
+
+namespace hpx
+

Top level HPX namespace.

+
+
+template<typename Sig>
class packaged_task#
+
+#include <packaged_task.hpp>
+

The class template hpx::packaged_task wraps any Callable` target (function, lambda expression, bind expression, or another function object) so that it can be invoked asynchronously. Its return value or exception thrown is stored in a shared state which can be accessed through hpx::future objects. Just like hpx::function, hpx::packaged_task is a polymorphic, allocator-aware container: the stored callable target may be allocated on heap or with a provided allocator.

+
+ +
+
+template<typename R, typename ...Ts>
class packaged_task<R(Ts...)>#
+
+

Public Functions

+
+
+packaged_task() = default#
+
+ +
+
+template<typename F, typename FD = std::decay_t<F>, typename Enable = std::enable_if_t<!std::is_same_v<FD, packaged_task> && is_invocable_r_v<R, FD&, Ts...>>>
inline explicit packaged_task(F &&f)#
+
+ +
+
+template<typename Allocator, typename F, typename FD = std::decay_t<F>, typename Enable = std::enable_if_t<!std::is_same_v<FD, packaged_task> && is_invocable_r_v<R, FD&, Ts...>>>
inline explicit packaged_task(std::allocator_arg_t, Allocator const &a, F &&f)#
+
+ +
+
+packaged_task(packaged_task const &rhs) noexcept = delete#
+
+ +
+
+packaged_task(packaged_task &&rhs) noexcept = default#
+
+ +
+
+packaged_task &operator=(packaged_task const &rhs) noexcept = delete#
+
+ +
+
+packaged_task &operator=(packaged_task &&rhs) noexcept = default#
+
+ +
+
+inline void swap(packaged_task &rhs) noexcept#
+
+ +
+
+inline void operator()(Ts... ts)#
+
+ +
+
+inline hpx::future<R> get_future(error_code &ec = throws)#
+
+ +
+
+inline bool valid() const noexcept#
+
+ +
+
+inline void reset(error_code &ec = throws)#
+
+ +
+
+inline void set_exception(std::exception_ptr const &e)#
+
+ +
+
+

Private Types

+
+
+using function_type = hpx::move_only_function<R(Ts...)>#
+
+ +
+
+

Private Members

+
+
+function_type function_#
+
+ +
+
+hpx::promise<R> promise_#
+
+ +
+
+ +
+
+namespace lcos
+
+
+namespace local#
+
+

Typedefs

+
+
+typedef hpx::packaged_task<Sig> instead#
+
+ +
+
+ +
+ +
+ +
+
+namespace std
+
+

Functions

+
+
+template<typename Sig>
void swap(hpx::packaged_task<Sig> &lhs, hpx::packaged_task<Sig> &rhs) noexcept#
+
+ +
+
+
+template<typename Sig, typename Allocator> packaged_task< Sig >, Allocator > : public true_type
+
+ +
+ +
+
+
hpx::promise#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<typename R, typename Allocator>
struct uses_allocator<hpx::promise<R>, Allocator> : public true_type#
+
+ +
+
+namespace hpx
+

Top level HPX namespace.

+
+
+template<typename R>
class promise : public hpx::detail::promise_base<R>#
+
+#include <promise.hpp>
+

The class template hpx::promise provides a facility to store a value or an exception that is later acquired asynchronously via a hpx::future object created by the hpx::promise object. Note that the hpx::promise object is meant to be used only once. Each promise is associated with a shared state, which contains some state information and a result which may be not yet evaluated, evaluated to a value (possibly void) or evaluated to an exception. A promise may do three things with the shared state:

    +
  • make ready: the promise stores the result or the exception in the shared state. Marks the state ready and unblocks any thread waiting on a future associated with the shared state.

  • +
  • release: the promise gives up its reference to the shared state. If this was the last such reference, the shared state is destroyed. Unless this was a shared state created by hpx::async which is not yet ready, this operation does not block.

  • +
  • abandon: the promise stores the exception of type hpx::future_error with error code hpx::error::broken_promise, makes the shared state ready, and then releases it. The promise is the “push” end of the promise-future communication channel: the operation that stores a value in the shared state synchronizes-with (as defined in hpx::memory_order) the successful return from any function that is waiting on the shared state (such as hpx::future::get). Concurrent access to the same shared state may conflict otherwise: for example multiple callers of hpx::shared_future::get must either all be read-only or provide external synchronization.

  • +
+

+
+

Public Functions

+
+
+promise() = default#
+
+ +
+
+template<typename Allocator>
inline promise(std::allocator_arg_t, Allocator const &a)#
+
+ +
+
+promise(promise &&other) noexcept = default#
+
+ +
+
+promise(promise const &other) = delete#
+
+ +
+
+~promise() = default#
+
+ +
+
+promise &operator=(promise &&other) noexcept = default#
+
+ +
+
+promise &operator=(promise const &other) = delete#
+
+ +
+
+inline void swap(promise &other) noexcept#
+
+ +
+
+inline void set_value(R const &r)#
+
+ +
+
+inline void set_value(R &&r)#
+
+ +
+
+template<typename ...Ts>
inline void set_value(Ts&&... ts)#
+
+ +
+
+

Private Types

+
+
+using base_type = detail::promise_base<R>#
+
+ +
+
+ +
+
+template<typename R>
class promise<R&> : public hpx::detail::promise_base<R&>#
+
+

Public Functions

+
+
+promise() = default#
+
+ +
+
+template<typename Allocator>
inline promise(std::allocator_arg_t, Allocator const &a)#
+
+ +
+
+promise(promise &&other) noexcept = default#
+
+ +
+
+promise(promise const &other) = delete#
+
+ +
+
+~promise() = default#
+
+ +
+
+promise &operator=(promise &&other) noexcept = default#
+
+ +
+
+promise &operator=(promise const &other) = delete#
+
+ +
+
+inline void swap(promise &other) noexcept#
+
+ +
+
+inline void set_value(R &r)#
+
+ +
+
+

Private Types

+
+
+using base_type = detail::promise_base<R&>#
+
+ +
+
+ +
+
+template<>
class promise<void> : public hpx::detail::promise_base<void>#
+
+

Public Functions

+
+
+promise() = default#
+
+ +
+
+template<typename Allocator>
inline promise(std::allocator_arg_t, Allocator const &a)#
+
+ +
+
+promise(promise &&other) noexcept = default#
+
+ +
+
+promise(promise const &other) noexcept = delete#
+
+ +
+
+~promise() = default#
+
+ +
+
+promise &operator=(promise &&other) noexcept = default#
+
+ +
+
+promise &operator=(promise const &other) noexcept = delete#
+
+ +
+
+inline void swap(promise &other) noexcept#
+
+ +
+
+inline void set_value()#
+
+ +
+
+

Private Types

+
+
+using base_type = detail::promise_base<void>#
+
+ +
+
+ +
+
+namespace lcos
+
+
+namespace local
+
+ +
+ +
+ +
+
+namespace std
+
+

Functions

+
+
+template<typename R>
void swap(hpx::promise<R> &x, hpx::promise<R> &y) noexcept#
+
+ +
+
+
+template<typename R, typename Allocator> promise< R >, Allocator > : public true_type
+
+ +
+ +
+
+
+
+
io_service#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/io_service/io_service_pool.hpp#
+

Defined in header hpx/io_service/io_service_pool.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+
+class io_service_pool#
+
+#include <io_service_pool.hpp>
+

A pool of io_service objects.

+
+

Public Functions

+
+
+HPX_NON_COPYABLE(io_service_pool)#
+
+ +
+
+explicit io_service_pool(std::size_t pool_size = 2, threads::policies::callback_notifier const &notifier = threads::policies::callback_notifier(), char const *pool_name = "", char const *name_postfix = "")#
+

Construct the io_service pool.

+
+
Parameters
+
    +
  • pool_size – [in] The number of threads to run to serve incoming requests

  • +
  • notifier – [in]

  • +
  • pool_name – [in]

  • +
  • name_postfix – [in]

  • +
+
+
+
+ +
+
+explicit io_service_pool(threads::policies::callback_notifier const &notifier, char const *pool_name = "", char const *name_postfix = "")#
+

Construct the io_service pool.

+
+
Parameters
+
    +
  • notifier – [in]

  • +
  • pool_name – [in]

  • +
  • name_postfix – [in]

  • +
+
+
+
+ +
+
+~io_service_pool()#
+
+ +
+
+bool run(bool join_threads = true, barrier *startup = nullptr)#
+

Run all io_service objects in the pool. If join_threads is true this will also wait for all threads to complete

+
+ +
+
+bool run(std::size_t num_threads, bool join_threads = true, barrier *startup = nullptr)#
+

Run all io_service objects in the pool. If join_threads is true this will also wait for all threads to complete

+
+ +
+
+void stop()#
+

Stop all io_service objects in the pool.

+
+ +
+
+void join()#
+

Join all io_service threads in the pool.

+
+ +
+
+void clear()#
+

Clear all internal data structures.

+
+ +
+
+void wait()#
+

Wait for all work to be done.

+
+ +
+
+bool stopped()#
+
+ +
+
+asio::io_context &get_io_service(int index = -1)#
+

Get an io_service to use.

+
+ +
+
+std::thread &get_os_thread_handle(std::size_t thread_num)#
+

access underlying thread handle

+
+ +
+
+inline constexpr std::size_t size() const noexcept#
+

Get number of threads associated with this I/O service.

+
+ +
+
+void thread_run(std::size_t index, barrier *startup = nullptr) const#
+

Activate the thread index for this thread pool.

+
+ +
+
+inline constexpr char const *get_name() const noexcept#
+

Return name of this pool.

+
+ +
+
+void init(std::size_t pool_size)#
+
+ +
+
+

Protected Functions

+
+
+bool run_locked(std::size_t num_threads, bool join_threads, barrier *startup)#
+
+ +
+
+void stop_locked()#
+
+ +
+
+void join_locked()#
+
+ +
+
+void clear_locked()#
+
+ +
+
+void wait_locked()#
+
+ +
+
+

Private Types

+
+
+using io_service_ptr = std::unique_ptr<asio::io_context>#
+
+ +
+
+using work_type = std::unique_ptr<asio::io_context::work>#
+
+ +
+
+

Private Members

+
+
+std::mutex mtx_#
+
+ +
+
+std::vector<io_service_ptr> io_services_#
+

The pool of io_services.

+
+ +
+
+std::vector<std::thread> threads_#
+
+ +
+
+std::vector<work_type> work_#
+

The work that keeps the io_services running.

+
+ +
+
+std::size_t next_io_service_#
+

The next io_service to use for a connection.

+
+ +
+
+bool stopped_#
+

set to true if stopped

+
+ +
+
+std::size_t pool_size_#
+

initial number of OS threads to execute in this pool

+
+ +
+
+threads::policies::callback_notifier const &notifier_#
+

call this for each thread start/stop

+
+ +
+
+char const *pool_name_#
+
+ +
+
+char const *pool_name_postfix_#
+
+ +
+
+bool waiting_#
+

Set to true if waiting for work to finish.

+
+ +
+
+std::unique_ptr<barrier> wait_barrier_#
+
+ +
+
+std::unique_ptr<barrier> continue_barrier_#
+
+ +
+
+

Private Static Functions

+
+
+static inline work_type initialize_work(asio::io_context &io_service)#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
lcos_local#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/lcos_local/trigger.hpp#
+

Defined in header hpx/lcos_local/trigger.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace lcos
+
+
+namespace local
+
+
+template<typename Mutex = hpx::spinlock>
struct base_trigger#
+
+

Public Functions

+
+
+inline base_trigger() noexcept#
+
+ +
+
+inline base_trigger(base_trigger &&rhs) noexcept#
+
+ +
+
+inline base_trigger &operator=(base_trigger &&rhs) noexcept#
+
+ +
+
+inline hpx::future<void> get_future(std::size_t *generation_value = nullptr, error_code &ec = hpx::throws)#
+

get a future allowing to wait for the trigger to fire

+
+ +
+
+inline bool set(error_code &ec = throws)#
+

Trigger this object.

+
+ +
+
+inline void synchronize(std::size_t generation_value, char const *function_name = "trigger::synchronize", error_code &ec = throws)#
+

Wait for the generational counter to reach the requested stage.

+
+ +
+
+inline std::size_t next_generation()#
+
+ +
+
+inline std::size_t generation() const#
+
+ +
+
+

Protected Types

+
+
+using mutex_type = Mutex#
+
+ +
+
+

Protected Functions

+
+
+inline bool trigger_conditions(error_code &ec = throws)#
+
+ +
+
+template<typename Lock>
inline void synchronize(std::size_t generation_value, Lock &l, char const *function_name = "trigger::synchronize", error_code &ec = throws)#
+
+ +
+
+

Private Types

+
+
+using condition_list_type = hpx::detail::intrusive_list<condition_list_entry>#
+
+ +
+
+

Private Functions

+
+
+inline bool test_condition(std::size_t generation_value) noexcept#
+
+ +
+
+

Private Members

+
+
+mutable mutex_type mtx_#
+
+ +
+
+hpx::promise<void> promise_#
+
+ +
+
+std::size_t generation_#
+
+ +
+
+condition_list_type conditions_#
+
+ +
+
+
+struct condition_list_entry : public conditional_trigger#
+
+

Public Functions

+
+
+condition_list_entry() = default#
+
+ +
+
+

Public Members

+
+
+condition_list_entry *prev = nullptr#
+
+ +
+
+condition_list_entry *next = nullptr#
+
+ +
+
+ +
+
+struct manage_condition#
+
+

Public Functions

+
+
+inline manage_condition(base_trigger &gate, condition_list_entry &cond) noexcept#
+
+ +
+
+inline ~manage_condition()#
+
+ +
+
+template<typename Condition>
inline hpx::future<void> get_future(Condition &&func, error_code &ec = hpx::throws)#
+
+ +
+
+

Public Members

+
+
+base_trigger &this_#
+
+ +
+
+condition_list_entry &e_#
+
+ +
+
+ +
+ +
+
+struct trigger : public hpx::lcos::local::base_trigger<hpx::no_mutex>#
+
+

Public Functions

+
+
+trigger() = default#
+
+ +
+
+inline trigger(trigger &&rhs) noexcept#
+
+ +
+
+inline trigger &operator=(trigger &&rhs) noexcept#
+
+ +
+
+template<typename Lock>
inline void synchronize(std::size_t generation_value, Lock &l, char const *function_name = "trigger::synchronize", error_code &ec = throws)#
+
+ +
+
+

Private Types

+
+
+using base_type = base_trigger<hpx::no_mutex>#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
+
+
pack_traversal#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/pack_traversal/pack_traversal.hpp#
+

Defined in header hpx/pack_traversal/pack_traversal.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+

Functions

+
+
+template<typename Mapper, typename... T> < unspecified > map_pack (Mapper &&mapper, T &&... pack)
+

Maps the pack with the given mapper.

+

This function tries to visit all plain elements which may be wrapped in:

    +
  • homogeneous containers (std::vector, std::list)

  • +
  • heterogeneous containers (hpx::tuple, std::pair, std::array) and re-assembles the pack with the result of the mapper. Mapping from one type to a different one is supported.

  • +
+

+

Elements that aren’t accepted by the mapper are routed through and preserved through the hierarchy.

+

// Maps all integers to floats
+map_pack([](int value) {
+    return float(value);
+},
+1, hpx::make_tuple(2, std::vector<int>{3, 4}), 5);
+
+
+

+
+
Throws
+

std::exception – like objects which are thrown by an invocation to the mapper.

+
+
Parameters
+
    +
  • mapper – A callable object, which accept an arbitrary type and maps it to another type or the same one.

  • +
  • pack – An arbitrary variadic pack which may contain any type.

  • +
+
+
Returns
+

The mapped element or in case the pack contains multiple elements, the pack is wrapped into a hpx::tuple.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/pack_traversal/pack_traversal_async.hpp#
+

Defined in header hpx/pack_traversal/pack_traversal_async.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+

Functions

+
+
+template<typename Visitor, typename ...T>
auto traverse_pack_async(Visitor &&visitor, T&&... pack) -> decltype(detail::apply_pack_transform_async(HPX_FORWARD(Visitor, visitor), HPX_FORWARD(T, pack)...))#
+

Traverses the pack with the given visitor in an asynchronous way.

+

This function works in the same way as traverse_pack, however, we are able to suspend and continue the traversal at later time. Thus we require a visitor callable object which provides three operator() overloads as depicted by the code sample below:

+

    // The synchronous overload is called for each object, // it may
+    return false to suspend the current control. // In that case the
+    overload below is called. template <typename T> bool
+    operator()(async_traverse_visit_tag, T&& element) {
+        return true;
+    }
+
+    // The asynchronous overload this is called when the //
+    synchronous overload returned false. // In addition to the
+    current visited element the overload is // called with a
+    continuation callable object which resumes the // traversal when
+    it's called later. // The continuation next may be stored and
+    called later or // dropped completely to abort the traversal
+    early. template <typename T, typename N> void
+    operator()(async_traverse_detach_tag, T&& element, N&& next) { }
+
+    // The overload is called when the traversal was finished. // As
+    argument the whole pack is passed over which we // traversed
+    asynchronously. template <typename T> void
+    operator()(async_traverse_complete_tag, T&& pack) { }
+};
+
+
+

+

+See traverse_pack for a detailed description about the traversal behavior and capabilities.

+
+
Parameters
+
    +
  • visitor – A visitor object which provides the three operator() overloads that were described above. Additionally the visitor must be compatible for referencing it from a hpx::intrusive_ptr. The visitor should must have a virtual destructor!

  • +
  • pack – The arbitrary parameter pack which is traversed asynchronously. Nested objects inside containers and tuple like types are traversed recursively.

  • +
+
+
Returns
+

A hpx::intrusive_ptr that references an instance of the given visitor object.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::functional::unwrap, hpx::functional::unwrap_n, hpx::functional::unwrap_all, hpx::unwrap, hpx::unwrap_n, hpx::unwrap_all, hpx::unwrapping, hpx::unwrapping_n, hpx::unwrapping_all#
+

Defined in header hpx/unwrap.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename ...Args>
auto unwrap(Args&&... args) -> decltype(util::detail::unwrap_depth_impl<1U>(HPX_FORWARD(Args, args)...))#
+

A helper function for retrieving the actual result of any hpx::future like type which is wrapped in an arbitrary way.

+

Unwraps the given pack of arguments, so that any hpx::future object is replaced by its future result type in the argument pack:

    +
  • hpx::future<int> -> int

  • +
  • hpx::future<std::vector<float>> -> std::vector<float>

  • +
  • std::vector<future<float>> -> std::vector<float>

  • +
+

+

The function is capable of unwrapping hpx::future like objects that are wrapped inside any container or tuple like type, see hpx::util::map_pack() for a detailed description about which surrounding types are supported. Non hpx::future like types are permitted as arguments and passed through.

+

hpx:unwrap(hpx::make_ready_future(0));
+
+// Multiple arguments hpx::tuple<int, int> i2 =
+    hpx:unwrap(hpx::make_ready_future(1),
+               hpx::make_ready_future(2));
+
+
+

+
+

Note

+

This function unwraps the given arguments until the first traversed nested hpx::future which corresponds to an unwrapping depth of one. See hpx::unwrap_n() for a function which unwraps the given arguments to a particular depth or hpx::unwrap_all() that unwraps all future like objects recursively which are contained in the arguments.

+
+
+
Parameters
+

args – the arguments that are unwrapped which may contain any arbitrary future or non future type.

+
+
Throws
+

std::exception – like objects in case any of the given wrapped hpx::future objects were resolved through an exception. See hpx::future::get() for details.

+
+
Returns
+

Depending on the count of arguments this function returns a hpx::tuple containing the unwrapped arguments if multiple arguments are given. In case the function is called with a single argument, the argument is unwrapped and returned.

+
+
+
+ +
+
+template<std::size_t Depth, typename ...Args>
auto unwrap_n(Args&&... args) -> decltype(util::detail::unwrap_depth_impl<Depth>(HPX_FORWARD(Args, args)...))#
+

An alterntive version of hpx::unwrap(), which unwraps the given arguments to a certain depth of hpx::future like objects.

+

+See unwrap for a detailed description.

+
+
Template Parameters
+

Depth – The count of hpx::future like objects which are unwrapped maximally.

+
+
+
+ +
+
+template<typename ...Args>
auto unwrap_all(Args&&... args) -> decltype(util::detail::unwrap_depth_impl<0U>(HPX_FORWARD(Args, args)...))#
+

An alterntive version of hpx::unwrap(), which unwraps the given arguments recursively so that all contained hpx::future like objects are replaced by their actual value.

+

See hpx::unwrap() for a detailed description.

+
+ +
+
+template<typename T>
auto unwrapping(T &&callable) -> decltype(util::detail::functional_unwrap_depth_impl<1U>(HPX_FORWARD(T, callable)))#
+

Returns a callable object which unwraps its arguments upon invocation using the hpx::unwrap() function and then passes the result to the given callable object.

+

    return left + right;
+});
+
+int i1 = callable(hpx::make_ready_future(1),
+                  hpx::make_ready_future(2));
+
+
+

+

See hpx::unwrap() for a detailed description.

+
+
Parameters
+

callable – the callable object which which is called with the result of the corresponding unwrap function.

+
+
+
+ +
+
+template<std::size_t Depth, typename T>
auto unwrapping_n(T &&callable) -> decltype(util::detail::functional_unwrap_depth_impl<Depth>(HPX_FORWARD(T, callable)))#
+

Returns a callable object which unwraps its arguments upon invocation using the hpx::unwrap_n() function and then passes the result to the given callable object.

+

See hpx::unwrapping() for a detailed description.

+
+ +
+
+template<typename T>
auto unwrapping_all(T &&callable) -> decltype(util::detail::functional_unwrap_depth_impl<0U>(HPX_FORWARD(T, callable)))#
+

Returns a callable object which unwraps its arguments upon invocation using the hpx::unwrap_all() function and then passes the result to the given callable object.

+

See hpx::unwrapping() for a detailed description.

+
+ +
+
+
+namespace functional
+
+
+struct unwrap#
+
+#include <unwrap.hpp>
+

A helper function object for functionally invoking hpx::unwrap. For more information please refer to its documentation.

+
+ +
+
+struct unwrap_all#
+
+#include <unwrap.hpp>
+

A helper function object for functionally invoking hpx::unwrap_all. For more information please refer to its documentation.

+
+ +
+
+template<std::size_t Depth>
struct unwrap_n#
+
+#include <unwrap.hpp>
+

A helper function object for functionally invoking hpx::unwrap_n. For more information please refer to its documentation.

+
+ +
+ +
+ +
+
+
+
+
preprocessor#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/preprocessor/cat.hpp#
+

Defined in header hpx/preprocessor/cat.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_PP_CAT(A, B)#
+

Concatenates the tokens A and B into a single token. Evaluates to AB

+
+
Parameters
+
    +
  • A – First token

  • +
  • B – Second token

  • +
+
+
+
+ +
+
+
+
hpx/preprocessor/expand.hpp#
+

Defined in header hpx/preprocessor/expand.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_PP_EXPAND(X)#
+

The HPX_PP_EXPAND macro performs a double macro-expansion on its argument.

+

This macro can be used to produce a delayed preprocessor expansion.

+

+

Example:

#define MACRO(a, b, c) (a)(b)(c)
+#define ARGS() (1, 2, 3)
+
+HPX_PP_EXPAND(MACRO ARGS()) // expands to (1)(2)(3)
+
+
+

+
+
Parameters
+
    +
  • X – Token to be expanded twice

  • +
+
+
+
+ +
+
+
+
hpx/preprocessor/nargs.hpp#
+

Defined in header hpx/preprocessor/nargs.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_PP_NARGS(...)#
+

Expands to the number of arguments passed in

+

+Example Usage:

HPX_PP_NARGS(hpx, pp, nargs)
+HPX_PP_NARGS(hpx, pp)
+HPX_PP_NARGS(hpx)
+
+
+

+

Expands to:

3
+2
+1
+
+
+

+
+
Parameters
+
    +
  • ... – The variadic number of arguments

  • +
+
+
+
+ +
+
+
+
hpx/preprocessor/stringize.hpp#
+

Defined in header hpx/preprocessor/stringize.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_PP_STRINGIZE(X)#
+

The HPX_PP_STRINGIZE macro stringizes its argument after it has been expanded.

+

+The passed argument X will expand to "X". Note that the stringizing operator (#) prevents arguments from expanding. This macro circumvents this shortcoming.

+
+
Parameters
+
    +
  • X – The text to be converted to a string literal

  • +
+
+
+
+ +
+
+
+
hpx/preprocessor/strip_parens.hpp#
+

Defined in header hpx/preprocessor/strip_parens.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_PP_STRIP_PARENS(X)#
+

For any symbol X, this macro returns the same symbol from which potential outer parens have been removed. If no outer parens are found, this macros evaluates to X itself without error.

+

The original implementation of this macro is from Steven Watanbe as shown in http://boost.2283326.n4.nabble.com/preprocessor-removing-parentheses-td2591973.html#a2591976

+

HPX_PP_STRIP_PARENS(no_parens)
+HPX_PP_STRIP_PARENS((with_parens))
+
+
+
+
Example Usage:

+
+
+

+

This produces the following output

no_parens
+with_parens
+
+
+

+
+
Parameters
+
    +
  • X – Symbol to strip parens from

  • +
+
+
+
+ +
+
+
+
+
+
resiliency#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/resiliency/replay_executor.hpp#
+

Defined in header hpx/resiliency/replay_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<typename BaseExecutor, typename Validator>
struct is_two_way_executor<hpx::resiliency::experimental::replay_executor<BaseExecutor, Validator>> : public true_type#
+
+ +
+
+template<typename BaseExecutor, typename Validator>
struct is_bulk_two_way_executor<hpx::resiliency::experimental::replay_executor<BaseExecutor, Validator>> : public true_type#
+
+ +
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+
+template<typename BaseExecutor, typename Validator> replay_executor< BaseExecutor, Validator > > : public true_type
+
+ +
+
+template<typename BaseExecutor, typename Validator> replay_executor< BaseExecutor, Validator > > : public true_type
+
+ +
+ +
+ +
+
+namespace resiliency#
+
+
+namespace experimental#
+
+

Functions

+
+
+template<typename Tag, typename BaseExecutor, typename Validate, typename Property>
auto tag_invoke(Tag tag, replay_executor<BaseExecutor, Validate> const &exec, Property &&prop) -> decltype(replay_executor<BaseExecutor, Validate>(std::declval<Tag>()(std::declval<BaseExecutor>(), std::declval<Property>()), std::declval<std::size_t>(), std::declval<Validate>()))#
+
+ +
+
+template<typename Tag, typename BaseExecutor, typename Validate>
auto tag_invoke(Tag tag, replay_executor<BaseExecutor, Validate> const &exec) -> decltype(std::declval<Tag>()(std::declval<BaseExecutor>()))#
+
+ +
+
+template<typename BaseExecutor, typename Validate>
replay_executor<BaseExecutor, std::decay_t<Validate>> make_replay_executor(BaseExecutor &exec, std::size_t n, Validate &&validate)#
+
+ +
+
+template<typename BaseExecutor>
replay_executor<BaseExecutor, detail::replay_validator> make_replay_executor(BaseExecutor &exec, std::size_t n)#
+
+ +
+
+
+template<typename BaseExecutor, typename Validate>
class replay_executor#
+
+

Public Types

+
+
+using execution_category = hpx::traits::executor_execution_category_t<BaseExecutor>#
+
+ +
+
+using executor_parameters_type = hpx::traits::executor_parameters_type_t<BaseExecutor>#
+
+ +
+
+template<typename Result>
using future_type = hpx::traits::executor_future_t<BaseExecutor, Result>#
+
+ +
+
+

Public Functions

+
+
+template<typename BaseExecutor_, typename F>
inline explicit replay_executor(BaseExecutor_ &&exec, std::size_t n, F &&f)#
+
+ +
+
+inline bool operator==(replay_executor const &rhs) const noexcept#
+
+ +
+
+inline bool operator!=(replay_executor const &rhs) const noexcept#
+
+ +
+
+inline constexpr replay_executor const &context() const noexcept#
+
+ +
+
+inline BaseExecutor const &get_executor() const#
+
+ +
+
+inline std::size_t get_replay_count() const#
+
+ +
+
+inline Validate const &get_validator() const#
+
+ +
+
+

Public Static Attributes

+
+
+static constexpr int num_spread = 4#
+
+ +
+
+static constexpr int num_tasks = 128#
+
+ +
+
+

Private Functions

+
+
+template<typename F, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::async_execute_t, replay_executor const &exec, F &&f, Ts&&... ts)#
+
+ +
+
+template<typename F, typename S, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::bulk_async_execute_t, replay_executor const &exec, F &&f, S const &shape, Ts&&... ts)#
+
+ +
+
+

Private Members

+
+
+BaseExecutor exec_#
+
+ +
+
+std::size_t replay_count_#
+
+ +
+
+Validate validator_#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/resiliency/replicate_executor.hpp#
+

Defined in header hpx/resiliency/replicate_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<typename BaseExecutor, typename Voter, typename Validator>
struct is_two_way_executor<hpx::resiliency::experimental::replicate_executor<BaseExecutor, Voter, Validator>> : public true_type#
+
+ +
+
+template<typename BaseExecutor, typename Voter, typename Validator>
struct is_bulk_two_way_executor<hpx::resiliency::experimental::replicate_executor<BaseExecutor, Voter, Validator>> : public true_type#
+
+ +
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+
+template<typename BaseExecutor, typename Voter, typename Validator> replicate_executor< BaseExecutor, Voter, Validator > > : public true_type
+
+ +
+
+template<typename BaseExecutor, typename Voter, typename Validator> replicate_executor< BaseExecutor, Voter, Validator > > : public true_type
+
+ +
+ +
+ +
+
+namespace resiliency
+
+
+namespace experimental
+
+

Functions

+
+
+template<typename Tag, typename BaseExecutor, typename Vote, typename Validate, typename Property>
auto tag_invoke(Tag tag, replicate_executor<BaseExecutor, Vote, Validate> const &exec, Property &&prop) -> decltype(replicate_executor<BaseExecutor, Vote, Validate>(std::declval<Tag>()(std::declval<BaseExecutor>(), std::declval<Property>()), std::declval<std::size_t>(), std::declval<Vote>(), std::declval<Validate>()))#
+
+ +
+
+template<typename Tag, typename BaseExecutor, typename Vote, typename Validate>
auto tag_invoke(Tag tag, replicate_executor<BaseExecutor, Vote, Validate> const &exec) -> decltype(std::declval<Tag>()(std::declval<BaseExecutor>()))#
+
+ +
+
+template<typename BaseExecutor, typename Voter, typename Validate>
replicate_executor<BaseExecutor, std::decay_t<Voter>, std::decay_t<Validate>> make_replicate_executor(BaseExecutor &exec, std::size_t n, Voter &&voter, Validate &&validate)#
+
+ +
+
+template<typename BaseExecutor, typename Validate>
replicate_executor<BaseExecutor, detail::replicate_voter, std::decay_t<Validate>> make_replicate_executor(BaseExecutor &exec, std::size_t n, Validate &&validate)#
+
+ +
+
+template<typename BaseExecutor>
replicate_executor<BaseExecutor, detail::replicate_voter, detail::replicate_validator> make_replicate_executor(BaseExecutor &exec, std::size_t n)#
+
+ +
+
+
+template<typename BaseExecutor, typename Vote, typename Validate>
class replicate_executor#
+
+

Public Types

+
+
+using execution_category = hpx::traits::executor_execution_category_t<BaseExecutor>#
+
+ +
+
+using executor_parameters_type = hpx::traits::executor_parameters_type_t<BaseExecutor>#
+
+ +
+
+template<typename Result>
using future_type = hpx::traits::executor_future_t<BaseExecutor, Result>#
+
+ +
+
+

Public Functions

+
+
+template<typename BaseExecutor_, typename V, typename F>
inline explicit replicate_executor(BaseExecutor_ &&exec, std::size_t n, V &&v, F &&f)#
+
+ +
+
+inline bool operator==(replicate_executor const &rhs) const noexcept#
+
+ +
+
+inline bool operator!=(replicate_executor const &rhs) const noexcept#
+
+ +
+
+inline constexpr replicate_executor const &context() const noexcept#
+
+ +
+
+inline BaseExecutor const &get_executor() const#
+
+ +
+
+inline std::size_t get_replicate_count() const#
+
+ +
+
+inline Vote const &get_voter() const#
+
+ +
+
+inline Validate const &get_validator() const#
+
+ +
+
+

Public Static Attributes

+
+
+static constexpr int num_spread = 4#
+
+ +
+
+static constexpr int num_tasks = 128#
+
+ +
+
+

Private Functions

+
+
+template<typename F, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::async_execute_t, replicate_executor const &exec, F &&f, Ts&&... ts)#
+
+ +
+
+template<typename F, typename S, typename ...Ts>
inline decltype(auto) friend tag_invoke(hpx::parallel::execution::bulk_async_execute_t, replicate_executor const &exec, F &&f, S const &shape, Ts&&... ts)#
+
+ +
+
+

Private Members

+
+
+BaseExecutor exec_#
+
+ +
+
+std::size_t replicate_count_#
+
+ +
+
+Vote voter_#
+
+ +
+
+Validate validator_#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
+
+
runtime_configuration#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::components::component_commandline_base#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_COMMANDLINE_REGISTRY(RegistryType, componentname)#
+

The macro HPX_REGISTER_COMMANDLINE_REGISTRY is used to register the given component factory with Hpx.Plugin. This macro has to be used for each of the components.

+
+ +
+
+HPX_REGISTER_COMMANDLINE_REGISTRY_DYNAMIC(RegistryType, componentname)#
+
+ +
+
+HPX_REGISTER_COMMANDLINE_OPTIONS()#
+

The macro HPX_REGISTER_COMMANDLINE_OPTIONS is used to define the required Hpx.Plugin entry point for the command line option registry. This macro has to be used in not more than one compilation unit of a component module.

+
+ +
+
+HPX_REGISTER_COMMANDLINE_OPTIONS_DYNAMIC()#
+
+ +
+
+
+namespace hpx
+
+
+namespace components#
+
+
+struct component_commandline_base#
+
+#include <component_commandline_base.hpp>
+

The component_commandline_base has to be used as a base class for all component command-line line handling registries.

+
+

Public Functions

+
+
+virtual ~component_commandline_base() = default#
+
+ +
+
+virtual hpx::program_options::options_description add_commandline_options() = 0#
+

Return any additional command line options valid for this component.

+
+

Note

+

This function will be executed by the runtime system during system startup.

+
+
+
Returns
+

The module is expected to fill a options_description object with any additional command line options this component will handle.

+
+
+
+ +
+
+ +
+ +
+ +
+
+
HPX_REGISTER_COMPONENT_MODULE#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_COMPONENT_FACTORY(componentname)#
+

This macro is used to register the given component factory with Hpx.Plugin. This macro has to be used for each of the component factories.

+
+ +
+
+HPX_REGISTER_COMPONENT_MODULE()#
+

This macro is used to define the required Hpx.Plugin entry points. This macro has to be used in exactly one compilation unit of a component module.

+
+ +
+
+HPX_REGISTER_COMPONENT_MODULE_DYNAMIC()#
+
+ +
+
+
+namespace hpx
+
+
+namespace components
+
+ +
+ +
+
+
hpx/runtime_configuration/component_registry_base.hpp#
+

Defined in header hpx/runtime_configuration/component_registry_base.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_COMPONENT_REGISTRY(RegistryType, componentname)#
+

This macro is used to register the given component factory with Hpx.Plugin. This macro has to be used for each of the components.

+
+ +
+
+HPX_REGISTER_COMPONENT_REGISTRY_DYNAMIC(RegistryType, componentname)#
+
+ +
+
+HPX_REGISTER_REGISTRY_MODULE()#
+

This macro is used to define the required Hpx.Plugin entry points. This macro has to be used in exactly one compilation unit of a component module.

+
+ +
+
+HPX_REGISTER_REGISTRY_MODULE_DYNAMIC()#
+
+ +
+
+
+namespace hpx
+
+
+namespace components
+
+
+struct component_registry_base#
+
+#include <component_registry_base.hpp>
+

The component_registry_base has to be used as a base class for all component registries.

+
+

Public Functions

+
+
+virtual ~component_registry_base() = default#
+
+ +
+
+virtual bool get_component_info(std::vector<std::string> &fillini, std::string const &filepath, bool is_static = false) = 0#
+

Return the ini-information for all contained components.

+
+
Parameters
+
    +
  • fillini – [in, out] The module is expected to fill this vector with the ini-information (one line per vector element) for all components implemented in this module.

  • +
  • filepath – [in]

  • +
  • is_static – [in]

  • +
+
+
Returns
+

Returns true if the parameter fillini has been successfully initialized with the registry data of all implemented in this module.

+
+
+
+ +
+
+virtual void register_component_type() = 0#
+

Register the component type represented by this component.

+
+ +
+
+ +
+ +
+ +
+
+
hpx/runtime_configuration/plugin_registry_base.hpp#
+

Defined in header hpx/runtime_configuration/plugin_registry_base.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_PLUGIN_BASE_REGISTRY(PluginType, name)#
+

This macro is used to register the given component factory with Hpx.Plugin. This macro has to be used for each of the components.

+
+ +
+
+HPX_REGISTER_PLUGIN_REGISTRY_MODULE()#
+

This macro is used to define the required Hpx.Plugin entry points. This macro has to be used in exactly one compilation unit of a component module.

+
+ +
+
+HPX_REGISTER_PLUGIN_REGISTRY_MODULE_DYNAMIC()#
+
+ +
+
+
+namespace hpx
+
+
+namespace plugins#
+
+
+struct plugin_registry_base#
+
+#include <plugin_registry_base.hpp>
+

The plugin_registry_base has to be used as a base class for all plugin registries.

+
+

Public Functions

+
+
+virtual ~plugin_registry_base() = default#
+
+ +
+
+virtual bool get_plugin_info(std::vector<std::string> &fillini) = 0#
+

Return the configuration information for any plugin implemented by this module

+
+
Parameters
+

fillini – [in, out] The module is expected to fill this vector with the ini-information (one line per vector element) for all plugins implemented in this module.

+
+
Returns
+

Returns true if the parameter fillini has been successfully initialized with the registry data of all implemented in this module.

+
+
+
+ +
+
+inline virtual void init(int*, char***, util::runtime_configuration&)#
+
+ +
+
+ +
+ +
+ +
+
+
hpx::runtime_mode#
+

Defined in header hpx/init.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Enums

+
+
+enum class runtime_mode#
+

A HPX runtime can be executed in two different modes: console mode and worker mode.

+

Values:

+
+
+enumerator invalid#
+
+ +
+
+enumerator console#
+

The runtime is the console locality.

+
+ +
+
+enumerator worker#
+

The runtime is a worker locality.

+
+ +
+
+enumerator connect#
+

The runtime is a worker locality connecting late

+
+ +
+
+enumerator local#
+

The runtime is fully local.

+
+ +
+
+enumerator default_#
+

The runtime mode will be determined based on the command line arguments

+
+ +
+
+enumerator last#
+
+ +
+ +
+
+

Functions

+
+
+char const *get_runtime_mode_name(runtime_mode state) noexcept#
+

Get the readable string representing the name of the given runtime_mode constant.

+
+ +
+
+runtime_mode get_runtime_mode_from_name(std::string const &mode)#
+

Returns the internal representation (runtime_mode constant) from the readable string representing the name.

+

This represents the internal representation from the readable string representing the name.

+
+
Parameters
+

mode – this represents the runtime mode

+
+
+
+ +
+
+ +
+
+
+
+
runtime_local#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/runtime_local/component_startup_shutdown_base.hpp#
+

Defined in header hpx/runtime_local/component_startup_shutdown_base.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_STARTUP_SHUTDOWN_REGISTRY(RegistryType, componentname)#
+

This macro is used to register the given component factory with Hpx.Plugin. This macro has to be used for each of the components.

+
+ +
+
+HPX_REGISTER_STARTUP_SHUTDOWN_REGISTRY_DYNAMIC(RegistryType, componentname)#
+
+ +
+
+HPX_REGISTER_STARTUP_SHUTDOWN_FUNCTIONS()#
+

This macro is used to define the required Hpx.Plugin entry point for the startup/shutdown registry. This macro has to be used in not more than one compilation unit of a component module.

+
+ +
+
+HPX_REGISTER_STARTUP_SHUTDOWN_FUNCTIONS_DYNAMIC()#
+
+ +
+
+
+namespace hpx
+
+
+namespace components
+
+
+struct component_startup_shutdown_base#
+
+#include <component_startup_shutdown_base.hpp>
+

The component_startup_shutdown_base has to be used as a base class for all component startup/shutdown registries.

+
+

Public Functions

+
+
+virtual ~component_startup_shutdown_base() = default#
+
+ +
+
+virtual bool get_startup_function(startup_function_type &startup, bool &pre_startup) = 0#
+

Return any startup function for this component.

+
+
Parameters
+
    +
  • startup – [in, out] The module is expected to fill this function object with a reference to a startup function. This function will be executed by the runtime system during system startup.

  • +
  • pre_startup – [in, out] Will be set to true if the returned startup function is executed during the first round of calls.

  • +
+
+
Returns
+

Returns true if the parameter startup has been successfully initialized with the startup function.

+
+
+
+ +
+
+virtual bool get_shutdown_function(shutdown_function_type &shutdown, bool &pre_shutdown) = 0#
+

Return any startup function for this component.

+
+
Parameters
+
    +
  • shutdown – [in, out] The module is expected to fill this function object with a reference to a startup function. This function will be executed by the runtime system during system startup.

  • +
  • pre_shutdown – [in, out] Will be set to true if the returned shutdown function is executed during the first round of calls.

  • +
+
+
Returns
+

Returns true if the parameter shutdown has been successfully initialized with the shutdown function.

+
+
+
+ +
+
+ +
+ +
+ +
+
+
hpx/runtime_local/custom_exception_info.hpp#
+

Defined in header hpx/runtime_local/custom_exception_info.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+std::string diagnostic_information(exception_info const &xi)#
+

Extract the diagnostic information embedded in the given exception and return a string holding a formatted message.

+

The function hpx::diagnostic_information can be used to extract all diagnostic information stored in the given exception instance as a formatted string. This simplifies debug output as it composes the diagnostics into one, easy to use function call. This includes the name of the source file and line number, the sequence number of the OS-thread and the HPX-thread id, the locality id and the stack backtrace of the point where the original exception was thrown.

+

+

See also

+

hpx::get_error_locality_id(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for all diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

std::bad_alloc – (if any of the required allocation operations fail)

+
+
Returns
+

The formatted string holding all the available diagnostic information stored in the given exception instance.

+
+
+
+ +
+
+std::uint32_t get_error_locality_id(hpx::exception_info const &xi) noexcept#
+

Return the locality id where the exception was thrown.

+

The function hpx::get_error_locality_id can be used to extract the diagnostic information element representing the locality id as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

nothing

+
+
Returns
+

The locality id of the locality where the exception was thrown. If the exception instance does not hold this information, the function will return hpx::naming::invalid_locality_id.

+
+
+
+ +
+
+std::string get_error_host_name(hpx::exception_info const &xi)#
+

Return the hostname of the locality where the exception was thrown.

+

The function hpx::get_error_host_name can be used to extract the diagnostic information element representing the host name as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information() hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error() hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

std::bad_alloc – (if one of the required allocations fails)

+
+
Returns
+

The hostname of the locality where the exception was thrown. If the exception instance does not hold this information, the function will return and empty string.

+
+
+
+ +
+
+std::int64_t get_error_process_id(hpx::exception_info const &xi) noexcept#
+

Return the (operating system) process id of the locality where the exception was thrown.

+

The function hpx::get_error_process_id can be used to extract the diagnostic information element representing the process id as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

nothing

+
+
Returns
+

The process id of the OS-process which threw the exception If the exception instance does not hold this information, the function will return 0.

+
+
+
+ +
+
+std::string get_error_env(hpx::exception_info const &xi)#
+

Return the environment of the OS-process at the point the exception was thrown.

+

The function hpx::get_error_env can be used to extract the diagnostic information element representing the environment of the OS-process collected at the point the exception was thrown.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error(), hpx::get_error_backtrace(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

std::bad_alloc – (if one of the required allocations fails)

+
+
Returns
+

The environment from the point the exception was thrown. If the exception instance does not hold this information, the function will return an empty string.

+
+
+
+ +
+
+std::string get_error_backtrace(hpx::exception_info const &xi)#
+

Return the stack backtrace from the point the exception was thrown.

+

The function hpx::get_error_backtrace can be used to extract the diagnostic information element representing the stack backtrace collected at the point the exception was thrown.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

std::bad_alloc – (if one of the required allocations fails)

+
+
Returns
+

The stack back trace from the point the exception was thrown. If the exception instance does not hold this information, the function will return an empty string.

+
+
+
+ +
+
+std::size_t get_error_os_thread(hpx::exception_info const &xi) noexcept#
+

Return the sequence number of the OS-thread used to execute HPX-threads from which the exception was thrown.

+

The function hpx::get_error_os_thread can be used to extract the diagnostic information element representing the sequence number of the OS-thread as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_thread_id(), hpx::get_error_thread_description(), hpx::get_error(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

nothing

+
+
Returns
+

The sequence number of the OS-thread used to execute the HPX-thread from which the exception was thrown. If the exception instance does not hold this information, the function will return std::size(-1).

+
+
+
+ +
+
+std::size_t get_error_thread_id(hpx::exception_info const &xi) noexcept#
+

Return the unique thread id of the HPX-thread from which the exception was thrown.

+

The function hpx::get_error_thread_id can be used to extract the diagnostic information element representing the HPX-thread id as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread() hpx::get_error_thread_description(), hpx::get_error(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error_what(), hpx::get_error_config(), hpx::get_error_state()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

nothing

+
+
Returns
+

The unique thread id of the HPX-thread from which the exception was thrown. If the exception instance does not hold this information, the function will return std::size_t(0).

+
+
+
+ +
+
+std::string get_error_thread_description(hpx::exception_info const &xi)#
+

Return any additionally available thread description of the HPX-thread from which the exception was thrown.

+

The function hpx::get_error_thread_description can be used to extract the diagnostic information element representing the additional thread description as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error(), hpx::get_error_state(), hpx::get_error_what(), hpx::get_error_config()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

std::bad_alloc – (if one of the required allocations fails)

+
+
Returns
+

Any additionally available thread description of the HPX-thread from which the exception was thrown. If the exception instance does not hold this information, the function will return an empty string.

+
+
+
+ +
+
+std::string get_error_config(hpx::exception_info const &xi)#
+

Return the HPX configuration information point from which the exception was thrown.

+

The function hpx::get_error_config can be used to extract the HPX configuration information element representing the full HPX configuration information as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error(), hpx::get_error_state() hpx::get_error_what(), hpx::get_error_thread_description()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

std::bad_alloc – (if one of the required allocations fails)

+
+
Returns
+

Any additionally available HPX configuration information the point from which the exception was thrown. If the exception instance does not hold this information, the function will return an empty string.

+
+
+
+ +
+
+std::string get_error_state(hpx::exception_info const &xi)#
+

Return the HPX runtime state information at which the exception was thrown.

+

The function hpx::get_error_state can be used to extract the HPX runtime state information element representing the state the runtime system is currently in as stored in the given exception instance.

+

+

See also

+

hpx::diagnostic_information(), hpx::get_error_host_name(), hpx::get_error_process_id(), hpx::get_error_function_name(), hpx::get_error_file_name(), hpx::get_error_line_number(), hpx::get_error_os_thread(), hpx::get_error_thread_id(), hpx::get_error_backtrace(), hpx::get_error_env(), hpx::get_error(), hpx::get_error_what(), hpx::get_error_thread_description()

+
+

+
+
Parameters
+

xi – The parameter e will be inspected for the requested diagnostic information elements which have been stored at the point where the exception was thrown. This parameter can be one of the following types: hpx::exception_info, hpx::error_code, std::exception, or std::exception_ptr.

+
+
Throws
+

std::bad_alloc – (if one of the required allocations fails)

+
+
Returns
+

The point runtime state at the point at which the exception was thrown. If the exception instance does not hold this information, the function will return an empty string.

+
+
+
+ +
+
+ +
+
+
hpx::get_locality_id#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+std::uint32_t get_locality_id(error_code &ec = throws)#
+

Return the number of the locality this function is being called from.

+

This function returns the id of the current locality.

+
+

Note

+

The returned value is zero based and its maximum value is smaller than the overall number of localities the current application is running on (as returned by get_num_localities()).

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise, it throws an instance of hpx::exception.

+
+
+

Note

+

This function needs to be executed on a HPX-thread. It will fail otherwise (it will return -1).

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
+
+ +
+
+ +
+
+
hpx::get_locality_name#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+std::string get_locality_name()#
+

Return the name of the locality this function is called on.

+

This function returns the name for the locality on which this function is called.

+

+

See also

+

future<std::string> get_locality_name(hpx::id_type const& id)

+
+

+
+
Returns
+

This function returns the name for the locality on which the function is called. The name is retrieved from the underlying networking layer and may be different for different parcelports.

+
+
+
+ +
+
+ +
+
+
hpx::get_initial_num_localities, hpx::get_num_localities#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+std::uint32_t get_initial_num_localities()#
+

Return the number of localities which were registered at startup for the running application.

+

The function get_initial_num_localities returns the number of localities which were connected to the console at application startup.

+

+

See also

+

hpx::find_all_localities, hpx::get_num_localities

+
+

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise, it throws an instance of hpx::exception.

+
+
+ +
+
+hpx::future<std::uint32_t> get_num_localities()#
+

Asynchronously return the number of localities which are currently registered for the running application.

+

The function get_num_localities asynchronously returns the number of localities currently connected to the console. The returned future represents the actual result.

+

+

See also

+

hpx::find_all_localities, hpx::get_num_localities

+
+

+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return 0 otherwise.

+
+
+ +
+
+std::uint32_t get_num_localities(launch::sync_policy, error_code &ec = throws)#
+

Return the number of localities which are currently registered for the running application.

+

The function get_num_localities returns the number of localities currently connected to the console.

+

+

See also

+

hpx::find_all_localities, hpx::get_num_localities

+
+

+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return 0 otherwise.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise, it throws an instance of hpx::exception.

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
+
+ +
+
+ +
+
+
hpx/runtime_local/get_os_thread_count.hpp#
+

Defined in header hpx/runtime_local/get_os_thread_count.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+std::size_t get_os_thread_count()#
+

Return the number of OS-threads running in the runtime instance the current HPX-thread is associated with.

+
+ +
+
+std::size_t get_os_thread_count(threads::executor const &exec)#
+

Return the number of worker OS- threads used by the given executor to execute HPX threads.

+

This function returns the number of cores used to execute HPX threads for the given executor. If the function is called while no HPX runtime system is active, it will return zero. If the executor is not valid, this function will fall back to retrieving the number of OS threads used by HPX.

+
+
Parameters
+

exec – [in] The executor to be used.

+
+
+
+ +
+
+
+namespace threads
+
+ +
+ +
+
+
hpx::get_thread_name#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+std::string get_thread_name()#
+

Return the name of the calling thread.

+

This function returns the name of the calling thread. This name uniquely identifies the thread in the context of HPX. If the function is called while no HPX runtime system is active, the result will be “<unknown>”.

+
+ +
+
+ +
+
+
hpx/runtime_local/get_worker_thread_num.hpp#
+

Defined in header hpx/runtime_local/get_worker_thread_num.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/runtime_local/report_error.hpp#
+

Defined in header hpx/runtime_local/report_error.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+void report_error(std::size_t num_thread, std::exception_ptr const &e)#
+

The function report_error reports the given exception to the console.

+
+ +
+
+void report_error(std::exception_ptr const &e)#
+

The function report_error reports the given exception to the console.

+
+ +
+
+ +
+
+
hpx/runtime_local/runtime_local.hpp#
+

Defined in header hpx/runtime_local/runtime_local.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+void set_error_handlers(hpx::util::runtime_configuration const &cfg)#
+
+ +
+
+
+class runtime#
+
+

Public Types

+
+
+using notification_policy_type = threads::policies::callback_notifier#
+

Generate a new notification policy instance for the given thread name prefix

+
+ +
+
+using hpx_main_function_type = int()#
+

The hpx_main_function_type is the default function type usable as the main HPX thread function.

+
+ +
+
+using hpx_errorsink_function_type = void(std::uint32_t, std::string const&)#
+
+ +
+
+

Public Functions

+
+
+virtual notification_policy_type get_notification_policy(char const *prefix, runtime_local::os_thread_type type)#
+
+ +
+
+state get_state() const#
+
+ +
+
+void set_state(state s)#
+
+ +
+
+explicit runtime(hpx::util::runtime_configuration rtcfg, bool initialize)#
+

Construct a new HPX runtime instance.

+
+ +
+
+virtual ~runtime()#
+

The destructor makes sure all HPX runtime services are properly shut down before exiting.

+
+ +
+
+void on_exit(hpx::function<void()> const &f)#
+

Manage list of functions to call on exit.

+
+ +
+
+void starting()#
+

Manage runtime ‘stopped’ state.

+
+ +
+
+void stopping()#
+

Call all registered on_exit functions.

+
+ +
+
+bool stopped() const#
+

This accessor returns whether the runtime instance has been stopped.

+
+ +
+
+hpx::util::runtime_configuration &get_config()#
+

access configuration information

+
+ +
+
+hpx::util::runtime_configuration const &get_config() const#
+
+ +
+
+std::size_t get_instance_number() const#
+
+ +
+
+util::thread_mapper &get_thread_mapper() const#
+

Return a reference to the internal PAPI thread manager.

+
+ +
+
+threads::topology const &get_topology() const#
+
+ +
+
+virtual int run(hpx::function<hpx_main_function_type> const &func)#
+

Run the HPX runtime system, use the given function for the main thread and block waiting for all threads to finish.

+
+

Note

+

The parameter func is optional. If no function is supplied, the runtime system will simply wait for the shutdown action without explicitly executing any main thread.

+
+
+
Parameters
+

func – [in] This is the main function of an HPX application. It will be scheduled for execution by the thread manager as soon as the runtime has been initialized. This function is expected to expose an interface as defined by the typedef hpx_main_function_type. This parameter is optional and defaults to none main thread function, in which case all threads have to be scheduled explicitly.

+
+
Returns
+

This function will return the value as returned as the result of the invocation of the function object given by the parameter func.

+
+
+
+ +
+
+virtual int run()#
+

Run the HPX runtime system, initially use the given number of (OS) threads in the thread-manager and block waiting for all threads to finish.

+
+
Returns
+

This function will always return 0 (zero).

+
+
+
+ +
+
+virtual void rethrow_exception()#
+

Rethrow any stored exception (to be called after stop())

+
+ +
+
+virtual int start(hpx::function<hpx_main_function_type> const &func, bool blocking = false)#
+

Start the runtime system.

+
+
Parameters
+
    +
  • func – [in] This is the main function of an HPX application. It will be scheduled for execution by the thread manager as soon as the runtime has been initialized. This function is expected to expose an interface as defined by the typedef hpx_main_function_type.

  • +
  • blocking – [in] This allows to control whether this call blocks until the runtime system has been stopped. If this parameter is true the function runtime::start will call runtime::wait internally.

  • +
+
+
Returns
+

If a blocking is a true, this function will return the value as returned as the result of the invocation of the function object given by the parameter func. Otherwise, it will return zero.

+
+
+
+ +
+
+virtual int start(bool blocking = false)#
+

Start the runtime system.

+
+
Parameters
+

blocking – [in] This allows to control whether this call blocks until the runtime system has been stopped. If this parameter is true the function runtime::start will call runtime::wait internally .

+
+
Returns
+

If a blocking is a true, this function will return the value as returned as the result of the invocation of the function object given by the parameter func. Otherwise, it will return zero.

+
+
+
+ +
+
+virtual int wait()#
+

Wait for the shutdown action to be executed.

+
+
Returns
+

This function will return the value as returned as the result of the invocation of the function object given by the parameter func.

+
+
+
+ +
+
+virtual void stop(bool blocking = true)#
+

Initiate termination of the runtime system.

+
+
Parameters
+

blocking – [in] This allows to control whether this call blocks until the runtime system has been fully stopped. If this parameter is false then this call will initiate the stop action but will return immediately. Use a second call to stop with this parameter set to true to wait for all internal work to be completed.

+
+
+
+ +
+
+virtual int suspend()#
+

Suspend the runtime system.

+
+ +
+
+virtual int resume()#
+

Resume the runtime system.

+
+ +
+
+virtual int finalize(double)#
+
+ +
+
+virtual bool is_networking_enabled()#
+

Return true if networking is enabled.

+
+ +
+
+virtual hpx::threads::threadmanager &get_thread_manager()#
+

Allow access to the thread manager instance used by the HPX runtime.

+
+ +
+
+virtual std::string here() const#
+

Returns a string of the locality endpoints (usable in debug output)

+
+ +
+
+virtual bool report_error(std::size_t num_thread, std::exception_ptr const &e, bool terminate_all = true)#
+

Report a non-recoverable error to the runtime system.

+
+
Parameters
+
    +
  • num_thread – [in] The number of the operating system thread the error has been detected in.

  • +
  • e – [in] This is an instance encapsulating an exception which lead to this function call.

  • +
  • terminate_all – [in] signal whether all localities should be terminated

  • +
+
+
+
+ +
+
+virtual bool report_error(std::exception_ptr const &e, bool terminate_all = true)#
+

Report a non-recoverable error to the runtime system.

+
+

Note

+

This function will retrieve the number of the current shepherd thread and forward to the report_error function above.

+
+
+
Parameters
+
    +
  • e – [in] This is an instance encapsulating an exception which lead to this function call.

  • +
  • terminate_all – [in] signal whether all localities should be terminated

  • +
+
+
+
+ +
+
+virtual void add_pre_startup_function(startup_function_type f)#
+

Add a function to be executed inside a HPX thread before hpx_main but guaranteed to be executed before any startup function registered with add_startup_function.

+
+

Note

+

The difference to a startup function is that all pre-startup functions will be (system-wide) executed before any startup function.

+
+
+
Parameters
+

f – The function ‘f’ will be called from inside a HPX thread before hpx_main is executed. This is very useful to set up the runtime environment of the application (install performance counters, etc.)

+
+
+
+ +
+
+virtual void add_startup_function(startup_function_type f)#
+

Add a function to be executed inside a HPX thread before hpx_main

+
+
Parameters
+

f – The function ‘f’ will be called from inside a HPX thread before hpx_main is executed. This is very useful to set up the runtime environment of the application (install performance counters, etc.)

+
+
+
+ +
+
+virtual void add_pre_shutdown_function(shutdown_function_type f)#
+

Add a function to be executed inside a HPX thread during hpx::finalize, but guaranteed before any of the shutdown functions is executed.

+
+

Note

+

The difference to a shutdown function is that all pre-shutdown functions will be (system-wide) executed before any shutdown function.

+
+
+
Parameters
+

f – The function ‘f’ will be called from inside a HPX thread while hpx::finalize is executed. This is very useful to tear down the runtime environment of the application (uninstall performance counters, etc.)

+
+
+
+ +
+
+virtual void add_shutdown_function(shutdown_function_type f)#
+

Add a function to be executed inside a HPX thread during hpx::finalize

+
+
Parameters
+

f – The function ‘f’ will be called from inside a HPX thread while hpx::finalize is executed. This is very useful to tear down the runtime environment of the application (uninstall performance counters, etc.)

+
+
+
+ +
+
+virtual hpx::util::io_service_pool *get_thread_pool(char const *name)#
+

Access one of the internal thread pools (io_service instances) HPX is using to perform specific tasks. The three possible values for the argument name are “main_pool”, “io_pool”, “parcel_pool”, and “timer_pool”. For any other argument value the function will return zero.

+
+ +
+
+virtual bool register_thread(char const *name, std::size_t num = 0, bool service_thread = true, error_code &ec = throws)#
+

Register an external OS-thread with HPX.

+

This function should be called from any OS-thread which is external to HPX (not created by HPX), but which needs to access HPX functionality, such as setting a value on a promise or similar.

+

+‘main’, ‘io’, ‘timer’, ‘parcel’, ‘worker’

+
+

Note

+

The function will compose a thread name of the form ‘<name>-thread#<num>’ which is used to register the thread. It is the user’s responsibility to ensure that each (composed) thread name is unique. HPX internally uses the following names for the threads it creates, do not reuse those:

+
+
+

Note

+

This function should be called for each thread exactly once. It will fail if it is called more than once.

+
+
+
Parameters
+
    +
  • name – [in] The name to use for thread registration.

  • +
  • num – [in] The sequence number to use for thread registration. The default for this parameter is zero.

  • +
  • service_thread – [in] The thread should be registered as a service thread. The default for this parameter is ‘true’. Any service threads will be pinned to cores not currently used by any of the HPX worker threads.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function will return whether the requested operation succeeded or not.

+
+
+
+ +
+
+virtual bool unregister_thread()#
+

Unregister an external OS-thread with HPX.

+

This function will unregister any external OS-thread from HPX.

+
+

Note

+

This function should be called for each thread exactly once. It will fail if it is called more than once. It will fail as well if the thread has not been registered before (see register_thread).

+
+
+
Returns
+

This function will return whether the requested operation succeeded or not.

+
+
+
+ +
+
+virtual runtime_local::os_thread_data get_os_thread_data(std::string const &label) const#
+

Access data for a given OS thread that was previously registered by register_thread.

+
+ +
+
+virtual bool enumerate_os_threads(hpx::function<bool(runtime_local::os_thread_data const&)> const &f) const#
+

Enumerate all OS threads that have registered with the runtime.

+
+ +
+
+notification_policy_type::on_startstop_type on_start_func() const#
+
+ +
+
+notification_policy_type::on_startstop_type on_stop_func() const#
+
+ +
+
+notification_policy_type::on_error_type on_error_func() const#
+
+ +
+
+notification_policy_type::on_startstop_type on_start_func(notification_policy_type::on_startstop_type&&)#
+
+ +
+
+notification_policy_type::on_startstop_type on_stop_func(notification_policy_type::on_startstop_type&&)#
+
+ +
+
+notification_policy_type::on_error_type on_error_func(notification_policy_type::on_error_type&&)#
+
+ +
+
+virtual std::uint32_t get_locality_id(error_code &ec) const#
+
+ +
+
+virtual std::size_t get_num_worker_threads() const#
+
+ +
+
+virtual std::uint32_t get_num_localities(hpx::launch::sync_policy, error_code &ec) const#
+
+ +
+
+virtual std::uint32_t get_initial_num_localities() const#
+
+ +
+
+virtual hpx::future<std::uint32_t> get_num_localities() const#
+
+ +
+
+virtual std::string get_locality_name() const#
+
+ +
+
+virtual std::uint32_t assign_cores(std::string const&, std::uint32_t)#
+
+ +
+
+virtual std::uint32_t assign_cores()#
+
+ +
+
+inline hpx::program_options::options_description const &get_app_options() const#
+
+ +
+
+inline void set_app_options(hpx::program_options::options_description const &app_options)#
+
+ +
+
+

Public Static Functions

+
+
+static std::uint64_t get_system_uptime()#
+

Return the system uptime measure on the thread executing this call.

+
+ +
+
+

Protected Types

+
+
+using on_exit_type = std::vector<hpx::function<void()>>#
+
+ +
+
+

Protected Functions

+
+
+explicit runtime(hpx::util::runtime_configuration rtcfg)#
+
+ +
+
+void set_notification_policies(notification_policy_type &&notifier, threads::detail::network_background_callback_type const &network_background_callback)#
+
+ +
+
+void init()#
+

Common initialization for different constructors.

+
+ +
+
+void init_global_data()#
+
+ +
+
+threads::thread_result_type run_helper(hpx::function<runtime::hpx_main_function_type> const &func, int &result, bool call_startup_functions, void (*handle_print_bind)(std::size_t) = nullptr)#
+
+ +
+
+void wait_helper(std::mutex &mtx, std::condition_variable &cond, bool &running)#
+
+ +
+
+

Protected Attributes

+
+
+on_exit_type on_exit_functions_#
+
+ +
+
+mutable std::mutex mtx_#
+
+ +
+
+hpx::util::runtime_configuration rtcfg_#
+
+ +
+
+long instance_number_#
+
+ +
+
+std::unique_ptr<util::thread_mapper> thread_support_#
+
+ +
+
+threads::topology &topology_#
+
+ +
+
+std::atomic<state> state_#
+
+ +
+
+notification_policy_type::on_startstop_type on_start_func_#
+
+ +
+
+notification_policy_type::on_startstop_type on_stop_func_#
+
+ +
+
+notification_policy_type::on_error_type on_error_func_#
+
+ +
+
+int result_#
+
+ +
+
+std::exception_ptr exception_#
+
+ +
+
+notification_policy_type main_pool_notifier_#
+
+ +
+
+std::unique_ptr<util::io_service_pool> main_pool_#
+
+ +
+
+notification_policy_type notifier_#
+
+ +
+
+std::unique_ptr<hpx::threads::threadmanager> thread_manager_#
+
+ +
+
+

Protected Static Functions

+
+
+static void deinit_global_data()#
+
+ +
+
+

Protected Static Attributes

+
+
+static std::atomic<int> instance_number_counter_#
+
+ +
+
+

Private Functions

+
+
+void stop_helper(bool blocking, std::condition_variable &cond, std::mutex &mtx) const#
+

Helper function to stop the runtime.

+
+
Parameters
+
    +
  • blocking – [in] This allows to control whether this call blocks until the runtime system has been fully stopped. If this parameter is false then this call will initiate the stop action but will return immediately. Use a second call to stop with this parameter set to true to wait for all internal work to be completed.

  • +
  • cond

  • +
  • mtx

  • +
+
+
+
+ +
+
+void deinit_tss_helper(char const *context, std::size_t num) const#
+
+ +
+
+void init_tss_ex(char const *context, runtime_local::os_thread_type type, std::size_t local_thread_num, std::size_t global_thread_num, char const *pool_name, char const *postfix, bool service_thread, error_code &ec) const#
+
+ +
+
+void init_tss_helper(char const *context, runtime_local::os_thread_type type, std::size_t local_thread_num, std::size_t global_thread_num, char const *pool_name, char const *postfix, bool service_thread) const#
+
+ +
+
+void notify_finalize()#
+
+ +
+
+void wait_finalize()#
+
+ +
+
+void call_startup_functions(bool pre_startup)#
+
+ +
+
+

Private Members

+
+
+std::list<startup_function_type> pre_startup_functions_#
+
+ +
+
+std::list<startup_function_type> startup_functions_#
+
+ +
+
+std::list<shutdown_function_type> pre_shutdown_functions_#
+
+ +
+
+std::list<shutdown_function_type> shutdown_functions_#
+
+ +
+
+bool stop_called_#
+
+ +
+
+bool stop_done_#
+
+ +
+
+std::condition_variable wait_condition_#
+
+ +
+
+hpx::program_options::options_description app_options_#
+
+ +
+
+ +
+
+namespace threads
+
+

Functions

+
+
+char const *get_stack_size_name(std::ptrdiff_t size)#
+

Returns the stack size name.

+

Get the readable string representing the given stack size constant.

+
+
Parameters
+

size – this represents the stack size

+
+
+
+ +
+
+std::ptrdiff_t get_default_stack_size()#
+

Returns the default stack size.

+

Get the default stack size in bytes.

+
+ +
+
+std::ptrdiff_t get_stack_size(thread_stacksize)#
+

Returns the stack size corresponding to the given stack size enumeration.

+

Get the stack size corresponding to the given stack size enumeration.

+
+
Parameters
+

size – this represents the stack size

+
+
+
+ +
+
+ +
+
+namespace util
+
+

Functions

+
+
+bool retrieve_commandline_arguments(hpx::program_options::options_description const &app_options, hpx::program_options::variables_map &vm)#
+
+ +
+
+bool retrieve_commandline_arguments(std::string const &appname, hpx::program_options::variables_map &vm)#
+
+ +
+
+ +
+ +
+
+
hpx::register_thread, hpx::unregister_thread, hpx::get_os_thread_data, hpx::enumerate_os_threads, hpx::get_runtime_instance_number, hpx::register_on_exit, hpx::is_starting, hpx::tolerate_node_faults, hpx::is_running, hpx::is_stopped, hpx::is_stopped_or_shutting_down, hpx::get_num_worker_threads, hpx::get_system_uptime#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+bool register_thread(runtime *rt, char const *name, error_code &ec = throws)#
+

Register the current kernel thread with HPX, this should be done once for each external OS-thread intended to invoke HPX functionality. Calling this function more than once will return false.

+
+ +
+
+void unregister_thread(runtime *rt)#
+

Unregister the thread from HPX, this should be done once in the end before the external thread exists.

+
+ +
+
+runtime_local::os_thread_data get_os_thread_data(std::string const &label)#
+

Access data for a given OS thread that was previously registered by register_thread. This function must be called from a thread that was previously registered with the runtime.

+
+ +
+
+bool enumerate_os_threads(hpx::function<bool(os_thread_data const&)> const &f)#
+

Enumerate all OS threads that have registered with the runtime.

+
+ +
+
+std::size_t get_runtime_instance_number()#
+

Return the runtime instance number associated with the runtime instance the current thread is running in.

+
+ +
+
+bool register_on_exit(hpx::function<void()> const&)#
+

Register a function to be called during system shutdown.

+
+ +
+
+bool is_starting()#
+

Test whether the runtime system is currently being started.

+

This function returns whether the runtime system is currently being started or not, e.g. whether the current state of the runtime system is hpx::state::startup

+
+

Note

+

This function needs to be executed on a HPX-thread. It will return false otherwise.

+
+
+ +
+
+bool tolerate_node_faults()#
+

Test if HPX runs in fault-tolerant mode.

+

This function returns whether the runtime system is running in fault-tolerant mode

+
+ +
+
+bool is_running()#
+

Test whether the runtime system is currently running.

+

This function returns whether the runtime system is currently running or not, e.g. whether the current state of the runtime system is hpx::state::running

+
+

Note

+

This function needs to be executed on a HPX-thread. It will return false otherwise.

+
+
+ +
+
+bool is_stopped()#
+

Test whether the runtime system is currently stopped.

+

This function returns whether the runtime system is currently stopped or not, e.g. whether the current state of the runtime system is hpx::state::stopped

+
+

Note

+

This function needs to be executed on a HPX-thread. It will return false otherwise.

+
+
+ +
+
+bool is_stopped_or_shutting_down()#
+

Test whether the runtime system is currently being shut down.

+

This function returns whether the runtime system is currently being shut down or not, e.g. whether the current state of the runtime system is hpx::state::stopped or hpx::state::shutdown

+
+

Note

+

This function needs to be executed on a HPX-thread. It will return false otherwise.

+
+
+ +
+
+std::size_t get_num_worker_threads()#
+

Return the number of worker OS- threads used to execute HPX threads.

+

This function returns the number of OS-threads used to execute HPX threads. If the function is called while no HPX runtime system is active, it will return zero.

+
+ +
+
+std::uint64_t get_system_uptime()#
+

Return the system uptime measure on the thread executing this call.

+

This function returns the system uptime measured in nanoseconds for the thread executing this call. If the function is called while no HPX runtime system is active, it will return zero.

+
+ +
+
+
+namespace threads
+
+ +
+ +
+
+
hpx/runtime_local/service_executors.hpp#
+

Defined in header hpx/runtime_local/service_executors.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Enums

+
+
+enum class service_executor_type : std::uint8_t#
+

Values:

+
+
+enumerator io_thread_pool#
+

Selects creating a service executor using the I/O pool of threads

+
+ +
+
+enumerator parcel_thread_pool#
+

Selects creating a service executor using the parcel pool of threads

+
+ +
+
+enumerator timer_thread_pool#
+

Selects creating a service executor using the timer pool of threads

+
+ +
+
+enumerator main_thread#
+

Selects creating a service executor using the main thread

+
+ +
+ +
+
+
+struct io_pool_executor : public service_executor#
+
+

Public Functions

+
+
+io_pool_executor()#
+
+ +
+
+ +
+
+struct main_pool_executor : public service_executor#
+
+

Public Functions

+
+
+main_pool_executor()#
+
+ +
+
+ +
+
+struct parcel_pool_executor : public service_executor#
+
+

Public Functions

+
+
+explicit parcel_pool_executor(char const *name_suffix = "-tcp")#
+
+ +
+
+ +
+
+struct service_executor : public service_executor#
+
+

Public Functions

+
+
+explicit service_executor(service_executor_type t, char const *name_suffix = "")#
+
+ +
+
+ +
+
+struct timer_pool_executor : public service_executor#
+
+

Public Functions

+
+
+timer_pool_executor()#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx::shutdown_function_type, hpx::register_pre_shutdown_function, hpx::register_shutdown_function#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Typedefs

+
+
+using shutdown_function_type = hpx::move_only_function<void()>#
+

The type of the function which is registered to be executed as a shutdown or pre-shutdown function.

+
+ +
+
+

Functions

+
+
+void register_pre_shutdown_function(shutdown_function_type f)#
+

Add a function to be executed by a HPX thread during hpx::finalize() but guaranteed before any shutdown function is executed (system-wide)

+

Any of the functions registered with register_pre_shutdown_function are guaranteed to be executed by an HPX thread during the execution of hpx::finalize() before any of the registered shutdown functions are executed (see: hpx::register_shutdown_function()).

+

+

+
+

Note

+

If this function is called while the pre-shutdown functions are being executed, or after that point, it will raise an invalid_status exception.

+
+
+
Parameters
+

f – [in] The function to be registered to run by an HPX thread as a pre-shutdown function.

+
+
+
+ +
+
+void register_shutdown_function(shutdown_function_type f)#
+

Add a function to be executed by a HPX thread during hpx::finalize() but guaranteed after any pre-shutdown function is executed (system-wide)

+

Any of the functions registered with register_shutdown_function are guaranteed to be executed by an HPX thread during the execution of hpx::finalize() after any of the registered pre-shutdown functions are executed (see: hpx::register_pre_shutdown_function()).

+

+

+
+

Note

+

If this function is called while the shutdown functions are being executed, or after that point, it will raise an invalid_status exception.

+
+
+
Parameters
+

f – [in] The function to be registered to run by an HPX thread as a shutdown function.

+
+
+
+ +
+
+ +
+
+
hpx::startup_function_type, hpx::register_pre_startup_function, hpx::register_startup_function#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Typedefs

+
+
+using startup_function_type = hpx::move_only_function<void()>#
+

The type of the function which is registered to be executed as a startup or pre-startup function.

+
+ +
+
+

Functions

+
+
+void register_pre_startup_function(startup_function_type f)#
+

Add a function to be executed by a HPX thread before hpx_main but guaranteed before any startup function is executed (system-wide).

+

Any of the functions registered with register_pre_startup_function are guaranteed to be executed by an HPX thread before any of the registered startup functions are executed (see hpx::register_startup_function()).

+

+This function is one of the few API functions which can be called before the runtime system has been fully initialized. It will automatically stage the provided startup function to the runtime system during its initialization (if necessary).

+

+

+
+

Note

+

If this function is called while the pre-startup functions are being executed or after that point, it will raise aninvalid_status exception.

+
+
+
Parameters
+

f – [in] The function to be registered to run by an HPX thread as a pre-startup function.

+
+
+
+ +
+
+void register_startup_function(startup_function_type f)#
+

Add a function to be executed by a HPX thread before hpx_main but guaranteed after any pre-startup function is executed (system-wide).

+

Any of the functions registered with register_startup_function are guaranteed to be executed by an HPX thread after any of the registered pre-startup functions are executed (see: hpx::register_pre_startup_function()), but before hpx_main is being called.

+

+This function is one of the few API functions which can be called before the runtime system has been fully initialized. It will automatically stage the provided startup function to the runtime system during its initialization (if necessary).

+

+

+
+

Note

+

If this function is called while the startup functions are being executed or after that point, it will raise an invalid_status exception.

+
+
+
Parameters
+

f – [in] The function to be registered to run by an HPX thread as a startup function.

+
+
+
+ +
+
+ +
+
+
hpx/runtime_local/thread_hooks.hpp#
+

Defined in header hpx/runtime_local/thread_hooks.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+threads::policies::callback_notifier::on_startstop_type get_thread_on_start_func()#
+

Retrieve the currently installed start handler function. This is a function that will be called by HPX for each newly created thread that is made known to the runtime. HPX stores exactly one such function reference, thus the caller needs to make sure any newly registered start function chains into the previous one (see register_thread_on_start_func).

+
+

Note

+

This function can be called before the HPX runtime is initialized.

+
+
+
Returns
+

The currently installed error handler function.

+
+
+
+ +
+
+threads::policies::callback_notifier::on_startstop_type get_thread_on_stop_func()#
+

Retrieve the currently installed stop handler function. This is a function that will be called by HPX for each newly created thread that is made known to the runtime. HPX stores exactly one such function reference, thus the caller needs to make sure any newly registered stop function chains into the previous one (see register_thread_on_stop_func).

+
+

Note

+

This function can be called before the HPX runtime is initialized.

+
+
+
Returns
+

The currently installed error handler function.

+
+
+
+ +
+
+threads::policies::callback_notifier::on_error_type get_thread_on_error_func()#
+

Retrieve the currently installed error handler function. This is a function that will be called by HPX for each newly created thread that is made known to the runtime. HPX stores exactly one such function reference, thus the caller needs to make sure any newly registered error function chains into the previous one (see register_thread_on_error_func).

+
+

Note

+

This function can be called before the HPX runtime is initialized.

+
+
+
Returns
+

The currently installed error handler function.

+
+
+
+ +
+
+threads::policies::callback_notifier::on_startstop_type register_thread_on_start_func(threads::policies::callback_notifier::on_startstop_type &&f)#
+

Set the currently installed start handler function. This is a function that will be called by HPX for each newly created thread that is made known to the runtime. HPX stores exactly one such function reference, thus the caller needs to make sure any newly registered start function chains into the previous one (see get_thread_on_start_func).

+
+

Note

+

This function can be called before the HPX runtime is initialized.

+
+
+
Parameters
+

f – The function to install as the new start handler.

+
+
Returns
+

The previously registered function of this category. It is the user’s responsibility to call that function if the callback is invoked by HPX.

+
+
+
+ +
+
+threads::policies::callback_notifier::on_startstop_type register_thread_on_stop_func(threads::policies::callback_notifier::on_startstop_type &&f)#
+

Set the currently installed stop handler function. This is a function that will be called by HPX for each newly created thread that is made known to the runtime. HPX stores exactly one such function reference, thus the caller needs to make sure any newly registered stop function chains into the previous one (see get_thread_on_stop_func).

+
+

Note

+

This function can be called before the HPX runtime is initialized.

+
+
+
Parameters
+

f – The function to install as the new stop handler.

+
+
Returns
+

The previously registered function of this category. It is the user’s responsibility to call that function if the callback is invoked by HPX.

+
+
+
+ +
+
+threads::policies::callback_notifier::on_error_type register_thread_on_error_func(threads::policies::callback_notifier::on_error_type &&f)#
+

Set the currently installed error handler function. This is a function that will be called by HPX for each newly created thread that is made known to the runtime. HPX stores exactly one such function reference, thus the caller needs to make sure any newly registered error function chains into the previous one (see get_thread_on_error_func).

+
+

Note

+

This function can be called before the HPX runtime is initialized.

+
+
+
Parameters
+

f – The function to install as the new error handler.

+
+
Returns
+

The previously registered function of this category. It is the user’s responsibility to call that function if the callback is invoked by HPX.

+
+
+
+ +
+
+ +
+
+
hpx/runtime_local/thread_pool_helpers.hpp#
+

Defined in header hpx/runtime_local/thread_pool_helpers.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace resource#
+
+

Functions

+
+
+std::size_t get_num_thread_pools()#
+

Return the number of thread pools currently managed by the resource_partitioner

+
+ +
+
+std::size_t get_num_threads()#
+

Return the number of threads in all thread pools currently managed by the resource_partitioner

+
+ +
+
+std::size_t get_num_threads(std::string const &pool_name)#
+

Return the number of threads in the given thread pool currently managed by the resource_partitioner

+
+ +
+
+std::size_t get_num_threads(std::size_t pool_index)#
+

Return the number of threads in the given thread pool currently managed by the resource_partitioner

+
+ +
+
+std::size_t get_pool_index(std::string const &pool_name)#
+

Return the internal index of the pool given its name.

+
+ +
+
+std::string const &get_pool_name(std::size_t pool_index)#
+

Return the name of the pool given its internal index.

+
+ +
+
+threads::thread_pool_base &get_thread_pool(std::string const &pool_name)#
+

Return the name of the pool given its name.

+
+ +
+
+threads::thread_pool_base &get_thread_pool(std::size_t pool_index)#
+

Return the thread pool given its internal index.

+
+ +
+
+bool pool_exists(std::string const &pool_name)#
+

Return true if the pool with the given name exists.

+
+ +
+
+bool pool_exists(std::size_t pool_index)#
+

Return true if the pool with the given index exists.

+
+ +
+
+ +
+
+namespace threads
+
+

Functions

+
+
+std::int64_t get_thread_count(thread_schedule_state state = thread_schedule_state::unknown)#
+

The function get_thread_count returns the number of currently known threads.

+
+

Note

+

If state == unknown this function will not only return the number of currently existing threads, but will add the number of registered task descriptions (which have not been converted into threads yet).

+
+
+
Parameters
+

state – [in] This specifies the thread-state for which the number of threads should be retrieved.

+
+
+
+ +
+
+std::int64_t get_thread_count(thread_priority priority, thread_schedule_state state = thread_schedule_state::unknown)#
+

The function get_thread_count returns the number of currently known threads.

+
+

Note

+

If state == unknown this function will not only return the number of currently existing threads, but will add the number of registered task descriptions (which have not been converted into threads yet).

+
+
+
Parameters
+
    +
  • priority – [in] This specifies the thread-priority for which the number of threads should be retrieved.

  • +
  • state – [in] This specifies the thread-state for which the number of threads should be retrieved.

  • +
+
+
+
+ +
+
+std::int64_t get_idle_core_count()#
+

The function get_idle_core_count returns the number of currently idling threads (cores).

+
+ +
+
+mask_type get_idle_core_mask()#
+

The function get_idle_core_mask returns a bit-mask representing the currently idling threads (cores).

+
+ +
+
+bool enumerate_threads(hpx::function<bool(thread_id_type)> const &f, thread_schedule_state state = thread_schedule_state::unknown)#
+

The function enumerate_threads will invoke the given function f for each thread with a matching thread state.

+
+
Parameters
+
    +
  • f – [in] The function which should be called for each matching thread. Returning ‘false’ from this function will stop the enumeration process.

  • +
  • state – [in] This specifies the thread-state for which the threads should be enumerated.

  • +
+
+
+
+ +
+
+ +
+ +
+
+
+
+
serialization#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/serialization/base_object.hpp#
+

Defined in header hpx/serialization/base_object.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<typename Derived, typename Base>
struct hpx::serialization::base_object_type<Derived, Base, std::enable_if_t<hpx::traits::is_intrusive_polymorphic_v<Derived>>>#
+
+

Public Functions

+
+
+inline explicit constexpr base_object_type(Derived &d) noexcept#
+
+ +
+
+template<typename Archive>
inline void save(Archive &ar, unsigned) const#
+
+ +
+
+template<typename Archive>
inline void load(Archive &ar, unsigned)#
+
+ +
+
+HPX_SERIALIZATION_SPLIT_MEMBER()#
+
+ +
+
+

Public Members

+
+
+Derived &d_#
+
+ +
+
+ +
+
+namespace hpx
+
+
+namespace serialization
+
+

Functions

+
+
+template<typename Base, typename Derived>
constexpr base_object_type<Derived, Base> base_object(Derived &d) noexcept#
+
+ +
+
+template<typename D, typename B>
output_archive &operator<<(output_archive &ar, base_object_type<D, B> t)#
+
+ +
+
+template<typename D, typename B>
input_archive &operator>>(input_archive &ar, base_object_type<D, B> t)#
+
+ +
+
+template<typename D, typename B>
output_archive &operator&(output_archive &ar, base_object_type<D, B> t)#
+
+ +
+
+template<typename D, typename B>
input_archive &operator&(input_archive &ar, base_object_type<D, B> t)#
+
+ +
+
+
+template<typename Derived, typename Base, typename Enable = void>
struct base_object_type#
+
+

Public Functions

+
+
+inline explicit constexpr base_object_type(Derived &d) noexcept#
+
+ +
+
+template<typename Archive>
inline void serialize(Archive &ar, unsigned)#
+
+ +
+
+

Public Members

+
+
+Derived &d_#
+
+ +
+
+ +
+
+template<typename Derived, typename Base> is_intrusive_polymorphic_v< Derived > > >
+
+

Public Functions

+
+
+inline explicit constexpr base_object_type(Derived &d) noexcept#
+
+ +
+
+template<typename Archive>
inline void save(Archive &ar, unsigned) const#
+
+ +
+
+template<typename Archive>
inline void load(Archive &ar, unsigned)#
+
+ +
+
+HPX_SERIALIZATION_SPLIT_MEMBER()#
+
+ +
+
+

Public Members

+
+
+Derived &d_#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
synchronization#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::barrier#
+

Defined in header hpx/barrier.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+template<typename OnCompletion = detail::empty_oncompletion>
class barrier#
+
+#include <barrier.hpp>
+

A barrier is a thread coordination mechanism whose lifetime consists of a sequence of barrier phases, where each phase allows at most an expected number of threads to block until the expected number of threads arrive at the barrier. [ Note: A barrier is useful for managing repeated tasks that are handled by multiple threads. - end note ] Each barrier phase consists of the following steps:

+

    +
  • The expected count is decremented by each call to arrive or arrive_and_drop.

  • +
  • When the expected count reaches zero, the phase completion step is run. For the specialization with the default value of the CompletionFunction template parameter, the completion step is run as part of the call to arrive or arrive_and_drop that caused the expected count to reach zero. For other specializations, the completion step is run on one of the threads that arrived at the barrier during the phase.

  • +
  • When the completion step finishes, the expected count is reset to what was specified by the expected argument to the constructor, possibly adjusted by calls to arrive_and_drop, and the next phase starts.

  • +
+

+

Each phase defines a phase synchronization point. Threads that arrive at the barrier during the phase can block on the phase synchronization point by calling wait, and will remain blocked until the phase completion step is run. The phase completion step that is executed at the end of each phase has the following effects:

+

    +
  • Invokes the completion function, equivalent to completion().

  • +
  • Unblocks all threads that are blocked on the phase synchronization point.

  • +
+

+

The end of the completion step strongly happens before the returns from all calls that were unblocked by the completion step. For specializations that do not have the default value of the CompletionFunction template parameter, the behavior is undefined if any of the barrier object’s member functions other than wait are called while the completion step is in progress.

+

Concurrent invocations of the member functions of barrier, other than its destructor, do not introduce data races. The member functions arrive and arrive_and_drop execute atomically.

+

CompletionFunction shall meet the Cpp17MoveConstructible (Table 28) and Cpp17Destructible (Table 32) requirements. std::is_nothrow_invocable_v<CompletionFunction&> shall be true.

+

The default value of the CompletionFunction template parameter is an unspecified type, such that, in addition to satisfying the requirements of CompletionFunction, it meets the Cpp17DefaultConstructible requirements (Table 27) and completion() has no effects.

+

barrier::arrival_token is an unspecified type, such that it meets the Cpp17MoveConstructible (Table 28), Cpp17MoveAssignable (Table 30), and Cpp17Destructible (Table 32) requirements.

+
+

Public Types

+
+
+using arrival_token = bool#
+
+ +
+
+

Public Functions

+
+
+inline explicit constexpr barrier(std::ptrdiff_t expected, OnCompletion completion = OnCompletion())#
+

Preconditions: expected >= 0 is true and expected <= max() is true.

+

Effects: Sets both the initial expected count for each barrier phase and the current expected count for the first phase to expected. Initializes completion with std::move(f). Starts the first phase. [Note: If expected is 0 this object can only be destroyed.- end note]

+

Throws: Any exception thrown by CompletionFunction’s move constructor.

+
+ +
+
+~barrier() = default#
+
+ +
+
+inline arrival_token arrive(std::ptrdiff_t update = 1)#
+

Preconditions: update > 0 is true, and update is less than or equal to the expected count for the current barrier phase.

+

Effects: Constructs an object of type arrival_token that is associated with the phase synchronization point for the current phase. Then, decrements the expected count by update.

+

Synchronization: The call to arrive strongly happens before the start of the phase completion step for the current phase.

+

+Error conditions: Any of the error conditions allowed for mutex types([thread.mutex.requirements.mutex]). [Note: This call can cause the completion step for the current phase to start.- end note]

+
+
Throws
+

system_error – when an exception is required ([thread.req.exception]).

+
+
Returns
+

: The constructed arrival_token object.

+
+
+
+ +
+
+inline void wait(arrival_token &&old_phase) const#
+

Preconditions: arrival is associated with the phase synchronization point for the current phase or the immediately preceding phase of the same barrier object.

+

Effects: Blocks at the synchronization point associated with HPX_MOVE(arrival) until the phase completion step of the synchronization point’s phase is run. [ Note: If arrival is associated with the synchronization point for a previous phase, the call returns immediately. - end note ]

+
+
Throws
+

system_error – when an exception is required ([thread.req.exception]). Error conditions: Any of the error conditions allowed for mutex types ([thread.mutex.requirements.mutex]).

+
+
+
+ +
+
+inline void arrive_and_wait()#
+

Effects: Equivalent to: wait(arrive()).

+
+ +
+
+inline void arrive_and_drop()#
+

Preconditions: The expected count for the current barrier phase is greater than zero.

+

Effects: Decrements the initial expected count for all subsequent phases by one. Then decrements the expected count for the current phase by one.

+

Synchronization: The call to arrive_and_drop strongly happens before the start of the phase completion step for the current phase.

+
+
Throws
+

system_error – when an exception is required ([thread.req.exception]).Error conditions: Any of the error conditions allowed for mutex types ([thread.mutex.requirements.mutex]). [Note: This call can cause the completion step for the current phase to start.- end note]

+
+
+
+ +
+
+

Public Static Functions

+
+
+static inline constexpr std::ptrdiff_t() max () noexcept
+
+ +
+
+

Private Types

+
+
+using mutex_type = hpx::spinlock#
+
+ +
+
+

Private Members

+
+
+hpx::intrusive_ptr<detail::barrier_data> mtx_#
+
+ +
+
+mutable hpx::lcos::local::detail::condition_variable cond_#
+
+ +
+
+std::ptrdiff_t expected_#
+
+ +
+
+std::ptrdiff_t arrived_#
+
+ +
+
+OnCompletion completion_#
+
+ +
+
+bool phase_#
+
+ +
+
+ +
+ +
+
+
hpx::binary_semaphore#
+

Defined in header hpx/semaphore.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+class binary_semaphore#
+
+#include <binary_semaphore.hpp>
+

A binary semaphore is a semaphore object that has only two states. binary_semaphore is an alias for specialization of hpx::counting_semaphore with LeastMaxValue being 1. HPX’s implementation of binary_semaphore is more efficient than the default implementation of a counting semaphore with a unit resource count (hpx::counting_semaphore).

+
+

Public Functions

+
+
+binary_semaphore(binary_semaphore const&) = delete#
+
+ +
+
+binary_semaphore &operator=(binary_semaphore const&) = delete#
+
+ +
+
+binary_semaphore(binary_semaphore&&) = delete#
+
+ +
+
+binary_semaphore &operator=(binary_semaphore&&) = delete#
+
+ +
+
+explicit binary_semaphore(std::ptrdiff_t value = 1)#
+

Constructs an object of type hpx::binary_semaphore with the internal counter initialized to value.

+
+
Parameters
+

value – The initial value of the internal semaphore lock count. Normally this value should be zero (which is the default), values greater than zero are equivalent to the same number of signals pre-set, and negative values are equivalent to the same number of waits pre-set.

+
+
+
+ +
+
+~binary_semaphore() = default#
+
+ +
+
+void release(std::ptrdiff_t update = 1)#
+

Atomically increments the internal counter by the value of update. Any thread(s) waiting for the counter to be greater than 0, such as due to being blocked in acquire, will subsequently be unblocked.

+
+

Note

+

Synchronization: Strongly happens before invocations of try_acquire that observe the result of the effects.

+
+
+
Throws
+

std::system_error

+
+
Parameters
+

update – the amount to increment the internal counter by

+
+
Pre
+

Both update >= 0 and update <= max() - counter are true, where counter is the value of the internal counter.

+
+
+
+ +
+
+bool try_acquire() noexcept#
+

Tries to atomically decrement the internal counter by 1 if it is greater than 0; no blocking occurs regardless.

+
+
Returns
+

true if it decremented the internal counter, otherwise false

+
+
+
+ +
+
+void acquire()#
+

Repeatedly performs the following steps, in order:

+

    +
  • Evaluates try_acquire. If the result is true, returns.

  • +
+

+

Blocks on *this until counter is greater than zero.

+
+
Throws
+

std::system_error

+
+
Returns
+

void.

+
+
+
+ +
+
+bool try_acquire_until(hpx::chrono::steady_time_point const &abs_time)#
+

Tries to atomically decrement the internal counter by 1 if it is greater than 0; otherwise blocks until it is greater than 0 and can successfully decrement the internal counter, or the abs_time time point has been passed.

+
+
Parameters
+

abs_time – the earliest time the function must wait until in order to fail

+
+
Throws
+

std::system_error

+
+
Returns
+

true if it decremented the internal counter, otherwise false.

+
+
+
+ +
+
+bool try_acquire_for(hpx::chrono::steady_duration const &rel_time)#
+

Tries to atomically decrement the internal counter by 1 if it is greater than 0; otherwise blocks until it is greater than 0 and can successfully decrement the internal counter, or the rel_time duration has been exceeded.

+
+
Throws
+

std::system_error

+
+
Parameters
+

rel_time – the minimum duration the function must wait for to fail

+
+
Returns
+

true if it decremented the internal counter, otherwise false

+
+
+
+ +
+
+

Public Static Functions

+
+
+static constexpr std::ptrdiff_t max() noexcept#
+

Returns The maximum value of counter. This value is greater than or equal to LeastMaxValue.

+
+
Returns
+

The internal counter’s maximum possible value, as a std::ptrdiff_t.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::condition_variable, hpx::condition_variable_any, hpx::cv_status#
+

Defined in header hpx/condition_variable.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Enums

+
+
+enum class cv_status#
+

The scoped enumeration hpx::cv_status describes whether a timed wait returned because of timeout or not. hpx::cv_status is used by the wait_for and wait_until member functions of hpx::condition_variable and hpx::condition_variable_any.

+

Values:

+
+
+enumerator no_timeout#
+

The condition variable was awakened with notify_all, notify_one, or spuriously

+
+ +
+
+enumerator timeout#
+

the condition variable was awakened by timeout expiration

+
+ +
+
+enumerator error#
+

there was an error

+
+ +
+ +
+
+
+class condition_variable#
+
+#include <condition_variable.hpp>
+

The condition_variable class is a synchronization primitive that can be used to block a thread, or multiple threads at the same time, until another thread both modifies a shared variable (the condition), and notifies the condition_variable.

+

The thread that intends to modify the shared variable has to

    +
  1. acquire a hpx::mutex (typically via std::lock_guard)

  2. +
  3. perform the modification while the lock is held

  4. +
  5. execute notify_one or notify_all on the condition_variable (the lock does not need to be held for notification)

  6. +
+

+

Even if the shared variable is atomic, it must be modified under the mutex in order to correctly publish the modification to the waiting thread. Any thread that intends to wait on condition_variable has to

    +
  1. acquire a std::unique_lock<hpx::mutex>, on the same mutex as used to protect the shared variable

  2. +
  3. either

      +
    1. check the condition, in case it was already updated and notified

    2. +
    3. execute wait, await_for, or wait_until. The wait operations atomically release the mutex and suspend the execution of the thread.

    4. +
    5. When the condition variable is notified, a timeout expires, or a spurious wakeup occurs, the thread is awakened, and the mutex is atomically reacquired. The thread should then check the condition and resume waiting if the wake up was spurious. or

    6. +
    +
      +
    1. use the predicated overload of wait, wait_for, and wait_until, which takes care of the three steps above.

    2. +
    +

  4. +
+

+

hpx::condition_variable works only with std::unique_lock<hpx::mutex>. This restriction allows for maximal efficiency on some platforms. hpx::condition_variable_any provides a condition variable that works with any BasicLockable object, such as std::shared_lock.

+

Condition variables permit concurrent invocation of the wait, wait_for, wait_until, notify_one and notify_all member functions.

+

The class hpx::condition_variable is a StandardLayoutType. It is not CopyConstructible, MoveConstructible, CopyAssignable, or MoveAssignable.

+
+

Public Functions

+
+
+inline condition_variable()#
+

Construct an object of type hpx::condition_variable.

+
+ +
+
+~condition_variable() = default#
+

Destroys the object of type hpx::condition_variable.

+

+IOW, ~condition_variable() can execute before a signaled thread returns from a wait. If this happens with condition_variable, that waiting thread will attempt to lock the destructed mutex. To fix this, there must be shared ownership of the data members between the condition_variable object and the member functions wait (wait_for, etc.).

+
+

Note

+

Preconditions: There is no thread blocked on *this. [Note: That is, all threads have been notified; they could subsequently block on the lock specified in the wait.This relaxes the usual rules, which would have required all wait calls to happen before destruction. Only the notification to unblock the wait needs to happen before destruction.The user should take care to ensure that no threads wait on *this once the destructor has been started, especially when the waiting threads are calling the wait functions in a loop or using the overloads of wait, wait_for, or wait_until that take a predicate. end note]

+
+
+ +
+
+condition_variable(condition_variable const&) = delete#
+
+ +
+
+condition_variable(condition_variable&&) = delete#
+
+ +
+
+condition_variable &operator=(condition_variable const&) = delete#
+
+ +
+
+condition_variable &operator=(condition_variable&&) = delete#
+
+ +
+
+inline void notify_one(error_code &ec = throws) const#
+

If any threads are waiting on *this, calling notify_one unblocks one of the waiting threads.

+
+
Parameters
+

ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

+
+
Returns
+

notify_one returns void.

+
+
+
+ +
+
+inline void notify_all(error_code &ec = throws) const#
+

Unblocks all threads currently waiting for *this.

+
+
Parameters
+

ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

+
+
Returns
+

notify_all returns void.

+
+
+
+ +
+
+template<typename Mutex>
inline void wait(std::unique_lock<Mutex> &lock, error_code &ec = throws)#
+

wait causes the current thread to block until the condition variable is notified or a spurious wakeup occurs, optionally looping until some predicate is satisfied (bool(pred())==true).

+

Atomically unlocks lock, blocks the current executing thread, and adds it to the list of threads waiting on *this. The thread will be unblocked when notify_all() or notify_one() is executed. It may also be unblocked spuriously. When unblocked, regardless of the reason, lock is reacquired and wait exits.

+
+

Note

+

1. Calling this function if lock.mutex() is not locked by the current thread is undefined behavior.

    +
  1. Calling this function if lock.mutex() is not the same mutex as the one used by all other threads that are currently waiting on the same condition variable is undefined behavior.

  2. +
+

+
+
+
Template Parameters
+

Mutex – Type of mutex to wait on.

+
+
Parameters
+
    +
  • lockunique_lock that must be locked by the current thread

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

wait returns void.

+
+
+
+ +
+
+template<typename Mutex, typename Predicate>
inline void wait(std::unique_lock<Mutex> &lock, Predicate pred, error_code& = throws)#
+

wait causes the current thread to block until the condition variable is notified or a spurious wakeup occurs, optionally looping until some predicate is satisfied (bool(pred())==true).

+

Equivalent to

while (!pred()) {
+    wait(lock);
+}
+
+
+

+

This overload may be used to ignore spurious awakenings while waiting for a specific condition to become true. Note that lock must be acquired before entering this method, and it is reacquired after wait(lock) exits, which means that lock can be used to guard access to pred().

+
+

Note

+

1. Calling this function if lock.mutex() is not locked by the current thread is undefined behavior.

    +
  1. Calling this function if lock.mutex() is not the same mutex as the one used by all other threads that are currently waiting on the same condition variable is undefined behavior.

  2. +
+

+
+
+
Template Parameters
+
    +
  • Mutex – Type of mutex to wait on.

  • +
  • Predicate – Type of predicate pred function.

  • +
+
+
Parameters
+
    +
  • lockunique_lock that must be locked by the current thread

  • +
  • pred – Predicate which returns false if the waiting should be continued (bool(pred())==false). The signature of the predicate function should be equivalent to the following: bool pred();

  • +
+
+
Returns
+

wait returns void.

+
+
+
+ +
+
+template<typename Mutex>
inline cv_status wait_until(std::unique_lock<Mutex> &lock, hpx::chrono::steady_time_point const &abs_time, error_code &ec = throws)#
+

wait_until causes the current thread to block until the condition variable is notified, a specific time is reached, or a spurious wakeup occurs, optionally looping until some predicate is satisfied (bool(pred())==true).

+

Atomically releases lock, blocks the current executing thread, and adds it to the list of threads waiting on *this. The thread will be unblocked when notify_all() or notify_one() is executed, or when the absolute time point abs_time is reached. It may also be unblocked spuriously. When unblocked, regardless of the reason, lock is reacquired and wait_until exits.

+
+

Note

+

1. Calling this function if lock.mutex() is not locked by the current thread is undefined behavior.

    +
  1. Calling this function if lock.mutex() is not the same mutex as the one used by all other threads that are currently waiting on the same condition variable is undefined behavior.

  2. +
+

+
+
+
Template Parameters
+

Mutex – Type of mutex to wait on.

+
+
Parameters
+
    +
  • lockunique_lock that must be locked by the current thread

  • +
  • abs_time – Represents the time when waiting should be stopped

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

cv_status wait_until returns hpx::cv_status::timeout if the absolute timeout specified by abs_time was reached and hpx::cv_status::no_timeout otherwise.

+
+
+
+ +
+
+template<typename Mutex, typename Predicate>
inline bool wait_until(std::unique_lock<Mutex> &lock, hpx::chrono::steady_time_point const &abs_time, Predicate pred, error_code &ec = throws)#
+

wait_until causes the current thread to block until the condition variable is notified, a specific time is reached, or a spurious wakeup occurs, optionally looping until some predicate is satisfied (bool(pred())==true).

+

Equivalent to

while (!pred()) {
+    if (wait_until(lock, abs_time) == hpx::cv_status::timeout) {
+        return pred();
+    }
+}
+return true;
+
+
+ This overload may be used to ignore spurious wakeups.

+
+

Note

+

1. Calling this function if lock.mutex() is not locked by the current thread is undefined behavior.

    +
  1. Calling this function if lock.mutex() is not the same mutex as the one used by all other threads that are currently waiting on the same condition variable is undefined behavior.

  2. +
+

+
+
+
Template Parameters
+
    +
  • Mutex – Type of mutex to wait on.

  • +
  • Predicate – Type of predicate pred function.

  • +
+
+
Parameters
+
    +
  • lockunique_lock that must be locked by the current thread

  • +
  • abs_time – Represents the time when waiting should be stopped

  • +
  • pred – Predicate which returns false if the waiting should be continued (bool(pred())==false). The signature of the predicate function should be equivalent to the following: bool pred();

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool wait_until returns false if the predicate pred still evaluates to false after the abs_time timeout has expired, otherwise true. If the timeout had already expired, evaluates and returns the result of pred.

+
+
+
+ +
+
+template<typename Mutex>
inline cv_status wait_for(std::unique_lock<Mutex> &lock, hpx::chrono::steady_duration const &rel_time, error_code &ec = throws)#
+

Atomically releases lock, blocks the current executing thread, and adds it to the list of threads waiting on *this. The thread will be unblocked when notify_all() or notify_one() is executed, or when the relative timeout rel_time expires. It may also be unblocked spuriously. When unblocked, regardless of the reason, lock is reacquired and wait_for() exits.

+

The standard recommends that a steady clock be used to measure the duration. This function may block for longer than rel_time due to scheduling or resource contention delays.

+
+

Note

+

1. Calling this function if lock.mutex() is not locked by the current thread is undefined behavior.

    +
  1. Calling this function if lock.mutex() is not the same mutex as the one used by all other threads that are currently waiting on the same condition variable is undefined behavior.

  2. +
  3. Even if notified under lock, this overload makes no guarantees about the state of the associated predicate when returning due to timeout.

  4. +
+

+
+
+
Template Parameters
+

Mutex – Type of mutex to wait on.

+
+
Parameters
+
    +
  • lockunique_lock that must be locked by the current thread

  • +
  • rel_time – represents the maximum time to spend waiting. Note that rel_time must be small enough not to overflow when added to hpx::chrono::steady_clock::now().

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

cv_status hpx::cv_status::timeout if the relative timeout specified by rel_time expired, hpx::cv_status::no_timeout otherwise.

+
+
+
+ +
+
+template<typename Mutex, typename Predicate>
inline bool wait_for(std::unique_lock<Mutex> &lock, hpx::chrono::steady_duration const &rel_time, Predicate pred, error_code &ec = throws)#
+

Equivalent to.

+

return wait_until(lock,
+           hpx::chrono::steady_clock::now() + rel_time,
+           hpx::move(pred));
+
+
+ This overload may be used to ignore spurious awakenings by looping until some predicate is satisfied (bool(pred())==true).

+

The standard recommends that a steady clock be used to measure the duration. This function may block for longer than rel_time due to scheduling or resource contention delays.

+
+

Note

+

1. Calling this function if lock.mutex() is not locked by the current thread is undefined behavior.

    +
  1. Calling this function if lock.mutex() is not the same mutex as the one used by all other threads that are currently waiting on the same condition variable is undefined behavior.

  2. +
+

+
+
+
Template Parameters
+
    +
  • Mutex – Type of mutex to wait on.

  • +
  • Predicate – Type of predicate pred function.

  • +
+
+
Parameters
+
    +
  • lockunique_lock that must be locked by the current thread

  • +
  • rel_time – represents the maximum time to spend waiting. Note that rel_time must be small enough not to overflow when added to hpx::chrono::steady_clock::now().

  • +
  • pred – Predicate which returns false if the waiting should be continued (bool(pred())==false). The signature of the predicate function should be equivalent to the following: bool pred();

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool wait_for returns false if the predicate pred still evaluates to false after the rel_time timeout expired, otherwise true.

+
+
+
+ +
+
+

Private Types

+
+
+using mutex_type = lcos::local::detail::condition_variable_data::mutex_type#
+
+ +
+
+using data_type = hpx::intrusive_ptr<lcos::local::detail::condition_variable_data>#
+
+ +
+
+

Private Members

+
+
+hpx::util::cache_aligned_data_derived<data_type> data_#
+
+ +
+
+ +
+
+class condition_variable_any#
+
+#include <condition_variable.hpp>
+

The condition_variable_any class is a generalization of hpx::condition_variable. Whereas hpx::condition_variable works only on std::unique_lock<std::mutex>, a condition_variable_any can operate on any lock that meets the BasicLockable requirements.

+

See hpx::condition_variable for the description of the semantics of condition variables. It is not CopyConstructible, MoveConstructible, CopyAssignable, or MoveAssignable.

+
+

Public Functions

+
+
+inline condition_variable_any()#
+

Constructs an object of type hpx::condition_variable_any.

+
+ +
+
+~condition_variable_any() = default#
+

Destroys the object of type hpx::condition_variable_any.

+

It is only safe to invoke the destructor if all threads have been notified. It is not required that they have exited their respective wait functions: some threads may still be waiting to reacquire the associated lock, or may be waiting to be scheduled to run after reacquiring it.

+

The programmer must ensure that no threads attempt to wait on *this once the destructor has been started, especially when the waiting threads are calling the wait functions in a loop or are using the overloads of the wait functions that take a predicate.

+

Preconditions: There is no thread blocked on *this. [Note: That is, all threads have been notified; they could subsequently block on the lock specified in the wait.This relaxes the usual rules, which would have required all wait calls to happen before destruction. Only the notification to unblock the wait needs to happen before destruction. The user should take care to ensure that no threads wait on *this once the destructor has been started, especially when the waiting threads are calling the wait functions in a loop or using the overloads of wait, wait_for, or wait_until that take a predicate. end note]

+

IOW, ~condition_variable_any() can execute before a signaled thread returns from a wait. If this happens with condition_variable_any, that waiting thread will attempt to lock the destructed mutex. To fix this, there must be shared ownership of the data members between the condition_variable_any object and the member functions wait (wait_for, etc.).

+
+ +
+
+condition_variable_any(condition_variable_any const&) = delete#
+
+ +
+
+condition_variable_any(condition_variable_any&&) = delete#
+
+ +
+
+condition_variable_any &operator=(condition_variable_any const&) = delete#
+
+ +
+
+condition_variable_any &operator=(condition_variable_any&&) = delete#
+
+ +
+
+inline void notify_one(error_code &ec = throws) const#
+

If any threads are waiting on *this, calling notify_one unblocks one of the waiting threads.

+

+The notifying thread does not need to hold the lock on the same mutex as the one held by the waiting thread(s); in fact doing so is a pessimization, since the notified thread would immediately block again, waiting for the notifying thread to release the lock. However, some implementations (in particular many implementations of pthreads) recognize this situation and avoid this “hurry up and wait” scenario by transferring the waiting thread from the condition variable’s queue directly to the queue of the mutex within the notify call, without waking it up.

+

Notifying while under the lock may nevertheless be necessary when precise scheduling of events is required, e.g. if the waiting thread would exit the program if the condition is satisfied, causing destruction of the notifying thread’s condition variable. A spurious wakeup after mutex unlock but before notify would result in notify called on a destroyed object.

+
+

Note

+

The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+
+
Parameters
+

ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

+
+
Returns
+

notify_one returns void.

+
+
+
+ +
+
+inline void notify_all(error_code &ec = throws) const#
+

Unblocks all threads currently waiting for *this.

+

+The notifying thread does not need to hold the lock on the same mutex as the one held by the waiting thread(s); in fact doing so is a pessimization, since the notified thread would immediately block again, waiting for the notifying thread to release the lock.

+
+

Note

+

The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+
+
Parameters
+

ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

+
+
Returns
+

notify_all returns void.

+
+
+
+ +
+
+template<typename Lock>
inline void wait(Lock &lock, error_code &ec = throws)#
+

wait causes the current thread to block until the condition variable is notified or a spurious wakeup occurs, optionally looping until some predicate is satisfied (bool(pred())==true).

+

Atomically unlocks lock, blocks the current executing thread, and adds it to the list of threads waiting on *this. The thread will be unblocked when notify_all() or notify_one() is executed. It may also be unblocked spuriously. When unblocked, regardless of the reason, lock is reacquired and wait exits.

+

+The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+

Note

+

If these functions fail to meet the postconditions (lock is locked by the calling thread), std::terminate is called. For example, this could happen if re-locking the mutex throws an exception.

+
+
+
Template Parameters
+

Lock – Type of lock.

+
+
Parameters
+
    +
  • lock – An object of type Lock that meets the BasicLockable requirements, which must be locked by the current thread

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special’throw on error’ error_code.

  • +
+
+
Returns
+

wait returns void.

+
+
+
+ +
+
+template<typename Lock, typename Predicate>
inline void wait(Lock &lock, Predicate pred, error_code& = throws)#
+

wait causes the current thread to block until the condition variable is notified or a spurious wakeup occurs, optionally looping until some predicate is satisfied (bool(pred())==true).

+

Equivalent to

while (!pred()) {
+    wait(lock);
+}
+
+
+

+

This overload may be used to ignore spurious awakenings while waiting for a specific condition to become true. Note that lock must be acquired before entering this method, and it is reacquired after wait(lock) exits, which means that lock can be used to guard access to pred().

+

+The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+

Note

+

If these functions fail to meet the postconditions (lock is locked by the calling thread), std::terminate is called. For example, this could happen if re-locking the mutex throws an exception.

+
+
+
Template Parameters
+
    +
  • Lock – Type of lock.

  • +
  • Predicate – Type of pred.

  • +
+
+
Parameters
+
    +
  • lock – an object of type Lock that meets the BasicLockable requirements, which must be locked by the current thread

  • +
  • pred – predicate which returns false if the waiting should be continued (bool(pred()) == false). The signature of the predicate function should be equivalent to the following: bool pred().

  • +
+
+
Returns
+

wait returns void.

+
+
+
+ +
+
+template<typename Lock>
inline cv_status wait_until(Lock &lock, hpx::chrono::steady_time_point const &abs_time, error_code &ec = throws)#
+

wait_until causes the current thread to block until the condition variable is notified, a specific time is reached, or a spurious wakeup occurs, optionally looping until some predicate is satisfied (bool(pred()) == true).

+

Atomically releases lock, blocks the current executing thread, and adds it to the list of threads waiting on *this. The thread will be unblocked when notify_all() or notify_one() is executed, or when the absolute time point abs_time is reached. It may also be unblocked spuriously. When unblocked, regardless of the reason, lock is reacquired and wait_until exits.

+
+

Note

+

The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+
+
Template Parameters
+

Lock – Type of lock.

+
+
Parameters
+
    +
  • lock – an object of type Lock that meets the requirements of BasicLockable, which must be locked by the current thread

  • +
  • abs_time – represents the time when waiting should be stopped.

  • +
  • ec – used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

cv_status hpx::cv_status::timeout if the absolute timeout specified by abs_time was reached, hpx::cv_status::no_timeout otherwise.

+
+
+
+ +
+
+template<typename Lock, typename Predicate>
inline bool wait_until(Lock &lock, hpx::chrono::steady_time_point const &abs_time, Predicate pred, error_code &ec = throws)#
+

wait_until causes the current thread to block until the condition variable is notified, a specific time is reached, or a spurious wakeup occurs, optionally looping until some predicate is satisfied (bool(pred()) == true).

+

Equivalent to

while (!pred()) {
+    if (wait_until(lock, timeout_time) == hpx::cv_status::timeout) {
+       return pred();
+    }
+}
+return true;
+
+
+

+

This overload may be used to ignore spurious wakeups.

+
+

Note

+

The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+
+
Template Parameters
+
    +
  • Lock – Type of lock.

  • +
  • Predicate – Type of pred.

  • +
+
+
Parameters
+
    +
  • lock – an object of type Lock that meets the requirements of BasicLockable, which must be locked by the current thread

  • +
  • abs_time – represents the time when waiting should be stopped.

  • +
  • pred – predicate which returns false if the waiting should be continued (bool(pred()) == false). The signature of the predicate function should be equivalent to the following: bool pred();.

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool false if the predicate pred still evaluates to false after the abs_time timeout expired, otherwise true. If the timeout had already expired, evaluates and returns the result of pred.

+
+
+
+ +
+
+template<typename Lock>
inline cv_status wait_for(Lock &lock, hpx::chrono::steady_duration const &rel_time, error_code &ec = throws)#
+

Atomically releases lock, blocks the current executing thread, and adds it to the list of threads waiting on *this. The thread will be unblocked when notify_all() or notify_one() is executed, or when the relative timeout rel_time expires. It may also be unblocked spuriously. When unblocked, regardless of the reason, lock is reacquired and wait_for() exits.

+

+The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+

Note

+

Even if notified under lock, this overload makes no guarantees about the state of the associated predicate when returning due to timeout.

+
+
+
Template Parameters
+

Lock – Type of lock.

+
+
Parameters
+
    +
  • lock – an object of type Lock that meets the BasicLockable requirements, which must be locked by the current thread.

  • +
  • rel_time – an object of type hpx::chrono::duration representing the maximum time to spend waiting. Note that rel_time must be small enough not to overflow when added to hpx::chrono::steady_clock::now().

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

cv_status hpx::cv_status::timeout if the relative timeout specified by rel_time expired, hpx::cv_status::no_timeout otherwise.

+
+
+
+ +
+
+template<typename Lock, typename Predicate>
inline bool wait_for(Lock &lock, hpx::chrono::steady_duration const &rel_time, Predicate pred, error_code &ec = throws)#
+

Equivalent to.

+

return wait_until(lock,
+    hpx::chrono::steady_clock::now() + rel_time,
+    std::move(pred));
+
+
+ This overload may be used to ignore spurious awakenings by looping until some predicate is satisfied (bool(pred()) == true).

+
+

Note

+

The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+
+
Template Parameters
+
    +
  • Lock – Type of lock.

  • +
  • Predicate – Type of pred.

  • +
+
+
Parameters
+
    +
  • lock – an object of type Lock that meets the BasicLockable requirements,which must be locked by the current thread.

  • +
  • rel_time – an object of type hpx::chrono::duration representing the maximum time to spend waiting. Note that rel_time must be small enough not to overflow when added to hpx::chrono::steady_clock::now().

  • +
  • pred – predicate which returns false if the waiting should be continued (bool(pred()) == false). The signature of the predicate function should be equivalent to the following: bool pred();.

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool false if the predicate pred still evaluates to false after the rel_time timeout expired, otherwise true.

+
+
+
+ +
+
+template<typename Lock, typename Predicate>
inline bool wait(Lock &lock, stop_token stoken, Predicate pred, error_code &ec = throws)#
+

wait causes the current thread to block until the condition variable is notified or a spurious wakeup occurs, optionally looping until some predicate is satisfied (bool(pred())==true).

+

An interruptible wait: registers the condition_variable_any for the duration of wait(), to be notified if a stop request is made on the given stoken’s associated stop-state; it is then equivalent to

while (!stoken.stop_requested()) {
+    if (pred()) return true;
+    wait(lock);
+}
+return pred();
+
+
+ Note that the returned value indicates whether pred evaluated to true, regardless of whether there was a stop requested or not.

+
+

Note

+

The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+
+
Template Parameters
+
    +
  • Lock – Type of lock.

  • +
  • Predicate – Type of pred.

  • +
+
+
Parameters
+
    +
  • lock – an object of type Lock that meets the BasicLockable requirements, which must be locked by the current thread

  • +
  • stoken – a hpx::stop_token to register interruption for

  • +
  • pred – predicate which returns false if the waiting should be continued (bool(pred()) == false). The signature of the predicate function should be equivalent to the following: bool pred().

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool result of pred().

+
+
+
+ +
+
+template<typename Lock, typename Predicate>
inline bool wait_until(Lock &lock, stop_token stoken, hpx::chrono::steady_time_point const &abs_time, Predicate pred, error_code &ec = throws)#
+

wait_until causes the current thread to block until the condition variable is notified, a specific time is reached, or a spurious wakeup occurs, optionally looping until some predicate is satisfied (bool(pred()) == true).

+

An interruptible wait: registers the condition_variable_any for the duration of wait_until(), to be notified if a stop request is made on the given stoken’s associated stop-state; it is then equivalent to

while (!stoken.stop_requested()) {
+    if (pred())
+        return true;
+    if (wait_until(lock, timeout_time) == hpx::cv_status::timeout)
+        return pred();
+}
+return pred();
+
+
+

+
+

Note

+

The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+
+
Template Parameters
+
    +
  • Lock – Type of lock.

  • +
  • Predicate – Type of pred.

  • +
+
+
Parameters
+
    +
  • lock – an object of type Lock that meets the requirements of BasicLockable, which must be locked by the current thread.

  • +
  • stoken – a hpx::stop_token to register interruption for.

  • +
  • abs_time – represents the time when waiting should be stopped.

  • +
  • pred – predicate which returns false if the waiting should be continued (bool(pred()) == false). The signature of the predicate function should be equivalent to the following: bool pred();.

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool pred(), regardless of whether the timeout was met or stop was requested.

+
+
+
+ +
+
+template<typename Lock, typename Predicate>
inline bool wait_for(Lock &lock, stop_token stoken, hpx::chrono::steady_duration const &rel_time, Predicate pred, error_code &ec = throws)#
+

Equivalent to.

+

return wait_until(lock, std::move(stoken),
+    hpx::chrono::steady_clock::now() + rel_time,
+    std::move(pred));
+
+
+

+
+

Note

+

The effects of notify_one()/notify_all() and each of the three atomic parts of wait()/wait_for()/wait_until() (unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition variable. This makes it impossible for notify_one() to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one() was made.

+
+
+
Template Parameters
+
    +
  • Lock – Type of lock.

  • +
  • Predicate – Type of pred.

  • +
+
+
Parameters
+
    +
  • lock – an object of type Lock that meets the BasicLockable requirements, which must be locked by the current thread.

  • +
  • stoken – a hpx::stop_token to register interruption for.

  • +
  • rel_time – an object of type hpx::chrono::duration representing the maximum time to spend waiting. Note that rel_time must be small enough not to overflow when added to hpx::chrono::steady_clock::now().

  • +
  • pred – predicate which returns false if the waiting should be continued (bool(pred()) == false). The signature of the predicate function should be equivalent to the following: bool pred();.

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool pred(), regardless of whether the timeout was met or stop was requested.

+
+
+
+ +
+
+

Private Types

+
+
+using mutex_type = lcos::local::detail::condition_variable_data::mutex_type#
+
+ +
+
+using data_type = hpx::intrusive_ptr<lcos::local::detail::condition_variable_data>#
+
+ +
+
+

Private Members

+
+
+hpx::util::cache_aligned_data_derived<data_type> data_#
+
+ +
+
+ +
+
+namespace lcos
+
+
+namespace local
+
+

Typedefs

+
+
+typedef hpx::condition_variable instead
+
+ +
+
+ +
+ +
+ +
+
+
hpx::counting_semaphore#
+

Defined in header hpx/semaphore.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+template<std::ptrdiff_t LeastMaxValue = PTRDIFF_MAX>
class counting_semaphore#
+
+#include <counting_semaphore.hpp>
+

A semaphore is a protected variable (an entity storing a value) or abstract data type (an entity grouping several variables that may or may not be numerical) which constitutes the classic method for restricting access to shared resources, such as shared memory, in a multiprogramming environment. Semaphores exist in many variants, though usually the term refers to a counting semaphore, since a binary semaphore is better known as a mutex. A counting semaphore is a counter for a set of available resources, rather than a locked/unlocked flag of a single resource. It was invented by Edsger Dijkstra. Semaphores are the classic solution to preventing race conditions in the dining philosophers problem, although they do not prevent resource deadlocks.

+

Counting semaphores can be used for synchronizing multiple threads as well: one thread waiting for several other threads to touch (signal) the semaphore, or several threads waiting for one other thread to touch this semaphore. Unlike hpx::mutex a counting_semaphore is not tied to threads of execution &#8212; acquiring a semaphore can occur on a different thread than releasing the semaphore, for example. All operations on counting_semaphore can be performed concurrently and without any relation to specific threads of execution, with the exception of the destructor which cannot be performed concurrently but can be performed on a different thread.

+

Semaphores are lightweight synchronization primitives used to constrain concurrent access to a shared resource. They are widely used to implement other synchronization primitives and, whenever both are applicable, can be more efficient than condition variables.

+

A counting semaphore is a semaphore object that models a non-negative resource count.

+

Class template counting_semaphore maintains an internal counter that is initialized when the semaphore is created. The counter is decremented when a thread acquires the semaphore, and is incremented when a thread releases the semaphore. If a thread tries to acquire the semaphore when the counter is zero, the thread will block until another thread increments the counter by releasing the semaphore.

+

Specializations of hpx::counting_semaphore are not DefaultConstructible, CopyConstructible, MoveConstructible, CopyAssignable, or MoveAssignable.

+
+

Note

+

counting_semaphore’s try_acquire() can spuriously fail.

+
+
+
Template Parameters
+

LeastMaxValuecounting_semaphore allows more than one concurrent access to the same resource, for at least LeastMaxValue concurrent accessors. As its name indicates, the LeastMaxValue is the minimum max value, not the actual max value. Thus max() can yield a number larger than LeastMaxValue.

+
+
+
+

Public Functions

+
+
+counting_semaphore(counting_semaphore const&) = delete#
+
+ +
+
+counting_semaphore &operator=(counting_semaphore const&) = delete#
+
+ +
+
+counting_semaphore(counting_semaphore&&) = delete#
+
+ +
+
+counting_semaphore &operator=(counting_semaphore&&) = delete#
+
+ +
+
+explicit counting_semaphore(std::ptrdiff_t value)#
+

Constructs an object of type hpx::counting_semaphore with the internal counter initialized to value.

+
+
Parameters
+

value – The initial value of the internal semaphore lock count. Normally this value should be zero (which is the default), values greater than zero are equivalent to the same number of signals pre-set, and negative values are equivalent to the same number of waits pre-set.

+
+
+
+ +
+
+~counting_semaphore() = default#
+
+ +
+
+void release(std::ptrdiff_t update = 1)#
+

Atomically increments the internal counter by the value of update. Any thread(s) waiting for the counter to be greater than 0, such as due to being blocked in acquire, will subsequently be unblocked.

+
+

Note

+

Synchronization: Strongly happens before invocations of try_acquire that observe the result of the effects.

+
+
+
Throws
+

std::system_error

+
+
Parameters
+

update – the amount to increment the internal counter by

+
+
Pre
+

Both update >= 0 and update <= max() - counter are true, where counter is the value of the internal counter.

+
+
+
+ +
+
+bool try_acquire() noexcept#
+

Tries to atomically decrement the internal counter by 1 if it is greater than 0; no blocking occurs regardless.

+
+
Returns
+

true if it decremented the internal counter, otherwise false

+
+
+
+ +
+
+void acquire()#
+

Repeatedly performs the following steps, in order:

+

    +
  • Evaluates try_acquire. If the result is true, returns.

  • +
  • Blocks on *this until counter is greater than zero.

  • +
+

+
+
Throws
+

std::system_error

+
+
Returns
+

void.

+
+
+
+ +
+
+bool try_acquire_until(hpx::chrono::steady_time_point const &abs_time)#
+

Tries to atomically decrement the internal counter by 1 if it is greater than 0; otherwise blocks until it is greater than 0 and can successfully decrement the internal counter, or the abs_time time point has been passed.

+
+
Parameters
+

abs_time – the earliest time the function must wait until in order to fail

+
+
Throws
+

std::system_error

+
+
Returns
+

true if it decremented the internal counter, otherwise false.

+
+
+
+ +
+
+bool try_acquire_for(hpx::chrono::steady_duration const &rel_time)#
+

Tries to atomically decrement the internal counter by 1 if it is greater than 0; otherwise blocks until it is greater than 0 and can successfully decrement the internal counter, or the rel_time duration has been exceeded.

+
+
Throws
+

std::system_error

+
+
Parameters
+

rel_time – the minimum duration the function must wait for to fail

+
+
Returns
+

true if it decremented the internal counter, otherwise false

+
+
+
+ +
+
+

Public Static Functions

+
+
+static constexpr std::ptrdiff_t max() noexcept#
+

Returns The maximum value of counter. This value is greater than or equal to LeastMaxValue.

+
+
Returns
+

The internal counter’s maximum possible value, as a std::ptrdiff_t.

+
+
+
+ +
+
+ +
+
+template<typename Mutex = hpx::spinlock, int N = 0>
class counting_semaphore_var#
+
+#include <counting_semaphore.hpp>
+

A semaphore is a protected variable (an entity storing a value) or abstract data type (an entity grouping several variables that may or may not be numerical) which constitutes the classic method for restricting access to shared resources, such as shared memory, in a multiprogramming environment. Semaphores exist in many variants, though usually the term refers to a counting semaphore, since a binary semaphore is better known as a mutex. A counting semaphore is a counter for a set of available resources, rather than a locked/unlocked flag of a single resource. It was invented by Edsger Dijkstra. Semaphores are the classic solution to preventing race conditions in the dining philosophers problem, although they do not prevent resource deadlocks.

+

Counting semaphores can be used for synchronizing multiple threads as well: one thread waiting for several other threads to touch (signal) the semaphore, or several threads waiting for one other thread to touch this semaphore. Unlike hpx::mutex a counting_semaphore_var is not tied to threads of execution &#8212; acquiring a semaphore can occur on a different thread than releasing the semaphore, for example. All operations on counting_semaphore_var can be performed concurrently and without any relation to specific threads of execution, with the exception of the destructor which cannot be performed concurrently but can be performed on a different thread.

+

Semaphores are lightweight synchronization primitives used to constrain concurrent access to a shared resource. They are widely used to implement other synchronization primitives and, whenever both are applicable, can be more efficient than condition variables.

+

A counting semaphore is a semaphore object that models a non-negative resource count.

+

Class template counting_semaphore_var maintains an internal counter that is initialized when the semaphore is created. The counter is decremented when a thread acquires the semaphore, and is incremented when a thread releases the semaphore. If a thread tries to acquire the semaphore when the counter is zero, the thread will block until another thread increments the counter by releasing the semaphore.

+

Specializations of hpx::counting_semaphore_var are not DefaultConstructible, CopyConstructible, MoveConstructible, CopyAssignable, or MoveAssignable.

+
+

Note

+

counting_semaphore_var’s try_acquire() can spuriously fail.

+
+
+
Template Parameters
+
    +
  • Mutex – Type of mutex

  • +
  • N – The initial value of the internal semaphore lock count.

  • +
+
+
+
+

Public Functions

+
+
+explicit counting_semaphore_var(std::ptrdiff_t value = N)#
+

Constructs an object of type hpx::counting_semaphore_value with the internal counter initialized to N.

+
+
Parameters
+

value – The initial value of the internal semaphore lock count. Normally this value should be zero, values greater than zero are equivalent to the same number of signals pre-set, and negative values are equivalent to the same number of waits pre-set. Defaults to N (which in turn defaults to zero).

+
+
+
+ +
+
+counting_semaphore_var(counting_semaphore_var const&) = delete#
+
+ +
+
+counting_semaphore_var &operator=(counting_semaphore_var const&) = delete#
+
+ +
+
+void wait(std::ptrdiff_t count = 1)#
+

Wait for the semaphore to be signaled.

+
+
Parameters
+

count – The value by which the internal lock count will be decremented. At the same time this is the minimum value of the lock count at which the thread is not yielded.

+
+
+
+ +
+
+bool try_wait(std::ptrdiff_t count = 1)#
+

Try to wait for the semaphore to be signaled.

+
+
Parameters
+

count – The value by which the internal lock count will be decremented. At the same time this is the minimum value of the lock count at which the thread is not yielded.

+
+
Returns
+

try_wait returns true if the calling thread was able to acquire the requested amount of credits. try_wait returns false if not sufficient credits are available at this point in time.

+
+
+
+ +
+
+void signal(std::ptrdiff_t count = 1)#
+

Signal the semaphore.

+
+
Parameters
+

count – The value by which the internal lock count will be incremented.

+
+
+
+ +
+
+std::ptrdiff_t signal_all()#
+

Unblock all acquirers.

+
+
Returns
+

std::ptrdiff_t internal lock count after the operation.

+
+
+
+ +
+
+void release(std::ptrdiff_t update = 1)#
+

Atomically increments the internal counter by the value of update. Any thread(s) waiting for the counter to be greater than 0, such as due to being blocked in acquire, will subsequently be unblocked.

+
+

Note

+

Synchronization: Strongly happens before invocations of try_acquire that observe the result of the effects.

+
+
+
Throws
+

std::system_error

+
+
Parameters
+

update – the amount to increment the internal counter by

+
+
Pre
+

Both update >= 0 and update <= max() - counter are true, where counter is the value of the internal counter.

+
+
+
+ +
+
+bool try_acquire() noexcept#
+

Tries to atomically decrement the internal counter by 1 if it is greater than 0; no blocking occurs regardless.

+
+
Returns
+

true if it decremented the internal counter, otherwise false

+
+
+
+ +
+
+void acquire()#
+

Repeatedly performs the following steps, in order:

+

    +
  • Evaluates try_acquire. If the result is true, returns.

  • +
+

+

Blocks on *this until counter is greater than zero.

+
+
Throws
+

std::system_error

+
+
Returns
+

void.

+
+
+
+ +
+
+bool try_acquire_until(hpx::chrono::steady_time_point const &abs_time)#
+

Tries to atomically decrement the internal counter by 1 if it is greater than 0; otherwise blocks until it is greater than 0 and can successfully decrement the internal counter, or the abs_time time point has been passed.

+
+
Parameters
+

abs_time – the earliest time the function must wait until in order to fail

+
+
Throws
+

std::system_error

+
+
Returns
+

true if it decremented the internal counter, otherwise false.

+
+
+
+ +
+
+bool try_acquire_for(hpx::chrono::steady_duration const &rel_time)#
+

Tries to atomically decrement the internal counter by 1 if it is greater than 0; otherwise blocks until it is greater than 0 and can successfully decrement the internal counter, or the rel_time duration has been exceeded.

+
+
Throws
+

std::system_error

+
+
Parameters
+

rel_time – the minimum duration the function must wait for to fail

+
+
Returns
+

true if it decremented the internal counter, otherwise false

+
+
+
+ +
+
+

Public Static Functions

+
+
+static constexpr std::ptrdiff_t max() noexcept#
+

Returns The maximum value of counter. This value is greater than or equal to LeastMaxValue.

+
+
Returns
+

The internal counter’s maximum possible value, as a std::ptrdiff_t.

+
+
+
+ +
+
+

Private Types

+
+
+using mutex_type = Mutex#
+
+ +
+
+ +
+ +
+
+
hpx/synchronization/event.hpp#
+

Defined in header hpx/synchronization/event.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace lcos
+
+
+namespace local
+
+
+class event#
+
+#include <event.hpp>
+

Event semaphores can be used for synchronizing multiple threads that need to wait for an event to occur. When the event occurs, all threads waiting for the event are woken up.

+
+

Public Functions

+
+
+inline event() noexcept#
+

Construct a new event semaphore.

+
+ +
+
+inline bool occurred() const noexcept#
+

Check if the event has occurred.

+
+ +
+
+inline void wait()#
+

Wait for the event to occur.

+
+ +
+
+inline void set()#
+

Release all threads waiting on this semaphore.

+
+ +
+
+inline void reset() noexcept#
+

Reset the event.

+
+ +
+
+

Private Types

+
+
+using mutex_type = hpx::spinlock#
+
+ +
+
+

Private Functions

+
+
+inline void wait_locked(std::unique_lock<mutex_type> &l)#
+
+ +
+
+inline void set_locked(std::unique_lock<mutex_type> l)#
+
+ +
+
+

Private Members

+
+
+mutex_type mtx_#
+

This mutex protects the queue.

+
+ +
+
+local::detail::condition_variable cond_#
+
+ +
+
+std::atomic<bool> event_#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx::latch#
+

Defined in header hpx/latch.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+class latch#
+
+#include <latch.hpp>
+

Latches are a thread coordination mechanism that allow one or more threads to block until an operation is completed. An individual latch is a single-use object; once the operation has been completed, the latch cannot be reused.

+

Subclassed by hpx::lcos::local::latch

+
+

Public Functions

+
+
+latch(latch const&) = delete#
+
+ +
+
+latch(latch&&) = delete#
+
+ +
+
+latch &operator=(latch const&) = delete#
+
+ +
+
+latch &operator=(latch&&) = delete#
+
+ +
+
+inline explicit latch(std::ptrdiff_t count)#
+

Initialize the latch

+

Requires: count >= 0. Synchronization: None Postconditions: counter_ == count.

+
+ +
+
+~latch() = default#
+

Requires: No threads are blocked at the synchronization point.

+
+

Note

+

May be called even if some threads have not yet returned from wait() or count_down_and_wait(), provided that counter_ is 0.

+
+
+

Note

+

The destructor might not return until all threads have exited wait() or count_down_and_wait().

+
+
+

Note

+

It is the caller’s responsibility to ensure that no other thread enters wait() after one thread has called the destructor. This may require additional coordination.

+
+
+ +
+
+inline void count_down(std::ptrdiff_t update)#
+

Decrements counter_ by n. Does not block.

+

Requires: counter_ >= n and n >= 0.

+

Synchronization: Synchronizes with all calls that block on this latch and with all try_wait calls on this latch that return true .

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline bool try_wait() const noexcept#
+

Returns: With very low probability false. Otherwise counter == 0.

+
+ +
+
+inline void wait() const#
+

If counter_ is 0, returns immediately. Otherwise, blocks the calling thread at the synchronization point until counter_ reaches 0.

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline void arrive_and_wait(std::ptrdiff_t update = 1)#
+

Effects: Equivalent to: count_down(update); wait();

+
+ +
+
+

Public Static Functions

+
+
+static inline constexpr std::ptrdiff_t() max () noexcept
+

Returns: The maximum value of counter that the implementation supports.

+
+ +
+
+

Protected Types

+
+
+using mutex_type = hpx::spinlock#
+
+ +
+
+

Protected Attributes

+
+
+mutable util::cache_line_data<mutex_type> mtx_#
+
+ +
+
+mutable util::cache_line_data<hpx::lcos::local::detail::condition_variable> cond_#
+
+ +
+
+std::atomic<std::ptrdiff_t> counter_#
+
+ +
+
+bool notified_#
+
+ +
+
+ +
+
+namespace lcos
+
+
+namespace local
+
+
+class latch : public hpx::latch#
+
+#include <latch.hpp>
+

A latch maintains an internal counter_ that is initialized when the latch is created. Threads may block at a synchronization point waiting for counter_ to be decremented to 0. When counter_ reaches 0, all such blocked threads are released.

+

Calls to countdown_and_wait() , count_down() , wait() , is_ready(), count_up() , and reset() behave as atomic operations.

+
+

Note

+

A hpx::latch is not an LCO in the sense that it has no global id and it can’t be triggered using the action (parcel) mechanism. Use hpx::distributed::latch instead if this is required. It is just a low level synchronization primitive allowing to synchronize a given number of threads.

+
+
+

Public Functions

+
+
+HPX_NON_COPYABLE(latch)#
+
+ +
+
+inline explicit latch(std::ptrdiff_t count)#
+

Initialize the latch

+

Requires: count >= 0. Synchronization: None Postconditions: counter_ == count.

+
+ +
+
+~latch() = default#
+

Requires: No threads are blocked at the synchronization point.

+
+

Note

+

May be called even if some threads have not yet returned from wait() or count_down_and_wait(), provided that counter_ is 0.

+
+
+

Note

+

The destructor might not return until all threads have exited wait() or count_down_and_wait().

+
+
+

Note

+

It is the caller’s responsibility to ensure that no other thread enters wait() after one thread has called the destructor. This may require additional coordination.

+
+
+ +
+
+inline void count_down_and_wait()#
+

Decrements counter_ by 1 . Blocks at the synchronization point until counter_ reaches 0.

+

Requires: counter_ > 0.

+

Synchronization: Synchronizes with all calls that block on this latch and with all is_ready calls on this latch that return true.

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline bool is_ready() const noexcept#
+

Returns: counter_ == 0. Does not block.

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline void abort_all() const#
+
+ +
+
+inline void count_up(std::ptrdiff_t n)#
+

Increments counter_ by n. Does not block.

+

Requires: n >= 0.

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline void reset(std::ptrdiff_t n)#
+

Reset counter_ to n. Does not block.

+

Requires: n >= 0.

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline bool reset_if_needed_and_count_up(std::ptrdiff_t n, std::ptrdiff_t count)#
+

Effects: Equivalent to: if (is_ready()) reset(count); count_up(n); Returns: true if the latch was reset

+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx::mutex, hpx::timed_mutex#
+

Defined in header hpx/mutex.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+class mutex#
+
+#include <mutex.hpp>
+

mutex class is a synchronization primitive that can be used to protect shared data from being simultaneously accessed by multiple threads. mutex offers exclusive, non-recursive ownership semantics:

+

    +
  • A calling thread owns a mutex from the time that it successfully calls either lock or try_lock until it calls unlock.

  • +
  • When a thread owns a mutex, all other threads will block (for calls to lock) or receive a false return value (for try_lock) if they attempt to claim ownership of the mutex.

  • +
  • A calling thread must not own the mutex prior to calling lock or try_lock.

  • +
+

+

The behavior of a program is undefined if a mutex is destroyed while still owned by any threads, or a thread terminates while owning a mutex. The mutex class satisfies all requirements of Mutex and StandardLayoutType.

+

hpx::mutex is neither copyable nor movable.

+

Subclassed by hpx::timed_mutex

+
+

Public Functions

+
+
+HPX_NON_COPYABLE(mutex)#
+

hpx::mutex is neither copyable nor movable

+
+ +
+
+inline HPX_HOST_DEVICE_CONSTEXPR mutex(char const*const = "") noexcept#
+

Constructs the mutex. The mutex is in unlocked state after the constructor completes.

+
+

Note

+

Because the default constructor is constexpr, static mutexes are initialized as part of static non-local initialization, before any dynamic non-local initialization begins. This makes it safe to lock a mutex in a constructor of any static object.

+
+
+
Parameters
+

description – description of the mutex.

+
+
+
+ +
+
+~mutex()#
+

Destroys the mutex. The behavior is undefined if the mutex is owned by any thread or if any thread terminates while holding any ownership of the mutex.

+
+ +
+
+void lock(char const *description, error_code &ec = throws)#
+

Locks the mutex. If another thread has already locked the mutex, a call to lock will block execution until the lock is acquired. If lock is called by a thread that already owns the mutex, the behavior is undefined: for example, the program may deadlock. hpx::mutex can detect the invalid usage and throws a std::system_error with error condition resource_deadlock_would_occur instead of deadlocking. Prior unlock() operations on the same mutex synchronize- with (as defined in std::memory_order) this operation.

+
+

Note

+

lock() is usually not called directly: std::unique_lock, std::scoped_lock, and std::lock_guard are used to manage exclusive locking.

+
+
+
Parameters
+
    +
  • description – Description of the mutex

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

void lock returns void.

+
+
+
+ +
+
+inline void lock(error_code &ec = throws)#
+

Locks the mutex. If another thread has already locked the mutex, a call to lock will block execution until the lock is acquired. If lock is called by a thread that already owns the mutex, the behavior is undefined: for example, the program may deadlock. hpx::mutex can detect the invalid usage and throws a std::system_error with error condition resource_deadlock_would_occur instead of deadlocking. Prior unlock() operations on the same mutex synchronize - with(as defined in std::memory_order) this operation.

+
+

Note

+

lock() is usually not called directly: std::unique_lock, std::scoped_lock, and std::lock_guard are used to manage exclusive locking. This overload essentially calls void lock(char const* description, error_code& ec =throws); with description as mutex::lock.

+
+
+
Parameters
+

ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

+
+
Returns
+

void lock returns void.

+
+
+
+ +
+
+bool try_lock(char const *description, error_code &ec = throws)#
+

Tries to lock the mutex. Returns immediately. On successful lock acquisition returns true, otherwise returns false. This function is allowed to fail spuriously and return false even if the mutex is not currently locked by any other thread. If try_lock is called by a thread that already owns the mutex, the behavior is undefined. Prior unlock() operation on the same mutex synchronizes-with (as defined in std::memory_order) this operation if it returns true. Note that prior lock() does not synchronize with this operation if it returns false.

+
+
Parameters
+
    +
  • description – Description of the mutex

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool try_lock returns true on successful lock acquisition, otherwise returns false.

+
+
+
+ +
+
+inline bool try_lock(error_code &ec = throws)#
+

Tries to lock the mutex. Returns immediately. On successful lock acquisition returns true, otherwise returns false. This function is allowed to fail spuriously and return false even if the mutex is not currently locked by any other thread. If try_lock is called by a thread that already owns the mutex, the behavior is undefined. Prior unlock() operation on the same mutex synchronizes-with (as defined in std::memory_order) this operation if it returns true. Note that prior lock() does not synchronize with this operation if it returns false.

+
+

Note

+

This overload essentially calls

void try_lock(char const* description,
+              error_code& ec = throws);
+
+
+ with description as mutex::try_lock.

+
+
+
Parameters
+

ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

+
+
Returns
+

bool try_lock returns true on successful lock acquisition, otherwise returns false.

+
+
+
+ +
+
+void unlock(error_code &ec = throws)#
+

Unlocks the mutex. The mutex must be locked by the current thread of execution, otherwise, the behavior is undefined. This operation synchronizes-with (as defined in std::memory_order) any subsequent lock operation that obtains ownership of the same mutex.

+
+
Parameters
+

ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

+
+
Returns
+

unlock returns void.

+
+
+
+ +
+
+ +
+
+class timed_mutex : private hpx::mutex#
+
+#include <mutex.hpp>
+

The timed_mutex class is a synchronization primitive that can be used to protect shared data from being simultaneously accessed by multiple threads. In a manner similar to mutex, timed_mutex offers exclusive, non-recursive ownership semantics. In addition, timed_mutex provides the ability to attempt to claim ownership of a timed_mutex with a timeout via the member functions try_lock_for() and try_lock_until(). The timed_mutex class satisfies all requirements of TimedMutex and StandardLayoutType.

+

hpx::timed_mutex is neither copyable nor movable.

+
+

Public Functions

+
+
+HPX_NON_COPYABLE(timed_mutex)#
+

hpx::timed_mutex is neither copyable nor movable

+
+ +
+
+timed_mutex(char const *const description = "")#
+

Constructs a timed_mutex. The mutex is in unlocked state after the call.

+
+
Parameters
+

description – Description of the timed_mutex.

+
+
+
+ +
+
+~timed_mutex()#
+

Destroys the timed_mutex. The behavior is undefined if the mutex is owned by any thread or if any thread terminates while holding any ownership of the mutex.

+
+ +
+
+bool try_lock_until(hpx::chrono::steady_time_point const &abs_time, char const *description, error_code &ec = throws)#
+

Tries to lock the mutex. Blocks until specified abs_time has been reached or the lock is acquired, whichever comes first. On successful lock acquisition returns true, otherwise returns false. If abs_time has already passed, this function behaves like try_lock(). As with try_lock(), this function is allowed to fail spuriously and return false even if the mutex was not locked by any other thread at some point before abs_time. Prior unlock() operation on the same mutex synchronizes-with (as defined in std::memory_order) this operation if it returns true. If try_lock_until is called by a thread that already owns the mutex, the behavior is undefined.

+
+
Parameters
+
    +
  • abs_time – time point to block until

  • +
  • description – Description of the timed_mutex

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool try_lock_until returns true if the lock was acquired successfully, otherwise false.

+
+
+
+ +
+
+inline bool try_lock_until(hpx::chrono::steady_time_point const &abs_time, error_code &ec = throws)#
+

Tries to lock the mutex. Blocks until specified abs_time has been reached or the lock is acquired, whichever comes first. On successful lock acquisition returns true, otherwise returns false. If abs_time has already passed, this function behaves like try_lock(). As with try_lock(), this function is allowed to fail spuriously and return false even if the mutex was not locked by any other thread at some point before abs_time. Prior unlock() operation on the same mutex synchronizes-with (as defined in std::memory_order) this operation if it returns true. If try_lock_until is called by a thread that already owns the mutex, the behavior is undefined.

+
+

Note

+

This overload essentially calls

bool try_lock_until(
+  hpx::chrono::steady_time_point const& abs_time,
+  char const* description, error_code& ec = throws);
+
+
+ with description as mutex::try_lock_until.

+
+
+
Parameters
+
    +
  • abs_time – time point to block until

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool try_lock_until returns true if the lock was acquired successfully, otherwise false.

+
+
+
+ +
+
+inline bool try_lock_for(hpx::chrono::steady_duration const &rel_time, char const *description, error_code &ec = throws)#
+

Tries to lock the mutex. Blocks until specified rel_time has elapsed or the lock is acquired, whichever comes first. On successful lock acquisition returns true, otherwise returns false. If rel_time is less or equal rel_time.zero(), the function behaves like try_lock(). This function may block for longer than rel_time due to scheduling or resource contention delays. As with try_lock(), this function is allowed to fail spuriously and return false even if the mutex was not locked by any other thread at some point during rel_time. Prior unlock() operation on the same mutex synchronizes-with (as defined in std::memory_order) this operation if it returns true. If try_lock_for is called by a thread that already owns the mutex, the behavior is undefined.

+
+
Parameters
+
    +
  • rel_time – minimum duration to block for

  • +
  • description – Description of the timed_mutex

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool try_lock_for returns true if the lock was acquired successfully, otherwise false.

+
+
+
+ +
+
+inline bool try_lock_for(hpx::chrono::steady_duration const &rel_time, error_code &ec = throws)#
+

Tries to lock the mutex. Blocks until specified rel_time has elapsed or the lock is acquired, whichever comes first. On successful lock acquisition returns true, otherwise returns false. If rel_time is less or equal rel_time.zero(), the function behaves like try_lock(). This function may block for longer than rel_time due to scheduling or resource contention delays. As with try_lock(), this function is allowed to fail spuriously and return false even if the mutex was not locked by any other thread at some point during rel_time. Prior unlock() operation on the same mutex synchronizes-with (as defined in std::memory_order) this operation if it returns true. If try_lock_for is called by a thread that already owns the mutex, the behavior is undefined.

+
+

Note

+

This overload essentially calls

bool try_lock_for(
+    hpx::chrono::steady_duration const& rel_time,
+    char const* description, error_code& ec = throws)
+
+
+ with description as mutex::try_lock_for.

+
+
+
Parameters
+
    +
  • rel_time – minimum duration to block for

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool try_lock_for returns true if the lock was acquired successfully, otherwise false.

+
+
+
+ +
+
+void lock(char const *description, error_code &ec = throws)#
+

Locks the mutex. If another thread has already locked the mutex, a call to lock will block execution until the lock is acquired. If lock is called by a thread that already owns the mutex, the behavior is undefined: for example, the program may deadlock. hpx::mutex can detect the invalid usage and throws a std::system_error with error condition resource_deadlock_would_occur instead of deadlocking. Prior unlock() operations on the same mutex synchronize- with (as defined in std::memory_order) this operation.

+
+

Note

+

lock() is usually not called directly: std::unique_lock, std::scoped_lock, and std::lock_guard are used to manage exclusive locking.

+
+
+
Parameters
+
    +
  • description – Description of the mutex

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

void lock returns void.

+
+
+
+ +
+
+inline void lock(error_code &ec = throws)#
+

Locks the mutex. If another thread has already locked the mutex, a call to lock will block execution until the lock is acquired. If lock is called by a thread that already owns the mutex, the behavior is undefined: for example, the program may deadlock. hpx::mutex can detect the invalid usage and throws a std::system_error with error condition resource_deadlock_would_occur instead of deadlocking. Prior unlock() operations on the same mutex synchronize - with(as defined in std::memory_order) this operation.

+
+

Note

+

lock() is usually not called directly: std::unique_lock, std::scoped_lock, and std::lock_guard are used to manage exclusive locking. This overload essentially calls void lock(char const* description, error_code& ec =throws); with description as mutex::lock.

+
+
+
Parameters
+

ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

+
+
Returns
+

void lock returns void.

+
+
+
+ +
+
+bool try_lock(char const *description, error_code &ec = throws)#
+

Tries to lock the mutex. Returns immediately. On successful lock acquisition returns true, otherwise returns false. This function is allowed to fail spuriously and return false even if the mutex is not currently locked by any other thread. If try_lock is called by a thread that already owns the mutex, the behavior is undefined. Prior unlock() operation on the same mutex synchronizes-with (as defined in std::memory_order) this operation if it returns true. Note that prior lock() does not synchronize with this operation if it returns false.

+
+
Parameters
+
    +
  • description – Description of the mutex

  • +
  • ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

  • +
+
+
Returns
+

bool try_lock returns true on successful lock acquisition, otherwise returns false.

+
+
+
+ +
+
+inline bool try_lock(error_code &ec = throws)#
+

Tries to lock the mutex. Returns immediately. On successful lock acquisition returns true, otherwise returns false. This function is allowed to fail spuriously and return false even if the mutex is not currently locked by any other thread. If try_lock is called by a thread that already owns the mutex, the behavior is undefined. Prior unlock() operation on the same mutex synchronizes-with (as defined in std::memory_order) this operation if it returns true. Note that prior lock() does not synchronize with this operation if it returns false.

+
+

Note

+

This overload essentially calls

void try_lock(char const* description,
+              error_code& ec = throws);
+
+
+ with description as mutex::try_lock.

+
+
+
Parameters
+

ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

+
+
Returns
+

bool try_lock returns true on successful lock acquisition, otherwise returns false.

+
+
+
+ +
+
+void unlock(error_code &ec = throws)#
+

Unlocks the mutex. The mutex must be locked by the current thread of execution, otherwise, the behavior is undefined. This operation synchronizes-with (as defined in std::memory_order) any subsequent lock operation that obtains ownership of the same mutex.

+
+
Parameters
+

ec – Used to hold error code value originated during the operation. Defaults to throws &#8212; A special ‘throw on error’ error_code.

+
+
Returns
+

unlock returns void.

+
+
+
+ +
+
+ +
+
+namespace lcos
+
+
+namespace local
+
+ +
+ +
+
+namespace threads
+
+

Typedefs

+
+
+using thread_id_ref_type = thread_id_ref#
+
+ +
+
+using thread_self = coroutines::detail::coroutine_self#
+
+ +
+
+

Functions

+
+
+thread_id get_self_id() noexcept#
+

The function get_self_id returns the HPX thread id of the current thread (or zero if the current thread is not a HPX thread).

+
+ +
+
+thread_self *get_self_ptr() noexcept#
+

The function get_self_ptr returns a pointer to the (OS thread specific) self reference to the current HPX thread.

+
+ +
+
+ +
+ +
+
+
hpx::no_mutex#
+

Defined in header hpx/mutex.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+struct no_mutex#
+
+#include <no_mutex.hpp>
+

no_mutex class can be used in cases where the shared data between multiple threads can be accessed simultaneously without causing inconsistencies.

+
+

Public Static Functions

+
+
+static inline constexpr void lock() noexcept#
+
+ +
+
+static inline constexpr bool try_lock() noexcept#
+
+ +
+
+static inline constexpr void unlock() noexcept#
+
+ +
+
+ +
+
+namespace lcos
+
+
+namespace local
+
+ +
+ +
+ +
+
+
hpx::once_flag, hpx::call_once#
+

Defined in header hpx/mutex.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_ONCE_INIT#
+
+ +
+
+
+namespace hpx
+
+

Functions

+
+
+template<typename F, typename ...Args>
void call_once(once_flag &flag, F &&f, Args&&... args)#
+

Executes the Callable object f exactly once, even if called concurrently, from several threads.

+

In detail:

    +
  • If, by the time call_once is called, flag indicates that f was already called, call_once returns right away (such a call to call_once is known as passive).

  • +
  • Otherwise, call_once invokes std::forward<Callable>(f) with the arguments std::forward<Args>(args)… (as if by hpx::invoke). Unlike the hpx::thread constructor or hpx::async, the arguments are not moved or copied because they don’t need to be transferred to another thread of execution. (such a call to call_once is known as active).

      +
    • If that invocation throws an exception, it is propagated to the caller of call_once, and the flag is not flipped so that another call will be attempted (such a call to call_once is known as exceptional).

    • +
    • If that invocation returns normally (such a call to call_once is known as returning), the flag is flipped, and all other calls to call_once with the same flag are guaranteed to be passive. All active calls on the same flag form a single total order consisting of zero or more exceptional calls, followed by one returning call. The end of each active call synchronizes-with the next active call in that order. The return from the returning call synchronizes-with the returns from all passive calls on the same flag: this means that all concurrent calls to call_once are guaranteed to observe any side-effects made by the active call, with no additional synchronization.

    • +
    +

  • +
+

+
+

Note

+

If concurrent calls to call_once pass different functions f, it is unspecified which f will be called. The selected function runs in the same thread as the call_once invocation it was passed to. Initialization of function-local statics is guaranteed to occur only once even when called from multiple threads, and may be more efficient than the equivalent code using hpx::call_once. The POSIX equivalent of this function is pthread_once.

+
+
+
Parameters
+
    +
  • flag – an object, for which exactly one function gets executed

  • +
  • f – Callable object to invoke

  • +
  • args – arguments to pass to the function

  • +
+
+
Throws
+

std::system_error – if any condition prevents calls to call_once from executing as specified or any exception thrown by f

+
+
+
+ +
+
+
+struct once_flag#
+
+#include <once.hpp>
+

The class hpx::once_flag is a helper structure for hpx::call_once. An object of type hpx::once_flag that is passed to multiple calls to hpx::call_once allows those calls to coordinate with each other such that only one of the calls will actually run to completion. hpx::once_flag is neither copyable nor movable.

+
+

Public Functions

+
+
+HPX_NON_COPYABLE(once_flag)#
+
+ +
+
+inline once_flag() noexcept#
+

Constructs an once_flag object. The internal state is set to indicate that no function has been called yet.

+
+ +
+
+

Private Members

+
+
+std::atomic<long> status_#
+
+ +
+
+lcos::local::event event_#
+
+ +
+
+

Friends

+
+
+template<typename F, typename ...Args>
friend void call_once(once_flag &flag, F &&f, Args&&... args)#
+

Executes the Callable object f exactly once, even if called concurrently, from several threads.

+

In detail:

    +
  • If, by the time call_once is called, flag indicates that f was already called, call_once returns right away (such a call to call_once is known as passive).

  • +
  • Otherwise, call_once invokes std::forward<Callable>(f) with the arguments std::forward<Args>(args)… (as if by hpx::invoke). Unlike the hpx::thread constructor or hpx::async, the arguments are not moved or copied because they don’t need to be transferred to another thread of execution. (such a call to call_once is known as active).

      +
    • If that invocation throws an exception, it is propagated to the caller of call_once, and the flag is not flipped so that another call will be attempted (such a call to call_once is known as exceptional).

    • +
    • If that invocation returns normally (such a call to call_once is known as returning), the flag is flipped, and all other calls to call_once with the same flag are guaranteed to be passive. All active calls on the same flag form a single total order consisting of zero or more exceptional calls, followed by one returning call. The end of each active call synchronizes-with the next active call in that order. The return from the returning call synchronizes-with the returns from all passive calls on the same flag: this means that all concurrent calls to call_once are guaranteed to observe any side-effects made by the active call, with no additional synchronization.

    • +
    +

  • +
+

+
+

Note

+

If concurrent calls to call_once pass different functions f, it is unspecified which f will be called. The selected function runs in the same thread as the call_once invocation it was passed to. Initialization of function-local statics is guaranteed to occur only once even when called from multiple threads, and may be more efficient than the equivalent code using hpx::call_once. The POSIX equivalent of this function is pthread_once.

+
+
+
Parameters
+
    +
  • flag – an object, for which exactly one function gets executed

  • +
  • f – Callable object to invoke

  • +
  • args – arguments to pass to the function

  • +
+
+
Throws
+

std::system_error – if any condition prevents calls to call_once from executing as specified or any exception thrown by f

+
+
+
+ +
+
+ +
+
+namespace lcos
+
+
+namespace local
+
+

Functions

+
+
+template<typename F, typename... Args>  HPX_DEPRECATED_V (1, 8, "hpx::lcos::local::call_once is deprecated, use hpx::call_once " "instead") void call_once(hpx
+
+ +
+
+ +
+ +
+ +
+
+
hpx::recursive_mutex#
+

Defined in header hpx/mutex.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Typedefs

+
+
+using recursive_mutex = detail::recursive_mutex_impl<>#
+
+ +
+
+
+namespace lcos
+
+
+namespace local
+
+ +
+ +
+ +
+
+
hpx::shared_mutex#
+

Defined in header hpx/shared_mutex.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Typedefs

+
+
+using shared_mutex = detail::shared_mutex<>#
+

The shared_mutex class is a synchronization primitive that can be used to protect shared data from being simultaneously accessed by multiple threads. In contrast to other mutex types which facilitate exclusive access, a shared_mutex has two levels of access:

    +
  • shared - several threads can share ownership of the same mutex.

  • +
  • exclusive - only one thread can own the mutex.

  • +
+

+

If one thread has acquired the exclusive lock (through lock, try_lock), no other threads can acquire the lock (including the shared). If one thread has acquired the shared lock (through lock_shared, try_lock_shared), no other thread can acquire the exclusive lock, but can acquire the shared lock. Only when the exclusive lock has not been acquired by any thread, the shared lock can be acquired by multiple threads. Within one thread, only one lock (shared or exclusive) can be acquired at the same time. Shared mutexes are especially useful when shared data can be safely read by any number of threads simultaneously, but a thread may only write the same data when no other thread is reading or writing at the same time. The shared_mutex class satisfies all requirements of SharedMutex and StandardLayoutType.

+
+ +
+
+
+namespace lcos
+
+
+namespace local
+
+ +
+ +
+ +
+
+
hpx/synchronization/sliding_semaphore.hpp#
+

Defined in header hpx/synchronization/sliding_semaphore.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Typedefs

+
+
+using sliding_semaphore = sliding_semaphore_var<>#
+
+ +
+
+
+template<typename Mutex = hpx::spinlock>
class sliding_semaphore_var#
+
+#include <sliding_semaphore.hpp>
+

A semaphore is a protected variable (an entity storing a value) or abstract data type (an entity grouping several variables that may or may not be numerical) which constitutes the classic method for restricting access to shared resources, such as shared memory, in a multiprogramming environment. Semaphores exist in many variants, though usually the term refers to a counting semaphore, since a binary semaphore is better known as a mutex. A counting semaphore is a counter for a set of available resources, rather than a locked/unlocked flag of a single resource. It was invented by Edsger Dijkstra. Semaphores are the classic solution to preventing race conditions in the dining philosophers problem, although they do not prevent resource deadlocks.

+

Sliding semaphores can be used for synchronizing multiple threads as well: one thread waiting for several other threads to touch (signal) the semaphore, or several threads waiting for one other thread to touch this semaphore. The difference to a counting semaphore is that a sliding semaphore will not limit the number of threads which are allowed to proceed, but will make sure that the difference between the (arbitrary) number passed to set and wait does not exceed a given threshold.

+
+

Public Functions

+
+
+sliding_semaphore_var(sliding_semaphore_var const&) = delete#
+
+ +
+
+sliding_semaphore_var &operator=(sliding_semaphore_var const&) = delete#
+
+ +
+
+sliding_semaphore_var(sliding_semaphore_var&&) = delete#
+
+ +
+
+sliding_semaphore_var &operator=(sliding_semaphore_var&&) = delete#
+
+ +
+
+inline explicit sliding_semaphore_var(std::int64_t max_difference, std::int64_t lower_limit = 0) noexcept#
+

Construct a new sliding semaphore.

+
+
Parameters
+
    +
  • max_difference – [in] The max difference between the upper limit (as set by wait()) and the lower limit (as set by signal()) which is allowed without suspending any thread calling wait().

  • +
  • lower_limit – [in] The initial lower limit.

  • +
+
+
+
+ +
+
+inline void set_max_difference(std::int64_t max_difference, std::int64_t lower_limit = 0) noexcept#
+

Set/Change the difference that will cause the semaphore to trigger

+
+
Parameters
+
    +
  • max_difference – [in] The max difference between the upper limit (as set by wait()) and the lower limit (as set by signal()) which is allowed without suspending any thread calling wait().

  • +
  • lower_limit – [in] The initial lower limit.

  • +
+
+
+
+ +
+
+inline void wait(std::int64_t upper_limit)#
+

Wait for the semaphore to be signaled.

+
+
Parameters
+

upper_limit – [in] The new upper limit. The calling thread will be suspended if the difference between this value and the largest lower_limit which was set by signal() is larger than the max_difference.

+
+
+
+ +
+
+inline bool try_wait(std::int64_t upper_limit = 1)#
+

Try to wait for the semaphore to be signaled.

+
+
Parameters
+

upper_limit – [in] The new upper limit. The calling thread will be suspended if the difference between this value and the largest lower_limit which was set by signal() is larger than the max_difference.

+
+
Returns
+

The function returns true if the calling thread would not block if it was calling wait().

+
+
+
+ +
+
+inline void signal(std::int64_t lower_limit)#
+

Signal the semaphore.

+
+
Parameters
+

lower_limit – [in] The new lower limit. This will update the current lower limit of this semaphore. It will also re-schedule all suspended threads for which their associated upper limit is not larger than the lower limit plus the max_difference.

+
+
+
+ +
+
+inline std::int64_t signal_all()#
+
+ +
+
+

Private Types

+
+
+using mutex_type = Mutex#
+
+ +
+
+using data_type = lcos::local::detail::sliding_semaphore_data<mutex_type>#
+
+ +
+
+

Private Members

+
+
+hpx::intrusive_ptr<data_type> data_#
+
+ +
+
+ +
+
+namespace lcos
+
+
+namespace local
+
+ +
+ +
+ +
+
+
hpx::spinlock#
+

Defined in header hpx/mutex.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Typedefs

+
+
+using spinlock = detail::spinlock<true>#
+

spinlock is a type of lock that causes a thread attempting to obtain it to check for its availability while waiting in a loop continuously.

+
+ +
+
+using spinlock_no_backoff = detail::spinlock<false>#
+
+ +
+
+
+namespace lcos
+
+
+namespace local
+
+ +
+ +
+ +
+
+
hpx::nostopstate, hpx::stop_callback, hpx::stop_source, hpx::stop_token, hpx::nostopstate_t#
+

Defined in header hpx/stop_token.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename Callback>
stop_callback(stop_token, Callback) -> stop_callback<Callback>#
+

The stop_callback class template provides an RAII object type that registers a callback function for an associated hpx::stop_token object, such that the callback function will be invoked when the hpx::stop_token’s associated hpx::stop_source is requested to stop. Callback functions registered via stop_callback’s constructor are invoked either in the same thread that successfully invokes request_stop() for a hpx::stop_source of the stop_callback’s associated hpx::stop_token; or if stop has already been requested prior to the constructor’s registration, then the callback is invoked in the thread constructing the stop_callback. More than one stop_callback can be created for the same hpx::stop_token, from the same or different threads concurrently. No guarantee is provided for the order in which they will be executed, but they will be invoked synchronously; except for stop_callback(s) constructed after stop has already been requested for the hpx::stop_token, as described previously. If an invocation of a callback exits via an exception then hpx::terminate is called. hpx::stop_callback is not CopyConstructible, CopyAssignable, MoveConstructible, nor MoveAssignable. The template param Callback type must be both invocable and destructible. Any return value is ignored.

+
+ +
+
+inline void swap(stop_token &lhs, stop_token &rhs) noexcept#
+
+ +
+
+inline void swap(stop_source &lhs, stop_source &rhs) noexcept#
+
+ +
+
+

Variables

+
+
+constexpr nostopstate_t nostopstate = {}#
+

This is a constant object instance of hpx::nostopstate_t for use in constructing an empty hpx::stop_source, as a placeholder value in the non-default constructor.

+
+ +
+
+
+struct nostopstate_t#
+
+#include <stop_token.hpp>
+

Unit type intended for use as a placeholder in hpx::stop_source non-default constructor, that makes the constructed hpx::stop_source empty with no associated stop-state.

+
+

Public Functions

+
+
+explicit nostopstate_t() = default#
+
+ +
+
+ +
+
+template<typename Callback>
class stop_callback
+
+ +
+
+class stop_source#
+
+#include <stop_token.hpp>
+

The stop_source class provides the means to issue a stop request, such as for hpx::jthread cancellation. A stop request made for one stop_source object is visible to all stop_sources and hpx::stop_tokens of the same associated stop-state; any hpx::stop_callback(s) registered for associated hpx::stop_token(s) will be invoked, and any hpx::condition_variable_any objects waiting on associated hpx::stop_token(s) will be awoken. Once a stop is requested, it cannot be withdrawn. Additional stop requests have no effect.

+
+

Note

+

For the purposes of hpx::jthread cancellation the stop_source object should be retrieved from the hpx::jthread object using get_stop_source(); or stop should be requested directly from the hpx::jthread object using request_stop(). This will then use the same associated stop-state as that passed into the hpx::jthread’s invoked function argument (i.e., the function being executed on its thread). For other uses, however, a stop_source can be constructed separately using the default constructor, which creates new stop-state.

+
+
+

Public Functions

+
+
+inline stop_source()#
+
+ +
+
+inline explicit stop_source(nostopstate_t) noexcept#
+
+ +
+
+inline stop_source(stop_source const &rhs) noexcept#
+
+ +
+
+stop_source(stop_source&&) noexcept = default#
+
+ +
+
+inline stop_source &operator=(stop_source const &rhs) noexcept#
+
+ +
+
+stop_source &operator=(stop_source&&) noexcept = default#
+
+ +
+
+inline ~stop_source()#
+
+ +
+
+inline void swap(stop_source &s) noexcept#
+

swaps two stop_source objects

+
+ +
+
+inline stop_token get_token() const noexcept#
+

returns a stop_token for the associated stop-state

+
+ +
+
+inline bool stop_possible() const noexcept#
+

checks whether associated stop-state can be requested to stop

+
+ +
+
+inline bool stop_requested() const noexcept#
+

checks whether the associated stop-state has been requested to stop

+
+ +
+
+inline bool request_stop() const noexcept#
+

makes a stop request for the associated stop-state, if any

+
+ +
+
+

Private Members

+
+
+hpx::intrusive_ptr<detail::stop_state> state_#
+
+ +
+
+

Friends

+
+
+inline friend bool operator==(stop_source const &lhs, stop_source const &rhs) noexcept#
+
+ +
+
+inline friend bool operator!=(stop_source const &lhs, stop_source const &rhs) noexcept#
+
+ +
+
+ +
+
+class stop_token#
+
+#include <stop_token.hpp>
+

The stop_token class provides the means to check if a stop request has been made or can be made, for its associated hpx::stop_source object. It is essentially a thread-safe “view” of the associated stop-state. The stop_token can also be passed to the constructor of hpx::stop_callback, such that the callback will be invoked if the stop_token’s associated hpx::stop_source is requested to stop. And stop_token can be passed to the interruptible waiting functions of hpx::condition_variable_any, to interrupt the condition variable’s wait if stop is requested.

+
+

Note

+

A stop_token object is not generally constructed independently, but rather retrieved from a hpx::jthread or hpx::stop_source. This makes it share the same associated stop-state as the hpx::jthread or hpx::stop_source.

+
+
+

Public Types

+
+
+template<typename Callback>
using callback_type = stop_callback<Callback>#
+
+ +
+
+

Public Functions

+
+
+constexpr stop_token() noexcept = default#
+
+ +
+
+stop_token(stop_token const &rhs) = default#
+
+ +
+
+stop_token(stop_token&&) noexcept = default#
+
+ +
+
+stop_token &operator=(stop_token const &rhs) = default#
+
+ +
+
+stop_token &operator=(stop_token&&) noexcept = default#
+
+ +
+
+~stop_token() = default#
+
+ +
+
+inline void swap(stop_token &s) noexcept#
+

swaps two stop_token objects

+
+ +
+
+inline bool stop_requested() const noexcept#
+

checks whether the associated stop-state has been requested to stop

+
+ +
+
+inline bool stop_possible() const noexcept#
+

checks whether associated stop-state can be requested to stop

+
+ +
+
+

Private Functions

+
+
+inline explicit stop_token(hpx::intrusive_ptr<detail::stop_state> state) noexcept#
+
+ +
+
+

Private Members

+
+
+hpx::intrusive_ptr<detail::stop_state> state_#
+
+ +
+
+

Friends

+
+
+friend class stop_callback
+
+ +
+
+friend class stop_source
+
+ +
+
+inline friend constexpr friend bool operator== (stop_token const &lhs, stop_token const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator!= (stop_token const &lhs, stop_token const &rhs) noexcept
+
+ +
+
+ +
+
+namespace experimental
+
+ +
+
+namespace p2300_stop_token#
+
+

Functions

+
+
+template<typename Callback>
in_place_stop_callback(in_place_stop_token, Callback) -> in_place_stop_callback<Callback>#
+
+ +
+
+
+template<typename Callback>
class in_place_stop_callback
+
+ +
+
+class in_place_stop_source#
+
+

Public Functions

+
+
+inline in_place_stop_source() noexcept#
+
+ +
+
+inline ~in_place_stop_source()#
+
+ +
+
+in_place_stop_source(in_place_stop_source const&) = delete#
+
+ +
+
+in_place_stop_source(in_place_stop_source&&) noexcept = delete#
+
+ +
+
+in_place_stop_source &operator=(in_place_stop_source const&) = delete#
+
+ +
+
+in_place_stop_source &operator=(in_place_stop_source&&) noexcept = delete#
+
+ +
+
+inline in_place_stop_token get_token() const noexcept#
+
+ +
+
+inline bool request_stop() noexcept#
+
+ +
+
+inline bool stop_requested() const noexcept#
+
+ +
+
+inline bool stop_possible() const noexcept#
+
+ +
+
+

Private Functions

+
+
+inline bool register_callback(hpx::detail::stop_callback_base *cb) noexcept#
+
+ +
+
+inline void remove_callback(hpx::detail::stop_callback_base *cb) noexcept#
+
+ +
+
+

Private Members

+
+
+hpx::detail::stop_state state_#
+
+ +
+
+

Friends

+
+
+friend class in_place_stop_token
+
+ +
+
+friend class in_place_stop_callback
+
+ +
+
+ +
+
+class in_place_stop_token#
+
+

Public Types

+
+
+template<typename Callback>
using callback_type = in_place_stop_callback<Callback>#
+
+ +
+
+

Public Functions

+
+
+inline constexpr in_place_stop_token() noexcept#
+
+ +
+
+~in_place_stop_token() = default#
+
+ +
+
+in_place_stop_token(in_place_stop_token const &rhs) noexcept = default#
+
+ +
+
+inline in_place_stop_token(in_place_stop_token &&rhs) noexcept#
+
+ +
+
+in_place_stop_token &operator=(in_place_stop_token const &rhs) noexcept = default#
+
+ +
+
+inline in_place_stop_token &operator=(in_place_stop_token &&rhs) noexcept#
+
+ +
+
+inline bool stop_requested() const noexcept#
+
+ +
+
+inline bool stop_possible() const noexcept#
+
+ +
+
+inline void swap(in_place_stop_token &rhs) noexcept#
+
+ +
+
+

Private Functions

+
+
+inline explicit in_place_stop_token(in_place_stop_source const *source) noexcept#
+
+ +
+
+

Private Members

+
+
+in_place_stop_source const *source_#
+
+ +
+
+

Friends

+
+
+friend class in_place_stop_source
+
+ +
+
+friend class in_place_stop_callback
+
+ +
+
+inline friend constexpr friend bool operator== (in_place_stop_token const &lhs, in_place_stop_token const &rhs) noexcept
+
+ +
+
+inline friend constexpr friend bool operator!= (in_place_stop_token const &lhs, in_place_stop_token const &rhs) noexcept
+
+ +
+
+inline friend void swap(in_place_stop_token &x, in_place_stop_token &y) noexcept#
+
+ +
+
+ +
+
+struct never_stop_token#
+
+

Public Types

+
+
+template<typename>
using callback_type = callback_impl#
+
+ +
+
+

Public Static Functions

+
+
+static inline constexpr bool stop_requested() noexcept#
+
+ +
+
+static inline constexpr bool stop_possible() noexcept#
+
+ +
+
+

Friends

+
+
+inline friend constexpr friend bool operator== (never_stop_token, never_stop_token) noexcept
+
+ +
+
+inline friend constexpr friend bool operator!= (never_stop_token, never_stop_token) noexcept
+
+ +
+
+
+struct callback_impl#
+
+

Public Functions

+
+
+template<typename Callback>
inline explicit constexpr callback_impl(never_stop_token, Callback&&) noexcept#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
+
+
tag_invoke#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::is_invocable, hpx::is_invocable_r#
+

Defined in header hpx/type_traits.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Variables

+
+
+template<typename F, typename ...Ts>
constexpr bool is_invocable_v = is_invocable<F, Ts...>::value#
+
+ +
+
+template<typename R, typename F, typename ...Ts>
constexpr bool is_invocable_r_v = is_invocable_r<R, F, Ts...>::value#
+
+ +
+
+template<typename F, typename ...Ts>
constexpr bool is_nothrow_invocable_v = is_nothrow_invocable<F, Ts...>::value#
+
+ +
+
+
+template<typename F, typename ...Ts>
struct is_invocable : public hpx::detail::is_invocable_impl<F&&(Ts&&...)>#
+
+#include <is_invocable.hpp>
+

Determines whether F can be invoked with the arguments Ts…. Formally, determines whether

INVOKE(std::declval<F>(), std::declval<Ts>()...)
+
+
+ is well formed when treated as an unevaluated operand, where INVOKE is the operation defined in Callable.

+

F, R and all types in the parameter pack Ts shall each be a complete type, (possibly cv-qualified) void, or an array of unknown bound. Otherwise, the behavior is undefined. If an instantiation of a template above depends, directly or indirectly, on an incomplete type, and that instantiation could yield a different result if that type were hypothetically completed, the behavior is undefined.

+
+ +
+
+template<typename R, typename F, typename ...Ts>
struct is_invocable_r : public hpx::detail::is_invocable_r_impl<F&&(Ts&&...), R>#
+
+#include <is_invocable.hpp>
+

Determines whether F can be invoked with the arguments Ts… to yield a result that is convertible to R and the implicit conversion does not bind a reference to a temporary object (since C++23). If R is cv void, the result can be any type. Formally, determines whether

INVOKE<R>(std::declval<F>(), std::declval<Ts>()...)
+
+
+ is well formed when treated as an unevaluated operand, where INVOKE is the operation defined in Callable. Determines whether F can be invoked with the arguments Ts…. Formally, determines whether
INVOKE(std::declval<F>(), std::declval<Ts>()...)
+
+
+ is well formed when treated as an unevaluated operand, where INVOKE is the operation defined in Callable.

+

F, R and all types in the parameter pack Ts shall each be a complete type, (possibly cv-qualified) void, or an array of unknown bound. Otherwise, the behavior is undefined. If an instantiation of a template above depends, directly or indirectly, on an incomplete type, and that instantiation could yield a different result if that type were hypothetically completed, the behavior is undefined.

+
+ +
+
+template<typename F, typename ...Ts>
struct is_nothrow_invocable : public hpx::detail::is_nothrow_invocable_impl<F(Ts...), is_invocable_v<F, Ts...>>#
+
+ +
+ +
+
+
+
+
thread_pool_util#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/thread_pool_util/thread_pool_suspension_helpers.hpp#
+

Defined in header hpx/thread_pool_util/thread_pool_suspension_helpers.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace threads
+
+

Functions

+
+
+hpx::future<void> resume_processing_unit(thread_pool_base &pool, std::size_t virt_core)#
+

Resumes the given processing unit. When the processing unit has been resumed the returned future will be ready.

+
+

Note

+

Can only be called from an HPX thread. Use resume_processing_unit_cb or to resume the processing unit from outside HPX. Requires that the pool has threads::policies::enable_elasticity set.

+
+
+
Parameters
+
    +
  • pool – [in] The thread pool to resume a processing unit on.

  • +
  • virt_core – [in] The processing unit on the pool to be resumed. The processing units are indexed starting from 0.

  • +
+
+
Returns
+

A future<void> which is ready when the given processing unit has been resumed.

+
+
+
+ +
+
+void resume_processing_unit_cb(thread_pool_base &pool, hpx::function<void()> callback, std::size_t virt_core, error_code &ec = throws)#
+

Resumes the given processing unit. Takes a callback as a parameter which will be called when the processing unit has been resumed.

+
+

Note

+

Requires that the pool has threads::policies::enable_elasticity set.

+
+
+
Parameters
+
    +
  • pool – [in] The thread pool to resume a processing unit on.

  • +
  • callback – [in] Callback which is called when the processing unit has been suspended.

  • +
  • virt_core – [in] The processing unit to resume.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+hpx::future<void> suspend_processing_unit(thread_pool_base &pool, std::size_t virt_core)#
+

Suspends the given processing unit. When the processing unit has been suspended the returned future will be ready.

+
+

Note

+

Can only be called from an HPX thread. Use suspend_processing_unit_cb or to suspend the processing unit from outside HPX. Requires that the pool has threads::policies::enable_elasticity set.

+
+
+
Parameters
+
    +
  • pool – [in] The thread pool to suspend a processing unit from.

  • +
  • virt_core – [in] The processing unit on the pool to be suspended. The processing units are indexed starting from 0.

  • +
+
+
Throws
+

hpx::exception – if called from outside the HPX runtime.

+
+
Returns
+

A future<void> which is ready when the given processing unit has been suspended.

+
+
+
+ +
+
+void suspend_processing_unit_cb(hpx::function<void()> callback, thread_pool_base &pool, std::size_t virt_core, error_code &ec = throws)#
+

Suspends the given processing unit. Takes a callback as a parameter which will be called when the processing unit has been suspended.

+
+

Note

+

Requires that the pool has threads::policies::enable_elasticity set.

+
+
+
Parameters
+
    +
  • pool – [in] The thread pool to suspend a processing unit from.

  • +
  • callback – [in] Callback which is called when the processing unit has been suspended.

  • +
  • virt_core – [in] The processing unit to suspend.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+hpx::future<void> resume_pool(thread_pool_base &pool)#
+

Resumes the thread pool. When the all OS threads on the thread pool have been resumed the returned future will be ready.

+
+

Note

+

Can only be called from an HPX thread. Use resume_cb or resume_direct to suspend the pool from outside HPX.

+
+
+
Parameters
+

pool – [in] The thread pool to resume.

+
+
Throws
+

hpx::exception – if called from outside the HPX runtime.

+
+
Returns
+

A future<void> which is ready when the thread pool has been resumed.

+
+
+
+ +
+
+void resume_pool_cb(thread_pool_base &pool, hpx::function<void()> callback, error_code &ec = throws)#
+

Resumes the thread pool. Takes a callback as a parameter which will be called when all OS threads on the thread pool have been resumed.

+
+
Parameters
+
    +
  • pool – [in] The thread pool to resume.

  • +
  • callback – [in] called when the thread pool has been resumed.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+hpx::future<void> suspend_pool(thread_pool_base &pool)#
+

Suspends the thread pool. When the all OS threads on the thread pool have been suspended the returned future will be ready.

+
+

Note

+

Can only be called from an HPX thread. Use suspend_cb or suspend_direct to suspend the pool from outside HPX. A thread pool cannot be suspended from an HPX thread running on the pool itself.

+
+
+
Parameters
+

pool – [in] The thread pool to suspend.

+
+
Throws
+

hpx::exception – if called from outside the HPX runtime.

+
+
Returns
+

A future<void> which is ready when the thread pool has been suspended.

+
+
+
+ +
+
+void suspend_pool_cb(thread_pool_base &pool, hpx::function<void()> callback, error_code &ec = throws)#
+

Suspends the thread pool. Takes a callback as a parameter which will be called when all OS threads on the thread pool have been suspended.

+
+

Note

+

A thread pool cannot be suspended from an HPX thread running on the pool itself.

+
+
+
Parameters
+
    +
  • pool – [in] The thread pool to suspend.

  • +
  • callback – [in] called when the thread pool has been suspended.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Throws
+

hpx::exception – if called from an HPX thread which is running on the pool itself.

+
+
+
+ +
+
+ +
+ +
+
+
+
+
thread_support#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::unlock_guard#
+

Defined in header hpx/mutex.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+template<typename Mutex>
class unlock_guard#
+
+#include <unlock_guard.hpp>
+

The class unlock_guard is a mutex wrapper that provides a convenient mechanism for releasing a mutex for the duration of a scoped block.

+

unlock_guard performs the opposite functionality of lock_guard. When a lock_guard object is created, it attempts to take ownership of the mutex it is given. When control leaves the scope in which the lock_guard object was created, the lock_guard is destructed and the mutex is released. Accordingly, when an unlock_guard object is created, it attempts to release the ownership of the mutex it is given. So, when control leaves the scope in which the unlock_guard object was created, the unlock_guard is destructed and the mutex is owned again. In this way, the mutex is unlocked in the constructor and locked in the destructor, so that one can have an unlocked section within a locked one.

+
+

Public Types

+
+
+using mutex_type = Mutex#
+
+ +
+
+

Public Functions

+
+
+inline explicit constexpr unlock_guard(Mutex &m) noexcept#
+
+ +
+
+HPX_NON_COPYABLE(unlock_guard)#
+
+ +
+
+inline ~unlock_guard()#
+
+ +
+
+

Private Members

+
+
+Mutex &m_#
+
+ +
+
+ +
+
+namespace util
+
+

Typedefs

+
+
+using instead = hpx::unlock_guard<Mutex>
+
+ +
+
+ +
+ +
+
+
+
+
threading#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::jthread#
+

Defined in header hpx/thread.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+inline void swap(jthread &lhs, jthread &rhs) noexcept#
+
+ +
+
+
+class jthread#
+
+#include <jthread.hpp>
+

The class jthread represents a single thread of execution. It has the same general behavior as hpx::thread, except that jthread automatically rejoins on destruction, and can be cancelled/stopped in certain situations. Threads begin execution immediately upon construction of the associated thread object (pending any OS scheduling delays), starting at the top-level function provided as a constructor argument. The return value of the top-level function is ignored and if it terminates by throwing an exception, hpx::terminate is called. The top-level function may communicate its return value or an exception to the caller via hpx::promise or by modifying shared variables (which may require synchronization, see hpx::mutex and hpx::atomic) Unlike hpx::thread, the jthread logically holds an internal private member of type hpx::stop_source, which maintains a shared stop-state. The jthread constructor accepts a function that takes a hpx::stop_token as its first argument, which will be passed in by the jthread from its internal stop_source. This allows the function to check if stop has been requested during its execution, and return if it has. hpx::jthread objects may also be in the state that does not represent any thread (after default construction, move from, detach, or join), and a thread of execution may be not associated with any jthread objects (after detach). No two hpx::jthread objects may represent the same thread of execution; hpx::jthread is not CopyConstructible or CopyAssignable, although it is MoveConstructible and MoveAssignable.

+
+

Public Types

+
+
+using id = thread::id#
+
+ +
+
+using native_handle_type = thread::native_handle_type#
+
+ +
+
+

Public Functions

+
+
+inline jthread() noexcept#
+
+ +
+
+template<typename F, typename ...Ts, typename Enable = std::enable_if_t<!std::is_same_v<std::decay_t<F>, jthread>>>
inline explicit jthread(F &&f, Ts&&... ts)#
+
+ +
+
+inline ~jthread()#
+
+ +
+
+jthread(jthread const&) = delete#
+
+ +
+
+jthread(jthread &&x) noexcept = default#
+
+ +
+
+jthread &operator=(jthread const&) = delete#
+
+ +
+
+jthread &operator=(jthread&&) noexcept = default#
+

moves the jthread object

+
+ +
+
+inline void swap(jthread &t) noexcept#
+

swaps two jthread objects

+
+ +
+
+inline bool joinable() const noexcept#
+

checks whether the thread is joinable, i.e. potentially running in parallel context

+
+ +
+
+inline void join()#
+

waits for the thread to finish its execution

+
+ +
+
+inline void detach()#
+

permits the thread to execute independently from the thread handle

+
+ +
+
+inline id get_id() const noexcept#
+

returns the id of the thread

+
+ +
+
+inline native_handle_type native_handle()#
+

returns the underlying implementation-defined thread handle

+
+ +
+
+inline stop_source get_stop_source() noexcept#
+

returns a stop_source object associated with the shared stop state of the thread

+
+ +
+
+inline stop_token get_stop_token() const noexcept#
+

returns a stop_token associated with the shared stop state of the thread

+
+ +
+
+inline bool request_stop() noexcept#
+

requests execution stop via the shared stop state of the thread

+
+ +
+
+

Public Static Functions

+
+
+static inline unsigned int hardware_concurrency()#
+

returns the number of concurrent threads supported by the implementation

+
+ +
+
+

Private Members

+
+
+stop_source ssource_#
+
+ +
+
+hpx::thread thread_ = {}#
+
+ +
+
+

Private Static Functions

+
+
+template<typename F, typename ...Ts>
static inline void invoke(std::false_type, F &&f, stop_token&&, Ts&&... ts)#
+
+ +
+
+template<typename F, typename ...Ts>
static inline void invoke(std::true_type, F &&f, stop_token &&st, Ts&&... ts)#
+
+ +
+
+ +
+ +
+
+
hpx::thread, hpx::this_thread::yield, hpx::this_thread::get_id, hpx::this_thread::sleep_for, hpx::this_thread::sleep_until#
+

Defined in header hpx/thread.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<>
struct std::hash<::hpx::thread::id>#
+
+

Public Functions

+
+
+inline std::size_t operator()(::hpx::thread::id const &id) const#
+
+ +
+
+ +
+
+namespace hpx
+
+

Typedefs

+
+
+using thread_termination_handler_type = hpx::function<void(std::exception_ptr const &e)>#
+
+ +
+
+

Functions

+
+
+void set_thread_termination_handler(thread_termination_handler_type f)#
+
+ +
+
+inline void swap(thread &x, thread &y) noexcept#
+
+ +
+
+inline bool operator==(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+inline bool operator!=(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+inline bool operator<(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+inline bool operator>(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+inline bool operator<=(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+inline bool operator>=(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+template<typename Char, typename Traits>
std::basic_ostream<Char, Traits> &operator<<(std::basic_ostream<Char, Traits> &out, thread::id const &id)#
+
+ +
+
+
+class thread#
+
+#include <thread.hpp>
+

The class thread represents a single thread of execution. Threads allow multiple functions to execute concurrently. hreads begin execution immediately upon construction of the associated thread object (pending any OS scheduling delays), starting at the top-level function provided as a constructor argument. The return value of the top-level function is ignored and if it terminates by throwing an exception, hpx::terminate is called. The top-level function may communicate its return value or an exception to the caller via hpx::promise or by modifying shared variables (which may require synchronization, see hpx::mutex and hpx::atomic) hpx::thread objects may also be in the state that does not represent any thread (after default construction, move from, detach, or join), and a thread of execution may not be associated with any thread objects (after detach). No two hpx::thread objects may represent the same thread of execution; hpx::thread is not CopyConstructible or CopyAssignable, although it is MoveConstructible and MoveAssignable.

+
+

Public Types

+
+
+using native_handle_type = threads::thread_id_type#
+
+ +
+
+

Public Functions

+
+
+thread() noexcept#
+
+ +
+
+template<typename F, typename Enable = std::enable_if_t<!std::is_same_v<std::decay_t<F>, thread>>>
inline explicit thread(F &&f)#
+
+ +
+
+template<typename F, typename ...Ts>
inline explicit thread(F &&f, Ts&&... vs)#
+
+ +
+
+template<typename F>
inline thread(threads::thread_pool_base *pool, F &&f)#
+
+ +
+
+template<typename F, typename ...Ts>
inline thread(threads::thread_pool_base *pool, F &&f, Ts&&... vs)#
+
+ +
+
+~thread()#
+
+ +
+
+thread(thread&&) noexcept#
+
+ +
+
+thread &operator=(thread&&) noexcept#
+
+ +
+
+void swap(thread&) noexcept#
+

swaps two thread objects

+
+ +
+
+inline bool joinable() const noexcept#
+

Checks whether the thread is joinable, i.e. potentially running in parallel context

+
+ +
+
+void join()#
+

waits for the thread to finish its execution

+
+ +
+
+inline void detach()#
+

permits the thread to execute independently from the thread handle

+
+ +
+
+id get_id() const noexcept#
+

returns the id of the thread

+
+ +
+
+inline native_handle_type native_handle() const#
+

returns the underlying implementation-defined thread handle

+
+ +
+
+void interrupt(bool flag = true)#
+
+ +
+
+bool interruption_requested() const#
+
+ +
+
+hpx::future<void> get_future(error_code &ec = throws)#
+
+ +
+
+std::size_t get_thread_data() const#
+
+ +
+
+std::size_t set_thread_data(std::size_t)#
+
+ +
+
+

Public Static Functions

+
+
+static unsigned int hardware_concurrency() noexcept#
+

returns the number of concurrent threads supported by the implementation

+
+ +
+
+static void interrupt(id, bool flag = true)#
+
+ +
+
+

Private Types

+
+
+using mutex_type = hpx::spinlock#
+
+ +
+
+

Private Functions

+
+
+void terminate(char const *function, char const *reason) const#
+
+ +
+
+inline bool joinable_locked() const noexcept#
+
+ +
+
+inline void detach_locked()#
+
+ +
+
+void start_thread(threads::thread_pool_base *pool, hpx::move_only_function<void()> &&func)#
+
+ +
+
+

Private Members

+
+
+mutable mutex_type mtx_#
+
+ +
+
+threads::thread_id_ref_type id_#
+
+ +
+
+

Private Static Functions

+
+
+static threads::thread_result_type thread_function_nullary(hpx::move_only_function<void()> const &func)#
+
+ +
+
+
+class id#
+
+

Public Functions

+
+
+id() noexcept = default#
+
+ +
+
+inline explicit id(threads::thread_id_type const &i) noexcept#
+
+ +
+
+inline explicit id(threads::thread_id_type &&i) noexcept#
+
+ +
+
+inline explicit id(threads::thread_id_ref_type const &i) noexcept#
+
+ +
+
+inline explicit id(threads::thread_id_ref_type &&i) noexcept#
+
+ +
+
+inline threads::thread_id_type const &native_handle() const noexcept#
+
+ +
+
+

Private Members

+
+
+threads::thread_id_type id_#
+
+ +
+
+

Friends

+
+
+friend class thread
+
+ +
+
+friend bool operator==(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+friend bool operator!=(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+friend bool operator<(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+friend bool operator>(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+friend bool operator<=(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+friend bool operator>=(thread::id const &x, thread::id const &y) noexcept#
+
+ +
+
+template<typename Char, typename Traits>
friend std::basic_ostream<Char, Traits> &operator<<(std::basic_ostream<Char, Traits>&, thread::id const&)#
+
+ +
+
+ +
+ +
+
+namespace this_thread
+
+

Functions

+
+
+thread::id get_id() noexcept#
+

Returns the id of the current thread.

+
+ +
+
+void yield() noexcept#
+

Provides a hint to the implementation to reschedule the execution of threads, allowing other threads to run.

+
+

Note

+

The exact behavior of this function depends on the implementation, in particular on the mechanics of the OS scheduler in use and the state of the system. For example, a first-in-first-out realtime scheduler (SCHED_FIFO in Linux) would suspend the current thread and put it on the back of the queue of the same-priority threads that are ready to run (and if there are no other threads at the same priority, yield has no effect).

+
+
+ +
+
+void yield_to(thread::id) noexcept#
+
+ +
+
+threads::thread_priority get_priority() noexcept#
+
+ +
+
+std::ptrdiff_t get_stack_size() noexcept#
+
+ +
+
+void interruption_point()#
+
+ +
+
+bool interruption_enabled()#
+
+ +
+
+bool interruption_requested()#
+
+ +
+
+void interrupt()#
+
+ +
+
+void sleep_until(hpx::chrono::steady_time_point const &abs_time)#
+

Blocks the execution of the current thread until specified abs_time has been reached.

+

It is recommended to use the clock tied to abs_time, in which case adjustments of the clock may be taken into account. Thus, the duration of the block might be more or less than abs_time-Clock::now() at the time of the call, depending on the direction of the adjustment and whether it is honored by the implementation. The function also may block until after abs_time has been reached due to process scheduling or resource contention delays.

+
+
Parameters
+

abs_time – absolute time to block until

+
+
+
+ +
+
+inline void sleep_for(hpx::chrono::steady_duration const &rel_time)#
+

Blocks the execution of the current thread for at least the specified rel_time. This function may block for longer than rel_time due to scheduling or resource contention delays.

+

It is recommended to use a steady clock to measure the duration. If an implementation uses a system clock instead, the wait time may also be sensitive to clock adjustments.

+
+
Parameters
+

rel_time – time duration to sleep

+
+
+
+ +
+
+std::size_t get_thread_data()#
+
+ +
+
+std::size_t set_thread_data(std::size_t)#
+
+ +
+
+
+class disable_interruption#
+
+

Public Functions

+
+
+disable_interruption()#
+
+ +
+
+~disable_interruption()#
+
+ +
+
+

Private Functions

+
+
+disable_interruption(disable_interruption const&)#
+
+ +
+
+disable_interruption &operator=(disable_interruption const&)#
+
+ +
+
+

Private Members

+
+
+bool interruption_was_enabled_#
+
+ +
+
+

Friends

+
+
+friend class restore_interruption
+
+ +
+
+ +
+
+class restore_interruption#
+
+

Public Functions

+
+
+explicit restore_interruption(disable_interruption &d)#
+
+ +
+
+~restore_interruption()#
+
+ +
+
+

Private Functions

+
+
+restore_interruption(restore_interruption const&)#
+
+ +
+
+restore_interruption &operator=(restore_interruption const&)#
+
+ +
+
+

Private Members

+
+
+bool interruption_was_enabled_#
+
+ +
+
+ +
+ +
+ +
+
+namespace std
+
+
+template<> id >
+
+

Public Functions

+
+
+inline std::size_t operator()(::hpx::thread::id const &id) const#
+
+ +
+
+ +
+ +
+
+
+
+
threading_base#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::annotated_function#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename F>
constexpr F &&annotated_function(F &&f, char const* = nullptr) noexcept#
+

Returns a function annotated with the given annotation.

+

Annotating includes setting the thread description per thread id.

+
+
Parameters
+

function

+
+
+
+ +
+
+template<typename F>
constexpr F &&annotated_function(F &&f, std::string const&) noexcept#
+
+ +
+
+
+namespace util
+
+

Functions

+
+
+template<typename F>
constexpr decltype(auto) annotated_function(F &&f, char const *name = nullptr) noexcept#
+
+ +
+
+template<typename F>
constexpr decltype(auto) annotated_function(F &&f, std::string const &name) noexcept#
+
+ +
+
+ +
+ +
+
+
hpx/threading_base/print.hpp#
+

Defined in header hpx/threading_base/print.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/threading_base/register_thread.hpp#
+

Defined in header hpx/threading_base/register_thread.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace threads
+
+

Functions

+
+
+template<typename F>
thread_function_type make_thread_function(F &&f)#
+
+ +
+
+template<typename F>
thread_function_type make_thread_function_nullary(F &&f)#
+
+ +
+
+void register_thread(threads::thread_init_data &data, threads::thread_pool_base *pool, threads::thread_id_ref_type &id, error_code &ec = hpx::throws)#
+

Create a new thread using the given data.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • data – [in] The data to use for creating the thread.

  • +
  • pool – [in] The thread pool to use for launching the work.

  • +
  • id – [out] The id of the newly created thread (if applicable)

  • +
  • ec – [in,out] This represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Throws
+

invalid_status – if the runtime system has not been started yet.

+
+
Returns
+

This function will return the internal id of the newly created HPX-thread.

+
+
+
+ +
+
+threads::thread_id_ref_type register_thread(threads::thread_init_data &data, threads::thread_pool_base *pool, error_code &ec = hpx::throws)#
+
+ +
+
+void register_thread(threads::thread_init_data &data, threads::thread_id_ref_type &id, error_code &ec = throws)#
+

Create a new thread using the given data on the same thread pool as the calling thread, or on the default thread pool if not on an HPX thread.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • data – [in] The data to use for creating the thread.

  • +
  • id – [out] The id of the newly created thread (if applicable)

  • +
  • ec – [in,out] This represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Throws
+

invalid_status – if the runtime system has not been started yet.

+
+
Returns
+

This function will return the internal id of the newly created HPX-thread.

+
+
+
+ +
+
+threads::thread_id_ref_type register_thread(threads::thread_init_data &data, error_code &ec = throws)#
+
+ +
+
+thread_id_ref_type register_work(threads::thread_init_data &data, threads::thread_pool_base *pool, error_code &ec = hpx::throws)#
+

Create a new work item using the given data.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • data – [in] The data to use for creating the thread.

  • +
  • pool – [in] The thread pool to use for launching the work.

  • +
  • ec – [in,out] This represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Throws
+

invalid_status – if the runtime system has not been started yet.

+
+
+
+ +
+
+thread_id_ref_type register_work(threads::thread_init_data &data, error_code &ec = throws)#
+

Create a new work item using the given data on the same thread pool as the calling thread, or on the default thread pool if not on an HPX thread.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • data – [in] The data to use for creating the thread.

  • +
  • ec – [in,out] This represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Throws
+

invalid_status – if the runtime system has not been started yet.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::scoped_annotation#
+

Defined in header hpx/functional.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+struct scoped_annotation#
+
+#include <scoped_annotation.hpp>
+

scoped_annotation associates a name with a section of code (scope). It can be used to visualize code execution in profiling tools like Intel VTune, Apex Profiler, etc. That allows analyzing performance to figure out which part(s) of code is (are) responsible for performance degradation, etc.

+
+

Public Functions

+
+
+HPX_NON_COPYABLE(scoped_annotation)#
+
+ +
+
+inline explicit constexpr scoped_annotation(char const*) noexcept#
+
+ +
+
+template<typename F>
inline explicit constexpr scoped_annotation(F&&) noexcept#
+
+ +
+
+inline ~scoped_annotation()#
+
+ +
+
+ +
+
+namespace util
+
+

Typedefs

+
+
+typedef hpx::scoped_annotation instead
+
+ +
+
+ +
+ +
+
+
hpx/threading_base/thread_data.hpp#
+

Defined in header hpx/threading_base/thread_data.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace threads
+
+

Functions

+
+
+constexpr thread_data *get_thread_id_data(thread_id_ref_type const &tid) noexcept#
+
+ +
+
+constexpr thread_data *get_thread_id_data(thread_id_type const &tid) noexcept#
+
+ +
+
+
+class thread_data : public thread_data_reference_counting#
+
+#include <thread_data.hpp>
+

A thread is the representation of a HPX thread. It’s a first class object in HPX. In our implementation this is a user level thread running on top of one of the OS threads spawned by the thread-manager.

+

A thread encapsulates:

    +
  • A thread status word (see the functions thread::get_state and thread::set_state)

  • +
  • A function to execute (the thread function)

  • +
  • A frame (in this implementation this is a block of memory used as the threads stack)

  • +
  • A block of registers (not implemented yet)

  • +
+

+

Generally, threads are not created or executed directly. All functionality related to the management of threads is implemented by the thread-manager.

+
+

Public Types

+
+
+using spinlock_pool = util::spinlock_pool<thread_data>#
+
+ +
+
+

Public Functions

+
+
+thread_data(thread_data const&) = delete#
+
+ +
+
+thread_data(thread_data&&) = delete#
+
+ +
+
+thread_data &operator=(thread_data const&) = delete#
+
+ +
+
+thread_data &operator=(thread_data&&) = delete#
+
+ +
+
+inline thread_state get_state(std::memory_order const order = std::memory_order_acquire) const noexcept#
+

The get_state function queries the state of this thread instance.

+
+

Note

+

This function will be seldom used directly. Most of the time the state of a thread will be retrieved by using the function threadmanager::get_state.

+
+
+
Returns
+

This function returns the current state of this thread. It will return one of the values as defined by the thread_state enumeration.

+
+
+
+ +
+
+inline thread_state set_state(thread_schedule_state const state, thread_restart_state state_ex = thread_restart_state::unknown, std::memory_order const load_order = std::memory_order_acquire, std::memory_order const exchange_order = std::memory_order_acq_rel) const noexcept#
+

The set_state function changes the state of this thread instance.

+
+

Note

+

This function will be seldom used directly. Most of the time the state of a thread will have to be changed using the thread-manager. Moreover, changing the thread state using this function does not change its scheduling status. It only sets the thread’s status word. To change the thread’s scheduling status threadmanager::set_state should be used.

+
+
+
Parameters
+
    +
  • state – [in] The new state to be set for the thread.

  • +
  • state_ex – [in]

  • +
  • load_order – [in]

  • +
  • exchange_order – [in]

  • +
+
+
+
+ +
+
+inline bool set_state_tagged(thread_schedule_state const newstate, thread_state const &prev_state, thread_state &new_tagged_state, std::memory_order exchange_order = std::memory_order_acq_rel) const noexcept#
+
+ +
+
+inline bool restore_state(thread_state const new_state, thread_state const old_state, std::memory_order const load_order = std::memory_order_relaxed, std::memory_order const load_exchange = std::memory_order_acq_rel) const noexcept#
+

The restore_state function changes the state of this thread instance depending on its current state. It will change the state atomically only if the current state is still the same as passed as the second parameter. Otherwise it won’t touch the thread state of this instance.

+
+

Note

+

This function will be seldom used directly. Most of the time the state of a thread will have to be changed using the threadmanager. Moreover, changing the thread state using this function does not change its scheduling status. It only sets the thread’s status word. To change the thread’s scheduling status threadmanager::set_state should be used.

+
+
+
Parameters
+
    +
  • new_state – [in] The new state to be set for the thread.

  • +
  • old_state – [in] The old state of the thread which still has to be the current state.

  • +
  • load_order – [in]

  • +
  • load_exchange – [in]

  • +
+
+
Returns
+

This function returns true if the state has been changed successfully

+
+
+
+ +
+
+inline bool restore_state(thread_schedule_state new_state, thread_restart_state const state_ex, thread_state old_state, std::memory_order const load_exchange = std::memory_order_acq_rel) const noexcept#
+
+ +
+
+inline constexpr thread_priority get_priority() const noexcept#
+
+ +
+
+inline void set_priority(thread_priority priority) noexcept#
+
+ +
+
+inline bool interruption_requested() const noexcept#
+
+ +
+
+inline bool interruption_enabled() const noexcept#
+
+ +
+
+inline bool set_interruption_enabled(bool enable) noexcept#
+
+ +
+
+inline void interrupt(bool flag = true)#
+
+ +
+
+bool interruption_point(bool throw_on_interrupt = true)#
+
+ +
+
+bool add_thread_exit_callback(function<void()> const &f)#
+
+ +
+
+void run_thread_exit_callbacks()#
+
+ +
+
+void free_thread_exit_callbacks()#
+
+ +
+
+inline bool runs_as_child(std::memory_order mo = std::memory_order_acquire) const noexcept#
+
+ +
+
+inline constexpr bool is_stackless() const noexcept#
+
+ +
+
+void destroy_thread() override#
+
+ +
+
+inline constexpr policies::scheduler_base *get_scheduler_base() const noexcept#
+
+ +
+
+inline constexpr std::size_t get_last_worker_thread_num() const noexcept#
+
+ +
+
+inline void set_last_worker_thread_num(std::size_t last_worker_thread_num) noexcept#
+
+ +
+
+inline constexpr std::ptrdiff_t get_stack_size() const noexcept#
+
+ +
+
+inline thread_stacksize get_stack_size_enum() const noexcept#
+
+ +
+
+template<typename ThreadQueue>
inline constexpr ThreadQueue &get_queue() noexcept#
+
+ +
+
+inline coroutine_type::result_type operator()(hpx::execution_base::this_thread::detail::agent_storage *agent_storage)#
+

Execute the thread function.

+
+
Returns
+

This function returns the thread state the thread should be scheduled from this point on. The thread manager will use the returned value to set the thread’s scheduling status.

+
+
+
+ +
+
+inline coroutine_type::result_type invoke_directly()#
+

Directly execute the thread function (inline)

+
+
Returns
+

This function returns the thread state the thread should be scheduled from this point on. The thread manager will use the returned value to set the thread’s scheduling status.

+
+
+
+ +
+
+inline virtual thread_id_type get_thread_id() const#
+
+ +
+
+inline virtual std::size_t get_thread_phase() const noexcept#
+
+ +
+
+virtual std::size_t get_thread_data() const = 0#
+
+ +
+
+virtual std::size_t set_thread_data(std::size_t data) = 0#
+
+ +
+
+virtual void init() = 0#
+
+ +
+
+virtual void rebind(thread_init_data &init_data) = 0#
+
+ +
+
+thread_data(thread_init_data &init_data, void *queue, std::ptrdiff_t stacksize, bool is_stackless = false, thread_id_addref addref = thread_id_addref::yes)#
+
+ +
+
+virtual ~thread_data() override#
+
+ +
+
+virtual void destroy() noexcept = 0#
+
+ +
+
+

Public Static Functions

+
+
+static inline constexpr std::uint64_t get_component_id() noexcept#
+

Return the id of the component this thread is running in.

+
+ +
+
+static inline constexpr threads::thread_description get_description() noexcept#
+
+ +
+
+static inline constexpr threads::thread_description set_description(threads::thread_description) noexcept#
+
+ +
+
+static inline constexpr threads::thread_description get_lco_description() noexcept#
+
+ +
+
+static inline constexpr threads::thread_description set_lco_description(threads::thread_description) noexcept#
+
+ +
+
+static inline constexpr std::uint32_t get_parent_locality_id() noexcept#
+

Return the locality of the parent thread.

+
+ +
+
+static inline constexpr thread_id_type get_parent_thread_id() noexcept#
+

Return the thread id of the parent thread.

+
+ +
+
+static inline constexpr std::size_t get_parent_thread_phase() noexcept#
+

Return the phase of the parent thread.

+
+ +
+
+static inline constexpr util::backtrace const *get_backtrace() noexcept#
+
+ +
+
+static inline constexpr util::backtrace const *set_backtrace(util::backtrace const*) noexcept#
+
+ +
+
+

Protected Functions

+
+
+inline thread_restart_state set_state_ex(thread_restart_state const new_state, std::memory_order const load_order = std::memory_order_acquire, std::memory_order const load_exchange = std::memory_order_acq_rel) const noexcept#
+

The set_state function changes the extended state of this thread instance.

+
+

Note

+

This function will be seldom used directly. Most of the time the state of a thread will have to be changed using the threadmanager.

+
+
+
Parameters
+
    +
  • new_state – [in] The new extended state to be set for the thread.

  • +
  • load_order – [in]

  • +
  • load_exchange – [in]

  • +
+
+
+
+ +
+
+void rebind_base(thread_init_data &init_data)#
+
+ +
+
+

Private Members

+
+
+mutable std::atomic<thread_state> current_state_#
+
+ +
+
+thread_priority priority_#
+
+ +
+
+bool requested_interrupt_#
+
+ +
+
+bool enabled_interrupt_#
+
+ +
+
+bool ran_exit_funcs_#
+
+ +
+
+const bool is_stackless_#
+
+ +
+
+std::atomic<bool> runs_as_child_#
+
+ +
+
+std::forward_list<hpx::function<void()>> exit_funcs_#
+
+ +
+
+policies::scheduler_base *scheduler_base_#
+
+ +
+
+std::size_t last_worker_thread_num_#
+
+ +
+
+std::ptrdiff_t stacksize_#
+
+ +
+
+thread_stacksize stacksize_enum_#
+
+ +
+
+void *queue_#
+
+ +
+
+ +
+ +
+ +
+
+
hpx/threading_base/thread_description.hpp#
+

Defined in header hpx/threading_base/thread_description.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace threads
+
+

Functions

+
+
+std::ostream &operator<<(std::ostream&, thread_description const&)#
+
+ +
+
+std::string as_string(thread_description const &desc)#
+
+ +
+
+threads::thread_description get_thread_description(thread_id_type const &id, error_code &ec = throws)#
+

The function get_thread_description is part of the thread related API allows to query the description of one of the threads known to the thread-manager.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread being queried.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns the description of the thread referenced by the id parameter. If the thread is not known to the thread-manager the return value will be the string “<unknown>”.

+
+
+
+ +
+
+threads::thread_description set_thread_description(thread_id_type const &id, threads::thread_description const &desc = threads::thread_description(), error_code &ec = throws)#
+
+ +
+
+threads::thread_description get_thread_lco_description(thread_id_type const &id, error_code &ec = throws)#
+
+ +
+
+threads::thread_description set_thread_lco_description(thread_id_type const &id, threads::thread_description const &desc = threads::thread_description(), error_code &ec = throws)#
+
+ +
+
+
+struct thread_description#
+
+

Public Types

+
+
+enum data_type#
+

Values:

+
+
+enumerator data_type_description#
+
+ +
+
+enumerator data_type_address#
+
+ +
+ +
+
+

Public Functions

+
+
+thread_description() noexcept = default#
+
+ +
+
+inline constexpr thread_description(char const*) noexcept#
+
+ +
+
+inline explicit constexpr thread_description(std::string const&) noexcept#
+
+ +
+
+template<typename F, typename = std::enable_if_t<!std::is_same_v<F, thread_description> && !traits::is_action_v<F>>>
inline explicit constexpr thread_description(F const&, char const* = nullptr) noexcept#
+
+ +
+
+template<typename Action, typename = std::enable_if_t<traits::is_action_v<Action>>>
inline explicit constexpr thread_description(Action, char const* = nullptr) noexcept#
+
+ +
+
+inline explicit constexpr operator bool() const noexcept#
+
+ +
+
+

Public Static Functions

+
+
+static inline constexpr data_type kind() noexcept#
+
+ +
+
+static inline constexpr char const *get_description() noexcept#
+
+ +
+
+static inline constexpr std::size_t get_address() noexcept#
+
+ +
+
+static inline constexpr bool valid() noexcept#
+
+ +
+
+

Private Functions

+
+
+void init_from_alternative_name(char const *altname)#
+
+ +
+
+ +
+ +
+
+namespace util
+
+ +
+ +
+
+
hpx/threading_base/thread_helpers.hpp#
+

Defined in header hpx/threading_base/thread_helpers.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace this_thread
+
+

Functions

+
+
+threads::thread_restart_state suspend(threads::thread_schedule_state state, threads::thread_id_type nextid, threads::thread_description const &description = threads::thread_description("this_thread::suspend"), error_code &ec = throws)#
+

The function suspend will return control to the thread manager (suspends the current thread). It sets the new state of this thread to the thread state passed as the parameter.

+
+

Note

+

Must be called from within a HPX-thread.

+
+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+inline threads::thread_restart_state suspend(threads::thread_schedule_state state = threads::thread_schedule_state::pending, threads::thread_description const &description = threads::thread_description("this_thread::suspend"), error_code &ec = throws)#
+

The function suspend will return control to the thread manager (suspends the current thread). It sets the new state of this thread to the thread state passed as the parameter.

+
+

Note

+

Must be called from within a HPX-thread.

+
+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+threads::thread_restart_state suspend(hpx::chrono::steady_time_point const &abs_time, threads::thread_id_type id, threads::thread_description const &description = threads::thread_description("this_thread::suspend"), error_code &ec = throws)#
+

The function suspend will return control to the thread manager (suspends the current thread). It sets the new state of this thread to suspended and schedules a wakeup for this threads at the given time.

+
+

Note

+

Must be called from within a HPX-thread.

+
+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+inline threads::thread_restart_state suspend(hpx::chrono::steady_time_point const &abs_time, threads::thread_description const &description = threads::thread_description("this_thread::suspend"), error_code &ec = throws)#
+

The function suspend will return control to the thread manager (suspends the current thread). It sets the new state of this thread to suspended and schedules a wakeup for this threads at the given time.

+
+

Note

+

Must be called from within a HPX-thread.

+
+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+inline threads::thread_restart_state suspend(hpx::chrono::steady_duration const &rel_time, threads::thread_description const &description = threads::thread_description("this_thread::suspend"), error_code &ec = throws)#
+

The function suspend will return control to the thread manager (suspends the current thread). It sets the new state of this thread to suspended and schedules a wakeup for this threads after the given duration.

+
+

Note

+

Must be called from within a HPX-thread.

+
+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+inline threads::thread_restart_state suspend(hpx::chrono::steady_duration const &rel_time, threads::thread_id_type const &id, threads::thread_description const &description = threads::thread_description("this_thread::suspend"), error_code &ec = throws)#
+

The function suspend will return control to the thread manager (suspends the current thread). It sets the new state of this thread to suspended and schedules a wakeup for this threads after the given duration.

+
+

Note

+

Must be called from within a HPX-thread.

+
+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+inline threads::thread_restart_state suspend(std::uint64_t ms, threads::thread_description const &description = threads::thread_description("this_thread::suspend"), error_code &ec = throws)#
+

The function suspend will return control to the thread manager (suspends the current thread). It sets the new state of this thread to suspended and schedules a wakeup for this threads after the given time (specified in milliseconds).

+
+

Note

+

Must be called from within a HPX-thread.

+
+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+threads::thread_pool_base *get_pool(error_code &ec = throws)#
+

Returns a pointer to the pool that was used to run the current thread

+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+ +
+
+namespace threads
+
+

Functions

+
+
+thread_state set_thread_state(thread_id_type const &id, thread_schedule_state state = thread_schedule_state::pending, thread_restart_state stateex = thread_restart_state::signaled, thread_priority priority = thread_priority::normal, bool retry_on_active = true, hpx::error_code &ec = throws)#
+

Set the thread state of the thread referenced by the thread_id id.

+
+

Note

+

If the thread referenced by the parameter id is in thread_state::active state this function schedules a new thread which will set the state of the thread as soon as its not active anymore. The function returns thread_state::active in this case.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread the state should be modified for.

  • +
  • state – [in] The new state to be set for the thread referenced by the id parameter.

  • +
  • stateex – [in] The new extended state to be set for the thread referenced by the id parameter.

  • +
  • priority – [in]

  • +
  • retry_on_active – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns the previous state of the thread referenced by the id parameter. It will return one of the values as defined by the thread_state enumeration. If the thread is not known to the thread-manager the return value will be thread_state::unknown.

+
+
+
+ +
+
+thread_id_ref_type set_thread_state(thread_id_type const &id, hpx::chrono::steady_time_point const &abs_time, std::atomic<bool> *started, thread_schedule_state state = thread_schedule_state::pending, thread_restart_state stateex = thread_restart_state::timeout, thread_priority priority = thread_priority::normal, bool retry_on_active = true, error_code &ec = throws)#
+

Set the thread state of the thread referenced by the thread_id id.

+

Set a timer to set the state of the given thread to the given new value after it expired (at the given time)

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread the state should be modified for.

  • +
  • abs_time – [in] Absolute point in time for the new thread to be run

  • +
  • started – [in,out] A helper variable allowing to track the state of the timer helper thread

  • +
  • state – [in] The new state to be set for the thread referenced by the id parameter.

  • +
  • stateex – [in] The new extended state to be set for the thread referenced by the id parameter.

  • +
  • priority – [in]

  • +
  • retry_on_active – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

+
+
+
+ +
+
+inline thread_id_ref_type set_thread_state(thread_id_type const &id, hpx::chrono::steady_time_point const &abs_time, thread_schedule_state state = thread_schedule_state::pending, thread_restart_state stateex = thread_restart_state::timeout, thread_priority priority = thread_priority::normal, bool retry_on_active = true, error_code& = throws)#
+
+ +
+
+inline thread_id_ref_type set_thread_state(thread_id_type const &id, hpx::chrono::steady_duration const &rel_time, thread_schedule_state state = thread_schedule_state::pending, thread_restart_state stateex = thread_restart_state::timeout, thread_priority priority = thread_priority::normal, bool retry_on_active = true, error_code &ec = throws)#
+

Set the thread state of the thread referenced by the thread_id id.

+

Set a timer to set the state of the given thread to the given new value after it expired (after the given duration)

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread the state should be modified for.

  • +
  • rel_time – [in] Time duration after which the new thread should be run

  • +
  • state – [in] The new state to be set for the thread referenced by the id parameter.

  • +
  • stateex – [in] The new extended state to be set for the thread referenced by the id parameter.

  • +
  • priority – [in]

  • +
  • retry_on_active – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

+
+
+
+ +
+
+thread_state get_thread_state(thread_id_type const &id, error_code &ec = throws) noexcept#
+

The function get_thread_backtrace is part of the thread related API allows to query the currently stored thread back trace (which is captured during thread suspension).

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception. The function get_thread_state is part of the thread related API. It queries the state of one of the threads known to the thread-manager.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread being queried.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
  • id – [in] The thread id of the thread the state should be modified for.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns the currently captured stack back trace of the thread referenced by the id parameter. If the thread is not known to the thread-manager the return value will be the zero.

+
+
Returns
+

This function returns the thread state of the thread referenced by the id parameter. If the thread is not known to the thread-manager the return value will be terminated.

+
+
+
+ +
+
+std::size_t get_thread_phase(thread_id_type const &id, error_code &ec = throws) noexcept#
+

The function get_thread_phase is part of the thread related API. It queries the phase of one of the threads known to the thread-manager.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread the phase should be modified for.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns the thread phase of the thread referenced by the id parameter. If the thread is not known to the thread-manager the return value will be ~0.

+
+
+
+ +
+
+bool get_thread_interruption_enabled(thread_id_type const &id, error_code &ec = throws)#
+

Returns whether the given thread can be interrupted at this point.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread which should be queried.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns true if the given thread can be interrupted at this point in time. It will return false otherwise.

+
+
+
+ +
+
+bool set_thread_interruption_enabled(thread_id_type const &id, bool enable, error_code &ec = throws)#
+

Set whether the given thread can be interrupted at this point.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread which should receive the new value.

  • +
  • enable – [in] This value will determine the new interruption enabled status for the given thread.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns the previous value of whether the given thread could have been interrupted.

+
+
+
+ +
+
+bool get_thread_interruption_requested(thread_id_type const &id, error_code &ec = throws)#
+

Returns whether the given thread has been flagged for interruption.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread which should be queried.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns true if the given thread was flagged for interruption. It will return false otherwise.

+
+
+
+ +
+
+void interrupt_thread(thread_id_type const &id, bool flag, error_code &ec = throws)#
+

Flag the given thread for interruption.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread which should be interrupted.

  • +
  • flag – [in] The flag encodes whether the thread should be interrupted (if it is true), or ‘uninterrupted’ (if it is false).

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+inline void interrupt_thread(thread_id_type const &id, error_code &ec = throws)#
+
+ +
+
+void interruption_point(thread_id_type const &id, error_code &ec = throws)#
+

Interrupt the current thread at this point if it was canceled. This will throw a thread_interrupted exception, which will cancel the thread.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread which should be interrupted.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+threads::thread_priority get_thread_priority(thread_id_type const &id, error_code &ec = throws) noexcept#
+

Return priority of the given thread

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread whose priority is queried.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+std::ptrdiff_t get_stack_size(thread_id_type const &id, error_code &ec = throws) noexcept#
+

Return stack size of the given thread

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The thread id of the thread whose priority is queried.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+threads::thread_pool_base *get_pool(thread_id_type const &id, error_code &ec = throws)#
+

Returns a pointer to the pool that was used to run the current thread

+
+
Throws
+

If&ec != &throws, never throws, but will set ec to an appropriate value when an error occurs. Otherwise, this function will throw an hpx::exception with an error code of hpx::error::yield_aborted if it is signaled with wait_aborted. If called outside of a HPX-thread, this function will throw an hpx::exception with an error code of hpx::error::null_thread_id. If this function is called while the thread-manager is not running, it will throw an hpx::exception with an error code of hpx::error::invalid_status.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::get_worker_thread_num, hpx::get_local_worker_thread_num, hpx::get_local_worker_thread_num, hpx::get_thread_pool_num, hpx::get_thread_pool_num#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+std::size_t get_worker_thread_num()#
+

Return the number of the current OS-thread running in the runtime instance the current HPX-thread is executed with.

+

This function returns the zero based index of the OS-thread which executes the current HPX-thread.

+
+

Note

+

The returned value is zero based and its maximum value is smaller than the overall number of OS-threads executed (as returned by get_os_thread_count().

+
+
+

Note

+

This function needs to be executed on a HPX-thread. It will fail otherwise (it will return -1).

+
+
+ +
+
+std::size_t get_worker_thread_num(error_code &ec)#
+

Return the number of the current OS-thread running in the runtime instance the current HPX-thread is executed with.

+

This function returns the zero based index of the OS-thread which executes the current HPX-thread.

+
+

Note

+

The returned value is zero based and its maximum value is smaller than the overall number of OS-threads executed (as returned by get_os_thread_count(). It will return -1 if the current thread is not a known thread or if the runtime is not in running state.

+
+
+

Note

+

This function needs to be executed on a HPX-thread. It will fail otherwise (it will return -1).

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit.

+
+
+
+ +
+
+std::size_t get_local_worker_thread_num()#
+

Return the number of the current OS-thread running in the current thread pool the current HPX-thread is executed with.

+

This function returns the zero based index of the OS-thread on the current thread pool which executes the current HPX-thread.

+
+

Note

+

The returned value is zero based and its maximum value is smaller than the number of OS-threads executed on the current thread pool. It will return -1 if the current thread is not a known thread or if the runtime is not in running state.

+
+
+

Note

+

This function needs to be executed on a HPX-thread. It will fail otherwise (it will return -1).

+
+
+ +
+
+std::size_t get_local_worker_thread_num(error_code &ec)#
+

Return the number of the current OS-thread running in the current thread pool the current HPX-thread is executed with.

+

This function returns the zero based index of the OS-thread on the current thread pool which executes the current HPX-thread.

+
+

Note

+

The returned value is zero based and its maximum value is smaller than the number of OS-threads executed on the current thread pool. It will return -1 if the current thread is not a known thread or if the runtime is not in running state.

+
+
+

Note

+

This function needs to be executed on a HPX-thread. It will fail otherwise (it will return -1).

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit.

+
+
+
+ +
+
+std::size_t get_thread_pool_num()#
+

Return the number of the current thread pool the current HPX-thread is executed with.

+

This function returns the zero based index of the thread pool which executes the current HPX-thread.

+
+

Note

+

The returned value is zero based and its maximum value is smaller than the number of thread pools started by the runtime. It will return -1 if the current thread pool is not a known thread pool or if the runtime is not in running state.

+
+
+

Note

+

This function needs to be executed on a HPX-thread. It will fail otherwise (it will return -1).

+
+
+ +
+
+std::size_t get_thread_pool_num(error_code &ec)#
+

Return the number of the current thread pool the current HPX-thread is executed with.

+

This function returns the zero based index of the thread pool which executes the current HPX-thread.

+
+

Note

+

The returned value is zero based and its maximum value is smaller than the number of thread pools started by the runtime. It will return -1 if the current thread pool is not a known thread pool or if the runtime is not in running state.

+
+
+

Note

+

This function needs to be executed on a HPX-thread. It will fail otherwise (it will return -1).

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit.

+
+
+
+ +
+
+
+namespace threads
+
+ +
+ +
+
+
hpx/threading_base/thread_pool_base.hpp#
+

Defined in header hpx/threading_base/thread_pool_base.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace threads
+
+

Functions

+
+
+std::ostream &operator<<(std::ostream &os, thread_pool_base const &thread_pool)#
+
+ +
+
+
+class thread_pool_base#
+
+#include <thread_pool_base.hpp>
+

The base class used to manage a pool of OS threads.

+
+

Public Functions

+
+
+virtual void suspend_processing_unit_direct(std::size_t virt_core, error_code &ec = throws) = 0#
+

Suspends the given processing unit. Blocks until the processing unit has been suspended.

+
+
Parameters
+
    +
  • virt_core – [in] The processing unit on the the pool to be suspended. The processing units are indexed starting from 0.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+virtual void resume_processing_unit_direct(std::size_t virt_core, error_code &ec = throws) = 0#
+

Resumes the given processing unit. Blocks until the processing unit has been resumed.

+
+
Parameters
+
    +
  • virt_core – [in] The processing unit on the the pool to be resumed. The processing units are indexed starting from 0.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+virtual void resume_direct(error_code &ec = throws) = 0#
+

Resumes the thread pool. Blocks until all OS threads on the thread pool have been resumed.

+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
+
+ +
+
+virtual void suspend_direct(error_code &ec = throws) = 0#
+

Suspends the thread pool. Blocks until all OS threads on the thread pool have been suspended.

+
+

Note

+

A thread pool cannot be suspended from an HPX thread running on the pool itself.

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
Throws
+

hpx::exception – if called from an HPX thread which is running on the pool itself.

+
+
+
+ +
+
+ +
+
+struct thread_pool_init_parameters#
+
+

Public Functions

+
+
+inline thread_pool_init_parameters(std::string const &name, std::size_t index, policies::scheduler_mode mode, std::size_t num_threads, std::size_t thread_offset, hpx::threads::policies::callback_notifier &notifier, hpx::threads::policies::detail::affinity_data const &affinity_data, hpx::threads::detail::network_background_callback_type const &network_background_callback = hpx::threads::detail::network_background_callback_type(), std::size_t max_background_threads = static_cast<std::size_t>(-1), std::size_t max_idle_loop_count = HPX_IDLE_LOOP_COUNT_MAX, std::size_t max_busy_loop_count = HPX_BUSY_LOOP_COUNT_MAX, std::size_t shutdown_check_count = 10)#
+
+ +
+
+

Public Members

+
+
+std::string const &name_#
+
+ +
+
+std::size_t index_#
+
+ +
+
+policies::scheduler_mode mode_#
+
+ +
+
+std::size_t num_threads_#
+
+ +
+
+std::size_t thread_offset_#
+
+ +
+
+hpx::threads::policies::callback_notifier &notifier_#
+
+ +
+
+hpx::threads::policies::detail::affinity_data const &affinity_data_#
+
+ +
+
+hpx::threads::detail::network_background_callback_type const &network_background_callback_#
+
+ +
+
+std::size_t max_background_threads_#
+
+ +
+
+std::size_t max_idle_loop_count_#
+
+ +
+
+std::size_t max_busy_loop_count_#
+
+ +
+
+std::size_t shutdown_check_count_#
+
+ +
+
+ +
+ +
+ +
+
+
hpx/threading_base/threading_base_fwd.hpp#
+

Defined in header hpx/threading_base/threading_base_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace threads
+
+

Functions

+
+
+thread_data *get_self_id_data() noexcept#
+

The function get_self_id_data returns the data of the HPX thread id associated with the current thread (or nullptr if the current thread is not a HPX thread).

+
+ +
+
+thread_self &get_self()#
+

The function get_self returns a reference to the (OS thread specific) self reference to the current HPX thread.

+
+ +
+
+thread_self *get_self_ptr() noexcept
+

The function get_self_ptr returns a pointer to the (OS thread specific) self reference to the current HPX thread.

+
+ +
+
+thread_self_impl_type *get_ctx_ptr()#
+

The function get_ctx_ptr returns a pointer to the internal data associated with each coroutine.

+
+ +
+
+thread_self *get_self_ptr_checked(error_code &ec = throws)#
+

The function get_self_ptr_checked returns a pointer to the (OS thread specific) self reference to the current HPX thread.

+
+ +
+
+thread_id_type get_self_id() noexcept
+

The function get_self_id returns the HPX thread id of the current thread (or zero if the current thread is not a HPX thread).

+
+ +
+
+thread_id_type get_outer_self_id() noexcept#
+

The function get_outer_self_id returns the HPX thread id of the current outer thread (or zero if the current thread is not a HPX thread). This usually returns the same as get_self_id, except for directly executed threads, in which case this returns the thread id of the outermost HPX thread.

+
+ +
+
+thread_id_type get_parent_id() noexcept#
+

The function get_parent_id returns the HPX thread id of the current thread’s parent (or zero if the current thread is not a HPX thread).

+
+

Note

+

This function will return a meaningful value only if the code was compiled with HPX_HAVE_THREAD_PARENT_REFERENCE being defined.

+
+
+ +
+
+std::size_t get_parent_phase() noexcept#
+

The function get_parent_phase returns the HPX phase of the current thread’s parent (or zero if the current thread is not a HPX thread).

+
+

Note

+

This function will return a meaningful value only if the code was compiled with HPX_HAVE_THREAD_PARENT_REFERENCE being defined.

+
+
+ +
+
+std::ptrdiff_t get_self_stacksize() noexcept#
+

The function get_self_stacksize returns the stack size of the current thread (or zero if the current thread is not a HPX thread).

+
+ +
+
+thread_stacksize get_self_stacksize_enum() noexcept#
+

The function get_self_stacksize_enum returns the stack size of the /.

+
+ +
+
+std::uint32_t get_parent_locality_id() noexcept#
+

The function get_parent_locality_id returns the id of the locality of the current thread’s parent (or zero if the current thread is not a HPX thread).

+
+

Note

+

This function will return a meaningful value only if the code was compiled with HPX_HAVE_THREAD_PARENT_REFERENCE being defined.

+
+
+ +
+
+std::uint64_t get_self_component_id() noexcept#
+

The function get_self_component_id returns the lva of the component the current thread is acting on

+
+

Note

+

This function will return a meaningful value only if the code was compiled with HPX_HAVE_THREAD_TARGET_ADDRESS being defined.

+
+
+ +
+
+
+namespace policies#
+
+ +
+ +
+ +
+
+
+
+
threadmanager#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/modules/threadmanager.hpp#
+

Defined in header hpx/modules/threadmanager.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace threads
+
+
+class threadmanager#
+
+#include <threadmanager.hpp>
+

The thread-manager class is the central instance of management for all (non-depleted) threads

+
+

Public Types

+
+
+using notification_policy_type = threads::policies::callback_notifier#
+
+ +
+
+using pool_type = std::unique_ptr<thread_pool_base>#
+
+ +
+
+using pool_vector = std::vector<pool_type>#
+
+ +
+
+

Public Functions

+
+
+threadmanager(hpx::util::runtime_configuration &rtcfg_, notification_policy_type &notifier, detail::network_background_callback_type const &network_background_callback = detail::network_background_callback_type())#
+
+ +
+
+threadmanager(threadmanager const&) = delete#
+
+ +
+
+threadmanager(threadmanager&&) = delete#
+
+ +
+
+threadmanager &operator=(threadmanager const&) = delete#
+
+ +
+
+threadmanager &operator=(threadmanager&&) = delete#
+
+ +
+
+~threadmanager()#
+
+ +
+
+void init() const#
+
+ +
+
+void create_pools()#
+
+ +
+
+void print_pools(std::ostream&) const#
+

FIXME move to private and add &#8212;hpx:printpools cmd line option.

+
+ +
+
+thread_pool_base &default_pool() const#
+
+ +
+
+thread_pool_base &get_pool(std::string const &pool_name) const#
+
+ +
+
+thread_pool_base &get_pool(pool_id_type const &pool_id) const#
+
+ +
+
+thread_pool_base &get_pool(std::size_t thread_index) const#
+
+ +
+
+bool pool_exists(std::string const &pool_name) const#
+
+ +
+
+bool pool_exists(std::size_t pool_index) const#
+
+ +
+
+thread_id_ref_type register_work(thread_init_data &data, error_code &ec = throws) const#
+

The function register_work adds a new work item to the thread manager. It doesn’t immediately create a new thread, it just adds the task parameters (function, initial state and description) to the internal management data structures. The thread itself will be created when the number of existing threads drops below the number of threads specified by the constructors max_count parameter.

+
+
Parameters
+
    +
  • data – [in] The value of this parameter allows to specify a description of the thread to create. This information is used for logging purposes mainly, but might be useful for debugging as well. This parameter is optional and defaults to an empty string.

  • +
  • ec

  • +
+
+
+
+ +
+
+void register_thread(thread_init_data &data, thread_id_ref_type &id, error_code &ec = throws) const#
+

The function register_thread adds a new work item to the thread manager. It creates a new thread, adds it to the internal management data structures, and schedules the new thread, if appropriate.

+
+
Parameters
+
    +
  • data – [in] The value of this parameter allows to specify a description of the thread to create. This information is used for logging purposes mainly, but might be useful for debugging as well. This parameter is optional and defaults to an empty string.

  • +
  • id – [out] This parameter will hold the id of the created thread. This id is guaranteed to be validly initialized before the thread function is executed.

  • +
  • ec

  • +
+
+
+
+ +
+
+bool run() const#
+

Run the thread manager’s work queue. This function instantiates the specified number of OS threads in each pool. All OS threads are started to execute the function tfunc.

+
+
Returns
+

The function returns true if the thread manager has been started successfully, otherwise it returns false.

+
+
+
+ +
+
+void stop(bool blocking = true) const#
+

Forcefully stop the thread-manager.

+
+
Parameters
+

blocking

+
+
+
+ +
+
+bool is_busy() const#
+
+ +
+
+bool is_idle() const#
+
+ +
+
+void wait() const#
+
+ +
+
+bool wait_for(hpx::chrono::steady_duration const &rel_time) const#
+
+ +
+
+void suspend() const#
+
+ +
+
+void resume() const#
+
+ +
+
+hpx::state status() const#
+

Return whether the thread manager is still running This returns the “minimal state”, i.e. the state of the least advanced thread pool

+
+ +
+
+std::int64_t get_thread_count(thread_schedule_state state = thread_schedule_state::unknown, thread_priority priority = thread_priority::default_, std::size_t num_thread = static_cast<std::size_t>(-1), bool reset = false) const#
+

return the number of HPX-threads with the given state

+
+

Note

+

This function locks the internal OS lock in the thread manager

+
+
+ +
+
+std::int64_t get_idle_core_count() const#
+
+ +
+
+mask_type get_idle_core_mask() const#
+
+ +
+
+std::int64_t get_background_thread_count() const#
+
+ +
+
+bool enumerate_threads(hpx::function<bool(thread_id_type)> const &f, thread_schedule_state state = thread_schedule_state::unknown) const#
+
+ +
+
+void abort_all_suspended_threads() const#
+
+ +
+
+bool cleanup_terminated(bool delete_all) const#
+
+ +
+
+std::size_t get_os_thread_count() const#
+

Return the number of OS threads running in this thread-manager.

+

This function will return correct results only if the thread-manager is running.

+
+ +
+
+std::thread &get_os_thread_handle(std::size_t num_thread) const#
+
+ +
+
+void report_error(std::size_t num_thread, std::exception_ptr const &e) const#
+

API functions forwarding to notification policy.

+

This notifies the thread manager that the passed exception has been raised. The exception will be routed through the notifier and the scheduler (which will result in it being passed to the runtime object, which in turn will report it to the console, etc.).

+
+ +
+
+mask_type get_used_processing_units() const#
+

Returns the mask identifying all processing units used by this thread manager.

+
+ +
+
+hwloc_bitmap_ptr get_pool_numa_bitmap(std::string const &pool_name) const#
+
+ +
+
+void set_scheduler_mode(threads::policies::scheduler_mode mode) const noexcept#
+
+ +
+
+void add_scheduler_mode(threads::policies::scheduler_mode mode) const noexcept#
+
+ +
+
+void add_remove_scheduler_mode(threads::policies::scheduler_mode to_add_mode, threads::policies::scheduler_mode to_remove_mode) const noexcept#
+
+ +
+
+void remove_scheduler_mode(threads::policies::scheduler_mode mode) const noexcept#
+
+ +
+
+void reset_thread_distribution() const noexcept#
+
+ +
+
+std::int64_t get_queue_length(bool reset) const#
+
+ +
+
+std::int64_t get_cumulative_duration(bool reset) const#
+
+ +
+
+std::int64_t get_thread_count_unknown(bool reset) const#
+
+ +
+
+std::int64_t get_thread_count_active(bool reset) const#
+
+ +
+
+std::int64_t get_thread_count_pending(bool reset) const#
+
+ +
+
+std::int64_t get_thread_count_suspended(bool reset) const#
+
+ +
+
+std::int64_t get_thread_count_terminated(bool reset) const#
+
+ +
+
+std::int64_t get_thread_count_staged(bool reset) const#
+
+ +
+
+

Public Static Functions

+
+
+static void init_tss(std::size_t global_thread_num)#
+
+ +
+
+static void deinit_tss()#
+
+ +
+
+

Private Types

+
+
+using mutex_type = std::mutex#
+
+ +
+
+

Private Functions

+
+
+policies::thread_queue_init_parameters get_init_parameters() const#
+
+ +
+
+void create_scheduler_user_defined(hpx::resource::scheduler_function const&, thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&)#
+
+ +
+
+void create_scheduler_local(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+void create_scheduler_local_priority_fifo(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+void create_scheduler_local_priority_lifo(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+void create_scheduler_static(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+void create_scheduler_static_priority(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+void create_scheduler_abp_priority_fifo(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+void create_scheduler_abp_priority_lifo(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+void create_scheduler_shared_priority(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+void create_scheduler_local_workrequesting_fifo(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+void create_scheduler_local_workrequesting_lifo(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+void create_scheduler_local_workrequesting_mc(thread_pool_init_parameters const&, policies::thread_queue_init_parameters const&, std::size_t)#
+
+ +
+
+

Private Members

+
+
+mutable mutex_type mtx_#
+
+ +
+
+hpx::util::runtime_configuration &rtcfg_#
+
+ +
+
+std::vector<pool_id_type> threads_lookup_#
+
+ +
+
+pool_vector pools_#
+
+ +
+
+notification_policy_type &notifier_#
+
+ +
+
+detail::network_background_callback_type network_background_callback_#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
timed_execution#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/timed_execution/timed_execution.hpp#
+

Defined in header hpx/timed_execution/timed_execution.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+ +
+ +
+ +
+
+
hpx/timed_execution/timed_execution_fwd.hpp#
+

Defined in header hpx/timed_execution/timed_execution_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Variables

+
+
+hpx::parallel::execution::post_at_t post_at#
+
+ +
+
+hpx::parallel::execution::post_after_t post_after#
+
+ +
+
+hpx::parallel::execution::async_execute_at_t async_execute_at#
+
+ +
+
+hpx::parallel::execution::async_execute_after_t async_execute_after#
+
+ +
+
+hpx::parallel::execution::sync_execute_at_t sync_execute_at#
+
+ +
+
+hpx::parallel::execution::sync_execute_after_t sync_execute_after#
+
+ +
+
+
+struct async_execute_after_t : public hpx::functional::detail::tag_fallback<async_execute_after_t>#
+
+#include <timed_execution_fwd.hpp>
+

Customization point of asynchronous execution agent creation supporting timed execution.

+

This asynchronously creates a single function invocation f() using the associated executor at the given point in time.

+
+

Note

+

This calls exec.async_execute_after(rel_time, f, ts…), if available, otherwise it emulates timed scheduling by delaying calling execution::async_execute() on the underlying non-time-scheduled execution agent.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param rel_time
+

[in] The duration of time after which the given function should be scheduled to run.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param ts…
+

[in] Additional arguments to use to invoke f.

+
+
Return
+

f(ts…)’s result through a future

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(async_execute_after_t, Executor &&exec, hpx::chrono::steady_duration const &rel_time, F &&f, Ts&&... ts)#
+
+ +
+
+ +
+
+struct async_execute_at_t : public hpx::functional::detail::tag_fallback<async_execute_at_t>#
+
+#include <timed_execution_fwd.hpp>
+

Customization point of asynchronous execution agent creation supporting timed execution.

+

This asynchronously creates a single function invocation f() using the associated executor at the given point in time.

+
+

Note

+

This calls exec.async_execute_at(abs_time, f, ts…), if available, otherwise it emulates timed scheduling by delaying calling execution::async_execute() on the underlying non-time-scheduled execution agent.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param abs_time
+

[in] The point in time the given function should be scheduled at to run.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param ts…
+

[in] Additional arguments to use to invoke f.

+
+
Return
+

f(ts…)’s result through a future

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(async_execute_at_t, Executor &&exec, hpx::chrono::steady_time_point const &abs_time, F &&f, Ts&&... ts)#
+
+ +
+
+ +
+
+struct post_after_t : public hpx::functional::detail::tag_fallback<post_after_t>#
+
+#include <timed_execution_fwd.hpp>
+

Customization point of asynchronous fire & forget execution agent creation supporting timed execution.

+

This asynchronously (fire & forget) creates a single function invocation f() using the associated executor at the given point in time.

+
+

Note

+

This calls exec.post_after(rel_time, f, ts…), if available, otherwise it emulates timed scheduling by delaying calling execution::post() on the underlying non-time-scheduled execution agent.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param rel_time
+

[in] The duration of time after which the given function should be scheduled to run.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param ts…
+

[in] Additional arguments to use to invoke f.

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(post_after_t, Executor &&exec, hpx::chrono::steady_duration const &rel_time, F &&f, Ts&&... ts)#
+
+ +
+
+ +
+
+struct post_at_t : public hpx::functional::detail::tag_fallback<post_at_t>#
+
+#include <timed_execution_fwd.hpp>
+

Customization point of asynchronous fire & forget execution agent creation supporting timed execution.

+

This asynchronously (fire & forget) creates a single function invocation f() using the associated executor at the given point in time.

+
+

Note

+

This calls exec.post_at(abs_time, f, ts…), if available, otherwise it emulates timed scheduling by delaying calling execution::post() on the underlying non-time-scheduled execution agent.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param abs_time
+

[in] The point in time the given function should be scheduled at to run.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param ts…
+

[in] Additional arguments to use to invoke f.

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(post_at_t, Executor &&exec, hpx::chrono::steady_time_point const &abs_time, F &&f, Ts&&... ts)#
+
+ +
+
+ +
+
+struct sync_execute_after_t : public hpx::functional::detail::tag_fallback<sync_execute_after_t>#
+
+#include <timed_execution_fwd.hpp>
+

Customization point of synchronous execution agent creation supporting timed execution.

+

This synchronously creates a single function invocation f() using the associated executor at the given point in time.

+
+

Note

+

This calls exec.sync_execute_after(rel_time, f, ts…), if available, otherwise it emulates timed scheduling by delaying calling execution::sync_execute() on the underlying non-time-scheduled execution agent.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param rel_time
+

[in] The duration of time after which the given function should be scheduled to run.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param ts…
+

[in] Additional arguments to use to invoke f.

+
+
Return
+

f(ts…)’s result

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(sync_execute_after_t, Executor &&exec, hpx::chrono::steady_duration const &rel_time, F &&f, Ts&&... ts)#
+
+ +
+
+ +
+
+struct sync_execute_at_t : public hpx::functional::detail::tag_fallback<sync_execute_at_t>#
+
+#include <timed_execution_fwd.hpp>
+

Customization point of synchronous execution agent creation supporting timed execution.

+

This synchronously creates a single function invocation f() using the associated executor at the given point in time.

+
+

Note

+

This calls exec.sync_execute_at(abs_time, f, ts…), if available, otherwise it emulates timed scheduling by delaying calling execution::sync_execute() on the underlying non-time-scheduled execution agent.

+
+
+
Param exec
+

[in] The executor object to use for scheduling of the function f.

+
+
Param abs_time
+

[in] The point in time the given function should be scheduled at to run.

+
+
Param f
+

[in] The function which will be scheduled using the given executor.

+
+
Param ts…
+

[in] Additional arguments to use to invoke f.

+
+
Return
+

f(ts…)’s result

+
+
+
+

Private Functions

+
+
+template<typename Executor, typename F, typename ...Ts>
inline decltype(auto) friend tag_fallback_invoke(sync_execute_at_t, Executor &&exec, hpx::chrono::steady_time_point const &abs_time, F &&f, Ts&&... ts)#
+
+ +
+
+ +
+
+template<typename BaseExecutor>
struct timed_executor#
+
+ +
+ +
+ +
+ +
+
+
hpx/timed_execution/timed_executors.hpp#
+

Defined in header hpx/timed_execution/timed_executors.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Typedefs

+
+
+using sequenced_timed_executor = timed_executor<hpx::execution::sequenced_executor>#
+
+ +
+
+using parallel_timed_executor = timed_executor<hpx::execution::parallel_executor>#
+
+ +
+
+
+template<typename BaseExecutor>
struct timed_executor
+
+ +
+ +
+ +
+ +
+
+
hpx/timed_execution/traits/is_timed_executor.hpp#
+

Defined in header hpx/timed_execution/traits/is_timed_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Typedefs

+
+
+template<typename T>
using is_timed_executor_t = typename is_timed_executor<T>::type#
+
+ +
+
+

Variables

+
+
+template<typename T>
constexpr bool is_timed_executor_v = is_timed_executor<T>::value#
+
+ +
+
+
+template<typename T>
struct is_timed_executor : public detail::is_timed_executor<std::decay_t<T>>#
+
+ +
+ +
+ +
+
+namespace traits
+
+
+template<typename Executor, typename Enable = void>
struct is_timed_executor : public hpx::parallel::execution::is_timed_executor<Executor>#
+
+ +
+ +
+ +
+
+
+
+
timing#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::chrono::high_resolution_clock#
+

Defined in header hpx/chrono.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace chrono#
+
+
+struct high_resolution_clock#
+
+#include <high_resolution_clock.hpp>
+

Class hpx::chrono::high_resolution_clock represents the clock with the smallest tick period provided by the implementation. It may be an alias of std::chrono::system_clock or std::chrono::steady_clock, or a third, independent clock. hpx::chrono::high_resolution_clock meets the requirements of TrivialClock.

+
+

Public Static Functions

+
+
+static inline std::uint64_t now() noexcept#
+

returns a std::chrono::time_point representing the current value of the clock

+
+ +
+
+static inline constexpr std::uint64_t() min () noexcept
+
+ +
+
+static inline constexpr std::uint64_t() max () noexcept
+
+ +
+
+ +
+ +
+ +
+
+
hpx::chrono::high_resolution_timer#
+

Defined in header hpx/chrono.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace chrono
+
+
+class high_resolution_timer#
+
+#include <high_resolution_timer.hpp>
+

high_resolution_timer is a timer object which measures the elapsed time

+
+

Public Types

+
+
+enum class init#
+

Values:

+
+
+enumerator no_init#
+
+ +
+ +
+
+

Public Functions

+
+
+inline high_resolution_timer() noexcept#
+
+ +
+
+inline explicit constexpr high_resolution_timer(init) noexcept#
+
+ +
+
+inline explicit constexpr high_resolution_timer(double t) noexcept#
+
+ +
+
+inline void restart() noexcept#
+

restarts the timer

+
+ +
+
+inline double elapsed() const noexcept#
+

returns the elapsed time in seconds

+
+ +
+
+inline std::int64_t elapsed_microseconds() const noexcept#
+

returns the elapsed time in microseconds

+
+ +
+
+inline std::int64_t elapsed_nanoseconds() const noexcept#
+

returns the elapsed time in nanoseconds

+
+ +
+
+

Public Static Functions

+
+
+static inline double now() noexcept#
+

returns the current time

+
+ +
+
+static inline constexpr double elapsed_max() noexcept#
+

returns the estimated maximum value for elapsed()

+
+ +
+
+static inline constexpr double elapsed_min() noexcept#
+

returns the estimated minimum value for elapsed()

+
+ +
+
+

Protected Static Functions

+
+
+static inline std::uint64_t take_time_stamp() noexcept#
+
+ +
+
+

Private Members

+
+
+std::uint64_t start_time_#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
topology#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/topology/cpu_mask.hpp#
+

Defined in header hpx/topology/cpu_mask.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace threads
+
+ +
+ +
+
+
hpx/topology/topology.hpp#
+

Defined in header hpx/topology/topology.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace threads
+
+

Typedefs

+
+
+using hwloc_bitmap_ptr = std::shared_ptr<hpx_hwloc_bitmap_wrapper>#
+
+ +
+
+

Enums

+
+
+enum hpx_hwloc_membind_policy#
+

Please see hwloc documentation for the corresponding enums HWLOC_MEMBIND_XXX.

+

Values:

+
+
+enumerator membind_default#
+
+ +
+
+enumerator membind_firsttouch#
+
+ +
+
+enumerator membind_bind#
+
+ +
+
+enumerator membind_interleave#
+
+ +
+
+enumerator membind_replicate#
+
+ +
+
+enumerator membind_nexttouch#
+
+ +
+
+enumerator membind_mixed#
+
+ +
+
+enumerator membind_user#
+
+ +
+ +
+
+

Functions

+
+
+topology &create_topology()#
+
+ +
+
+inline std::size_t get_memory_page_size()#
+
+ +
+
+
+struct hpx_hwloc_bitmap_wrapper#
+
+

Public Functions

+
+
+HPX_NON_COPYABLE(hpx_hwloc_bitmap_wrapper)#
+
+ +
+
+inline hpx_hwloc_bitmap_wrapper() noexcept#
+
+ +
+
+inline explicit hpx_hwloc_bitmap_wrapper(void *bmp) noexcept#
+
+ +
+
+inline ~hpx_hwloc_bitmap_wrapper()#
+
+ +
+
+inline void reset(hwloc_bitmap_t bmp) noexcept#
+
+ +
+
+inline explicit constexpr operator bool() const noexcept#
+
+ +
+
+inline hwloc_bitmap_t get_bmp() const noexcept#
+
+ +
+
+

Private Members

+
+
+hwloc_bitmap_t bmp_#
+
+ +
+
+

Friends

+
+
+friend std::ostream &operator<<(std::ostream &os, hpx_hwloc_bitmap_wrapper const *bmp)#
+
+ +
+
+ +
+
+struct topology#
+
+

Public Functions

+
+
+topology()#
+
+ +
+
+topology(topology const&) = delete#
+
+ +
+
+topology(topology&&) = delete#
+
+ +
+
+topology &operator=(topology const&) = delete#
+
+ +
+
+topology &operator=(topology&&) = delete#
+
+ +
+
+~topology()#
+
+ +
+
+inline std::size_t get_socket_number(std::size_t num_thread, [[maybe_unused]] error_code &ec = throws) const noexcept#
+

Return the Socket number of the processing unit the given thread is running on.

+
+
Parameters
+
    +
  • num_thread – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+inline std::size_t get_numa_node_number(std::size_t num_thread, [[maybe_unused]] error_code &ec = throws) const noexcept#
+

Return the NUMA node number of the processing unit the given thread is running on.

+
+
Parameters
+
    +
  • num_thread – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+mask_cref_type get_machine_affinity_mask(error_code &ec = throws) const noexcept#
+

Return a bit mask where each set bit corresponds to a processing unit available to the application.

+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
+
+ +
+
+mask_type get_service_affinity_mask(mask_cref_type used_processing_units, error_code &ec = throws) const#
+

Return a bit mask where each set bit corresponds to a processing unit available to the service threads in the application.

+
+
Parameters
+
    +
  • used_processing_units – [in] This is the mask of processing units which are not available for service threads.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+mask_cref_type get_socket_affinity_mask(std::size_t num_thread, error_code &ec = throws) const#
+

Return a bit mask where each set bit corresponds to a processing unit available to the given thread inside the socket it is running on.

+
+
Parameters
+
    +
  • num_thread – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+mask_cref_type get_numa_node_affinity_mask(std::size_t num_thread, error_code &ec = throws) const#
+

Return a bit mask where each set bit corresponds to a processing unit available to the given thread inside the NUMA domain it is running on.

+
+
Parameters
+
    +
  • num_thread – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+mask_cref_type get_core_affinity_mask(std::size_t num_thread, error_code &ec = throws) const#
+

Return a bit mask where each set bit corresponds to a processing unit available to the given thread inside the core it is running on.

+
+
Parameters
+
    +
  • num_thread – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+mask_cref_type get_thread_affinity_mask(std::size_t num_thread, error_code &ec = throws) const#
+

Return a bit mask where each set bit corresponds to a processing unit available to the given thread.

+
+
Parameters
+
    +
  • num_thread – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+void set_thread_affinity_mask(mask_cref_type mask, error_code &ec = throws) const#
+

Use the given bit mask to set the affinity of the given thread. Each set bit corresponds to a processing unit the thread will be allowed to run on.

+
+

Note

+

Use this function on systems where the affinity must be set from inside the thread itself.

+
+
+
Parameters
+
    +
  • mask – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+mask_type get_thread_affinity_mask_from_lva(void const *lva, error_code &ec = throws) const#
+

Return a bit mask where each set bit corresponds to a processing unit co-located with the memory the given address is currently allocated on.

+
+
Parameters
+
    +
  • lva – [in]

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+void print_affinity_mask(std::ostream &os, std::size_t num_thread, mask_cref_type m, std::string const &pool_name) const#
+

Prints the given mask m to os in a human readable form.

+
+ +
+
+bool reduce_thread_priority(error_code &ec = throws) const#
+

Reduce thread priority of the current thread.

+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
+
+ +
+
+std::size_t get_number_of_sockets() const#
+

Return the number of available NUMA domains.

+
+ +
+
+std::size_t get_number_of_numa_nodes() const#
+

Return the number of available NUMA domains.

+
+ +
+
+std::size_t get_number_of_cores() const#
+

Return the number of available cores.

+
+ +
+
+std::size_t get_number_of_pus() const noexcept#
+

Return the number of available hardware processing units.

+
+ +
+
+std::size_t get_number_of_numa_node_cores(std::size_t numa) const#
+

Return number of cores in given numa domain.

+
+ +
+
+std::size_t get_number_of_numa_node_pus(std::size_t numa) const#
+

Return number of processing units in a given numa domain.

+
+ +
+
+std::size_t get_number_of_socket_pus(std::size_t socket) const#
+

Return number of processing units in a given socket.

+
+ +
+
+std::size_t get_number_of_core_pus(std::size_t core) const#
+

Return number of processing units in given core.

+
+ +
+
+std::size_t get_number_of_socket_cores(std::size_t socket) const#
+

Return number of cores units in given socket.

+
+ +
+
+inline std::size_t get_core_number(std::size_t num_thread, error_code& = throws) const#
+
+ +
+
+std::size_t get_pu_number(std::size_t num_core, std::size_t num_pu, error_code &ec = throws) const#
+
+ +
+
+std::size_t get_cache_size(mask_cref_type mask, int level) const#
+

Return the size of the cache associated with the given mask.

+
+ +
+
+mask_type get_cpubind_mask(error_code &ec = throws) const#
+
+ +
+
+mask_type get_cpubind_mask(std::thread &handle, error_code &ec = throws) const#
+
+ +
+
+hwloc_bitmap_ptr cpuset_to_nodeset(mask_cref_type mask) const#
+

convert a cpu mask into a numa node mask in hwloc bitmap form

+
+ +
+
+void write_to_log() const#
+
+ +
+
+void *allocate(std::size_t len) const#
+

This is equivalent to malloc(), except that it tries to allocate page-aligned memory from the OS.

+
+ +
+
+void *allocate_membind(std::size_t len, const hwloc_bitmap_ptr &bitmap, hpx_hwloc_membind_policy policy, int flags) const#
+

allocate memory with binding to a numa node set as specified by the policy and flags (see hwloc docs)

+
+ +
+
+threads::mask_type get_area_membind_nodeset(void const *addr, std::size_t len) const#
+
+ +
+
+bool set_area_membind_nodeset(void const *addr, std::size_t len, void *nodeset) const#
+
+ +
+
+int get_numa_domain(void const *addr) const#
+
+ +
+
+void deallocate(void *addr, std::size_t len) const noexcept#
+

Free memory that was previously allocated by allocate.

+
+ +
+
+void print_hwloc(std::ostream&) const#
+
+ +
+
+mask_type init_socket_affinity_mask_from_socket(std::size_t num_socket) const#
+
+ +
+
+mask_type init_numa_node_affinity_mask_from_numa_node(std::size_t num_numa_node) const#
+
+ +
+
+mask_type init_core_affinity_mask_from_core(std::size_t num_core, mask_cref_type default_mask = empty_mask) const#
+
+ +
+
+mask_type init_thread_affinity_mask(std::size_t num_thread) const#
+
+ +
+
+mask_type init_thread_affinity_mask(std::size_t num_core, std::size_t num_pu) const#
+
+ +
+
+hwloc_bitmap_t mask_to_bitmap(mask_cref_type mask, hwloc_obj_type_t htype) const#
+
+ +
+
+mask_type bitmap_to_mask(hwloc_bitmap_t bitmap, hwloc_obj_type_t htype) const#
+
+ +
+
+

Public Static Functions

+
+
+static void print_vector(std::ostream &os, std::vector<std::size_t> const &v)#
+
+ +
+
+static void print_mask_vector(std::ostream &os, std::vector<mask_type> const &v)#
+
+ +
+
+

Private Types

+
+
+using mutex_type = hpx::util::spinlock#
+
+ +
+
+

Private Functions

+
+
+std::size_t init_node_number(std::size_t num_thread, hwloc_obj_type_t type) const#
+
+ +
+
+inline std::size_t init_socket_number(std::size_t num_thread) const#
+
+ +
+
+std::size_t init_numa_node_number(std::size_t num_thread) const#
+
+ +
+
+inline std::size_t init_core_number(std::size_t num_thread) const#
+
+ +
+
+void extract_node_mask(hwloc_obj_t parent, mask_type &mask) const#
+
+ +
+
+std::size_t get_number_of_core_pus_locked(std::size_t core) const#
+
+ +
+
+std::size_t extract_node_count(hwloc_obj_t parent, hwloc_obj_type_t type, std::size_t count) const#
+
+ +
+
+std::size_t extract_node_count_locked(hwloc_obj_t parent, hwloc_obj_type_t type, std::size_t count) const#
+
+ +
+
+mask_type init_machine_affinity_mask() const#
+
+ +
+
+inline mask_type init_socket_affinity_mask(std::size_t num_thread) const#
+
+ +
+
+inline mask_type init_numa_node_affinity_mask(std::size_t num_thread) const#
+
+ +
+
+inline mask_type init_core_affinity_mask(std::size_t num_thread) const#
+
+ +
+
+void init_num_of_pus()#
+
+ +
+
+hwloc_obj_t get_pu_obj(std::size_t num_pu) const#
+
+ +
+
+

Private Members

+
+
+hwloc_topology_t topo = nullptr#
+
+ +
+
+std::size_t num_of_pus_ = 0#
+
+ +
+
+bool use_pus_as_cores_ = false#
+
+ +
+
+mutable mutex_type topo_mtx#
+
+ +
+
+std::vector<std::size_t> socket_numbers_#
+
+ +
+
+std::vector<std::size_t> numa_node_numbers_#
+
+ +
+
+std::vector<std::size_t> core_numbers_#
+
+ +
+
+mask_type machine_affinity_mask_ = mask_type()#
+
+ +
+
+std::vector<mask_type> socket_affinity_masks_#
+
+ +
+
+std::vector<mask_type> numa_node_affinity_masks_#
+
+ +
+
+std::vector<mask_type> core_affinity_masks_#
+
+ +
+
+std::vector<mask_type> thread_affinity_masks_#
+
+ +
+
+

Private Static Attributes

+
+
+static mask_type empty_mask#
+
+ +
+
+static std::size_t memory_page_size_#
+
+ +
+
+static constexpr std::size_t pu_offset = 0#
+
+ +
+
+static constexpr std::size_t core_offset = 0#
+
+ +
+
+

Friends

+
+
+friend std::size_t get_memory_page_size()#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
util#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/util/insert_checked.hpp#
+

Defined in header hpx/util/insert_checked.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+

Functions

+
+
+template<typename Iterator>
constexpr bool insert_checked(std::pair<Iterator, bool> const &r) noexcept#
+

Helper function for writing predicates that test whether an std::map insertion succeeded. This inline template function negates the need to explicitly write the sometimes lengthy std::pair<Iterator, bool> type.

+
+
Parameters
+

r – [in] The return value of a std::map insert operation.

+
+
Returns
+

This function returns r.second.

+
+
+
+ +
+
+template<typename Iterator>
bool insert_checked(std::pair<Iterator, bool> const &r, Iterator &it)#
+

Helper function for writing predicates that test whether an std::map insertion succeeded. This inline template function negates the need to explicitly write the sometimes lengthy std::pair<Iterator, bool> type.

+
+
Parameters
+
    +
  • r – [in] The return value of a std::map insert operation.

  • +
  • r – [out] A reference to an Iterator, which is set to r.first.

  • +
  • it – [out] on exit, will hold the iterator referring to the inserted element

  • +
+
+
Returns
+

This function returns r.second.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/util/sed_transform.hpp#
+

Defined in header hpx/util/sed_transform.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+

Functions

+
+
+bool parse_sed_expression(std::string const &input, std::string &search, std::string &replace)#
+

Parse a sed command.

+
+

Note

+

Currently, only supports search and replace syntax (s/search/replace/)

+
+
+
Parameters
+
    +
  • input – [in] The content to parse.

  • +
  • search – [out] If the parsing is successful, this string is set to the search expression.

  • +
  • replace – [out] If the parsing is successful, this string is set to the replace expression.

  • +
+
+
Returns
+

true if the parsing was successful, false otherwise.

+
+
+
+ +
+
+
+struct sed_transform#
+
+#include <sed_transform.hpp>
+

An unary function object which applies a sed command to its subject and returns the resulting string.

+
+

Note

+

Currently, only supports search and replace syntax (s/search/replace/)

+
+
+

Public Functions

+
+
+sed_transform(std::string const &search, std::string replace)#
+
+ +
+
+explicit sed_transform(std::string const &expression)#
+
+ +
+
+std::string operator()(std::string const &input) const#
+
+ +
+
+inline explicit operator bool() const noexcept#
+
+ +
+
+inline bool operator!() const noexcept#
+
+ +
+
+

Private Members

+
+
+std::shared_ptr<command> command_#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
actions#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/actions/action_support.hpp#
+

Defined in header hpx/actions/action_support.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/actions/actions_fwd.hpp#
+

Defined in header hpx/actions/actions_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/actions/base_action.hpp#
+

Defined in header hpx/actions/base_action.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/actions/transfer_action.hpp#
+

Defined in header hpx/actions/transfer_action.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/actions/transfer_base_action.hpp#
+

Defined in header hpx/actions/transfer_base_action.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
+
+
actions_base#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/actions_base/actions_base_fwd.hpp#
+

Defined in header hpx/actions_base/actions_base_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace actions#
+
+ +
+ +
+
+
hpx/actions_base/actions_base_support.hpp#
+

Defined in header hpx/actions_base/actions_base_support.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace actions
+
+ +
+ +
+
+
HPX_REGISTER_ACTION_DECLARATION, HPX_REGISTER_ACTION#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_ACTION_DECLARATION(...)#
+

Declare the necessary component action boilerplate code.

+

The macro HPX_REGISTER_ACTION_DECLARATION can be used to declare all the boilerplate code which is required for proper functioning of component actions in the context of HPX.

+

The parameter action is the type of the action to declare the boilerplate for.

+

This macro can be invoked with an optional second parameter. This parameter specifies a unique name of the action to be used for serialization purposes. The second parameter has to be specified if the first parameter is not usable as a plain (non-qualified) C++ identifier, i.e. the first parameter contains special characters which cannot be part of a C++ identifier, such as ‘<’, ‘>’, or ‘:’.

+

namespace app
+{
+    // Define a simple component exposing one action 'print_greeting'
+    class HPX_COMPONENT_EXPORT server
+      : public hpx::components::component_base<server>
+    {
+        void print_greeting ()
+        {
+            hpx::cout << "Hey, how are you?\n" << std::flush;
+        }
+
+        // Component actions need to be declared, this also defines the
+        // type 'print_greeting_action' representing the action.
+        HPX_DEFINE_COMPONENT_ACTION(server,
+            print_greeting, print_greeting_action);
+    };
+}
+
+// Declare boilerplate code required for each of the component actions.
+HPX_REGISTER_ACTION_DECLARATION(app::server::print_greeting_action)
+
+
+
+
Example:

+
+
+

+
+

Note

+

This macro has to be used once for each of the component actions defined using one of the HPX_DEFINE_COMPONENT_ACTION macros. It has to be visible in all translation units using the action, thus it is recommended to place it into the header file defining the component.

+
+
+ +
+
+HPX_REGISTER_ACTION_DECLARATION_(...)#
+
+ +
+
+HPX_REGISTER_ACTION_DECLARATION_1(action)#
+
+ +
+
+HPX_REGISTER_ACTION(...)#
+

Define the necessary component action boilerplate code.

+

The macro HPX_REGISTER_ACTION can be used to define all the boilerplate code which is required for proper functioning of component actions in the context of HPX.

+

The parameter action is the type of the action to define the boilerplate for.

+

This macro can be invoked with an optional second parameter. This parameter specifies a unique name of the action to be used for serialization purposes. The second parameter has to be specified if the first parameter is not usable as a plain (non-qualified) C++ identifier, i.e. the first parameter contains special characters which cannot be part of a C++ identifier, such as ‘<’, ‘>’, or ‘:’.

+
+

Note

+

This macro has to be used once for each of the component actions defined using one of the HPX_DEFINE_COMPONENT_ACTION or HPX_DEFINE_PLAIN_ACTION macros. It has to occur exactly once for each of the actions, thus it is recommended to place it into the source file defining the component.

+
+
+

Note

+

Only one of the forms of this macro HPX_REGISTER_ACTION or HPX_REGISTER_ACTION_ID should be used for a particular action, never both.

+
+
+ +
+
+HPX_REGISTER_ACTION_ID(action, actionname, actionid)#
+

Define the necessary component action boilerplate code and assign a predefined unique id to the action.

+

The macro HPX_REGISTER_ACTION can be used to define all the boilerplate code which is required for proper functioning of component actions in the context of HPX.

+

The parameter action is the type of the action to define the boilerplate for.

+

The parameter actionname specifies an unique name of the action to be used for serialization purposes. The second parameter has to be usable as a plain (non-qualified) C++ identifier, it should not contain special characters which cannot be part of a C++ identifier, such as ‘<’, ‘>’, or ‘:’.

+

The parameter actionid specifies an unique integer value which will be used to represent the action during serialization.

+
+

Note

+

This macro has to be used once for each of the component actions defined using one of the HPX_DEFINE_COMPONENT_ACTION or global actions HPX_DEFINE_PLAIN_ACTION macros. It has to occur exactly once for each of the actions, thus it is recommended to place it into the source file defining the component.

+
+
+

Note

+

Only one of the forms of this macro HPX_REGISTER_ACTION or HPX_REGISTER_ACTION_ID should be used for a particular action, never both.

+
+
+ +
+
+
+namespace hpx
+
+
+namespace actions
+
+ +
+ +
+
+
hpx/actions_base/basic_action_fwd.hpp#
+

Defined in header hpx/actions_base/basic_action_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace actions
+
+
+template<typename Component, typename Signature, typename Derived>
struct basic_action#
+
+#include <basic_action_fwd.hpp>
+
+
Template Parameters
+
    +
  • Component – component type

  • +
  • Signature – return type and arguments

  • +
  • Derived – derived action class

  • +
+
+
+
+ +
+ +
+ +
+
+
HPX_DEFINE_COMPONENT_ACTION#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_DEFINE_COMPONENT_ACTION(...)#
+

Registers a member function of a component as an action type with HPX.

+

The macro HPX_DEFINE_COMPONENT_ACTION can be used to register a member function of a component as an action type named action_type.

+

The parameter component is the type of the component exposing the member function func which should be associated with the newly defined action type. The parameter action_type is the name of the action type to register with HPX.

+

namespace app
+{
+    // Define a simple component exposing one action 'print_greeting'
+    class HPX_COMPONENT_EXPORT server
+      : public hpx::components::component_base<server>
+    {
+        void print_greeting() const
+        {
+            hpx::cout << "Hey, how are you?\n" << std::flush;
+        }
+
+        // Component actions need to be declared, this also defines the
+        // type 'print_greeting_action' representing the action.
+        HPX_DEFINE_COMPONENT_ACTION(server, print_greeting,
+            print_greeting_action);
+    };
+}
+
+
+
+
Example:

+
+
+

+

The first argument must provide the type name of the component the action is defined for.

+

The second argument must provide the member function name the action should wrap.

+

+The default value for the third argument (the typename of the defined action) is derived from the name of the function (as passed as the second argument) by appending ‘_action’. The third argument can be omitted only if the second argument with an appended suffix ‘_action’ resolves to a valid, unqualified C++ type name.

+
+

Note

+

The macro HPX_DEFINE_COMPONENT_ACTION can be used with 2 or 3 arguments. The third argument is optional.

+
+
+ +
+
+
+namespace hpx
+
+
+namespace actions
+
+ +
+ +
+
+
hpx/actions_base/lambda_to_action.hpp#
+

Defined in header hpx/actions_base/lambda_to_action.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/actions_base/plain_action.hpp#
+

Defined in header hpx/actions_base/plain_action.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_DEFINE_PLAIN_ACTION(...)#
+

Defines a plain action type.

+

namespace app
+{
+    void some_global_function(double d)
+    {
+        cout << d;
+    }
+
+    // This will define the action type 'app::some_global_action' which
+    // represents the function 'app::some_global_function'.
+    HPX_DEFINE_PLAIN_ACTION(some_global_function, some_global_action);
+}
+
+
+
+
Example:

+
+
+

+
+

Note

+

Usually this macro will not be used in user code unless the intent is to avoid defining the action_type in global namespace. Normally, the use of the macro HPX_PLAIN_ACTION is recommended.

+
+
+

Note

+

The macro HPX_DEFINE_PLAIN_ACTION can be used with 1 or 2 arguments. The second argument is optional. The default value for the second argument (the typename of the defined action) is derived from the name of the function (as passed as the first argument) by appending ‘_action’. The second argument can be omitted only if the first argument with an appended suffix ‘_action’ resolves to a valid, unqualified C++ type name.

+
+
+ +
+
+HPX_DECLARE_PLAIN_ACTION(...)#
+

Declares a plain action type.

+
+ +
+
+HPX_PLAIN_ACTION(...)#
+

Defines a plain action type based on the given function func and registers it with HPX.

+

The macro HPX_PLAIN_ACTION can be used to define a plain action (e.g. an action encapsulating a global or free function) based on the given function func. It defines the action type name representing the given function. This macro additionally registers the newly define action type with HPX.

+

The parameter func is a global or free (non-member) function which should be encapsulated into a plain action. The parameter name is the name of the action type defined by this macro.

+

namespace app {
+    void some_global_function(double d) {
+        cout << d;
+    }
+}
+
+// This will define the action type 'some_global_action' which
+// represents the function 'app::some_global_function'.
+HPX_PLAIN_ACTION(app::some_global_function, some_global_action)
+
+
+
+
Example:

+
+
+

+
+

Note

+

The macro HPX_PLAIN_ACTION has to be used at global namespace even if the wrapped function is located in some other namespace. The newly defined action type is placed into the global namespace as well.

+
+
+

Note

+

The macro HPX_PLAIN_ACTION_ID can be used with 1, 2, or 3 arguments. The second and third arguments are optional. The default value for the second argument (the typename of the defined action) is derived from the name of the function (as passed as the first argument) by appending ‘_action’. The second argument can be omitted only if the first argument with an appended suffix ‘_action’ resolves to a valid, unqualified C++ type name. The default value for the third argument is hpx::components::factory_state::check.

+
+
+

Note

+

Only one of the forms of this macro HPX_PLAIN_ACTION or HPX_PLAIN_ACTION_ID should be used for a particular action, never both.

+
+
+ +
+
+HPX_PLAIN_ACTION_ID(func, name, id)#
+

Defines a plain action type based on the given function func and registers it with HPX.

+

The macro HPX_PLAIN_ACTION_ID can be used to define a plain action (e.g. an action encapsulating a global or free function) based on the given function func. It defines the action type actionname representing the given function.

+

The parameter actionid specifies a unique integer value which will be used to represent the action during serialization.

+

The parameter func is a global or free (non-member) function which should be encapsulated into a plain action. The parameter name is the name of the action type defined by this macro.

+

The second parameter has to be usable as a plain (non-qualified) C++ identifier, it should not contain special characters which cannot be part of a C++ identifier, such as ‘<’, ‘>’, or ‘:’.

+

namespace app {
+    void some_global_function(double d) {
+        cout << d;
+    }
+}
+
+// This will define the action type 'some_global_action' which
+// represents the function 'app::some_global_function'.
+HPX_PLAIN_ACTION_ID(app::some_global_function, some_global_action,
+    some_unique_id);
+
+
+
+
Example:

+
+
+

+
+

Note

+

The macro HPX_PLAIN_ACTION_ID has to be used at global namespace even if the wrapped function is located in some other namespace. The newly defined action type is placed into the global namespace as well.

+
+
+

Note

+

Only one of the forms of this macro HPX_PLAIN_ACTION or HPX_PLAIN_ACTION_ID should be used for a particular action, never both.

+
+
+ +
+
+
+namespace hpx
+
+
+namespace actions
+
+ +
+
+namespace traits
+
+ +
+ +
+
+
hpx/actions_base/preassigned_action_id.hpp#
+

Defined in header hpx/actions_base/preassigned_action_id.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace actions
+
+ +
+ +
+
+
hpx/actions_base/traits/action_remote_result.hpp#
+

Defined in header hpx/actions_base/traits/action_remote_result.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace traits
+
+

Typedefs

+
+
+template<typename Result>
using action_remote_result_t = typename action_remote_result<Result>::type#
+
+ +
+
+
+template<typename Result>
struct action_remote_result : public detail::action_remote_result_customization_point<Result>#
+
+ +
+ +
+ +
+
+
+
+
agas#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/agas/addressing_service.hpp#
+

Defined in header hpx/agas/addressing_service.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace agas#
+
+
+struct addressing_service#
+
+

Public Types

+
+
+using component_id_type = components::component_type#
+
+ +
+
+using iterate_names_return_type = std::map<std::string, hpx::id_type>#
+
+ +
+
+using iterate_types_function_type = hpx::function<void(std::string const&, components::component_type), true>#
+
+ +
+
+using mutex_type = hpx::spinlock#
+
+ +
+
+using gva_cache_type = hpx::util::cache::lru_cache<gva_cache_key, gva, hpx::util::cache::statistics::local_full_statistics>#
+
+ +
+
+using migrated_objects_table_type = std::set<naming::gid_type>#
+
+ +
+
+using refcnt_requests_type = std::map<naming::gid_type, std::int64_t>#
+
+ +
+
+using resolved_localities_type = std::map<naming::gid_type, parcelset::endpoints_type>#
+
+ +
+
+

Public Functions

+
+
+HPX_NON_COPYABLE(addressing_service)#
+
+ +
+
+explicit addressing_service(util::runtime_configuration const &ini_)#
+
+ +
+
+~addressing_service() = default#
+
+ +
+
+void bootstrap(parcelset::endpoints_type const &endpoints, util::runtime_configuration &rtcfg)#
+
+ +
+
+void initialize(std::uint64_t rts_lva)#
+
+ +
+
+void adjust_local_cache_size(std::size_t) const#
+

Adjust the size of the local AGAS Address resolution cache.

+
+ +
+
+inline state get_status() const#
+
+ +
+
+inline void set_status(state new_state)#
+
+ +
+
+inline naming::gid_type const &get_local_locality(error_code& = throws) const#
+
+ +
+
+void set_local_locality(naming::gid_type const &g)#
+
+ +
+
+void register_console(parcelset::endpoints_type const &eps)#
+
+ +
+
+inline bool is_bootstrap() const#
+
+ +
+
+inline bool is_console() const#
+

Returns whether this addressing_service represents the console locality.

+
+ +
+
+inline bool is_connecting() const#
+

Returns whether this addressing_service is connecting to a running application.

+
+ +
+
+bool resolve_locally_known_addresses(naming::gid_type const &id, naming::address &addr) const#
+
+ +
+
+void register_server_instances()#
+
+ +
+
+void garbage_collect_non_blocking(error_code &ec = throws)#
+
+ +
+
+void garbage_collect(error_code &ec = throws)#
+
+ +
+
+inline server::primary_namespace &get_local_primary_namespace_service()#
+
+ +
+
+inline naming::address::address_type get_primary_ns_lva() const#
+
+ +
+
+inline naming::address::address_type get_symbol_ns_lva() const#
+
+ +
+
+inline server::component_namespace *get_local_component_namespace_service() const#
+
+ +
+
+inline server::locality_namespace *get_local_locality_namespace_service() const#
+
+ +
+
+inline server::symbol_namespace &get_local_symbol_namespace_service() const#
+
+ +
+
+inline naming::address::address_type get_runtime_support_lva() const#
+
+ +
+
+std::uint64_t get_cache_entries(bool) const#
+
+ +
+
+std::uint64_t get_cache_hits(bool) const#
+
+ +
+
+std::uint64_t get_cache_misses(bool) const#
+
+ +
+
+std::uint64_t get_cache_evictions(bool) const#
+
+ +
+
+std::uint64_t get_cache_insertions(bool) const#
+
+ +
+
+std::uint64_t get_cache_get_entry_count(bool reset) const#
+
+ +
+
+std::uint64_t get_cache_insertion_entry_count(bool reset) const#
+
+ +
+
+std::uint64_t get_cache_update_entry_count(bool reset) const#
+
+ +
+
+std::uint64_t get_cache_erase_entry_count(bool reset) const#
+
+ +
+
+std::uint64_t get_cache_get_entry_time(bool reset) const#
+
+ +
+
+std::uint64_t get_cache_insertion_entry_time(bool reset) const#
+
+ +
+
+std::uint64_t get_cache_update_entry_time(bool reset) const#
+
+ +
+
+std::uint64_t get_cache_erase_entry_time(bool reset) const#
+
+ +
+
+bool register_locality(parcelset::endpoints_type const &endpoints, naming::gid_type &prefix, std::uint32_t num_threads, error_code &ec = throws)#
+

Add a locality to the runtime.

+
+ +
+
+parcelset::endpoints_type const &resolve_locality(naming::gid_type const &gid, error_code &ec = throws)#
+

Resolve a locality to its prefix.

+
+
Returns
+

Returns an empty vector if the locality is not registered.

+
+
+
+ +
+
+bool has_resolved_locality(naming::gid_type const &gid)#
+
+ +
+
+bool unregister_locality(naming::gid_type const &gid, error_code &ec = throws)#
+

Remove a locality from the runtime.

+
+ +
+
+void remove_resolved_locality(naming::gid_type const &gid)#
+

remove given locality from locality cache

+
+ +
+
+bool get_console_locality(naming::gid_type &locality, error_code &ec = throws)#
+

Get locality locality_id of the console locality.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • locality – [out] The locality_id value uniquely identifying the console locality. This is valid only, if the return value of this function is true.

  • +
  • try_cache – [in] If this is set to true the console is first tried to be found in the local cache. Otherwise this function will always query AGAS, even if the console locality_id is already known locally.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns true if a console locality_id exists and returns false otherwise.

+
+
+
+ +
+
+bool get_localities(std::vector<naming::gid_type> &locality_ids, components::component_type type, error_code &ec = throws) const#
+

Query for the locality_ids of all known localities.

+

This function returns the locality_ids of all localities known to the AGAS server or all localities having a registered factory for a given component type.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise, it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • locality_ids – [out] The vector will contain the prefixes of all localities registered with the AGAS server. The returned vector holds the prefixes representing the runtime_support components of these localities.

  • +
  • type – [in] The component type will be used to determine the set of prefixes having a registered factory for this component. The default value for this parameter is components::component_enum_type::invalid, which will return prefixes of all localities.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+inline bool get_localities(std::vector<naming::gid_type> &locality_ids, error_code &ec = throws) const#
+
+ +
+
+hpx::future<std::uint32_t> get_num_localities_async(components::component_type type = to_int(hpx::components::component_enum_type::invalid)) const#
+

Query for the number of all known localities.

+

This function returns the number of localities known to the AGAS server or the number of localities having a registered factory for a given component type.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise, it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • type – [in] The component type will be used to determine the set of prefixes having a registered factory for this component. The default value for this parameter is components::component_type::invalid, which will return prefixes of all localities.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+std::uint32_t get_num_localities(components::component_type type, error_code &ec = throws) const#
+
+ +
+
+inline std::uint32_t get_num_localities(error_code &ec = throws) const#
+
+ +
+
+hpx::future<std::uint32_t> get_num_overall_threads_async() const#
+
+ +
+
+std::uint32_t get_num_overall_threads(error_code &ec = throws) const#
+
+ +
+
+hpx::future<std::vector<std::uint32_t>> get_num_threads_async() const#
+
+ +
+
+std::vector<std::uint32_t> get_num_threads(error_code &ec = throws) const#
+
+ +
+
+components::component_type get_component_id(std::string const &name, error_code &ec = throws) const#
+

Return a unique id usable as a component type.

+

This function returns the component type id associated with the given component name. If this is the first request for this component name a new unique id will be created.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • name – [in] The component name (string) to get the component type for.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

The function returns the currently associated component type. Any error results in an exception thrown from this function.

+
+
+
+ +
+
+void iterate_types(iterate_types_function_type const &f, error_code &ec = throws) const#
+
+ +
+
+std::string get_component_type_name(components::component_type id, error_code &ec = throws) const#
+
+ +
+
+inline components::component_type register_factory(naming::gid_type const &locality_id, std::string const &name, error_code &ec = throws) const#
+

Register a factory for a specific component type.

+

This function allows to register a component factory for a given locality and component type.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • locality_id – [in] The locality value uniquely identifying the given locality the factory needs to be registered for.

  • +
  • name – [in] The component name (string) to register a factory for the given component type for.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

The function returns the currently associated component type. Any error results in an exception thrown from this function. The returned component type is the same as if the function get_component_id was called using the same component name.

+
+
+
+ +
+
+components::component_type register_factory(std::uint32_t locality_id, std::string const &name, error_code &ec = throws) const#
+
+ +
+
+bool get_id_range(std::uint64_t count, naming::gid_type &lower_bound, naming::gid_type &upper_bound, error_code &ec = throws)#
+

Get unique range of freely assignable global ids.

+

Every locality needs to be able to assign global ids to different components without having to consult the AGAS server for every id to generate. This function can be called to preallocate a range of ids usable for this purpose.

+
+

Note

+

This function assigns a range of global ids usable by the given locality for newly created components. Any of the returned global ids still has to be bound to a local address, either by calling bind or bind_range.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • l – [in] The locality the locality id needs to be generated for. Repeating calls using the same locality results in identical locality_id values.

  • +
  • count – [in] The number of global ids to be generated.

  • +
  • lower_bound – [out] The lower bound of the assigned id range. The returned value can be used as the first id to assign. This is valid only, if the return value of this function is true.

  • +
  • upper_bound – [out] The upper bound of the assigned id range. The returned value can be used as the last id to assign. This is valid only, if the return value of this function is true.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns true if a new range has been generated (it has been called for the first time for the given locality) and returns false if this locality already got a range assigned in an earlier call. Any error results in an exception thrown from this function.

+
+
+
+ +
+
+inline bool bind_local(naming::gid_type const &id, naming::address const &addr, error_code &ec = throws)#
+

Bind a global address to a local address.

+

Every element in the HPX namespace has a unique global address (global id). This global address has to be associated with a concrete local address to be able to address an instance of a component using its global address.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

Binding a gid to a local address sets its global reference count to one.

+
+
+
Parameters
+
    +
  • id – [in] The global address which has to be bound to the local address.

  • +
  • addr – [in] The local address to be bound to the global address.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns true, if this global id got associated with an local address. It returns false otherwise.

+
+
+
+ +
+
+inline hpx::future<bool> bind_async(naming::gid_type const &id, naming::address const &addr, std::uint32_t locality_id)#
+
+ +
+
+inline hpx::future<bool> bind_async(naming::gid_type const &id, naming::address const &addr, naming::gid_type const &locality)#
+
+ +
+
+bool bind_range_local(naming::gid_type const &lower_id, std::uint64_t count, naming::address const &baseaddr, std::uint64_t offset, error_code &ec = throws)#
+

Bind unique range of global ids to given base address.

+

Every locality needs to be able to bind global ids to different components without having to consult the AGAS server for every id to bind. This function can be called to bind a range of consecutive global ids to a range of consecutive local addresses (separated by a given offset).

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

Binding a gid to a local address sets its global reference count to one.

+
+
+
Parameters
+
    +
  • lower_id – [in] The lower bound of the assigned id range. The value can be used as the first id to assign.

  • +
  • count – [in] The number of consecutive global ids to bind starting at lower_id.

  • +
  • baseaddr – [in] The local address to bind to the global id given by lower_id. This is the base address for all additional local addresses to bind to the remaining global ids.

  • +
  • offset – [in] The offset to use to calculate the local addresses to be bound to the range of global ids.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns true, if the given range was successfully bound. It returns false otherwise.

+
+
+
+ +
+
+hpx::future<bool> bind_range_async(naming::gid_type const &lower_id, std::uint64_t count, naming::address const &baseaddr, std::uint64_t offset, naming::gid_type const &locality)#
+
+ +
+
+inline hpx::future<bool> bind_range_async(naming::gid_type const &lower_id, std::uint64_t count, naming::address const &baseaddr, std::uint64_t offset, std::uint32_t locality_id)#
+
+ +
+
+inline bool unbind_local(naming::gid_type const &id, error_code &ec = throws)#
+

Unbind a global address.

+

Remove the association of the given global address with any local address, which was bound to this global address. Additionally it returns the local address which was bound at the time of this call.

+
+

Note

+

You can unbind only global ids bound using the function bind. Do not use this function to unbind any of the global ids bound using bind_range.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will raise an error if the global reference count of the given gid is not zero!

+
+
+
Parameters
+
    +
  • id – [in] The global address (id) for which the association has to be removed.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

The function returns true if the association has been removed, and it returns false if no association existed. Any error results in an exception thrown from this function.

+
+
+
+ +
+
+inline bool unbind_local(naming::gid_type const &id, naming::address &addr, error_code &ec = throws)#
+

Unbind a global address.

+

Remove the association of the given global address with any local address, which was bound to this global address. Additionally it returns the local address which was bound at the time of this call.

+
+

Note

+

You can unbind only global ids bound using the function bind. Do not use this function to unbind any of the global ids bound using bind_range.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will raise an error if the global reference count of the given gid is not zero!

+
+
+
Parameters
+
    +
  • id – [in] The global address (id) for which the association has to be removed.

  • +
  • addr – [out] The local address which was associated with the given global address (id). This is valid only if the return value of this function is true.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

The function returns true if the association has been removed, and it returns false if no association existed. Any error results in an exception thrown from this function.

+
+
+
+ +
+
+inline bool unbind_range_local(naming::gid_type const &lower_id, std::uint64_t count, error_code &ec = throws)#
+

Unbind the given range of global ids.

+
+

Note

+

You can unbind only global ids bound using the function bind_range. Do not use this function to unbind any of the global ids bound using bind.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will raise an error if the global reference count of the given gid is not zero!

+
+
+
Parameters
+
    +
  • lower_id – [in] The lower bound of the assigned id range. The value must the first id of the range as specified to the corresponding call to bind_range.

  • +
  • count – [in] The number of consecutive global ids to unbind starting at lower_id. This number must be identical to the number of global ids bound by the corresponding call to bind_range

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns true if a new range has been generated (it has been called for the first time for the given locality) and returns false if this locality already got a range assigned in an earlier call. Any error results in an exception thrown from this function.

+
+
+
+ +
+
+bool unbind_range_local(naming::gid_type const &lower_id, std::uint64_t count, naming::address &addr, error_code &ec = throws)#
+

Unbind the given range of global ids.

+
+

Note

+

You can unbind only global ids bound using the function bind_range. Do not use this function to unbind any of the global ids bound using bind.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will raise an error if the global reference count of the given gid is not zero!

+
+
+
Parameters
+
    +
  • lower_id – [in] The lower bound of the assigned id range. The value must the first id of the range as specified to the corresponding call to bind_range.

  • +
  • count – [in] The number of consecutive global ids to unbind starting at lower_id. This number must be identical to the number of global ids bound by the corresponding call to bind_range

  • +
  • addr – [out] The local address which was associated with the given global address (id). This is valid only if the return value of this function is true.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns true if a new range has been generated (it has been called for the first time for the given locality) and returns false if this locality already got a range assigned in an earlier call.

+
+
+
+ +
+
+hpx::future<naming::address> unbind_range_async(naming::gid_type const &lower_id, std::uint64_t count = 1)#
+
+ +
+
+inline bool is_local_address_cached(naming::gid_type const &id, error_code &ec = throws)#
+

Test whether the given address refers to a local object.

+

This function will test whether the given address refers to an object living on the locality of the caller.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The address to test.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns true if the passed address refers to an object which lives on the locality of the caller.

+
+
+
+ +
+
+bool is_local_address_cached(naming::gid_type const &id, naming::address &addr, error_code &ec = throws)#
+
+ +
+
+bool is_local_address_cached(naming::gid_type const &id, naming::address &addr, std::pair<bool, components::pinned_ptr> &r, hpx::move_only_function<std::pair<bool, components::pinned_ptr>(naming::address const&)> &&f, error_code &ec = throws)#
+
+ +
+
+bool is_local_lva_encoded_address(std::uint64_t msb) const#
+
+ +
+
+inline bool resolve_local(naming::gid_type const &id, naming::address &addr, error_code &ec = throws)#
+

Resolve a given global address (id) to its associated local address.

+

This function returns the local address which is currently associated with the given global address (id).

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The global address (id) for which the associated local address should be returned.

  • +
  • addr – [out] The local address which currently is associated with the given global address (id), this is valid only if the return value of this function is true.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns true if the global address has been resolved successfully (there exists an association to a local address) and the associated local address has been returned. The function returns false if no association exists for the given global address. Any error results in an exception thrown from this function.

+
+
+
+ +
+
+inline bool resolve_local(hpx::id_type const &id, naming::address &addr, error_code &ec = throws)#
+
+ +
+
+inline naming::address resolve_local(naming::gid_type const &id, error_code &ec = throws)#
+
+ +
+
+inline naming::address resolve_local(hpx::id_type const &id, error_code &ec = throws)#
+
+ +
+
+hpx::future_or_value<naming::address> resolve_async(naming::gid_type const &id)#
+
+ +
+
+inline hpx::future_or_value<naming::address> resolve_async(hpx::id_type const &id)#
+
+ +
+
+hpx::future_or_value<id_type> get_colocation_id_async(hpx::id_type const &id)#
+
+ +
+
+bool resolve_full_local(naming::gid_type const &id, naming::address &addr, error_code &ec = throws)#
+
+ +
+
+inline bool resolve_full_local(hpx::id_type const &id, naming::address &addr, error_code &ec = throws)#
+
+ +
+
+inline naming::address resolve_full_local(naming::gid_type const &id, error_code &ec = throws)#
+
+ +
+
+inline naming::address resolve_full_local(hpx::id_type const &id, error_code &ec = throws)#
+
+ +
+
+hpx::future_or_value<naming::address> resolve_full_async(naming::gid_type const &id)#
+
+ +
+
+inline hpx::future_or_value<naming::address> resolve_full_async(hpx::id_type const &id)#
+
+ +
+
+bool resolve_cached(naming::gid_type const &id, naming::address &addr, error_code &ec = throws)#
+
+ +
+
+inline bool resolve_cached(hpx::id_type const &id, naming::address &addr, error_code &ec = throws)#
+
+ +
+
+inline bool resolve_local(naming::gid_type const *gids, naming::address *addrs, std::size_t size, hpx::detail::dynamic_bitset<> &locals, error_code &ec = throws)#
+
+ +
+
+bool resolve_full_local(naming::gid_type const *gids, naming::address *addrs, std::size_t size, hpx::detail::dynamic_bitset<> &locals, error_code &ec = throws)#
+
+ +
+
+bool resolve_cached(naming::gid_type const *gids, naming::address *addrs, std::size_t size, hpx::detail::dynamic_bitset<> &locals, error_code &ec = throws)#
+
+ +
+
+hpx::future_or_value<std::int64_t> incref_async(naming::gid_type const &gid, std::int64_t credits = 1, hpx::id_type const &keep_alive = hpx::invalid_id)#
+

Increment the global reference count for the given id.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • gid – [in] The global address (id) for which the global reference count has to be incremented.

  • +
  • credits – [in] The number of reference counts to add for the given id.

  • +
  • keep_alive – [in] Id to keep alive (if valid)

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

Whether the operation was successful.

+
+
+
+ +
+
+inline std::int64_t incref(naming::gid_type const &gid, std::int64_t credits = 1, error_code &ec = throws)#
+
+ +
+
+void decref(naming::gid_type const &id, std::int64_t credits = 1, error_code &ec = throws)#
+

Decrement the global reference count for the given id.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The global address (id) for which the global reference count has to be decremented.

  • +
  • t – [out] If this was the last outstanding global reference for the given gid (the return value of this function is zero), t will be set to the component type of the corresponding element. Otherwise t will not be modified.

  • +
  • credits – [in] The number of reference counts to add for the given id.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

The global reference count after the decrement.

+
+
+
+ +
+
+hpx::future<iterate_names_return_type> iterate_ids(std::string const &pattern) const#
+

Invoke the supplied hpx::function for every registered global name.

+

This function iterates over all registered global ids and returns every found entry matching the given name pattern. Any error results in an exception thrown (or reported) from this function.

+
+
Parameters
+

pattern – [in] pattern (possibly using wildcards) to match all existing entries against

+
+
+
+ +
+
+bool register_name(std::string const &name, naming::gid_type const &id, error_code &ec = throws) const#
+

Register a global name with a global address (id)

+

This function registers an association between a global name (string) and a global address (id) usable with one of the functions above (bind, unbind, and resolve).

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • name – [in] The global name (string) to be associated with the global address.

  • +
  • id – [in] The global address (id) to be associated with the global address.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

The function returns true if the global name was registered. It returns false if the global name is not registered.

+
+
+
+ +
+
+hpx::future<bool> register_name_async(std::string const &name, hpx::id_type const &id) const#
+
+ +
+
+bool register_name(std::string const &name, hpx::id_type const &id, error_code &ec = throws) const#
+
+ +
+
+hpx::future<hpx::id_type> unregister_name_async(std::string const &name) const#
+

Unregister a global name (release any existing association)

+

This function releases any existing association of the given global name with a global address (id).

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • name – [in] The global name (string) for which any association with a global address (id) has to be released.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

The function returns true if an association of this global name has been released, and it returns false, if no association existed. Any error results in an exception thrown from this function.

+
+
+
+ +
+
+hpx::id_type unregister_name(std::string const &name, error_code &ec = throws) const#
+
+ +
+
+hpx::future<hpx::id_type> resolve_name_async(std::string const &name) const#
+

Query for the global address associated with a given global name.

+

This function returns the global address associated with the given global name.

+

+This function returns true if it returned global address (id), which is currently associated with the given global name, and it returns false, if currently there is no association for this global name. Any error results in an exception thrown from this function.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • name – [in] The global name (string) for which the currently associated global address has to be retrieved.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

[out] The id currently associated with the given global name (valid only if the return value is true).

+
+
+
+ +
+
+hpx::id_type resolve_name(std::string const &name, error_code &ec = throws) const#
+
+ +
+
+future<hpx::id_type> on_symbol_namespace_event(std::string const &name, bool call_for_past_events = false) const#
+

Install a listener for a given symbol namespace event.

+

This function installs a listener for a given symbol namespace event. It returns a future which becomes ready as a result of the listener being triggered.

+
+

Note

+

The only event type which is currently supported is symbol_ns_bind, i.e. the listener is triggered whenever a global id is registered with the given name.

+
+
+
Parameters
+
    +
  • name – [in] The global name (string) for which the given event should be triggered.

  • +
  • evt – [in] The event for which a listener should be installed.

  • +
  • call_for_past_events – [in, optional] Trigger the listener even if the given event has already happened in the past. The default for this parameter is false.

  • +
+
+
Returns
+

A future instance encapsulating the global id which is causing the registered listener to be triggered.

+
+
+
+ +
+
+void update_cache_entry(naming::gid_type const &gid, gva const &gva, error_code &ec = throws)#
+
+

Warning

+

This function is for internal use only. It is dangerous and may break your code if you use it.

+
+
+ +
+
+inline void update_cache_entry(naming::gid_type const &gid, naming::address const &addr, std::uint64_t count = 0, std::uint64_t offset = 0, error_code &ec = throws)#
+
+

Warning

+

This function is for internal use only. It is dangerous and may break your code if you use it.

+
+
+ +
+
+bool get_cache_entry(naming::gid_type const &gid, gva &gva, naming::gid_type &idbase, error_code &ec = throws) const#
+
+

Warning

+

This function is for internal use only. It is dangerous and may break your code if you use it.

+
+
+ +
+
+void remove_cache_entry(naming::gid_type const &id, error_code &ec = throws) const#
+
+

Warning

+

This function is for internal use only. It is dangerous and may break your code if you use it.

+
+
+ +
+
+void clear_cache(error_code &ec = throws) const#
+
+

Warning

+

This function is for internal use only. It is dangerous and may break your code if you use it.

+
+
+ +
+
+void start_shutdown(error_code &ec = throws)#
+
+ +
+
+hpx::future<std::pair<hpx::id_type, naming::address>> begin_migration(hpx::id_type const &id)#
+

start/stop migration of an object

+
+
Returns
+

Current locality and address of the object to migrate

+
+
+
+ +
+
+bool end_migration(hpx::id_type const &id)#
+
+ +
+
+std::pair<bool, components::pinned_ptr> was_object_migrated(naming::gid_type const &gid, hpx::move_only_function<components::pinned_ptr()> &&f)#
+

Maintain list of migrated objects.

+
+ +
+
+hpx::future<void> mark_as_migrated(naming::gid_type const &gid, hpx::move_only_function<std::pair<bool, hpx::future<void>>()> &&f, bool expect_to_be_marked_as_migrating)#
+

Mark the given object as being migrated (if the object is unpinned). Delay migration until the object is unpinned otherwise.

+
+ +
+
+void unmark_as_migrated(naming::gid_type const &gid_, hpx::move_only_function<void()> &&f)#
+

Remove the given object from the table of migrated objects.

+
+ +
+
+void pre_cache_endpoints(std::vector<parcelset::endpoints_type> const&)#
+
+ +
+
+

Public Members

+
+
+mutable hpx::shared_mutex gva_cache_mtx_#
+
+ +
+
+std::shared_ptr<gva_cache_type> gva_cache_#
+
+ +
+
+mutable mutex_type migrated_objects_mtx_#
+
+ +
+
+migrated_objects_table_type migrated_objects_table_#
+
+ +
+
+mutable mutex_type console_cache_mtx_#
+
+ +
+
+std::uint32_t console_cache_#
+
+ +
+
+const std::size_t max_refcnt_requests_#
+
+ +
+
+mutex_type refcnt_requests_mtx_#
+
+ +
+
+std::size_t refcnt_requests_count_#
+
+ +
+
+bool enable_refcnt_caching_#
+
+ +
+
+std::shared_ptr<refcnt_requests_type> refcnt_requests_#
+
+ +
+
+const service_mode service_type#
+
+ +
+
+const runtime_mode runtime_type#
+
+ +
+
+const bool caching_#
+
+ +
+
+const bool range_caching_#
+
+ +
+
+const threads::thread_priority action_priority_#
+
+ +
+
+std::uint64_t rts_lva_#
+
+ +
+
+std::unique_ptr<component_namespace> component_ns_#
+
+ +
+
+std::unique_ptr<locality_namespace> locality_ns_#
+
+ +
+
+symbol_namespace symbol_ns_#
+
+ +
+
+primary_namespace primary_ns_#
+
+ +
+
+std::atomic<hpx::state> state_#
+
+ +
+
+naming::gid_type locality_#
+
+ +
+
+mutable hpx::shared_mutex resolved_localities_mtx_#
+
+ +
+
+resolved_localities_type resolved_localities_#
+
+ +
+
+

Public Static Functions

+
+
+static std::int64_t synchronize_with_async_incref(std::int64_t old_credit, hpx::id_type const &id, std::int64_t compensated_credit)#
+
+ +
+
+

Protected Functions

+
+
+void launch_bootstrap(parcelset::endpoints_type const &endpoints, util::runtime_configuration &rtcfg)#
+
+ +
+
+naming::address resolve_full_postproc(naming::gid_type const &id, primary_namespace::resolved_type const&)#
+
+ +
+
+bool bind_postproc(naming::gid_type const &id, gva const &g, future<bool> f)#
+
+ +
+
+bool was_object_migrated_locked(naming::gid_type const &id)#
+

Maintain list of migrated objects.

+
+ +
+
+

Private Functions

+
+
+void send_refcnt_requests(std::unique_lock<mutex_type> &l, error_code &ec = throws)#
+

Assumes that refcnt_requests_mtx_ is locked.

+
+ +
+
+void send_refcnt_requests_non_blocking(std::unique_lock<mutex_type> &l, error_code &ec)#
+

Assumes that refcnt_requests_mtx_ is locked.

+
+ +
+
+std::vector<hpx::future<std::vector<std::int64_t>>> send_refcnt_requests_async(std::unique_lock<mutex_type> &l)#
+

Assumes that refcnt_requests_mtx_ is locked.

+
+ +
+
+void send_refcnt_requests_sync(std::unique_lock<mutex_type> &l, error_code &ec)#
+

Assumes that refcnt_requests_mtx_ is locked.

+
+ +
+
+ +
+ +
+ +
+
+
+
+
agas_base#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/agas_base/server/primary_namespace.hpp#
+

Defined in header hpx/agas_base/server/primary_namespace.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Variables

+
+
+HPX_ACTION_USES_MEDIUM_STACK(hpx::agas::server::primary_namespace::allocate_action) HPX_REGISTER_ACTION_DECLARATION(hpx typedef std::pair< hpx::id_type, hpx::naming::address > std_pair_address_id_type
+
+ +
+
+
+namespace hpx
+
+
+namespace agas
+
+

Functions

+
+
+naming::gid_type bootstrap_primary_namespace_gid()#
+
+ +
+
+hpx::id_type bootstrap_primary_namespace_id()#
+
+ +
+
+
+namespace server#
+

AGAS’s primary namespace maps 128-bit global identifiers (GIDs) to resolved addresses.

+

+The following is the canonical description of the partitioning of AGAS’s primary namespace.

|-----MSB------||------LSB-----|
+BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
+|prefix||RC||----identifier----|
+
+MSB        - Most significant bits (bit 64 to bit 127)
+LSB        - Least significant bits (bit 0 to bit 63)
+prefix     - Highest 32 bits (bit 96 to bit 127) of the MSB. Each
+             locality is assigned a prefix. This creates a 96-bit
+             address space for each locality.
+RC         - Bit 88 to bit 92 of the MSB. This is the log2 of the number
+             of reference counting credits on the GID.
+             Bit 93 is used by the locking scheme for gid_types.
+             Bit 94 is a flag which is set if the credit value is valid.
+             Bit 95 is a flag that is set if a GID's credit count is
+             ever split (e.g. if the GID is ever passed to another
+             locality).
+           - Bit 87 marks the gid such that it will not be stored in
+             any of the AGAS caches. This is used mainly for ids
+             which represent 'one-shot' objects (like promises).
+identifier - Bit 64 to bit 86 of the MSB, and the entire LSB. The
+             content of these bits depends on the component type of
+             the underlying object. For all user-defined components,
+             these bits contain a unique 88-bit number which is
+             assigned sequentially for each locality. For
+             \a hpx#components#component_enum_type#runtime_support
+             the high 24 bits are zeroed and the low 64 bits hold the
+             LVA of the component.
+
+
+

+

The following address ranges are reserved. Some are either explicitly or implicitly protected by AGAS. The letter x represents a single-byte wild card.

00000000xxxxxxxxxxxxxxxxxxxxxxxx
+    Historically unused address space reserved for future use.
+xxxxxxxxxxxx0000xxxxxxxxxxxxxxxx
+    Address space for LVA-encoded GIDs.
+00000001xxxxxxxxxxxxxxxxxxxxxxxx
+    Prefix of the bootstrap AGAS locality.
+00000001000000010000000000000001
+    Address of the primary_namespace component on the bootstrap AGAS
+    locality.
+00000001000000010000000000000002
+    Address of the component_namespace component on the bootstrap AGAS
+    locality.
+00000001000000010000000000000003
+    Address of the symbol_namespace component on the bootstrap AGAS
+    locality.
+00000001000000010000000000000004
+    Address of the locality_namespace component on the bootstrap AGAS
+    locality.
+
+
+

+
+

Note

+

The layout of the address space is implementation defined, and subject to change. Never write application code that relies on the internal layout of GIDs. AGAS only guarantees that all assigned GIDs will be unique.

+
+
+

Variables

+
+
+static constexpr char const *const primary_namespace_service_name = "primary/"#
+
+ +
+
+
+struct primary_namespace : public components::fixed_component_base<primary_namespace>#
+
+

Public Types

+
+
+using mutex_type = hpx::spinlock#
+
+ +
+
+using base_type = components::fixed_component_base<primary_namespace>#
+
+ +
+
+using component_type = std::int32_t#
+
+ +
+
+using gva_table_data_type = std::pair<gva, naming::gid_type>#
+
+ +
+
+using gva_table_type = std::map<naming::gid_type, gva_table_data_type>#
+
+ +
+
+using refcnt_table_type = std::map<naming::gid_type, std::int64_t>#
+
+ +
+
+using resolved_type = hpx::tuple<naming::gid_type, gva, naming::gid_type>#
+
+ +
+
+

Public Functions

+
+
+inline mutex_type &mutex()#
+
+ +
+
+void wait_for_migration_locked(std::unique_lock<mutex_type> &l, naming::gid_type const &id, error_code &ec)#
+
+ +
+
+inline primary_namespace()#
+
+ +
+
+void finalize() const#
+
+ +
+
+inline void set_local_locality(naming::gid_type const &g)#
+
+ +
+
+void register_server_instance(char const *servicename, std::uint32_t locality_id = naming::invalid_locality_id, error_code &ec = throws)#
+
+ +
+
+void unregister_server_instance(error_code &ec = throws) const#
+
+ +
+
+bool bind_gid(gva const &g, naming::gid_type id, naming::gid_type const &locality)#
+
+ +
+
+std::pair<hpx::id_type, naming::address> begin_migration(naming::gid_type id)#
+
+ +
+
+bool end_migration(naming::gid_type const &id)#
+
+ +
+
+resolved_type resolve_gid(naming::gid_type const &id)#
+
+ +
+
+hpx::id_type colocate(naming::gid_type const &id)#
+
+ +
+
+naming::address unbind_gid(std::uint64_t count, naming::gid_type id)#
+
+ +
+
+std::int64_t increment_credit(std::int64_t credits, naming::gid_type lower, naming::gid_type upper)#
+
+ +
+
+std::vector<std::int64_t> decrement_credit(std::vector<hpx::tuple<std::int64_t, naming::gid_type, naming::gid_type>> const &requests)#
+
+ +
+
+std::pair<naming::gid_type, naming::gid_type> allocate(std::uint64_t count)#
+
+ +
+
+resolved_type resolve_gid_locked(std::unique_lock<mutex_type> &l, naming::gid_type const &gid, error_code &ec)#
+
+ +
+
+

Public Members

+
+
+counter_data counter_data_#
+
+ +
+
+

Private Types

+
+
+using migration_table_type = std::map<naming::gid_type, hpx::tuple<bool, std::size_t, lcos::local::detail::condition_variable>>#
+
+ +
+
+using free_entry_allocator_type = util::internal_allocator<free_entry>#
+
+ +
+
+using free_entry_list_type = std::list<free_entry, free_entry_allocator_type>#
+
+ +
+
+

Private Functions

+
+
+resolved_type resolve_gid_locked_non_local(std::unique_lock<mutex_type> &l, naming::gid_type const &gid, error_code &ec)#
+
+ +
+
+void increment(naming::gid_type const &lower, naming::gid_type const &upper, std::int64_t const &credits, error_code &ec)#
+
+ +
+
+void resolve_free_list(std::unique_lock<mutex_type> &l, std::list<refcnt_table_type::iterator> const &free_list, free_entry_list_type &free_entry_list, naming::gid_type const &lower, naming::gid_type const &upper, error_code &ec)#
+
+ +
+
+void decrement_sweep(free_entry_list_type &free_list, naming::gid_type const &lower, naming::gid_type const &upper, std::int64_t credits, error_code &ec)#
+
+ +
+
+void free_components_sync(free_entry_list_type const &free_list, naming::gid_type const &lower, naming::gid_type const &upper, error_code &ec) const#
+
+ +
+
+

Private Members

+
+
+mutex_type mutex_#
+
+ +
+
+gva_table_type gvas_#
+
+ +
+
+refcnt_table_type refcnts_#
+
+ +
+
+std::string instance_name_#
+
+ +
+
+naming::gid_type next_id_#
+
+ +
+
+naming::gid_type locality_#
+
+ +
+
+migration_table_type migrating_objects_#
+
+ +
+
+
+struct counter_data#
+
+

Public Functions

+
+
+HPX_NON_COPYABLE(counter_data)#
+
+ +
+
+counter_data() = default#
+
+ +
+
+std::int64_t get_bind_gid_count(bool)#
+
+ +
+
+std::int64_t get_resolve_gid_count(bool)#
+
+ +
+
+std::int64_t get_unbind_gid_count(bool)#
+
+ +
+
+std::int64_t get_increment_credit_count(bool)#
+
+ +
+
+std::int64_t get_decrement_credit_count(bool)#
+
+ +
+
+std::int64_t get_allocate_count(bool)#
+
+ +
+
+std::int64_t get_begin_migration_count(bool)#
+
+ +
+
+std::int64_t get_end_migration_count(bool)#
+
+ +
+
+std::int64_t get_overall_count(bool)#
+
+ +
+
+std::int64_t get_bind_gid_time(bool)#
+
+ +
+
+std::int64_t get_resolve_gid_time(bool)#
+
+ +
+
+std::int64_t get_unbind_gid_time(bool)#
+
+ +
+
+std::int64_t get_increment_credit_time(bool)#
+
+ +
+
+std::int64_t get_decrement_credit_time(bool)#
+
+ +
+
+std::int64_t get_allocate_time(bool)#
+
+ +
+
+std::int64_t get_begin_migration_time(bool)#
+
+ +
+
+std::int64_t get_end_migration_time(bool)#
+
+ +
+
+std::int64_t get_overall_time(bool)#
+
+ +
+
+void increment_bind_gid_count()#
+
+ +
+
+void increment_resolve_gid_count()#
+
+ +
+
+void increment_unbind_gid_count()#
+
+ +
+
+void increment_increment_credit_count()#
+
+ +
+
+void increment_decrement_credit_count()#
+
+ +
+
+void increment_allocate_count()#
+
+ +
+
+void increment_begin_migration_count()#
+
+ +
+
+void increment_end_migration_count()#
+
+ +
+
+void enable_all()#
+
+ +
+
+

Public Members

+
+
+api_counter_data bind_gid_#
+
+ +
+
+api_counter_data resolve_gid_#
+
+ +
+
+api_counter_data unbind_gid_#
+
+ +
+
+api_counter_data increment_credit_#
+
+ +
+
+api_counter_data decrement_credit_#
+
+ +
+
+api_counter_data allocate_#
+
+ +
+
+api_counter_data begin_migration_#
+
+ +
+
+api_counter_data end_migration_#
+
+ +
+
+
+struct api_counter_data#
+
+

Public Functions

+
+
+inline api_counter_data()#
+
+ +
+
+

Public Members

+
+
+std::atomic<std::int64_t> count_#
+
+ +
+
+std::atomic<std::int64_t> time_#
+
+ +
+
+bool enabled_#
+
+ +
+
+ +
+ +
+
+struct free_entry#
+
+

Public Functions

+
+
+inline free_entry(agas::gva const &gva, naming::gid_type const &gid, naming::gid_type const &loc)#
+
+ +
+
+

Public Members

+
+
+agas::gva gva_#
+
+ +
+
+naming::gid_type gid_#
+
+ +
+
+naming::gid_type locality_#
+
+ +
+
+ +
+ +
+ +
+ +
+ +
+
+
+
+
async_colocated#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::get_colocation_id#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+hpx::id_type get_colocation_id(launch::sync_policy, hpx::id_type const &id, error_code &ec = throws)#
+

Return the id of the locality where the object referenced by the given id is currently located on.

+

The function hpx::get_colocation_id() returns the id of the locality where the given object is currently located.

+

+

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • id – [in] The id of the object to locate.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+hpx::future<hpx::id_type> get_colocation_id(hpx::id_type const &id)#
+

Asynchronously return the id of the locality where the object referenced by the given id is currently located on.

+

+

See also

+

hpx::get_colocation_id(launch::sync_policy)

+
+

+
+
Parameters
+

id – [in] The id of the object to locate.

+
+
+
+ +
+
+ +
+
+
+
+
async_distributed#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::async (distributed)#
+

Defined in header hpx/async.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename Action, typename Target, typename ...Ts>
auto async(Action &&action, Target &&target, Ts&&... ts)#
+

The distributed implementation of hpx::async can be used by giving an action instance as argument instead of a function, and also by providing another argument with the locality ID or the target ID. The action executes asynchronously.

+
+
Template Parameters
+
    +
  • Action – The type of action instance

  • +
  • Target – The type of target where the action should be executed

  • +
  • Ts – The type of any additional arguments

  • +
+
+
Parameters
+
    +
  • action – The action instance to be executed

  • +
  • target – The target where the action should be executed

  • +
  • ts – Additional arguments

  • +
+
+
Returns
+

hpx::future referring to the shared state created by this call to hpx::async

+
+
+
+ +
+
+ +
+
+
hpx/async_distributed/base_lco.hpp#
+

Defined in header hpx/async_distributed/base_lco.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<>
struct hpx::get_lva<hpx::lcos::base_lco>#
+
+

Public Static Functions

+
+
+static inline constexpr hpx::lcos::base_lco *call(hpx::naming::address_type lva) noexcept#
+
+ +
+
+ +
+
+template<>
struct hpx::get_lva<hpx::lcos::base_lco const>#
+
+

Public Static Functions

+
+
+static inline constexpr hpx::lcos::base_lco const *call(hpx::naming::address_type lva) noexcept#
+
+ +
+
+ +
+
+namespace hpx
+
+
+template<> base_lco >
+
+

Public Static Functions

+
+
+static inline constexpr hpx::lcos::base_lco *call(hpx::naming::address_type lva) noexcept#
+
+ +
+
+ +
+
+template<> base_lco const >
+
+

Public Static Functions

+
+
+static inline constexpr hpx::lcos::base_lco const *call(hpx::naming::address_type lva) noexcept
+
+ +
+
+ +
+
+namespace lcos
+
+
+class base_lco#
+
+#include <base_lco.hpp>
+

The base_lco class is the common base class for all LCO’s implementing a simple set_event action

+

Subclassed by hpx::lcos::base_lco_with_value< Result, RemoteResult, ComponentTag >, hpx::lcos::base_lco_with_value< void, void, ComponentTag >

+
+

Public Types

+
+
+typedef components::managed_component<base_lco> wrapping_type#
+
+ +
+
+typedef base_lco base_type_holder#
+
+ +
+
+

Public Functions

+
+
+virtual void set_event() = 0#
+
+ +
+
+virtual void set_exception(std::exception_ptr const &e)#
+
+ +
+
+virtual void connect(hpx::id_type const&)#
+
+ +
+
+virtual void disconnect(hpx::id_type const&)#
+
+ +
+
+virtual ~base_lco()#
+

Destructor, needs to be virtual to allow for clean destruction of derived objects

+
+ +
+
+void set_event_nonvirt()#
+

The function set_event_nonvirt is called whenever a set_event_action is applied on a instance of a LCO. This function just forwards to the virtual function set_event, which is overloaded by the derived concrete LCO.

+
+ +
+
+void set_exception_nonvirt(std::exception_ptr const &e)#
+

The function set_exception is called whenever a set_exception_action is applied on a instance of a LCO. This function just forwards to the virtual function set_exception, which is overloaded by the derived concrete LCO.

+
+
Parameters
+

e – [in] The exception encapsulating the error to report to this LCO instance.

+
+
+
+ +
+
+void connect_nonvirt(hpx::id_type const &id)#
+

The function connect_nonvirt is called whenever a connect_action is applied on a instance of a LCO. This function just forwards to the virtual function connect, which is overloaded by the derived concrete LCO.

+
+
Parameters
+

id – [in] target id

+
+
+
+ +
+
+void disconnect_nonvirt(hpx::id_type const &id)
+

The function disconnect_nonvirt is called whenever a disconnect_action is applied on a instance of a LCO. This function just forwards to the virtual function disconnect, which is overloaded by the derived concrete LCO.

+
+
Parameters
+

id – [in] target id

+
+
+
+ +
+
+HPX_DEFINE_COMPONENT_DIRECT_ACTION (base_lco, set_event_nonvirt, set_event_action) HPX_DEFINE_COMPONENT_DIRECT_ACTION(base_lco
+

Each of the exposed functions needs to be encapsulated into an action type, allowing to generate all required boilerplate code for threads, serialization, etc.

+

The set_event_action may be used to unconditionally trigger any LCO instances, it carries no additional parameters. The set_exception_action may be used to transfer arbitrary error information from the remote site to the LCO instance specified as a continuation. This action carries 2 parameters:

+
+
Parameters
+

std::exception_ptr – [in] The exception encapsulating the error to report to this LCO instance.

+
+
+
+ +
+
+set_exception_action HPX_DEFINE_COMPONENT_DIRECT_ACTION (base_lco, connect_nonvirt, connect_action) HPX_DEFINE_COMPONENT_DIRECT_ACTION(base_lco
+

The connect_action may be used to.

+

The set_exception_action may be used to

+
+ +
+
+

Public Members

+
+
+set_exception_nonvirt
+
+ +
+
+set_exception_action disconnect_nonvirt#
+
+ +
+
+

Public Static Functions

+
+
+static components::component_type get_component_type() noexcept#
+
+ +
+
+static void set_component_type(components::component_type type)#
+
+ +
+
+ +
+ +
+ +
+
+
hpx/async_distributed/base_lco_with_value.hpp#
+

Defined in header hpx/async_distributed/base_lco_with_value.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_DECLARATION(...)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_DECLARATION_(...)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_DECLARATION2(Value, RemoteValue, Name)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_DECLARATION_1(Value)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_DECLARATION_2(Value, Name)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_DECLARATION_3(Value, RemoteValue, Name)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_DECLARATION_4(Value, RemoteValue, Name, Tag)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE(...)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_(...)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_1(Value)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_2(Value, Name)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_3(Value, RemoteValue, Name)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_4(Value, RemoteValue, Name, Tag)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_ID(...)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_ID_(...)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_ID2(Value, RemoteValue, Name, ActionIdGet, ActionIdSet)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_ID_4(Value, Name, ActionIdGet, ActionIdSet)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_ID_5(Value, RemoteValue, Name, ActionIdGet, ActionIdSet)#
+
+ +
+
+HPX_REGISTER_BASE_LCO_WITH_VALUE_ID_6(Value, RemoteValue, Name, ActionIdGet, ActionIdSet, Tag)#
+
+ +
+
+
+namespace hpx
+
+
+namespace components
+
+ +
+
+namespace lcos
+
+
+template<typename Result, typename RemoteResult, typename ComponentTag>
class base_lco_with_value : public hpx::lcos::base_lco, public ComponentTag#
+
+#include <base_lco_with_value.hpp>
+

The base_lco_with_value class is the common base class for all LCO’s synchronizing on a value. The RemoteResult template argument should be set to the type of the argument expected for the set_value action.

+
+
Template Parameters
+
    +
  • RemoteResult – The type of the result value to be carried back to the LCO instance.

  • +
  • ComponentTag – The tag type representing the type of the component (either component_tag or managed_component_tag).

  • +
+
+
+
+

Public Types

+
+
+using wrapping_type = typename detail::base_lco_wrapping_type<ComponentTag, base_lco_with_value>::type#
+
+ +
+
+using base_type_holder = base_lco_with_value#
+
+ +
+
+

Public Functions

+
+
+inline void set_value_nonvirt(RemoteResult &&result)#
+

The function set_value_nonvirt is called whenever a set_value_action is applied on this LCO instance. This function just forwards to the virtual function set_value, which is overloaded by the derived concrete LCO.

+
+
Parameters
+

result – [in] The result value to be transferred from the remote operation back to this LCO instance.

+
+
+
+ +
+
+inline Result get_value_nonvirt()#
+

The function get_result_nonvirt is called whenever a get_result_action is applied on this LCO instance. This function just forwards to the virtual function get_result, which is overloaded by the derived concrete LCO.

+
+ +
+
+HPX_DEFINE_COMPONENT_DIRECT_ACTION (base_lco_with_value, set_value_nonvirt, set_value_action) HPX_DEFINE_COMPONENT_DIRECT_ACTION(base_lco_with_value
+

The set_value_action may be used to trigger any LCO instances while carrying an additional parameter of any type.

+

RemoteResult is taken by rvalue ref. This allows for perfect forwarding. When the action thread function is created, the values are moved into the called function. If we took it by const lvalue reference, we would disable the possibility to further move the result to the designated destination.

+
+
Parameters
+

RemoteResult – [in] The type of the result to be transferred back to this LCO instance. The get_value_action may be used to query the value this LCO instance exposes as its ‘result’ value.

+
+
+
+ +
+
+

Public Members

+
+
+get_value_nonvirt
+
+ +
+
+

Public Static Functions

+
+
+static inline components::component_type get_component_type() noexcept#
+
+ +
+
+static inline void set_component_type(components::component_type type)#
+
+ +
+
+

Protected Types

+
+
+using result_type = std::conditional_t<std::is_void_v<Result>, util::unused_type, Result>#
+
+ +
+
+

Protected Functions

+
+
+~base_lco_with_value() override = default#
+

Destructor, needs to be virtual to allow for clean destruction of derived objects

+
+ +
+
+inline virtual void set_event() override#
+
+ +
+
+virtual void set_value(RemoteResult &&result) = 0#
+
+ +
+
+virtual result_type get_value() = 0#
+
+ +
+
+inline virtual result_type get_value(error_code&)#
+
+ +
+
+ +
+
+template<typename ComponentTag>
class base_lco_with_value<void, void, ComponentTag> : public hpx::lcos::base_lco, public ComponentTag#
+
+#include <base_lco_with_value.hpp>
+

The base_lco<void> specialization is used whenever the set_event action for a particular LCO doesn’t carry any argument.

+
+
Template Parameters
+

void – This specialization expects no result value and is almost completely equivalent to the plain base_lco.

+
+
+
+

Public Types

+
+
+using wrapping_type = typename detail::base_lco_wrapping_type<ComponentTag, base_lco_with_value>::type#
+
+ +
+
+using base_type_holder = base_lco_with_value#
+
+ +
+
+using set_value_action = typename base_lco::set_event_action#
+
+ +
+
+

Public Functions

+
+
+inline void get_value()#
+
+ +
+
+

Protected Functions

+
+
+~base_lco_with_value() override = default#
+

Destructor, needs to be virtual to allow for clean destruction of derived objects

+
+ +
+
+ +
+ +
+
+namespace traits
+
+ +
+ +
+
+
hpx::dataflow (distributed)#
+

Defined in header hpx/async.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename Action, typename Target, typename ...Ts>
decltype(auto) dataflow(Action &&action, Target &&target, Ts&&... ts)#
+

The distributed implementation of hpx::dataflow can be used by giving an action instance as argument instead of a function, and also by providing another argument with the locality ID or the target ID. The action executes asynchronously.

+
+

Note

+

Its behavior is similar to hpx::async with the exception that if one of the arguments is a future, then hpx::dataflow will wait for the future to be ready to launch the thread.

+
+
+
Template Parameters
+
    +
  • Action – The type of action instance

  • +
  • Target – The type of target where the action should be executed

  • +
  • Ts – The type of any additional arguments

  • +
+
+
Parameters
+
    +
  • action – The action instance to be executed

  • +
  • target – The target where the action should be executed

  • +
  • ts – Additional arguments

  • +
+
+
Returns
+

hpx::future referring to the shared state created by this call to hpx::dataflow

+
+
+
+ +
+
+ +
+
+
hpx::distributed::promise#
+

Defined in header hpx/future.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace distributed
+
+
+template<typename Result, typename RemoteResult>
class promise#
+
+#include <promise.hpp>
+

A promise can be used by a single thread to invoke a (remote) action and wait for the result. The result is expected to be sent back to the promise using the LCO’s set_event action

+

A promise is one of the simplest synchronization primitives provided by HPX. It allows to synchronize on a eager evaluated remote operation returning a result of the type Result. The promise allows to synchronize exactly one thread (the one passed during construction time).

+

// Create the promise (the expected result is a id_type)
+hpx::distributed::promise<hpx::id_type> p;
+
+// Get the associated future
+future<hpx::id_type> f = p.get_future();
+
+// initiate the action supplying the promise as a
+// continuation
+apply<some_action>(new continuation(p.get_id()), ...);
+
+// Wait for the result to be returned, yielding control
+// in the meantime.
+hpx::id_type result = f.get();
+// ...
+
+
+

+
+

Note

+

The action executed by the promise must return a value of a type convertible to the type as specified by the template parameter RemoteResult

+
+
+
Template Parameters
+
    +
  • Result – The template parameter Result defines the type this promise is expected to return from promise::get.

  • +
  • RemoteResult – The template parameter RemoteResult defines the type this promise is expected to receive from the remote action.

  • +
+
+
+
+ +
+ +
+
+namespace lcos
+
+

Typedefs

+
+
+using instead = hpx::distributed::promise<Result, RemoteResult>
+
+ +
+
+
+template<typename Result, typename RemoteResult, typename ComponentTag>
class base_lco_with_value : public hpx::lcos::base_lco, public ComponentTag
+
+#include <base_lco_with_value.hpp>
+
+ +
+
+template<typename Action, typename Result = typename traits::promise_local_result<typename Action::remote_result_type>::type, bool DirectExecute = Action::direct_execution::value>
class packaged_action#
+
+#include <packaged_action.hpp>
+

A packaged_action can be used by a single thread to invoke a (remote) action and wait for the result. The result is expected to be sent back to the packaged_action using the LCO’s set_event action

+

A packaged_action is one of the simplest synchronization primitives provided by HPX. It allows to synchronize on a eager evaluated remote operation returning a result of the type Result.

+
+

Note

+

The action executed using the packaged_action as a continuation must return a value of a type convertible to the type as specified by the template parameter Result.

+
+
+
Template Parameters
+
    +
  • Action – The template parameter Action defines the action to be executed by this packaged_action instance. The arguments arg0,… argN are used as parameters for this action.

  • +
  • Result – The template parameter Result defines the type this packaged_action is expected to return from its associated future packaged_action::get_future.

  • +
  • DirectExecute – The template parameter DirectExecute is an optimization aid allowing to execute the action directly if the target is local (without spawning a new thread for this). This template does not have to be supplied explicitly as it is derived from the template parameter Action.

  • +
+
+
+
+ +
+ +
+ +
+
+namespace lcos
+
+ +
+
+
hpx/async_distributed/packaged_action.hpp#
+

Defined in header hpx/async_distributed/packaged_action.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace lcos
+
+
+template<typename Action, typename Result = typename traits::promise_local_result<typename Action::remote_result_type>::type, bool DirectExecute = Action::direct_execution::value>
class packaged_action
+
+#include <packaged_action.hpp>
+
+ +
+
+template<typename Action, typename Result>
class packaged_action<Action, Result, false> : public hpx::distributed::promise<Result, hpx::traits::extract_action<Action>::remote_result_type>#
+

Subclassed by hpx::lcos::packaged_action< Action, Result, true >

+
+

Public Functions

+
+
+inline packaged_action()#
+
+ +
+
+template<typename Allocator>
inline packaged_action(std::allocator_arg_t, Allocator const &alloc)#
+
+ +
+
+template<typename ...Ts>
inline void post(hpx::id_type const &id, Ts&&... vs)#
+
+ +
+
+template<typename ...Ts>
inline void post(naming::address &&addr, hpx::id_type const &id, Ts&&... vs)#
+
+ +
+
+template<typename Callback, typename ...Ts>
inline void post_cb(hpx::id_type const &id, Callback &&cb, Ts&&... vs)#
+
+ +
+
+template<typename Callback, typename ...Ts>
inline void post_cb(naming::address &&addr, hpx::id_type const &id, Callback &&cb, Ts&&... vs)#
+
+ +
+
+template<typename ...Ts>
inline void post_p(hpx::id_type const &id, hpx::launch policy, Ts&&... vs)#
+
+ +
+
+template<typename ...Ts>
inline void post_p(naming::address &&addr, hpx::id_type const &id, hpx::launch policy, Ts&&... vs)#
+
+ +
+
+template<typename Callback, typename ...Ts>
inline void post_p_cb(hpx::id_type const &id, hpx::launch policy, Callback &&cb, Ts&&... vs)#
+
+ +
+
+template<typename Callback, typename ...Ts>
inline void post_p_cb(naming::address &&addr, hpx::id_type const &id, hpx::launch policy, Callback &&cb, Ts&&... vs)#
+
+ +
+
+template<typename ...Ts>
inline void post_deferred(naming::address &&addr, hpx::id_type const &id, hpx::launch policy, Ts&&... vs)#
+
+ +
+
+template<typename Callback, typename ...Ts>
inline void post_deferred_cb(naming::address &&addr, hpx::id_type const &id, hpx::launch policy, Callback &&cb, Ts&&... vs)#
+
+ +
+
+

Protected Types

+
+
+using action_type = typename hpx::traits::extract_action<Action>::type#
+
+ +
+
+using remote_result_type = typename action_type::remote_result_type#
+
+ +
+
+using base_type = hpx::distributed::promise<Result, remote_result_type>#
+
+ +
+
+

Protected Functions

+
+
+template<typename ...Ts>
inline void do_post(naming::address &&addr, hpx::id_type const &id, hpx::launch policy, Ts&&... vs)#
+
+ +
+
+template<typename ...Ts>
inline void do_post(hpx::id_type const &id, hpx::launch policy, Ts&&... vs)#
+
+ +
+
+template<typename Callback, typename ...Ts>
inline void do_post_cb(naming::address &&addr, hpx::id_type const &id, hpx::launch policy, Callback &&cb, Ts&&... vs)#
+
+ +
+
+template<typename Callback, typename ...Ts>
inline void do_post_cb(hpx::id_type const &id, hpx::launch policy, Callback &&cb, Ts&&... vs)#
+
+ +
+
+ +
+
+template<typename Action, typename Result>
class packaged_action<Action, Result, true> : public hpx::lcos::packaged_action<Action, Result, false>#
+
+

Public Functions

+
+
+inline packaged_action()#
+

Construct a (non-functional) instance of an packaged_action. To use this instance its member function post needs to be directly called.

+
+ +
+
+template<typename Allocator>
inline packaged_action(std::allocator_arg_t, Allocator const &alloc)#
+
+ +
+
+template<typename ...Ts>
inline void post(hpx::id_type const &id, Ts&&... vs)#
+
+ +
+
+template<typename ...Ts>
inline void post(naming::address &&addr, hpx::id_type const &id, Ts&&... vs)#
+
+ +
+
+template<typename Callback, typename ...Ts>
inline void post_cb(hpx::id_type const &id, Callback &&cb, Ts&&... vs)#
+
+ +
+
+template<typename Callback, typename ...Ts>
inline void post_cb(naming::address &&addr, hpx::id_type const &id, Callback &&cb, Ts&&... vs)#
+
+ +
+
+

Private Types

+
+
+using action_type = typename packaged_action<Action, Result, false>::action_type#
+
+ +
+
+ +
+ +
+ +
+
+
hpx::post (distributed)#
+

Defined in header hpx/async.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename Action, typename Target, typename ...Ts>
bool post(Action &&action, Target &&target, Ts&&... ts)#
+

The distributed implementation of hpx::post can be used by giving an action instance as argument instead of a function, and also by providing another argument with the locality ID or the target ID.

+
+
Template Parameters
+
    +
  • Action – The type of action instance

  • +
  • Target – The type of target where the action should be executed

  • +
  • Ts – The type of any additional arguments

  • +
+
+
Parameters
+
    +
  • action – The action instance to be executed

  • +
  • target – The target where the action should be executed

  • +
  • ts – Additional arguments

  • +
+
+
Returns
+

true if the action was successfully posted, false otherwise.

+
+
+
+ +
+
+ +
+
+
hpx/async_distributed/promise.hpp#
+

Defined in header hpx/async_distributed/promise.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<>
class hpx::distributed::promise<void, hpx::util::unused_type> : public lcos::detail::promise_base<void, hpx::util::unused_type, lcos::detail::promise_data<void>>#
+
+

Public Functions

+
+
+promise() = default#
+

constructs a promise object and a shared state.

+
+ +
+
+template<typename Allocator>
inline promise(std::allocator_arg_t, Allocator const &a)#
+

constructs a promise object and a shared state. The constructor uses the allocator a to allocate the memory for the shared state.

+
+ +
+
+promise(promise &&other) noexcept = default#
+

constructs a new promise object and transfers ownership of the shared state of other (if any) to the newly- constructed object.

+
+
Post
+

other has no shared state.

+
+
+
+ +
+
+~promise() = default#
+

Abandons any shared state.

+
+ +
+
+promise &operator=(promise &&other) noexcept = default#
+

Abandons any shared state (30.6.4) and then as if promise(HPX_MOVE(other)).swap(*this).

+
+
Returns
+

*this.

+
+
+
+ +
+
+inline void swap(promise &other) noexcept#
+

Exchanges the shared state of *this and other.

+
+
Post
+

*this has the shared state (if any) that other had prior to the call to swap. other has the shared state (if any) that *this had prior to the call to swap.

+
+
+
+ +
+
+inline void set_value()#
+

atomically stores the value r in the shared state and makes that state ready (30.6.4).

+
+
Throws
+

future_error – if its shared state already has a stored value. if shared state has no stored value exception is raised. promise_already_satisfied if its shared state already has a stored value or exception. no_state if *this has no shared state.

+
+
+
+ +
+
+

Private Types

+
+
+using base_type = lcos::detail::promise_base<void, hpx::util::unused_type, lcos::detail::promise_data<void>>#
+
+ +
+
+ +
+
+template<typename R, typename Allocator>
struct uses_allocator<hpx::distributed::promise<R>, Allocator> : public true_type#
+
+#include <promise.hpp>
+

Requires: Allocator shall be an allocator (17.6.3.5)

+
+ +
+
+namespace hpx
+
+
+namespace distributed
+
+

Functions

+
+
+template<typename Result, typename RemoteResult>
void swap(promise<Result, RemoteResult> &x, promise<Result, RemoteResult> &y) noexcept#
+
+ +
+
+
+template<typename Result, typename RemoteResult>
class promise
+
+#include <promise.hpp>
+
+ +
+
+template<> unused_type > : public lcos::detail::promise_base< void, hpx::util::unused_type, lcos::detail::promise_data< void > >
+
+

Public Functions

+
+
+promise() = default#
+

constructs a promise object and a shared state.

+
+ +
+
+template<typename Allocator>
inline promise(std::allocator_arg_t, Allocator const &a)#
+

constructs a promise object and a shared state. The constructor uses the allocator a to allocate the memory for the shared state.

+
+ +
+
+promise(promise &&other) noexcept = default#
+

constructs a new promise object and transfers ownership of the shared state of other (if any) to the newly- constructed object.

+
+
Post
+

other has no shared state.

+
+
+
+ +
+
+~promise() = default#
+

Abandons any shared state.

+
+ +
+
+promise &operator=(promise &&other) noexcept = default#
+

Abandons any shared state (30.6.4) and then as if promise(HPX_MOVE(other)).swap(*this).

+
+
Returns
+

*this.

+
+
+
+ +
+
+inline void swap(promise &other) noexcept#
+

Exchanges the shared state of *this and other.

+
+
Post
+

*this has the shared state (if any) that other had prior to the call to swap. other has the shared state (if any) that *this had prior to the call to swap.

+
+
+
+ +
+
+inline void set_value()#
+

atomically stores the value r in the shared state and makes that state ready (30.6.4).

+
+
Throws
+

future_error – if its shared state already has a stored value. if shared state has no stored value exception is raised. promise_already_satisfied if its shared state already has a stored value or exception. no_state if *this has no shared state.

+
+
+
+ +
+
+

Private Types

+
+
+using base_type = lcos::detail::promise_base<void, hpx::util::unused_type, lcos::detail::promise_data<void>>#
+
+ +
+
+ +
+ +
+ +
+
+namespace std
+
+
+template<typename R, typename Allocator> promise< R >, Allocator > : public true_type
+
+#include <promise.hpp>
+

Requires: Allocator shall be an allocator (17.6.3.5)

+
+ +
+ +
+
+
hpx::sync (distributed)#
+

Defined in header hpx/async.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename Action, typename Target, typename ...Ts>
decltype(auto) sync(Action &&action, Target &&target, Ts&&... ts)#
+

The distributed implementation of hpx::sync can be used by giving an action instance as argument instead of a function, and also by providing another argument with the locality ID or the target ID. The action executes synchronously.

+
+
Template Parameters
+
    +
  • Action – The type of action instance

  • +
  • Target – The type of target where the action should be executed

  • +
  • Ts – The type of any additional arguments

  • +
+
+
Parameters
+
    +
  • action – The action instance to be executed

  • +
  • target – The target where the action should be executed

  • +
  • ts – Additional arguments

  • +
+
+
Returns
+

hpx::future referring to the shared state created by this call to hpx::sync

+
+
+
+ +
+
+ +
+
+
hpx/async_distributed/transfer_continuation_action.hpp#
+

Defined in header hpx/async_distributed/transfer_continuation_action.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/async_distributed/trigger_lco.hpp#
+

Defined in header hpx/async_distributed/trigger_lco.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+ +
+
+
hpx/async_distributed/trigger_lco_fwd.hpp#
+

Defined in header hpx/async_distributed/trigger_lco_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+void trigger_lco_event(hpx::id_type const &id, naming::address &&addr, bool move_credits = true)#
+

Trigger the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should be triggered.

  • +
  • addr – [in] This represents the addr of the LCO which should be triggered.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+inline void trigger_lco_event(hpx::id_type const &id, bool move_credits = true)#
+

Trigger the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should be triggered.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+void trigger_lco_event(hpx::id_type const &id, naming::address &&addr, hpx::id_type const &cont, bool move_credits = true)#
+

Trigger the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should be triggered.

  • +
  • addr – [in] This represents the addr of the LCO which should be triggered.

  • +
  • cont – [in] This represents the LCO to trigger after completion.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+inline void trigger_lco_event(hpx::id_type const &id, hpx::id_type const &cont, bool move_credits = true)#
+

Trigger the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should be triggered.

  • +
  • cont – [in] This represents the LCO to trigger after completion.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+template<typename Result>
void set_lco_value(hpx::id_type const &id, naming::address &&addr, Result &&t, bool move_credits = true)#
+

Set the result value for the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the given value.

  • +
  • addr – [in] This represents the addr of the LCO which should be triggered.

  • +
  • t – [in] This is the value which should be sent to the LCO.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+template<typename Result>
std::enable_if_t<!std::is_same_v<std::decay_t<Result>, naming::address>> set_lco_value(hpx::id_type const &id, Result &&t, bool move_credits = true)#
+

Set the result value for the (managed) LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the given value.

  • +
  • t – [in] This is the value which should be sent to the LCO.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+template<typename Result>
std::enable_if_t<!std::is_same_v<std::decay_t<Result>, naming::address>> set_lco_value_unmanaged(hpx::id_type const &id, Result &&t, bool move_credits = true)#
+

Set the result value for the (unmanaged) LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the given value.

  • +
  • t – [in] This is the value which should be sent to the LCO.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+template<typename Result>
void set_lco_value(hpx::id_type const &id, naming::address &&addr, Result &&t, hpx::id_type const &cont, bool move_credits = true)#
+

Set the result value for the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the given value.

  • +
  • addr – [in] This represents the addr of the LCO which should be triggered.

  • +
  • t – [in] This is the value which should be sent to the LCO.

  • +
  • cont – [in] This represents the LCO to trigger after completion.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+template<typename Result>
std::enable_if_t<!std::is_same_v<std::decay_t<Result>, naming::address>> set_lco_value(hpx::id_type const &id, Result &&t, hpx::id_type const &cont, bool move_credits = true)#
+

Set the result value for the (managed) LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the given value.

  • +
  • t – [in] This is the value which should be sent to the LCO.

  • +
  • cont – [in] This represents the LCO to trigger after completion.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+template<typename Result>
std::enable_if_t<!std::is_same_v<std::decay_t<Result>, naming::address>> set_lco_value_unmanaged(hpx::id_type const &id, Result &&t, hpx::id_type const &cont, bool move_credits = true)#
+

Set the result value for the (unmanaged) LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the given value.

  • +
  • t – [in] This is the value which should be sent to the LCO.

  • +
  • cont – [in] This represents the LCO to trigger after completion.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+void set_lco_error(hpx::id_type const &id, naming::address &&addr, std::exception_ptr const &e, bool move_credits = true)#
+

Set the error state for the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the error value.

  • +
  • addr – [in] This represents the addr of the LCO which should be triggered.

  • +
  • e – [in] This is the error value which should be sent to the LCO.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+void set_lco_error(hpx::id_type const &id, naming::address &&addr, std::exception_ptr &&e, bool move_credits = true)#
+

Set the error state for the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the error value.

  • +
  • addr – [in] This represents the addr of the LCO which should be triggered.

  • +
  • e – [in] This is the error value which should be sent to the LCO.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+inline void set_lco_error(hpx::id_type const &id, std::exception_ptr const &e, bool move_credits = true)#
+

Set the error state for the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the error value.

  • +
  • e – [in] This is the error value which should be sent to the LCO.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+inline void set_lco_error(hpx::id_type const &id, std::exception_ptr &&e, bool move_credits = true)#
+

Set the error state for the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the error value.

  • +
  • e – [in] This is the error value which should be sent to the LCO.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+void set_lco_error(hpx::id_type const &id, naming::address &&addr, std::exception_ptr const &e, hpx::id_type const &cont, bool move_credits = true)#
+

Set the error state for the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the error value.

  • +
  • addr – [in] This represents the addr of the LCO which should be triggered.

  • +
  • e – [in] This is the error value which should be sent to the LCO.

  • +
  • cont – [in] This represents the LCO to trigger after completion.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+void set_lco_error(hpx::id_type const &id, naming::address &&addr, std::exception_ptr &&e, hpx::id_type const &cont, bool move_credits = true)#
+

Set the error state for the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the error value.

  • +
  • addr – [in] This represents the addr of the LCO which should be triggered.

  • +
  • e – [in] This is the error value which should be sent to the LCO.

  • +
  • cont – [in] This represents the LCO to trigger after completion.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+inline void set_lco_error(hpx::id_type const &id, std::exception_ptr const &e, hpx::id_type const &cont, bool move_credits = true)#
+

Set the error state for the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the error value.

  • +
  • e – [in] This is the error value which should be sent to the LCO.

  • +
  • cont – [in] This represents the LCO to trigger after completion.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+inline void set_lco_error(hpx::id_type const &id, std::exception_ptr &&e, hpx::id_type const &cont, bool move_credits = true)#
+

Set the error state for the LCO referenced by the given id.

+
+
Parameters
+
    +
  • id – [in] This represents the id of the LCO which should receive the error value.

  • +
  • e – [in] This is the error value which should be sent to the LCO.

  • +
  • cont – [in] This represents the LCO to trigger after completion.

  • +
  • move_credits – [in] If this is set to true then it is ok to send all credits in id along with the generated message. The default value is true.

  • +
+
+
+
+ +
+
+ +
+
+
+
+
checkpoint#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/checkpoint/checkpoint.hpp#
+

Defined in header hpx/checkpoint/checkpoint.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+

This header defines the save_checkpoint and restore_checkpoint functions. These functions are designed to help HPX application developer’s checkpoint their applications. Save_checkpoint serializes one or more objects and saves them as a byte stream. Restore_checkpoint converts the byte stream back into instances of the objects.

+
+
+namespace hpx
+
+
+namespace util
+
+

Functions

+
+
+inline std::ostream &operator<<(std::ostream &ost, checkpoint const &ckp)#
+

Operator<< Overload

+

+This overload is the main way to write data from a checkpoint to an object such as a file. Inside the function, the size of the checkpoint will be written to the stream before the checkpoint’s data. The operator>> overload uses this to read the correct number of bytes. Be mindful of this additional write and read when you use different facilities to write out or read in data to a checkpoint!

+
+
Parameters
+
    +
  • ost – Output stream to write to.

  • +
  • ckp – Checkpoint to copy from.

  • +
+
+
Returns
+

Operator<< returns the ostream object.

+
+
+
+ +
+
+inline std::istream &operator>>(std::istream &ist, checkpoint &ckp)#
+

Operator>> Overload

+

+This overload is the main way to read in data from an object such as a file to a checkpoint. It is important to note that inside the function, the first variable to be read is the size of the checkpoint. This size variable is written to the stream before the checkpoint’s data in the operator<< overload. Be mindful of this additional read and write when you use different facilities to read in or write out data from a checkpoint!

+
+
Parameters
+
    +
  • ist – Input stream to write from.

  • +
  • ckp – Checkpoint to write to.

  • +
+
+
Returns
+

Operator>> returns the ostream object.

+
+
+
+ +
+
+template<typename T, typename ...Ts, typename U = typename std::enable_if<!hpx::traits::is_launch_policy<T>::value && !std::is_same<typename std::decay<T>::type, checkpoint>::value>::type>
hpx::future<checkpoint> save_checkpoint(T &&t, Ts&&... ts)#
+

Save_checkpoint

+

+Save_checkpoint takes any number of objects which a user may wish to store and returns a future to a checkpoint object. This function can also store a component either by passing a shared_ptr to the component or by passing a component’s client instance to save_checkpoint. Additionally the function can take a policy as a first object which changes its behavior depending on the policy passed to it. Most notably, if a sync policy is used save_checkpoint will simply return a checkpoint object.

+
+
Template Parameters
+
    +
  • T – Containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
  • Ts – More containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
  • U – This parameter is used to make sure that T is not a launch policy or a checkpoint. This forces the compiler to choose the correct overload.

  • +
+
+
Parameters
+
    +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

Save_checkpoint returns a future to a checkpoint with one exception: if you pass hpx::launch::sync as the first argument. In this case save_checkpoint will simply return a checkpoint.

+
+
+
+ +
+
+template<typename T, typename ...Ts>
hpx::future<checkpoint> save_checkpoint(checkpoint &&c, T &&t, Ts&&... ts)#
+

Save_checkpoint - Take a pre-initialized checkpoint

+

+Save_checkpoint takes any number of objects which a user may wish to store and returns a future to a checkpoint object. This function can also store a component either by passing a shared_ptr to the component or by passing a component’s client instance to save_checkpoint. Additionally the function can take a policy as a first object which changes its behavior depending on the policy passed to it. Most notably, if a sync policy is used save_checkpoint will simply return a checkpoint object.

+
+
Template Parameters
+
    +
  • T – Containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
  • Ts – More containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
+
+
Parameters
+
    +
  • c – Takes a pre-initialized checkpoint to copy data into.

  • +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

Save_checkpoint returns a future to a checkpoint with one exception: if you pass hpx::launch::sync as the first argument. In this case save_checkpoint will simply return a checkpoint.

+
+
+
+ +
+
+template<typename T, typename ...Ts, typename U = typename std::enable_if<!std::is_same<typename std::decay<T>::type, checkpoint>::value>::type>
hpx::future<checkpoint> save_checkpoint(hpx::launch p, T &&t, Ts&&... ts)#
+

Save_checkpoint - Policy overload

+

+Save_checkpoint takes any number of objects which a user may wish to store and returns a future to a checkpoint object. This function can also store a component either by passing a shared_ptr to the component or by passing a component’s client instance to save_checkpoint. Additionally the function can take a policy as a first object which changes its behavior depending on the policy passed to it. Most notably, if a sync policy is used save_checkpoint will simply return a checkpoint object.

+
+
Template Parameters
+
    +
  • T – Containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
  • Ts – More containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
+
+
Parameters
+
    +
  • p – Takes an HPX launch policy. Allows the user to change the way the function is launched i.e. async, sync, etc.

  • +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

Save_checkpoint returns a future to a checkpoint with one exception: if you pass hpx::launch::sync as the first argument. In this case save_checkpoint will simply return a checkpoint.

+
+
+
+ +
+
+template<typename T, typename ...Ts>
hpx::future<checkpoint> save_checkpoint(hpx::launch p, checkpoint &&c, T &&t, Ts&&... ts)#
+

Save_checkpoint - Policy overload & pre-initialized checkpoint

+

+Save_checkpoint takes any number of objects which a user may wish to store and returns a future to a checkpoint object. This function can also store a component either by passing a shared_ptr to the component or by passing a component’s client instance to save_checkpoint. Additionally the function can take a policy as a first object which changes its behavior depending on the policy passed to it. Most notably, if a sync policy is used save_checkpoint will simply return a checkpoint object.

+
+
Template Parameters
+
    +
  • T – Containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
  • Ts – More containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
+
+
Parameters
+
    +
  • p – Takes an HPX launch policy. Allows the user to change the way the function is launched i.e. async, sync, etc.

  • +
  • c – Takes a pre-initialized checkpoint to copy data into.

  • +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

Save_checkpoint returns a future to a checkpoint with one exception: if you pass hpx::launch::sync as the first argument. In this case save_checkpoint will simply return a checkpoint.

+
+
+
+ +
+
+template<typename T, typename ...Ts, typename U = typename std::enable_if<!std::is_same<typename std::decay<T>::type, checkpoint>::value>::type>
checkpoint save_checkpoint(hpx::launch::sync_policy sync_p, T &&t, Ts&&... ts)#
+

Save_checkpoint - Sync_policy overload

+

+Save_checkpoint takes any number of objects which a user may wish to store and returns a future to a checkpoint object. This function can also store a component either by passing a shared_ptr to the component or by passing a component’s client instance to save_checkpoint. Additionally the function can take a policy as a first object which changes its behavior depending on the policy passed to it. Most notably, if a sync policy is used save_checkpoint will simply return a checkpoint object.

+
+
Template Parameters
+
    +
  • T – Containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
  • Ts – More containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
  • U – This parameter is used to make sure that T is not a checkpoint. This forces the compiler to choose the correct overload.

  • +
+
+
Parameters
+
    +
  • sync_p – hpx::launch::sync_policy

  • +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

Save_checkpoint which is passed hpx::launch::sync_policy will return a checkpoint which contains the serialized values checkpoint.

+
+
+
+ +
+
+template<typename T, typename ...Ts>
checkpoint save_checkpoint(hpx::launch::sync_policy sync_p, checkpoint &&c, T &&t, Ts&&... ts)#
+

Save_checkpoint - Sync_policy overload & pre-init. checkpoint

+

+Save_checkpoint takes any number of objects which a user may wish to store and returns a future to a checkpoint object. This function can also store a component either by passing a shared_ptr to the component or by passing a component’s client instance to save_checkpoint. Additionally the function can take a policy as a first object which changes its behavior depending on the policy passed to it. Most notably, if a sync policy is used save_checkpoint will simply return a checkpoint object.

+
+
Template Parameters
+
    +
  • T – Containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
  • Ts – More containers passed to save_checkpoint to be serialized and placed into a checkpoint object.

  • +
+
+
Parameters
+
    +
  • sync_p – hpx::launch::sync_policy

  • +
  • c – Takes a pre-initialized checkpoint to copy data into.

  • +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

Save_checkpoint which is passed hpx::launch::sync_policy will return a checkpoint which contains the serialized values checkpoint.

+
+
+
+ +
+
+template<typename T, typename ...Ts, typename U = typename std::enable_if<!hpx::traits::is_launch_policy<T>::value && !std::is_same<typename std::decay<T>::type, checkpoint>::value>::type>
hpx::future<checkpoint> prepare_checkpoint(T const &t, Ts const&... ts)#
+

prepare_checkpoint

+

prepare_checkpoint takes the containers which have to be filled from the byte stream by a subsequent restore_checkpoint invocation. prepare_checkpoint will calculate the necessary buffer size and will return an appropriately sized checkpoint object.

+
+
Template Parameters
+
    +
  • T – A container to restore.

  • +
  • Ts – Other containers to restore. Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Parameters
+
    +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

prepare_checkpoint returns a properly resized checkpoint object that can be used for a subsequent restore_checkpoint operation.

+
+
+
+ +
+
+template<typename T, typename ...Ts>
hpx::future<checkpoint> prepare_checkpoint(checkpoint &&c, T const &t, Ts const&... ts)#
+

prepare_checkpoint

+

prepare_checkpoint takes the containers which have to be filled from the byte stream by a subsequent restore_checkpoint invocation. prepare_checkpoint will calculate the necessary buffer size and will return an appropriately sized checkpoint object.

+
+
Template Parameters
+
    +
  • T – A container to restore.

  • +
  • Ts – Other containers to restore. Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Parameters
+
    +
  • c – Takes a pre-initialized checkpoint to prepare

  • +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

prepare_checkpoint returns a properly resized checkpoint object that can be used for a subsequent restore_checkpoint operation.

+
+
+
+ +
+
+template<typename T, typename ...Ts, typename U = typename std::enable_if<!std::is_same<T, checkpoint>::value>::type>
hpx::future<checkpoint> prepare_checkpoint(hpx::launch p, T const &t, Ts const&... ts)#
+

prepare_checkpoint

+

prepare_checkpoint takes the containers which have to be filled from the byte stream by a subsequent restore_checkpoint invocation. prepare_checkpoint will calculate the necessary buffer size and will return an appropriately sized checkpoint object.

+
+
Template Parameters
+
    +
  • T – A container to restore.

  • +
  • Ts – Other containers to restore. Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Parameters
+
    +
  • p – Takes an HPX launch policy. Allows the user to change the way the function is launched i.e. async, sync, etc.

  • +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

prepare_checkpoint returns a properly resized checkpoint object that can be used for a subsequent restore_checkpoint operation.

+
+
+
+ +
+
+template<typename T, typename ...Ts>
hpx::future<checkpoint> prepare_checkpoint(hpx::launch p, checkpoint &&c, T const &t, Ts const&... ts)#
+

prepare_checkpoint

+

prepare_checkpoint takes the containers which have to be filled from the byte stream by a subsequent restore_checkpoint invocation. prepare_checkpoint will calculate the necessary buffer size and will return an appropriately sized checkpoint object.

+
+
Template Parameters
+
    +
  • T – A container to restore.

  • +
  • Ts – Other containers to restore. Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Parameters
+
    +
  • p – Takes an HPX launch policy. Allows the user to change the way the function is launched i.e. async, sync, etc.

  • +
  • c – Takes a pre-initialized checkpoint to prepare

  • +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

prepare_checkpoint returns a properly resized checkpoint object that can be used for a subsequent restore_checkpoint operation.

+
+
+
+ +
+
+template<typename T, typename ...Ts>
void restore_checkpoint(checkpoint const &c, T &t, Ts&... ts)#
+

Restore_checkpoint

+

Restore_checkpoint takes a checkpoint object as a first argument and the containers which will be filled from the byte stream (in the same order as they were placed in save_checkpoint). Restore_checkpoint can resurrect a stored component in two ways: by passing in a instance of a component’s shared_ptr or by passing in an instance of the component’s client.

+
+
Template Parameters
+
    +
  • T – A container to restore.

  • +
  • Ts – Other containers to restore. Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Parameters
+
    +
  • c – The checkpoint to restore.

  • +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

Restore_checkpoint returns void.

+
+
+
+ +
+
+
+class checkpoint#
+
+#include <checkpoint.hpp>
+

Checkpoint Object

+

Checkpoint is the container object which is produced by save_checkpoint and is consumed by a restore_checkpoint. A checkpoint may be moved into the save_checkpoint object to write the byte stream to the pre-created checkpoint object.

+

Checkpoints are able to store all containers which are able to be serialized including components.

+
+

Public Types

+
+
+using const_iterator = std::vector<char>::const_iterator#
+
+ +
+
+

Public Functions

+
+
+checkpoint() = default#
+
+ +
+
+~checkpoint() = default#
+
+ +
+
+checkpoint(checkpoint const &c) = default#
+
+ +
+
+checkpoint(checkpoint &&c) noexcept = default#
+
+ +
+
+inline checkpoint(std::vector<char> const &vec)#
+
+ +
+
+inline checkpoint(std::vector<char> &&vec) noexcept#
+
+ +
+
+checkpoint &operator=(checkpoint const &c) = default#
+
+ +
+
+checkpoint &operator=(checkpoint &&c) noexcept = default#
+
+ +
+
+inline const_iterator begin() const noexcept#
+
+ +
+
+inline const_iterator end() const noexcept#
+
+ +
+
+inline std::size_t size() const noexcept#
+
+ +
+
+inline char *data() noexcept#
+
+ +
+
+inline char const *data() const noexcept#
+
+ +
+
+

Private Functions

+
+
+template<typename Archive>
inline void serialize(Archive &arch, const unsigned int)#
+
+ +
+
+

Private Members

+
+
+std::vector<char> data_#
+
+ +
+
+

Friends

+
+
+friend class hpx::serialization::access
+
+ +
+
+friend std::ostream &operator<<(std::ostream &ost, checkpoint const &ckp)#
+

Operator<< Overload

+

+This overload is the main way to write data from a checkpoint to an object such as a file. Inside the function, the size of the checkpoint will be written to the stream before the checkpoint’s data. The operator>> overload uses this to read the correct number of bytes. Be mindful of this additional write and read when you use different facilities to write out or read in data to a checkpoint!

+
+
Parameters
+
    +
  • ost – Output stream to write to.

  • +
  • ckp – Checkpoint to copy from.

  • +
+
+
Returns
+

Operator<< returns the ostream object.

+
+
+
+ +
+
+friend std::istream &operator>>(std::istream &ist, checkpoint &ckp)#
+

Operator>> Overload

+

+This overload is the main way to read in data from an object such as a file to a checkpoint. It is important to note that inside the function, the first variable to be read is the size of the checkpoint. This size variable is written to the stream before the checkpoint’s data in the operator<< overload. Be mindful of this additional read and write when you use different facilities to read in or write out data from a checkpoint!

+
+
Parameters
+
    +
  • ist – Input stream to write from.

  • +
  • ckp – Checkpoint to write to.

  • +
+
+
Returns
+

Operator>> returns the ostream object.

+
+
+
+ +
+
+template<typename T, typename ...Ts>
friend void restore_checkpoint(checkpoint const &c, T &t, Ts&... ts)#
+

Restore_checkpoint

+

Restore_checkpoint takes a checkpoint object as a first argument and the containers which will be filled from the byte stream (in the same order as they were placed in save_checkpoint). Restore_checkpoint can resurrect a stored component in two ways: by passing in a instance of a component’s shared_ptr or by passing in an instance of the component’s client.

+
+
Template Parameters
+
    +
  • T – A container to restore.

  • +
  • Ts – Other containers to restore. Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Parameters
+
    +
  • c – The checkpoint to restore.

  • +
  • t – A container to restore.

  • +
  • ts – Other containers to restore Containers must be in the same order that they were inserted into the checkpoint.

  • +
+
+
Returns
+

Restore_checkpoint returns void.

+
+
+
+ +
+
+inline friend bool operator==(checkpoint const &lhs, checkpoint const &rhs)#
+
+ +
+
+inline friend bool operator!=(checkpoint const &lhs, checkpoint const &rhs)#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
checkpoint_base#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/checkpoint_base/checkpoint_data.hpp#
+

Defined in header hpx/checkpoint_base/checkpoint_data.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace util
+
+

Functions

+
+
+template<typename Container, typename ...Ts>
void save_checkpoint_data(Container &data, Ts&&... ts)#
+

save_checkpoint_data

+

+Save_checkpoint_data takes any number of objects which a user may wish to store in the given container.

+
+
Template Parameters
+
    +
  • Container – Container used to store the check-pointed data.

  • +
  • Ts – Types of variables to checkpoint

  • +
+
+
Parameters
+
    +
  • data – Container instance used to store the checkpoint data

  • +
  • ts – Variable instances to be inserted into the checkpoint.

  • +
+
+
+
+ +
+
+template<typename ...Ts>
std::size_t prepare_checkpoint_data(Ts const&... ts)#
+

prepare_checkpoint_data

+

+prepare_checkpoint_data takes any number of objects which a user may wish to store in a subsequent save_checkpoint_data operation. The function will return the number of bytes necessary to store the data that will be produced.

+
+
Template Parameters
+

Ts – Types of variables to checkpoint

+
+
Parameters
+

ts – Variable instances to be inserted into the checkpoint.

+
+
+
+ +
+
+template<typename Container, typename ...Ts>
void restore_checkpoint_data(Container const &cont, Ts&... ts)#
+

restore_checkpoint_data

+

+restore_checkpoint_data takes any number of objects which a user may wish to restore from the given container. The sequence of objects has to correspond to the sequence of objects for the corresponding call to save_checkpoint_data that had used the given container instance.

+
+
Template Parameters
+
    +
  • Container – Container used to restore the check-pointed data.

  • +
  • Ts – Types of variables to restore

  • +
+
+
Parameters
+
    +
  • cont – Container instance used to restore the checkpoint data

  • +
  • ts – Variable instances to be restored from the container

  • +
+
+
+
+ +
+
+
+struct checkpointing_tag#
+
+ +
+
+template<>
struct extra_data_helper<checkpointing_tag>#
+
+

Public Static Functions

+
+
+static extra_data_id_type id() noexcept#
+
+ +
+
+static inline constexpr void reset(checkpointing_tag*) noexcept#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
collectives#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/collectives/all_gather.hpp#
+

Defined in header hpx/collectives/all_gather.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives#
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename T>
hpx::future<std::vector<std::decay_t<T>>> all_gather(char const *basename, T &&result, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg(), root_site_arg root_site = root_site_arg())#
+

AllGather a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+
+
Parameters
+
    +
  • basename – The base name identifying the all_gather operation

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_gather operation performed on the given base name. This is optional and needs to be supplied only if the all_gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero. \params root_site The site that is responsible for creating the all_gather support object. This value is optional and defaults to ‘0’ (zero).

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the all_gather operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<std::vector<std::decay_t<T>>> all_gather(communicator comm, T &&result, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

AllGather a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+

+AllGather a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the all_gather operation has been completed.

+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the all_gather operation has been completed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/all_reduce.hpp#
+

Defined in header hpx/collectives/all_reduce.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename T, typename F>
hpx::future<std::decay_t<T>> all_reduce(char const *basename, T &&result, F &&op, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg(), root_site_arg root_site = root_site_arg())#
+

AllReduce a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+
+
Parameters
+
    +
  • basename – The base name identifying the all_reduce operation

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns. \params root_site The site that is responsible for creating the all_reduce support object. This value is optional and defaults to ‘0’ (zero).

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the all_reduce operation has been completed.

+
+
+
+ +
+
+template<typename T, typename F>
hpx::future<std::decay_t<T>> all_reduce(communicator comm, T &&result, F &&op, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

AllReduce a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+

+AllReduce a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the all_reduce operation has been completed.

+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the all_reduce operation has been completed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/all_to_all.hpp#
+

Defined in header hpx/collectives/all_to_all.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename T>
hpx::future<std::vector<T>> all_to_all(char const *basename, std::vector<T> &&local_result, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg(), root_site_arg root_site = root_site_arg())#
+

AllToAll a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+
+
Parameters
+
    +
  • basename – The base name identifying the all_to_all operation

  • +
  • local_result – A vector of values to transmit to all participating sites from this call site.

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_to_all operation performed on the given base name. This is optional and needs to be supplied only if the all_to_all operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • root_site – The site that is responsible for creating the all_to_all support object. This value is optional and defaults to ‘0’ (zero).

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the all_to_all operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<std::vector<T>> all_to_all(communicator fid, std::vector<T> &&local_result, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

AllToAll a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+

+AllToAll a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+
+
Parameters
+
    +
  • fid – A communicator object returned from create_communicator

  • +
  • local_result – A vector of values to transmit to all participating sites from this call site.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_to_all operation performed on the given base name. This is optional and needs to be supplied only if the all_to_all operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • fid – A communicator object returned from create_communicator

  • +
  • local_result – A vector of values to transmit to all participating sites from this call site.

  • +
  • generation – The generational counter identifying the sequence number of the all_to_all operation performed on the given base name. This is optional and needs to be supplied only if the all_to_all operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the all_to_all operation has been completed.

+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the all_to_all operation has been completed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/argument_types.hpp#
+

Defined in header hpx/collectives/argument_types.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Typedefs

+
+
+using num_sites_arg = detail::argument_type<detail::num_sites_tag>#
+

The number of participating sites (default: all localities)

+
+ +
+
+using this_site_arg = detail::argument_type<detail::this_site_tag>#
+

The local end of the communication channel.

+
+ +
+
+using that_site_arg = detail::argument_type<detail::that_site_tag>#
+

The opposite end of the communication channel.

+
+ +
+
+using generation_arg = detail::argument_type<detail::generation_tag>#
+

The generational counter identifying the sequence number of the operation performed on the given base name. It needs to be supplied only if the operation on the given base name has to be performed more than once. It must be a positive number greater than zero.

+
+ +
+
+using root_site_arg = detail::argument_type<detail::root_site_tag, 0>#
+

The site that is responsible for creating the support object of the operation. It defaults to ‘0’ (zero).

+
+ +
+
+using tag_arg = detail::argument_type<detail::tag_tag, 0>#
+

The tag identifying the concrete operation.

+
+ +
+
+using arity_arg = detail::argument_type<detail::arity_tag>#
+

The number of children each of the communication nodes is connected to (default: picked based on num_sites).

+
+ +
+
+ +
+ +
+
+
hpx::distributed::barrier#
+

Defined in header hpx/barrier.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace distributed
+
+

Functions

+
+
+explicit barrier(std::string const &base_name)#
+

Creates a barrier, rank is locality id, size is number of localities

+

+A barrier base_name is created. It expects that hpx::get_num_localities() participate and the local rank is hpx::get_locality_id().

+
+
Parameters
+

base_name – The name of the barrier

+
+
+
+ +
+
+barrier(std::string const &base_name, std::size_t num)#
+

Creates a barrier with a given size, rank is locality id

+

+A barrier base_name is created. It expects that num participate and the local rank is hpx::get_locality_id().

+
+
Parameters
+
    +
  • base_name – The name of the barrier

  • +
  • num – The number of participating threads

  • +
+
+
+
+ +
+
+barrier(std::string const &base_name, std::size_t num, std::size_t rank)#
+

Creates a barrier with a given size and rank

+

+A barrier base_name is created. It expects that num participate and the local rank is rank.

+
+
Parameters
+
    +
  • base_name – The name of the barrier

  • +
  • num – The number of participating threads

  • +
  • rank – The rank of the calling site for this invocation

  • +
+
+
+
+ +
+
+barrier(std::string const &base_name, std::vector<std::size_t> const &ranks, std::size_t rank)#
+

Creates a barrier with a vector of ranks

+

+A barrier base_name is created. It expects that ranks.size() and the local rank is rank (must be contained in ranks).

+
+
Parameters
+
    +
  • base_name – The name of the barrier

  • +
  • ranks – Gives a list of participating ranks (this could be derived from a list of locality ids

  • +
  • rank – The rank of the calling site for this invocation

  • +
+
+
+
+ +
+
+void wait() const#
+

Wait until each participant entered the barrier. Must be called by all participants

+
+
Returns
+

This function returns once all participants have entered the barrier (have called wait).

+
+
+
+ +
+
+hpx::future<void> wait(hpx::launch::async_policy) const#
+

Wait until each participant entered the barrier. Must be called by all participants

+
+
Returns
+

a future that becomes ready once all participants have entered the barrier (have called wait).

+
+
+
+ +
+
+static void synchronize()#
+

Perform a global synchronization using the default global barrier The barrier is created once at startup and can be reused throughout the lifetime of an HPX application.

+
+

Note

+

This function currently does not support dynamic connection and disconnection of localities.

+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/broadcast.hpp#
+

Defined in header hpx/collectives/broadcast.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename T>
hpx::future<void> broadcast_to(char const *basename, T &&local_result, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Broadcast a value to different call sites

+

This function sends a set of values to all call sites operating on the given base name.

+
+
Parameters
+
    +
  • basename – The base name identifying the broadcast operation

  • +
  • local_result – A value to transmit to all participating sites from this call site.

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • generation – The generational counter identifying the sequence number of the broadcast operation performed on the given base name. This is optional and needs to be supplied only if the broadcast operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future that will become ready once the broadcast operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<void> broadcast_to(communicator comm, T &&local_result, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Broadcast a value to different call sites

+

This function sends a set of values to all call sites operating on the given base name.

+
+

Note

+

The generation values from corresponding broadcast_to and broadcast_from have to match.

+
+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – A value to transmit to all participating sites from this call site.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the broadcast operation performed on the given base name. This is optional and needs to be supplied only if the broadcast operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
+
+
Returns
+

This function returns a future that will become ready once the broadcast operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<void> broadcast_to(communicator comm, generation_arg generation, T &&local_result, this_site_arg this_site = this_site_arg())#
+

Broadcast a value to different call sites

+

This function sends a set of values to all call sites operating on the given base name.

+
+

Note

+

The generation values from corresponding broadcast_to and broadcast_from have to match.

+
+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – A value to transmit to all participating sites from this call site.

  • +
  • generation – The generational counter identifying the sequence number of the broadcast operation performed on the given base name. This is optional and needs to be supplied only if the broadcast operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future that will become ready once the broadcast operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<T> broadcast_from(char const *basename, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Receive a value that was broadcast to different call sites

+

This function sends a set of values to all call sites operating on the given base name.

+
+
Parameters
+
    +
  • basename – The base name identifying the broadcast operation

  • +
  • generation – The generational counter identifying the sequence number of the broadcast operation performed on the given base name. This is optional and needs to be supplied only if the broadcast operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding the value that was sent to all participating sites. It will become ready once the broadcast operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<T> broadcast_from(communicator comm, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Receive a value that was broadcast to different call sites

+

This function sends a set of values to all call sites operating on the given base name.

+

+Receive a value that was broadcast to different call sites

+

This function sends a set of values to all call sites operating on the given base name.

+
+

Note

+

The generation values from corresponding broadcast_to and broadcast_from have to match.

+
+
+

Note

+

The generation values from corresponding broadcast_to and broadcast_from have to match.

+
+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the broadcast operation performed on the given base name. This is optional and needs to be supplied only if the broadcast operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • comm – A communicator object returned from create_communicator

  • +
  • generation – The generational counter identifying the sequence number of the broadcast operation performed on the given base name. This is optional and needs to be supplied only if the broadcast operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding the value that was sent to all participating sites. It will become ready once the broadcast operation has been completed.

+
+
Returns
+

This function returns a future holding the value that was sent to all participating sites. It will become ready once the broadcast operation has been completed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/broadcast_direct.hpp#
+

Defined in header hpx/collectives/broadcast_direct.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace lcos
+
+

Functions

+
+
+template<typename Action, typename ArgN, ...> hpx::future< std::vector< decltype(Action(hpx::id_type, ArgN,...))> > broadcast (std::vector< hpx::id_type > const &ids, ArgN argN,...)
+

Perform a distributed broadcast operation.

+

The function hpx::lcos::broadcast performs a distributed broadcast operation resulting in action invocations on a given set of global identifiers. The action can be either a plain action (in which case the global identifiers have to refer to localities) or a component action (in which case the global identifiers have to refer to instances of a component type which exposes the action.

+

The given action is invoked asynchronously on all given identifiers, and the arguments ArgN are passed along to those invocations.

+
+

Note

+

If decltype(Action(…)) is void, then the result of this function is future<void>.

+
+
+
Parameters
+
    +
  • ids – [in] A list of global identifiers identifying the target objects for which the given action will be invoked.

  • +
  • argN – [in] Any number of arbitrary arguments (passed by const reference) which will be forwarded to the action invocation.

  • +
+
+
Returns
+

This function returns a future representing the result of the overall reduction operation.

+
+
+
+ +
+
+template<typename Action, typename ArgN, ...> void broadcast_post (std::vector< hpx::id_type > const &ids, ArgN argN,...)
+

Perform an asynchronous (fire&forget) distributed broadcast operation.

+

The function hpx::lcos::broadcast_post performs an asynchronous (fire&forget) distributed broadcast operation resulting in action invocations on a given set of global identifiers. The action can be either a plain action (in which case the global identifiers have to refer to localities) or a component action (in which case the global identifiers have to refer to instances of a component type which exposes the action.

+

The given action is invoked asynchronously on all given identifiers, and the arguments ArgN are passed along to those invocations.

+
+
Parameters
+
    +
  • ids – [in] A list of global identifiers identifying the target objects for which the given action will be invoked.

  • +
  • argN – [in] Any number of arbitrary arguments (passed by const reference) which will be forwarded to the action invocation.

  • +
+
+
+
+ +
+
+template<typename Action, typename ArgN, ...> hpx::future< std::vector< decltype(Action(hpx::id_type, ArgN,..., std::size_t))> > broadcast_with_index (std::vector< hpx::id_type > const &ids, ArgN argN,...)
+

Perform a distributed broadcast operation.

+

The function hpx::lcos::broadcast_with_index performs a distributed broadcast operation resulting in action invocations on a given set of global identifiers. The action can be either a plain action (in which case the global identifiers have to refer to localities) or a component action (in which case the global identifiers have to refer to instances of a component type which exposes the action.

+

The given action is invoked asynchronously on all given identifiers, and the arguments ArgN are passed along to those invocations.

+

The function passes the index of the global identifier in the given list of identifiers as the last argument to the action.

+
+

Note

+

If decltype(Action(…)) is void, then the result of this function is future<void>.

+
+
+
Parameters
+
    +
  • ids – [in] A list of global identifiers identifying the target objects for which the given action will be invoked.

  • +
  • argN – [in] Any number of arbitrary arguments (passed by const reference) which will be forwarded to the action invocation.

  • +
+
+
Returns
+

This function returns a future representing the result of the overall reduction operation.

+
+
+
+ +
+
+template<typename Action, typename ArgN, ...> void broadcast_post_with_index (std::vector< hpx::id_type > const &ids, ArgN argN,...)
+

Perform an asynchronous (fire&forget) distributed broadcast operation.

+

The function hpx::lcos::broadcast_post_with_index performs an asynchronous (fire&forget) distributed broadcast operation resulting in action invocations on a given set of global identifiers. The action can be either a plain action (in which case the global identifiers have to refer to localities) or a component action (in which case the global identifiers have to refer to instances of a component type which exposes the action.

+

The given action is invoked asynchronously on all given identifiers, and the arguments ArgN are passed along to those invocations.

+

The function passes the index of the global identifier in the given list of identifiers as the last argument to the action.

+
+
Parameters
+
    +
  • ids – [in] A list of global identifiers identifying the target objects for which the given action will be invoked.

  • +
  • argN – [in] Any number of arbitrary arguments (passed by const reference) which will be forwarded to the action invocation.

  • +
+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/channel_communicator.hpp#
+

Defined in header hpx/collectives/channel_communicator.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+hpx::future<channel_communicator> create_channel_communicator(char const *basename, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg())#
+

Create a new communicator object usable with peer-to-peer channel-based operations

+

This functions creates a new communicator object that can be called in order to pre-allocate a communicator object usable with multiple invocations of channel-based peer-to-peer operations.

+
+
Parameters
+
    +
  • basename – The base name identifying the collective operation

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future to a new communicator object usable with the collective operation.

+
+
+
+ +
+
+channel_communicator create_channel_communicator(hpx::launch::sync_policy, char const *basename, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg())#
+

Create a new communicator object usable with peer-to-peer channel-based operations

+

This functions creates a new communicator object that can be called in order to pre-allocate a communicator object usable with multiple invocations of channel-based peer-to-peer operations.

+
+
Parameters
+
    +
  • basename – The base name identifying the collective operation

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a new communicator object usable with the collective operation.

+
+
+
+ +
+
+template<typename T>
hpx::future<void> set(channel_communicator comm, that_site_arg site, T &&value, tag_arg tag = tag_arg())#
+

Send a value to the given site

+

This function sends a value to the given site based on the given communicator.

+
+
Parameters
+
    +
  • comm – The channel communicator object to use for the data transfer

  • +
  • site – The destination site

  • +
  • value – The value to send

  • +
  • tag – The (optional) tag identifying the concrete operation

  • +
+
+
Returns
+

This function returns a future<void> that becomes ready once the data transfer operation has finished.

+
+
+
+ +
+
+template<typename T>
hpx::future<T> get(channel_communicator comm, that_site_arg site, tag_arg tag = tag_arg())#
+

Send a value to the given site

+

This function receives a value from the given site based on the given communicator.

+
+
Parameters
+
    +
  • comm – The channel communicator object to use for the data transfer

  • +
  • site – The source site

  • +
+
+
Returns
+

This function returns a future<T> that becomes ready once the data transfer operation has finished. The future will hold the received value.

+
+
+
+ +
+
+
+class channel_communicator#
+
+#include <channel_communicator.hpp>
+

A handle identifying the communication channel to use for get/set operations

+
+ +
+ +
+ +
+
+
hpx/collectives/communication_set.hpp#
+

Defined in header hpx/collectives/communication_set.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+communicator create_communication_set(char const *basename, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg(), arity_arg arity = arity_arg())#
+

The function create_communication_set sets up a (distributed) tree-like communication structure that can be used with any of the collective APIs (such like all_to_all and similar).

+
+
Parameters
+
    +
  • basename – The base name identifying the all_to_all operation

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the collective operation performed on the given base name. This is optional and needs to be supplied only if the collective operation on the given base name has to be performed more than once.

  • +
  • arity – The number of children each of the communication nodes is connected to (default: picked based on num_sites).

  • +
+
+
Returns
+

This function returns a new communicator object usable with the collective operation.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/create_communicator.hpp#
+

Defined in header hpx/collectives/create_communicator.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+communicator create_communicator(char const *basename, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg(), root_site_arg root_site = root_site_arg())#
+

Create a new communicator object usable with any collective operation

+

This functions creates a new communicator object that can be called in order to pre-allocate a communicator object usable with multiple invocations of any of the collective operations (such as all_gather, all_reduce, all_to_all, broadcast, etc.).

+
+
Parameters
+
    +
  • basename – The base name identifying the collective operation

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the collective operation performed on the given base name. This is optional and needs to be supplied only if the collective operation on the given base name has to be performed more than once.

  • +
  • root_site – The site that is responsible for creating the collective support object. This value is optional and defaults to ‘0’ (zero).

  • +
+
+
Returns
+

This function returns a new communicator object usable with the collective operation.

+
+
+
+ +
+
+communicator create_local_communicator(char const *basename, num_sites_arg num_sites, this_site_arg this_site, generation_arg generation = generation_arg(), root_site_arg root_site = root_site_arg())#
+

Create a new communicator object usable with any local collective operation

+

This functions creates a new communicator object that can be called in order to pre-allocate a communicator object usable with multiple invocations of any of the collective operations (such as all_gather, all_reduce, all_to_all, broadcast, etc.).

+
+
Parameters
+
    +
  • basename – The base name identifying the collective operation

  • +
  • num_sites – The number of participating sites

  • +
  • this_site – The sequence number of this invocation (usually the sequence number of the object participating in the collective operation). This value must be in the range [0, num_sites).

  • +
  • generation – The generational counter identifying the sequence number of the collective operation performed on the given base name. This is optional and needs to be supplied only if the collective operation on the given base name has to be performed more than once.

  • +
  • root_site – The site that is responsible for creating the collective support object. This value is optional and defaults to ‘0’ (zero).

  • +
+
+
Returns
+

This function returns a new communicator object usable for all local collective operations.

+
+
+
+ +
+
+
+struct communicator#
+
+#include <create_communicator.hpp>
+

A communicator instance represents the list of sites that participate in a particular collective operation.

+
+

Public Functions

+
+
+void set_info(num_sites_arg num_sites, this_site_arg this_site) noexcept#
+

Store the number of used sites and the index of the current site for this communicator instance.

+
+
Parameters
+
    +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this site (usually the locality id).

  • +
+
+
+
+ +
+
+std::pair<num_sites_arg, this_site_arg> get_info() const noexcept#
+

Retrieve the number of used sites and the index of the current site for this communicator instance.

+
+ +
+
+bool is_root() const#
+

Return whether this communicator instance represents the root site of the communication operation.

+
+ +
+
+ +
+ +
+ +
+
+
hpx/collectives/exclusive_scan.hpp#
+

Defined in header hpx/collectives/exclusive_scan.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename T, typename F>
hpx::future<std::decay_t<T>> exclusive_scan(char const *basename, T &&result, F &&op, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg(), root_site_arg root_site = root_site_arg())#
+

Exclusive scan a set of values from different call sites

+

This function performs an exclusive scan operation on a set of values received from all call sites operating on the given base name.

+
+

Note

+

The result returned on the root_site is always the same as the result returned on thus_site == 1 and is the same as the value provided by the root_site.

+
+
+
Parameters
+
    +
  • basename – The base name identifying the exclusive_scan operation

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the exclusive_scan operation performed on the given base name. This is optional and needs to be supplied only if the exclusive_scan operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero. \params root_site The site that is responsible for creating the exclusive_scan support object. This value is optional and defaults to ‘0’ (zero).

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the exclusive_scan operation has been completed.

+
+
+
+ +
+
+template<typename T, typename F>
hpx::future<std::decay_t<T>> exclusive_scan(communicator comm, T &&result, F &&op, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Exclusive scan a set of values from different call sites

+

This function performs an exclusive scan operation on a set of values received from all call sites operating on the given base name.

+

+Exclusive scan a set of values from different call sites

+

This function performs an exclusive scan operation on a set of values received from all call sites operating on the given base name.

+
+

Note

+

The result returned on the root_site is always the same as the result returned on thus_site == 1 and is the same as the value provided by the root_site.

+
+
+

Note

+

The result returned on the root_site is always the same as the result returned on thus_site == 1 and is the same as the value provided by the root_site.

+
+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the exclusive_scan operation performed on the given base name. This is optional and needs to be supplied only if the exclusive_scan operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • generation – The generational counter identifying the sequence number of the exclusive_scan operation performed on the given base name. This is optional and needs to be supplied only if the exclusive_scan operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the exclusive_scan operation has been completed.

+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the exclusive_scan operation has been completed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/fold.hpp#
+

Defined in header hpx/collectives/fold.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace lcos
+
+

Functions

+
+
+template<typename Action, typename FoldOp, typename Init, typename ArgN, ...> hpx::future< decltype(Action(hpx::id_type, ArgN,...))> fold (std::vector< hpx::id_type > const &ids, FoldOp &&fold_op, Init &&init, ArgN argN,...)
+

Perform a distributed fold operation.

+

The function hpx::lcos::fold performs a distributed folding operation over results returned from action invocations on a given set of global identifiers. The action can be either a plain action (in which case the global identifiers have to refer to localities) or a component action (in which case the global identifiers have to refer to instances of a component type which exposes the action.

+
+

Note

+

The type of the initial value must be convertible to the result type returned from the invoked action.

+
+
+
Parameters
+
    +
  • ids – [in] A list of global identifiers identifying the target objects for which the given action will be invoked.

  • +
  • fold_op – [in] A binary function expecting two results as returned from the action invocations. The function (or function object) is expected to return the result of the folding operation performed on its arguments.

  • +
  • init – [in] The initial value to be used for the folding operation

  • +
  • argN – [in] Any number of arbitrary arguments (passed by value, by const reference or by rvalue reference) which will be forwarded to the action invocation.

  • +
+
+
Returns
+

This function returns a future representing the result of the overall folding operation.

+
+
+
+ +
+
+template<typename Action, typename FoldOp, typename Init, typename ArgN, ...> hpx::future< decltype(Action(hpx::id_type, ArgN,..., std::size_t))> fold_with_index (std::vector< hpx::id_type > const &ids, FoldOp &&fold_op, Init &&init, ArgN argN,...)
+

Perform a distributed folding operation.

+

The function hpx::lcos::fold_with_index performs a distributed folding operation over results returned from action invocations on a given set of global identifiers. The action can be either plain action (in which case the global identifiers have to refer to localities) or a component action (in which case the global identifiers have to refer to instances of a component type which exposes the action.

+

The function passes the index of the global identifier in the given list of identifiers as the last argument to the action.

+
+

Note

+

The type of the initial value must be convertible to the result type returned from the invoked action.

+
+
+
Parameters
+
    +
  • ids – [in] A list of global identifiers identifying the target objects for which the given action will be invoked.

  • +
  • fold_op – [in] A binary function expecting two results as returned from the action invocations. The function (or function object) is expected to return the result of the folding operation performed on its arguments.

  • +
  • init – [in] The initial value to be used for the folding operation

  • +
  • argN – [in] Any number of arbitrary arguments (passed by value, by const reference or by rvalue reference) which will be forwarded to the action invocation.

  • +
+
+
Returns
+

This function returns a future representing the result of the overall folding operation.

+
+
+
+ +
+
+template<typename Action, typename FoldOp, typename Init, typename ArgN, ...> hpx::future< decltype(Action(hpx::id_type, ArgN,...))> inverse_fold (std::vector< hpx::id_type > const &ids, FoldOp &&fold_op, Init &&init, ArgN argN,...)
+

Perform a distributed inverse folding operation.

+

The function hpx::lcos::inverse_fold performs an inverse distributed folding operation over results returned from action invocations on a given set of global identifiers. The action can be either a plain action (in which case the global identifiers have to refer to localities) or a component action (in which case the global identifiers have to refer to instances of a component type which exposes the action.

+
+

Note

+

The type of the initial value must be convertible to the result type returned from the invoked action.

+
+
+
Parameters
+
    +
  • ids – [in] A list of global identifiers identifying the target objects for which the given action will be invoked.

  • +
  • fold_op – [in] A binary function expecting two results as returned from the action invocations. The function (or function object) is expected to return the result of the folding operation performed on its arguments.

  • +
  • init – [in] The initial value to be used for the folding operation

  • +
  • argN – [in] Any number of arbitrary arguments (passed by value, by const reference or by rvalue reference) which will be forwarded to the action invocation.

  • +
+
+
Returns
+

This function returns a future representing the result of the overall folding operation.

+
+
+
+ +
+
+template<typename Action, typename FoldOp, typename Init, typename ArgN, ...> hpx::future< decltype(Action(hpx::id_type, ArgN,..., std::size_t))> inverse_fold_with_index (std::vector< hpx::id_type > const &ids, FoldOp &&fold_op, Init &&init, ArgN argN,...)
+

Perform a distributed inverse folding operation.

+

The function hpx::lcos::inverse_fold_with_index performs an inverse distributed folding operation over results returned from action invocations on a given set of global identifiers. The action can be either plain action (in which case the global identifiers have to refer to localities) or a component action (in which case the global identifiers have to refer to instances of a component type which exposes the action.

+

The function passes the index of the global identifier in the given list of identifiers as the last argument to the action.

+
+

Note

+

The type of the initial value must be convertible to the result type returned from the invoked action.

+
+
+
Parameters
+
    +
  • ids – [in] A list of global identifiers identifying the target objects for which the given action will be invoked.

  • +
  • fold_op – [in] A binary function expecting two results as returned from the action invocations. The function (or function object) is expected to return the result of the folding operation performed on its arguments.

  • +
  • init – [in] The initial value to be used for the folding operation

  • +
  • argN – [in] Any number of arbitrary arguments (passed by value, by const reference or by rvalue reference) which will be forwarded to the action invocation.

  • +
+
+
Returns
+

This function returns a future representing the result of the overall folding operation.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/gather.hpp#
+

Defined in header hpx/collectives/gather.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename T>
hpx::future<std::vector<decay_t<T>>> gather_here(char const *basename, T &&result, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Gather a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+
+
Parameters
+
    +
  • basename – The base name identifying the gather operation

  • +
  • result – The value to transmit to the central gather point from this call site.

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the gather operation performed on the given base name. This is optional and needs to be supplied only if the gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
+
+
Returns
+

This function returns a future holding a vector with all gathered values. It will become ready once the gather operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<std::vector<decay_t<T>>> gather_here(communicator comm, T &&result, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Gather a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+

+Gather a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+
+

Note

+

The generation values from corresponding gather_here and gather_there have to match.

+
+
+

Note

+

The generation values from corresponding gather_here and gather_there have to match.

+
+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • result – The value to transmit to the central gather point from this call site.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the gather operation performed on the given base name. This is optional and needs to be supplied only if the gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • comm – A communicator object returned from create_communicator

  • +
  • result – The value to transmit to the central gather point from this call site.

  • +
  • generation – The generational counter identifying the sequence number of the gather operation performed on the given base name. This is optional and needs to be supplied only if the gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a vector with all gathered values. It will become ready once the gather operation has been completed.

+
+
Returns
+

This function returns a future holding a vector with all gathered values. It will become ready once the gather operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<void> gather_there(char const *basename, T &&local_result, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg(), root_site_arg root_site = root_site_arg())#
+

Gather a given value at the given call site

+

This function transmits the value given by result to a central gather site (where the corresponding gather_here is executed)

+
+
Parameters
+
    +
  • basename – The base name identifying the gather operation

  • +
  • local_result – The value to transmit to the central gather point from this call site.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the gather operation performed on the given base name. This is optional and needs to be supplied only if the gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • root_site – The sequence number of the central gather point (usually the locality id). This value is optional and defaults to 0.

  • +
+
+
Returns
+

This function returns a future holding a vector with all gathered values. It will become ready once the gather operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<void> gather_there(communicator fid, T &&local_result, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Gather a given value at the given call site

+

This function transmits the value given by result to a central gather site (where the corresponding gather_here is executed)

+

+Gather a given value at the given call site

+

This function transmits the value given by result to a central gather site (where the corresponding gather_here is executed)

+
+

Note

+

The generation values from corresponding gather_here and gather_there have to match.

+
+
+

Note

+

The generation values from corresponding gather_here and gather_there have to match.

+
+
+
Parameters
+
    +
  • fid – A communicator object returned from create_communicator

  • +
  • local_result – The value to transmit to the central gather point from this call site.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the gather operation performed on the given base name. This is optional and needs to be supplied only if the gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • fid – A communicator object returned from create_communicator

  • +
  • local_result – The value to transmit to the central gather point from this call site.

  • +
  • generation – The generational counter identifying the sequence number of the gather operation performed on the given base name. This is optional and needs to be supplied only if the gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a vector with all gathered values. It will become ready once the gather operation has been completed.

+
+
Returns
+

This function returns a future holding a vector with all gathered values. It will become ready once the gather operation has been completed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/inclusive_scan.hpp#
+

Defined in header hpx/collectives/inclusive_scan.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename T, typename F>
hpx::future<std::decay_t<T>> inclusive_scan(char const *basename, T &&result, F &&op, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg(), root_site_arg root_site = root_site_arg())#
+

Inclusive inclusive_scan a set of values from different call sites

+

This function performs an inclusive scan operation on a set of values received from all call sites operating on the given base name.

+
+
Parameters
+
    +
  • basename – The base name identifying the inclusive_scan operation

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the inclusive_scan operation performed on the given base name. This is optional and needs to be supplied only if the inclusive_scan operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero. \params root_site The site that is responsible for creating the inclusive_scan support object. This value is optional and defaults to ‘0’ (zero).

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the inclusive_scan operation has been completed.

+
+
+
+ +
+
+template<typename T, typename F>
hpx::future<std::decay_t<T>> inclusive_scan(communicator comm, T &&result, F &&op, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Inclusive inclusive_scan a set of values from different call sites

+

This function performs an inclusive scan operation on a set of values received from all call sites operating on the given base name.

+

+Inclusive inclusive_scan a set of values from different call sites

+

This function performs an inclusive scan operation on a set of values received from all call sites operating on the given base name.

+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the inclusive_scan operation performed on the given base name. This is optional and needs to be supplied only if the inclusive_scan operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – The value to transmit to all participating sites from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • generation – The generational counter identifying the sequence number of the inclusive_scan operation performed on the given base name. This is optional and needs to be supplied only if the inclusive_scan operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the inclusive_scan operation has been completed.

+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the inclusive_scan operation has been completed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::distributed::latch#
+

Defined in header hpx/latch.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace distributed
+
+
+class latch : public components::client_base<latch, hpx::lcos::server::latch>#
+
+#include <latch.hpp>
+

Latch is an implementation of a synchronization primitive that allows multiple threads to wait for a shared event to occur before proceeding. This latch can be invoked in a distributed application.

+

For a local only latch

+

See also

+

hpx::latch.

+
+

+
+

Public Functions

+
+
+latch() = default#
+
+ +
+
+explicit latch(std::ptrdiff_t count)#
+

Initialize the latch

+

Requires: count >= 0. Synchronization: None Postconditions: counter_ == count.

+
+ +
+
+inline latch(hpx::id_type const &id)#
+

Extension: Create a client side representation for the existing server::latch instance with the given global id id.

+
+ +
+
+inline latch(hpx::future<hpx::id_type> &&f)#
+

Extension: Create a client side representation for the existing server::latch instance with the given global id id.

+
+ +
+
+inline latch(hpx::shared_future<hpx::id_type> const &id)#
+

Extension: Create a client side representation for the existing server::latch instance with the given global id id.

+
+ +
+
+inline latch(hpx::shared_future<hpx::id_type> &&id)#
+
+ +
+
+inline void count_down_and_wait()#
+

Decrements counter_ by 1 . Blocks at the synchronization point until counter_ reaches 0.

+

Requires: counter_ > 0.

+

Synchronization: Synchronizes with all calls that block on this latch and with all is_ready calls on this latch that return true.

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline void arrive_and_wait()#
+

Decrements counter_ by update . Blocks at the synchronization point until counter_ reaches 0.

+

Requires: counter_ > 0.

+

Synchronization: Synchronizes with all calls that block on this latch and with all is_ready calls on this latch that return true.

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline void count_down(std::ptrdiff_t n)#
+

Decrements counter_ by n. Does not block.

+

Requires: counter_ >= n and n >= 0.

+

Synchronization: Synchronizes with all calls that block on this latch and with all is_ready calls on this latch that return true .

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline bool is_ready() const noexcept#
+

Returns: counter_ == 0. Does not block.

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline bool try_wait() const noexcept#
+

Returns: counter_ == 0. Does not block.

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+inline void wait() const#
+

If counter_ is 0, returns immediately. Otherwise, blocks the calling thread at the synchronization point until counter_ reaches 0.

+
+
Throws
+

Nothing.

+
+
+
+ +
+
+

Private Types

+
+
+typedef components::client_base<latch, hpx::lcos::server::latch> base_type#
+
+ +
+
+ +
+ +
+
+namespace lcos
+
+ +
+ +
+
+
hpx/collectives/reduce.hpp#
+

Defined in header hpx/collectives/reduce.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename T, typename F>
hpx::future<std::decay_t<T>> reduce_here(char const *basename, T &&result, F &&op, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Reduce a set of values from different call sites

+

This function receives a set of values from all call sites operating on the given base name.

+
+
Parameters
+
    +
  • basename – The base name identifying the all_reduce operation

  • +
  • local_result – A value to reduce on the central reduction point from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
+
+
Returns
+

This function returns a future holding a vector with all values send by all participating sites. It will become ready once the all_reduce operation has been completed.

+
+
+
+ +
+
+template<typename T, typename F>
hpx::future<decay_t<T>> reduce_here(communicator comm, T &&local_result, F &&op, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Reduce a set of values from different call sites

+

This function receives a set of values that are the result of applying a given operator on values supplied from all call sites operating on the given base name.

+

+Reduce a set of values from different call sites

+

This function receives a set of values that are the result of applying a given operator on values supplied from all call sites operating on the given base name.

+
+

Note

+

The generation values from corresponding reduce_here and reduce_there have to match.

+
+
+

Note

+

The generation values from corresponding reduce_here and reduce_there have to match.

+
+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – A value to reduce on the root_site from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – A value to reduce on the root_site from this call site.

  • +
  • op – Reduction operation to apply to all values supplied from all participating sites

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a value calculated based on the values send by all participating sites. It will become ready once the all_reduce operation has been completed.

+
+
Returns
+

This function returns a future holding a value calculated based on the values send by all participating sites. It will become ready once the all_reduce operation has been completed.

+
+
+
+ +
+
+template<typename T, typename F>
hpx::future<void> reduce_there(char const *basename, T &&result, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg(), root_site_arg root_site = root_site_arg())#
+

Reduce a given value at the given call site

+

This function transmits the value given by result to a central reduce site (where the corresponding reduce_here is executed)

+
+
Parameters
+
    +
  • basename – The base name identifying the reduction operation

  • +
  • result – A future referring to the value to transmit to the central reduction point from this call site.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • root_site – The sequence number of the central reduction point (usually the locality id). This value is optional and defaults to 0.

  • +
+
+
Returns
+

This function returns a future<void>. It will become ready once the reduction operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<void> reduce_there(communicator comm, T &&local_result, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Reduce a given value at the given call site

+

This function transmits the value given by result to a central reduce site (where the corresponding reduce_here is executed)

+

+Reduce a given value at the given call site

+

This function transmits the value given by result to a central reduce site (where the corresponding reduce_here is executed)

+
+

Note

+

The generation values from corresponding reduce_here and reduce_there have to match.

+
+
+

Note

+

The generation values from corresponding reduce_here and reduce_there have to match.

+
+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – A value to reduce on the central reduction point from this call site.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • comm – A communicator object returned from create_communicator

  • +
  • local_result – A value to reduce on the central reduction point from this call site.

  • +
  • generation – The generational counter identifying the sequence number of the all_reduce operation performed on the given base name. This is optional and needs to be supplied only if the all_reduce operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a value calculated based on the values send by all participating sites. It will become ready once the all_reduce operation has been completed.

+
+
Returns
+

This function returns a future holding a value calculated based on the values send by all participating sites. It will become ready once the all_reduce operation has been completed.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/reduce_direct.hpp#
+

Defined in header hpx/collectives/reduce_direct.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace lcos
+
+

Functions

+
+
+template<typename Action, typename ReduceOp, typename ArgN, ...> hpx::future< decltype(Action(hpx::id_type, ArgN,...))> reduce (std::vector< hpx::id_type > const &ids, ReduceOp &&reduce_op, ArgN argN,...)
+

Perform a distributed reduction operation.

+

The function hpx::lcos::reduce performs a distributed reduction operation over results returned from action invocations on a given set of global identifiers. The action can be either a plain action (in which case the global identifiers have to refer to localities) or a component action (in which case the global identifiers have to refer to instances of a component type which exposes the action.

+
+
Parameters
+
    +
  • ids – [in] A list of global identifiers identifying the target objects for which the given action will be invoked.

  • +
  • reduce_op – [in] A binary function expecting two results as returned from the action invocations. The function (or function object) is expected to return the result of the reduction operation performed on its arguments.

  • +
  • argN – [in] Any number of arbitrary arguments (passed by by const reference) which will be forwarded to the action invocation.

  • +
+
+
Returns
+

This function returns a future representing the result of the overall reduction operation.

+
+
+
+ +
+
+template<typename Action, typename ReduceOp, typename ArgN, ...> hpx::future< decltype(Action(hpx::id_type, ArgN,..., std::size_t))> reduce_with_index (std::vector< hpx::id_type > const &ids, ReduceOp &&reduce_op, ArgN argN,...)
+

Perform a distributed reduction operation.

+

The function hpx::lcos::reduce_with_index performs a distributed reduction operation over results returned from action invocations on a given set of global identifiers. The action can be either plain action (in which case the global identifiers have to refer to localities) or a component action (in which case the global identifiers have to refer to instances of a component type which exposes the action.

+

The function passes the index of the global identifier in the given list of identifiers as the last argument to the action.

+
+
Parameters
+
    +
  • ids – [in] A list of global identifiers identifying the target objects for which the given action will be invoked.

  • +
  • reduce_op – [in] A binary function expecting two results as returned from the action invocations. The function (or function object) is expected to return the result of the reduction operation performed on its arguments.

  • +
  • argN – [in] Any number of arbitrary arguments (passed by by const reference) which will be forwarded to the action invocation.

  • +
+
+
Returns
+

This function returns a future representing the result of the overall reduction operation.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/collectives/scatter.hpp#
+

Defined in header hpx/collectives/scatter.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+

Top level HPX namespace.

+
+
+namespace collectives
+

Top level HPX namespace.

+
+

Functions

+
+
+template<typename T>
hpx::future<T> scatter_from(char const *basename, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg(), root_site_arg root_site = root_site_arg())#
+

Scatter (receive) a set of values to different call sites

+

This function receives an element of a set of values operating on the given base name.

+
+
Parameters
+
    +
  • basename – The base name identifying the scatter operation

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_gather operation performed on the given base name. This is optional and needs to be supplied only if the all_gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • root_site – The sequence number of the central scatter point (usually the locality id). This value is optional and defaults to 0.

  • +
+
+
Returns
+

This function returns a future holding a the scattered value. It will become ready once the scatter operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<T> scatter_from(communicator comm, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Scatter (receive) a set of values to different call sites

+

This function receives an element of a set of values operating on the given base name.

+

+Scatter (receive) a set of values to different call sites

+

This function receives an element of a set of values operating on the given base name.

+
+

Note

+

The generation values from corresponding scatter_to and scatter_from have to match.

+
+
+

Note

+

The generation values from corresponding scatter_to and scatter_from have to match.

+
+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_gather operation performed on the given base name. This is optional and needs to be supplied only if the all_gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • comm – A communicator object returned from create_communicator

  • +
  • generation – The generational counter identifying the sequence number of the all_gather operation performed on the given base name. This is optional and needs to be supplied only if the all_gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a the scattered value. It will become ready once the scatter operation has been completed.

+
+
Returns
+

This function returns a future holding a the scattered value. It will become ready once the scatter operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<T> scatter_to(char const *basename, std::vector<T> &&result, num_sites_arg num_sites = num_sites_arg(), this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Scatter (send) a part of the value set at the given call site

+

This function transmits the value given by result to a central scatter site (where the corresponding scatter_from is executed)

+
+
Parameters
+
    +
  • basename – The base name identifying the scatter operation

  • +
  • result – The value to transmit to the central scatter point from this call site.

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • generation – The generational counter identifying the sequence number of the all_gather operation performed on the given base name. This is optional and needs to be supplied only if the all_gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a the scattered value. It will become ready once the scatter operation has been completed.

+
+
+
+ +
+
+template<typename T>
hpx::future<T> scatter_to(communicator comm, std::vector<T> &&result, this_site_arg this_site = this_site_arg(), generation_arg generation = generation_arg())#
+

Scatter (send) a part of the value set at the given call site

+

This function transmits the value given by result to a central scatter site (where the corresponding scatter_from is executed)

+

+Scatter (send) a part of the value set at the given call site

+

This function transmits the value given by result to a central scatter site (where the corresponding scatter_from is executed)

+
+

Note

+

The generation values from corresponding scatter_to and scatter_from have to match.

+
+
+

Note

+

The generation values from corresponding scatter_to and scatter_from have to match.

+
+
+
Parameters
+
    +
  • comm – A communicator object returned from create_communicator

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
  • generation – The generational counter identifying the sequence number of the all_gather operation performed on the given base name. This is optional and needs to be supplied only if the all_gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • comm – A communicator object returned from create_communicator

  • +
  • num_sites – The number of participating sites (default: all localities).

  • +
  • generation – The generational counter identifying the sequence number of the all_gather operation performed on the given base name. This is optional and needs to be supplied only if the all_gather operation on the given base name has to be performed more than once. The generation number (if given) must be a positive number greater than zero.

  • +
  • this_site – The sequence number of this invocation (usually the locality id). This value is optional and defaults to whatever hpx::get_locality_id() returns.

  • +
+
+
Returns
+

This function returns a future holding a the scattered value. It will become ready once the scatter operation has been completed.

+
+
Returns
+

This function returns a future holding a the scattered value. It will become ready once the scatter operation has been completed.

+
+
+
+ +
+
+ +
+ +
+
+
+
+
components#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/components/basename_registration.hpp#
+

Defined in header hpx/components/basename_registration.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename Client>
std::vector<Client> find_all_from_basename(std::string base_name, std::size_t num_ids)#
+

Return all registered clients from all localities from the given base name.

+

This function locates all ids which were registered with the given base name. It returns a list of futures representing those ids.

+

+Return all registered ids from all localities from the given base name.

+

This function locates all ids which were registered with the given base name. It returns a list of futures representing those ids.

+
+

Note

+

The futures embedded in the returned client objects will become ready even if the event (for instance, binding the name to an id) has already happened in the past. This is important in order to reliably retrieve ids from a name, even if the name was already registered.

+
+
+

Note

+

The futures will become ready even if the event (for instance, binding the name to an id) has already happened in the past. This is important in order to reliably retrieve ids from a name, even if the name was already registered.

+
+
+
Template Parameters
+

Client – The client type to return

+
+
Parameters
+
    +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • num_ids – [in] The number of registered ids to expect.

  • +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • num_ids – [in] The number of registered ids to expect.

  • +
+
+
Returns
+

A list of futures representing the ids which were registered using the given base name.

+
+
Returns
+

A list of futures representing the ids which were registered using the given base name.

+
+
+
+ +
+
+template<typename Client>
std::vector<Client> find_from_basename(std::string base_name, std::vector<std::size_t> const &ids)#
+

Return registered clients from the given base name and sequence numbers.

+

This function locates the ids which were registered with the given base name and the given sequence numbers. It returns a list of futures representing those ids.

+

+Return registered ids from the given base name and sequence numbers.

+

This function locates the ids which were registered with the given base name and the given sequence numbers. It returns a list of futures representing those ids.

+
+

Note

+

The futures embedded in the returned client objects will become ready even if the event (for instance, binding the name to an id) has already happened in the past. This is important in order to reliably retrieve ids from a name, even if the name was already registered.

+
+
+

Note

+

The futures will become ready even if the event (for instance, binding the name to an id) has already happened in the past. This is important in order to reliably retrieve ids from a name, even if the name was already registered.

+
+
+
Template Parameters
+

Client – The client type to return

+
+
Parameters
+
    +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • ids – [in] The sequence numbers of the registered ids.

  • +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • ids – [in] The sequence numbers of the registered ids.

  • +
+
+
Returns
+

A list of futures representing the ids which were registered using the given base name and sequence numbers.

+
+
Returns
+

A list of futures representing the ids which were registered using the given base name and sequence numbers.

+
+
+
+ +
+
+template<typename Client>
Client find_from_basename(std::string base_name, std::size_t sequence_nr)#
+

Return registered id from the given base name and sequence number.

+

This function locates the id which was registered with the given base name and the given sequence number. It returns a future representing those id.

+

+This function locates the id which was registered with the given base name and the given sequence number. It returns a future representing those id.

+
+

Note

+

The future embedded in the returned client object will become ready even if the event (for instance, binding the name to an id) has already happened in the past. This is important in order to reliably retrieve ids from a name, even if the name was already registered.

+
+
+

Note

+

The future will become ready even if the event (for instance, binding the name to an id) has already happened in the past. This is important in order to reliably retrieve ids from a name, even if the name was already registered.

+
+
+
Template Parameters
+

Client – The client type to return

+
+
Parameters
+
    +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • sequence_nr – [in] The sequence number of the registered id.

  • +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • sequence_nr – [in] The sequence number of the registered id.

  • +
+
+
Returns
+

A representing the id which was registered using the given base name and sequence numbers.

+
+
Returns
+

A representing the id which was registered using the given base name and sequence numbers.

+
+
+
+ +
+
+template<typename Client, typename Stub, typename Data>
hpx::future<bool> register_with_basename(std::string base_name, components::client_base<Client, Stub, Data> &client, std::size_t sequence_nr)#
+

Register the id wrapped in the given client using the given base name.

+

The function registers the object the given client refers to using the provided base name.

+
+

Note

+

The operation will fail if the given sequence number is not unique.

+
+
+
Template Parameters
+

Client – The client type to register

+
+
Parameters
+
    +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • client – [in] The client which should be registered using the given base name.

  • +
  • sequence_nr – [in, optional] The sequential number to use for the registration of the id. This number has to be unique system-wide for each registration using the same base name. The default is the current locality identifier. Also, the sequence numbers have to be consecutive starting from zero.

  • +
+
+
Returns
+

A future representing the result of the registration operation itself.

+
+
+
+ +
+
+template<typename Client>
Client unregister_with_basename(std::string base_name, std::size_t sequence_nr = ~static_cast<std::size_t>(0))#
+

Unregister the given id using the given base name.

+

Unregister the given base name.

+

The function unregisters the given ids using the provided base name.

+

+The function unregisters the given ids using the provided base name.

+
+
Template Parameters
+

Client – The client type to return

+
+
Parameters
+
    +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • sequence_nr – [in, optional] The sequential number to use for the un-registration. This number has to be the same as has been used with register_with_basename before.

  • +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • sequence_nr – [in, optional] The sequential number to use for the un-registration. This number has to be the same as has been used with register_with_basename before.

  • +
+
+
Returns
+

A future representing the result of the un-registration operation itself.

+
+
Returns
+

A future representing the result of the un-registration operation itself.

+
+
+
+ +
+
+ +
+
+
hpx/components/basename_registration_fwd.hpp#
+

Defined in header hpx/components/basename_registration_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+hpx::future<bool> register_with_basename(std::string base_name, hpx::id_type const &id, std::size_t sequence_nr = ~static_cast<std::size_t>(0))#
+

Register the given id using the given base name.

+

The function registers the given ids using the provided base name.

+
+

Note

+

The operation will fail if the given sequence number is not unique.

+
+
+
Parameters
+
    +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • id – [in] The id to register using the given base name.

  • +
  • sequence_nr – [in, optional] The sequential number to use for the registration of the id. This number has to be unique system-wide for each registration using the same base name. The default is the current locality identifier. Also, the sequence numbers have to be consecutive starting from zero.

  • +
+
+
Returns
+

A future representing the result of the registration operation itself.

+
+
+
+ +
+
+bool register_with_basename(hpx::launch::sync_policy, std::string base_name, hpx::id_type const &id, std::size_t sequence_nr = ~static_cast<std::size_t>(0), error_code &ec = throws)#
+
+ +
+
+hpx::future<bool> register_with_basename(std::string base_name, hpx::future<hpx::id_type> f, std::size_t sequence_nr = ~static_cast<std::size_t>(0))#
+

Register the id wrapped in the given future using the given base name.

+

The function registers the object the given future refers to using the provided base name.

+
+

Note

+

The operation will fail if the given sequence number is not unique.

+
+
+
Parameters
+
    +
  • base_name – [in] The base name for which to retrieve the registered ids.

  • +
  • f – [in] The future which should be registered using the given base name.

  • +
  • sequence_nr – [in, optional] The sequential number to use for the registration of the id. This number has to be unique system-wide for each registration using the same base name. The default is the current locality identifier. Also, the sequence numbers have to be consecutive starting from zero.

  • +
+
+
Returns
+

A future representing the result of the registration operation itself.

+
+
+
+ +
+
+ +
+
+
hpx::components::client#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+
+template<typename Component, typename Data = void>
class client : public hpx::components::client_base<client<Component, void>, Component, void>#
+
+#include <client.hpp>
+

The client class is a wrapper that manages a distributed component. It extends client_base with specific Component and Data types.

+
+
Template Parameters
+
    +
  • Component – The type of the component.

  • +
  • Data – The type of the data associated with the client (default is void).

  • +
+
+
+
+

Public Functions

+
+
+client() = default#
+
+ +
+
+inline explicit client(hpx::id_type const &id)#
+
+ +
+
+inline explicit client(hpx::id_type &&id)#
+
+ +
+
+inline explicit client(future_type const &f) noexcept#
+
+ +
+
+inline explicit client(future_type &&f) noexcept#
+
+ +
+
+inline client(future<hpx::id_type> &&f) noexcept#
+
+ +
+
+inline client(future<client> &&c)#
+
+ +
+
+client(client const &rhs) noexcept = default#
+
+ +
+
+client(client &&rhs) noexcept = default#
+
+ +
+
+~client() = default#
+
+ +
+
+inline client &operator=(hpx::id_type const &id)#
+
+ +
+
+inline client &operator=(hpx::id_type &&id)#
+
+ +
+
+inline client &operator=(future_type const &f) noexcept#
+
+ +
+
+inline client &operator=(future_type &&f) noexcept#
+
+ +
+
+inline client &operator=(future<hpx::id_type> &&f) noexcept#
+
+ +
+
+client &operator=(client const &rhs) noexcept = default#
+
+ +
+
+client &operator=(client &&rhs) noexcept = default#
+
+ +
+
+

Private Types

+
+
+using base_type = client_base<client, Component, Data>#
+
+ +
+
+using future_type = typename base_type::future_type#
+
+ +
+
+ +
+ +
+ +
+
+
hpx::components::client_base#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<typename Derived>
struct is_client<Derived, std::void_t<typename Derived::is_client_tag>> : public true_type#
+
+ +
+
+namespace hpx
+
+
+namespace components
+
+

Functions

+
+
+template<typename Derived, typename Stub, typename Data>
bool operator==(client_base<Derived, Stub, Data> const &lhs, client_base<Derived, Stub, Data> const &rhs)#
+
+ +
+
+template<typename Derived, typename Stub, typename Data>
bool operator<(client_base<Derived, Stub, Data> const &lhs, client_base<Derived, Stub, Data> const &rhs)#
+
+ +
+
+
+template<typename Derived, typename Stub, typename Data>
class client_base : public detail::make_stub::type<Stub>#
+
+#include <client_base.hpp>
+

This class template serves as a base class for client components, providing common functionality such as managing shared state, ID retrieval, and asynchronous operations.

+
+
Template Parameters
+
    +
  • Derived – The derived client component type.

  • +
  • Stub – The stub type used for communication.

  • +
  • Data – The extra data type used for additional information.

  • +
+
+
+
+

Public Types

+
+
+using stub_argument_type = Stub#
+
+ +
+
+using server_component_type = typename detail::make_stub<Stub>::server_component_type#
+
+ +
+
+using is_client_tag = void#
+
+ +
+
+

Public Functions

+
+
+client_base() = default#
+
+ +
+
+inline explicit client_base(id_type const &id)#
+
+ +
+
+inline explicit client_base(id_type &&id)#
+
+ +
+
+inline explicit client_base(hpx::shared_future<hpx::id_type> const &f) noexcept#
+
+ +
+
+inline explicit client_base(hpx::shared_future<hpx::id_type> &&f) noexcept#
+
+ +
+
+inline explicit client_base(hpx::future<hpx::id_type> &&f) noexcept#
+
+ +
+
+client_base(client_base const &rhs) = default#
+
+ +
+
+client_base(client_base &&rhs) noexcept = default#
+
+ +
+
+inline client_base(hpx::future<Derived> &&d)#
+
+ +
+
+~client_base() = default#
+
+ +
+
+inline client_base &operator=(hpx::id_type const &id)#
+
+ +
+
+inline client_base &operator=(hpx::id_type &&id)#
+
+ +
+
+inline client_base &operator=(hpx::shared_future<hpx::id_type> const &f) noexcept#
+
+ +
+
+inline client_base &operator=(hpx::shared_future<hpx::id_type> &&f) noexcept#
+
+ +
+
+inline client_base &operator=(hpx::future<hpx::id_type> &&f) noexcept#
+
+ +
+
+client_base &operator=(client_base const &rhs) = default#
+
+ +
+
+client_base &operator=(client_base &&rhs) noexcept = default#
+
+ +
+
+inline bool valid() const noexcept#
+
+ +
+
+inline explicit operator bool() const noexcept#
+
+ +
+
+inline void free()#
+
+ +
+
+inline hpx::id_type const &get_id(error_code &ec = hpx::throws) const#
+
+ +
+
+inline naming::gid_type const &get_raw_gid() const#
+
+ +
+
+inline hpx::shared_future<hpx::id_type> detach()#
+
+ +
+
+inline hpx::shared_future<hpx::id_type> share() const#
+
+ +
+
+inline void reset(hpx::id_type const &id)#
+
+ +
+
+inline void reset(hpx::id_type &&id)#
+
+ +
+
+inline void reset(shared_future<hpx::id_type> &&rhs)#
+
+ +
+
+inline id_type const &get(error_code &ec = hpx::throws) const#
+
+ +
+
+inline bool is_ready() const noexcept#
+
+ +
+
+inline bool has_value() const noexcept#
+
+ +
+
+inline bool has_exception() const noexcept#
+
+ +
+
+inline void wait() const#
+
+ +
+
+inline std::exception_ptr get_exception_ptr() const#
+
+ +
+
+template<typename F>
inline hpx::traits::future_then_result_t<Derived, F> then(launch l, F &&f) const#
+
+ +
+
+template<typename F>
inline hpx::traits::future_then_result_t<Derived, F> then(launch::sync_policy l, F &&f) const#
+
+ +
+
+template<typename F>
inline hpx::traits::future_then_result_t<Derived, F> then(F &&f) const#
+
+ +
+
+inline hpx::future<bool> register_as(std::string symbolic_name, bool manage_lifetime = true)#
+
+ +
+
+inline bool register_as(launch::sync_policy, std::string symbolic_name, bool manage_lifetime = true)#
+
+ +
+
+inline void connect_to(std::string const &symbolic_name)#
+
+ +
+
+inline std::string const &registered_name() const#
+
+ +
+
+template<typename T>
inline T &get_extra_data()#
+
+ +
+
+template<typename T>
inline T *try_get_extra_data() const noexcept#
+
+ +
+
+

Protected Types

+
+
+using stub_type = typename detail::make_stub<Stub>::type#
+
+ +
+
+using base_shared_state_type = lcos::detail::future_data_base<hpx::id_type>#
+
+ +
+
+using shared_state_type = lcos::detail::future_data<hpx::id_type>#
+
+ +
+
+using future_type = shared_future<hpx::id_type>#
+
+ +
+
+using extra_data_type = Data#
+
+ +
+
+

Protected Functions

+
+
+inline client_base(hpx::intrusive_ptr<base_shared_state_type> const &state)#
+
+ +
+
+inline client_base(hpx::intrusive_ptr<base_shared_state_type> &&state)#
+
+ +
+
+

Protected Attributes

+
+
+hpx::intrusive_ptr<base_shared_state_type> shared_state_#
+
+ +
+
+

Private Static Functions

+
+
+template<typename F>
static inline hpx::traits::future_then_result<Derived, F>::cont_result on_ready(hpx::shared_future<id_type> &&fut, F f)#
+
+ +
+
+static inline bool register_as_helper(client_base const &f, std::string symbolic_name, bool manage_lifetime)#
+
+ +
+
+ +
+ +
+
+namespace lcos
+
+ +
+
+namespace serialization
+
+

Functions

+
+
+template<typename Archive, typename Derived, typename Stub, typename Data>
void serialize(Archive &ar, ::hpx::components::client_base<Derived, Stub, Data> &f, unsigned version)#
+
+ +
+
+ +
+
+namespace traits
+
+
+template<typename Derived> is_client_tag > > : public true_type
+
+ +
+ +
+ +
+
+
hpx/components/get_ptr.hpp#
+

Defined in header hpx/components/get_ptr.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename Component>
hpx::future<std::shared_ptr<Component>> get_ptr(hpx::id_type const &id)#
+

Returns a future referring to the pointer to the underlying memory of a component.

+

The function hpx::get_ptr can be used to extract a future referring to the pointer to the underlying memory of a given component.

+
+

Note

+

This function will successfully return the requested result only if the given component is currently located on the calling locality. Otherwise, the function will raise an error.

+
+
+

Note

+

The component instance the returned pointer refers to can not be migrated as long as there is at least one copy of the returned shared_ptr alive.

+
+
+
Parameters
+

id – [in] The global id of the component for which the pointer to the underlying memory should be retrieved.

+
+
Template Parameters
+

Component – The type of the server side component.

+
+
Returns
+

This function returns a future representing the pointer to the underlying memory for the component instance with the given id.

+
+
+
+ +
+
+template<typename Derived, typename Stub, typename Data>
hpx::future<std::shared_ptr<typename components::client_base<Derived, Stub, Data>::server_component_type>> get_ptr(components::client_base<Derived, Stub, Data> const &c)#
+

Returns a future referring to the pointer to the underlying memory of a component.

+

The function hpx::get_ptr can be used to extract a future referring to the pointer to the underlying memory of a given component.

+
+

Note

+

This function will successfully return the requested result only if the given component is currently located on the calling locality. Otherwise, the function will raise an error.

+
+
+

Note

+

The component instance the returned pointer refers to can not be migrated as long as there is at least one copy of the returned shared_ptr alive.

+
+
+
Parameters
+

c – [in] A client side representation of the component for which the pointer to the underlying memory should be retrieved.

+
+
Returns
+

This function returns a future representing the pointer to the underlying memory for the component instance with the given id.

+
+
+
+ +
+
+template<typename Component>
std::shared_ptr<Component> get_ptr(launch::sync_policy p, hpx::id_type const &id, error_code &ec = throws)#
+

Returns the pointer to the underlying memory of a component.

+

The function hpx::get_ptr_sync can be used to extract the pointer to the underlying memory of a given component.

+
+

Note

+

This function will successfully return the requested result only if the given component is currently located on the requesting locality. Otherwise, the function will raise and error.

+
+
+

Note

+

The component instance the returned pointer refers to can not be migrated as long as there is at least one copy of the returned shared_ptr alive.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise, it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • p – [in] The parameter p represents a placeholder type to turn make the call synchronous.

  • +
  • id – [in] The global id of the component for which the pointer to the underlying memory should be retrieved.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Template Parameters
+

Component – The only template parameter has to be the type of the server side component.

+
+
Returns
+

This function returns the pointer to the underlying memory for the component instance with the given id.

+
+
+
+ +
+
+template<typename Derived, typename Stub, typename Data>
std::shared_ptr<typename components::client_base<Derived, Stub, Data>::server_component_type> get_ptr(launch::sync_policy p, components::client_base<Derived, Stub, Data> const &c, error_code &ec = throws)#
+

Returns the pointer to the underlying memory of a component.

+

The function hpx::get_ptr_sync can be used to extract the pointer to the underlying memory of a given component.

+
+

Note

+

This function will successfully return the requested result only if the given component is currently located on the requesting locality. Otherwise, the function will raise and error.

+
+
+

Note

+

The component instance the returned pointer refers to can not be migrated as long as there is at least one copy of the returned shared_ptr alive.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise, it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • p – [in] The parameter p represents a placeholder type to turn make the call synchronous.

  • +
  • c – [in] A client side representation of the component for which the pointer to the underlying memory should be retrieved.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function returns the pointer to the underlying memory for the component instance with the given id.

+
+
+
+ +
+
+ +
+
+
+
+
components_base#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/components_base/agas_interface.hpp#
+

Defined in header hpx/components_base/agas_interface.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace agas
+
+

Functions

+
+
+bool is_console()#
+
+ +
+
+bool register_name(launch::sync_policy, std::string const &name, naming::gid_type const &gid, error_code &ec = throws)#
+
+ +
+
+bool register_name(launch::sync_policy, std::string const &name, hpx::id_type const &id, error_code &ec = throws)#
+
+ +
+
+hpx::future<bool> register_name(std::string const &name, hpx::id_type const &id)#
+
+ +
+
+hpx::id_type unregister_name(launch::sync_policy, std::string const &name, error_code &ec = throws)#
+
+ +
+
+hpx::future<hpx::id_type> unregister_name(std::string const &name)#
+
+ +
+
+hpx::id_type resolve_name(launch::sync_policy, std::string const &name, error_code &ec = throws)#
+
+ +
+
+hpx::future<hpx::id_type> resolve_name(std::string const &name)#
+
+ +
+
+hpx::future<std::uint32_t> get_num_localities(naming::component_type type = naming::component_invalid)#
+
+ +
+
+std::uint32_t get_num_localities(launch::sync_policy, naming::component_type type, error_code &ec = throws)#
+
+ +
+
+inline std::uint32_t get_num_localities(launch::sync_policy, error_code &ec = throws)#
+
+ +
+
+std::string get_component_type_name(naming::component_type type, error_code &ec = throws)#
+
+ +
+
+hpx::future<std::vector<std::uint32_t>> get_num_threads()#
+
+ +
+
+std::vector<std::uint32_t> get_num_threads(launch::sync_policy, error_code &ec = throws)#
+
+ +
+
+hpx::future<std::uint32_t> get_num_overall_threads()#
+
+ +
+
+std::uint32_t get_num_overall_threads(launch::sync_policy, error_code &ec = throws)#
+
+ +
+
+std::uint32_t get_locality_id(error_code &ec = throws)#
+
+ +
+
+inline hpx::naming::gid_type get_locality()#
+
+ +
+
+std::vector<std::uint32_t> get_all_locality_ids(naming::component_type type, error_code &ec = throws)#
+
+ +
+
+inline std::vector<std::uint32_t> get_all_locality_ids(error_code &ec = throws)#
+
+ +
+
+bool is_local_address_cached(naming::gid_type const &gid, error_code &ec = throws)#
+
+ +
+
+bool is_local_address_cached(naming::gid_type const &gid, naming::address &addr, error_code &ec = throws)#
+
+ +
+
+bool is_local_address_cached(naming::gid_type const &gid, naming::address &addr, std::pair<bool, components::pinned_ptr> &r, hpx::move_only_function<std::pair<bool, components::pinned_ptr>(naming::address const&)> &&f, error_code &ec = throws)#
+
+ +
+
+inline bool is_local_address_cached(hpx::id_type const &id, error_code &ec = throws)#
+
+ +
+
+inline bool is_local_address_cached(hpx::id_type const &id, naming::address &addr, error_code &ec = throws)#
+
+ +
+
+inline bool is_local_address_cached(hpx::id_type const &id, naming::address &addr, std::pair<bool, components::pinned_ptr> &r, hpx::move_only_function<std::pair<bool, components::pinned_ptr>(naming::address const&)> &&f, error_code &ec = throws)#
+
+ +
+
+void update_cache_entry(naming::gid_type const &gid, naming::address const &addr, std::uint64_t count = 0, std::uint64_t offset = 0, error_code &ec = throws)#
+
+ +
+
+bool is_local_lva_encoded_address(naming::gid_type const &gid)#
+
+ +
+
+inline bool is_local_lva_encoded_address(hpx::id_type const &id)#
+
+ +
+
+hpx::future_or_value<naming::address> resolve_async(hpx::id_type const &id)#
+
+ +
+
+hpx::future<naming::address> resolve(hpx::id_type const &id)#
+
+ +
+
+naming::address resolve(launch::sync_policy, hpx::id_type const &id, error_code &ec = throws)#
+
+ +
+
+bool resolve_local(naming::gid_type const &gid, naming::address &addr, error_code &ec = throws)#
+
+ +
+
+bool resolve_cached(naming::gid_type const &gid, naming::address &addr)#
+
+ +
+
+hpx::future<bool> bind(naming::gid_type const &gid, naming::address const &addr, std::uint32_t locality_id)#
+
+ +
+
+bool bind(launch::sync_policy, naming::gid_type const &gid, naming::address const &addr, std::uint32_t locality_id, error_code &ec = throws)#
+
+ +
+
+hpx::future<bool> bind(naming::gid_type const &gid, naming::address const &addr, naming::gid_type const &locality_)#
+
+ +
+
+bool bind(launch::sync_policy, naming::gid_type const &gid, naming::address const &addr, naming::gid_type const &locality_, error_code &ec = throws)#
+
+ +
+
+hpx::future<naming::address> unbind(naming::gid_type const &gid, std::uint64_t count = 1)#
+
+ +
+
+naming::address unbind(launch::sync_policy, naming::gid_type const &gid, std::uint64_t count = 1, error_code &ec = throws)#
+
+ +
+
+bool bind_gid_local(naming::gid_type const &gid, naming::address const &addr, error_code &ec = throws)#
+
+ +
+
+void unbind_gid_local(naming::gid_type const &gid, error_code &ec = throws)#
+
+ +
+
+bool bind_range_local(naming::gid_type const &gid, std::size_t count, naming::address const &addr, std::size_t offset, error_code &ec = throws)#
+
+ +
+
+void unbind_range_local(naming::gid_type const &gid, std::size_t count, error_code &ec = throws)#
+
+ +
+
+void garbage_collect_non_blocking(error_code &ec = throws)#
+
+ +
+
+void garbage_collect(error_code &ec = throws)#
+
+ +
+
+void garbage_collect_non_blocking(hpx::id_type const &id, error_code &ec = throws)#
+

Invoke an asynchronous garbage collection step on the given target locality.

+
+ +
+
+void garbage_collect(hpx::id_type const &id, error_code &ec = throws)#
+

Invoke a synchronous garbage collection step on the given target locality.

+
+ +
+
+hpx::id_type get_console_locality(error_code &ec = throws)#
+

Return an id_type referring to the console locality.

+
+ +
+
+naming::gid_type get_next_id(std::size_t count, error_code &ec = throws)#
+
+ +
+
+void decref(naming::gid_type const &id, std::int64_t credits, error_code &ec = throws)#
+
+ +
+
+hpx::future_or_value<std::int64_t> incref(naming::gid_type const &gid, std::int64_t credits, hpx::id_type const &keep_alive = hpx::invalid_id)#
+
+ +
+
+std::int64_t incref(launch::sync_policy, naming::gid_type const &gid, std::int64_t credits = 1, hpx::id_type const &keep_alive = hpx::invalid_id, error_code &ec = throws)#
+
+ +
+
+std::int64_t replenish_credits(naming::gid_type &gid)#
+
+ +
+
+hpx::future_or_value<id_type> get_colocation_id(hpx::id_type const &id)#
+
+ +
+
+hpx::id_type get_colocation_id(launch::sync_policy, hpx::id_type const &id, error_code &ec = throws)#
+
+ +
+
+hpx::future<hpx::id_type> on_symbol_namespace_event(std::string const &name, bool call_for_past_events)#
+
+ +
+
+hpx::future<std::pair<hpx::id_type, naming::address>> begin_migration(hpx::id_type const &id)#
+
+ +
+
+bool end_migration(hpx::id_type const &id)#
+
+ +
+
+hpx::future<void> mark_as_migrated(naming::gid_type const &gid, hpx::move_only_function<std::pair<bool, hpx::future<void>>()> &&f, bool expect_to_be_marked_as_migrating)#
+
+ +
+
+std::pair<bool, components::pinned_ptr> was_object_migrated(naming::gid_type const &gid, hpx::move_only_function<components::pinned_ptr()> &&f)#
+
+ +
+
+void unmark_as_migrated(naming::gid_type const &gid, hpx::move_only_function<void()> &&f)#
+
+ +
+
+hpx::future<std::map<std::string, hpx::id_type>> find_symbols(std::string const &pattern = "*")#
+
+ +
+
+std::map<std::string, hpx::id_type> find_symbols(hpx::launch::sync_policy, std::string const &pattern = "*")#
+
+ +
+
+naming::component_type register_factory(std::uint32_t prefix, std::string const &name, error_code &ec = throws)#
+
+ +
+
+naming::component_type get_component_id(std::string const &name, error_code &ec = throws)#
+
+ +
+
+void destroy_component(naming::gid_type const &gid, naming::address const &addr)#
+
+ +
+
+naming::address_type get_primary_ns_lva()#
+
+ +
+
+naming::address_type get_symbol_ns_lva()#
+
+ +
+
+naming::address_type get_runtime_support_lva()#
+
+ +
+
+struct agas_interface_functions &agas_init()#
+
+ +
+
+ +
+ +
+
+
HPX_REGISTER_COMMANDLINE_MODULE#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_DEFINE_COMPONENT_COMMANDLINE_OPTIONS(add_options_function)#
+
+ +
+
+HPX_REGISTER_COMMANDLINE_MODULE(add_options_function)#
+

Macro to register a command-line module with the HPX runtime.

+

This macro facilitates the registration of a command-line module with the HPX runtime system. A command-line module typically provides additional command-line options that can be used to configure the HPX application.

+
+
Parameters
+
    +
  • add_options_function – The function that adds custom command-line options.

  • +
+
+
+
+ +
+
+HPX_REGISTER_COMMANDLINE_MODULE_DYNAMIC(add_options_function)#
+
+ +
+
+
+namespace hpx
+
+
+namespace components
+
+
+struct component_commandline : public component_commandline_base#
+
+#include <component_commandline.hpp>
+

The component_startup_shutdown provides a minimal implementation of a component’s startup/shutdown function provider.

+
+

Public Functions

+
+
+inline hpx::program_options::options_description add_commandline_options() override#
+

Return any additional command line options valid for this component.

+
+

Note

+

This function will be executed by the runtime system during system startup.

+
+
+
Returns
+

The module is expected to fill a options_description object with any additional command line options this component will handle.

+
+
+
+ +
+
+ +
+
+namespace commandline_options_provider#
+
+

Functions

+
+
+hpx::program_options::options_description add_commandline_options()#
+
+ +
+
+ +
+ +
+ +
+
+
HPX_REGISTER_STARTUP_MODULE#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_DEFINE_COMPONENT_STARTUP_SHUTDOWN(startup_, shutdown_)#
+
+ +
+
+HPX_REGISTER_STARTUP_SHUTDOWN_MODULE_(startup, shutdown)#
+
+ +
+
+HPX_REGISTER_STARTUP_SHUTDOWN_MODULE(startup, shutdown)#
+
+ +
+
+HPX_REGISTER_STARTUP_SHUTDOWN_MODULE_DYNAMIC(startup, shutdown)#
+
+ +
+
+HPX_REGISTER_STARTUP_MODULE(startup)#
+

Macro to register a startup module with the HPX runtime.

+

This macro facilitates the registration of a startup module with the HPX runtime system. A startup module typically contains initialization code that should be executed when the HPX runtime starts.

+
+
Parameters
+
    +
  • startup – The name of the startup function to be registered.

  • +
+
+
+
+ +
+
+HPX_REGISTER_STARTUP_MODULE_DYNAMIC(startup)#
+
+ +
+
+HPX_REGISTER_SHUTDOWN_MODULE(shutdown)#
+
+ +
+
+HPX_REGISTER_SHUTDOWN_MODULE_DYNAMIC(shutdown)#
+
+ +
+
+
+namespace hpx
+
+
+namespace components
+
+
+template<bool (*Startup)(startup_function_type&, bool&), bool (*Shutdown)(shutdown_function_type&, bool&)>
struct component_startup_shutdown : public component_startup_shutdown_base#
+
+#include <component_startup_shutdown.hpp>
+

The component_startup_shutdown class provides a minimal implementation of a component’s startup/shutdown function provider.

+
+

Public Functions

+
+
+inline bool get_startup_function(startup_function_type &startup, bool &pre_startup) override#
+

Return any startup function for this component.

+
+
Parameters
+
    +
  • startup – [in, out] The module is expected to fill this function object with a reference to a startup function. This function will be executed by the runtime system during system startup.

  • +
  • pre_startup

  • +
+
+
Returns
+

Returns true if the parameter startup has been successfully initialized with the startup function.

+
+
+
+ +
+
+inline bool get_shutdown_function(shutdown_function_type &shutdown, bool &pre_shutdown) override#
+

Return any startup function for this component.

+
+
Parameters
+
    +
  • shutdown – [in, out] The module is expected to fill this function object with a reference to a startup function. This function will be executed by the runtime system during system startup.

  • +
  • pre_shutdown

  • +
+
+
Returns
+

Returns true if the parameter shutdown has been successfully initialized with the shutdown function.

+
+
+
+ +
+
+ +
+ +
+ +
+
+
hpx/components_base/component_type.hpp#
+

Defined in header hpx/components_base/component_type.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_COMPONENT_ENUM_TYPE_ENUM_DEPRECATION_MSG#
+
+ +
+
+HPX_FACTORY_STATE_ENUM_DEPRECATION_MSG#
+
+ +
+
+HPX_DEFINE_GET_COMPONENT_TYPE(component)#
+
+ +
+
+HPX_DEFINE_GET_COMPONENT_TYPE_TEMPLATE(template_, component)#
+
+ +
+
+HPX_DEFINE_GET_COMPONENT_TYPE_STATIC(component, type)#
+
+ +
+
+HPX_DEFINE_COMPONENT_NAME(...)#
+
+ +
+
+HPX_DEFINE_COMPONENT_NAME_(...)#
+
+ +
+
+HPX_DEFINE_COMPONENT_NAME_2(Component, name)#
+
+ +
+
+HPX_DEFINE_COMPONENT_NAME_3(Component, name, base_name)#
+
+ +
+
+
+namespace hpx
+
+
+namespace components
+
+

Typedefs

+
+
+using component_deleter_type = void (*)(hpx::naming::gid_type const&, hpx::naming::address const&)#
+
+ +
+
+

Enums

+
+
+enum class component_enum_type : naming::component_type#
+

Values:

+
+
+enumerator invalid#
+
+ +
+
+enumerator runtime_support#
+
+ +
+
+enumerator plain_function#
+
+ +
+
+enumerator base_lco#
+
+ +
+
+enumerator base_lco_with_value_unmanaged#
+
+ +
+
+enumerator base_lco_with_value#
+
+ +
+
+enumerator latch#
+
+ +
+
+enumerator barrier#
+
+ +
+
+enumerator promise#
+
+ +
+
+enumerator agas_locality_namespace#
+
+ +
+
+enumerator agas_primary_namespace#
+
+ +
+
+enumerator agas_component_namespace#
+
+ +
+
+enumerator agas_symbol_namespace#
+
+ +
+
+enumerator last#
+
+ +
+
+enumerator first_dynamic#
+
+ +
+ +
+
+enum class factory_state : std::uint8_t#
+

Values:

+
+
+enumerator enabled#
+
+ +
+
+enumerator disabled#
+
+ +
+
+enumerator check#
+
+ +
+ +
+
+

Functions

+
+
+constexpr naming::component_type to_int(component_enum_type t) noexcept#
+
+ +
+
+constexpr int to_int(factory_state t) noexcept#
+
+ +
+
+bool &enabled(component_type type)#
+
+ +
+
+util::atomic_count &instance_count(component_type type)#
+
+ +
+
+component_deleter_type &deleter(component_type type)#
+
+ +
+
+bool enumerate_instance_counts(hpx::move_only_function<bool(component_type)> const &f)#
+
+ +
+
+std::string get_component_type_name(component_type type)#
+

Return the string representation for a given component type id.

+
+ +
+
+constexpr component_type get_base_type(component_type t) noexcept#
+

The lower short word of the component type is the type of the component exposing the actions.

+
+ +
+
+constexpr component_type get_derived_type(component_type t) noexcept#
+

The upper short word of the component is the actual component type.

+
+ +
+
+constexpr component_type derived_component_type(component_type derived, component_type base) noexcept#
+

A component derived from a base component exposing the actions needs to have a specially formatted component type.

+
+ +
+
+constexpr bool types_are_compatible(component_type lhs, component_type rhs) noexcept#
+

Verify the two given component types are matching (compatible)

+
+ +
+
+template<typename Component, typename Enable = void>
char const *get_component_name() noexcept#
+
+ +
+
+template<typename Component, typename Enable = void>
char const *get_component_base_name() noexcept#
+
+ +
+
+template<typename Component>
component_type get_component_type() noexcept#
+
+ +
+
+template<typename Component>
void set_component_type(component_type type)#
+
+ +
+
+

Variables

+
+
+constexpr component_enum_type component_invalid = component_enum_type::invalid#
+
+ +
+
+constexpr component_enum_type component_runtime_support = component_enum_type::runtime_support#
+
+ +
+
+constexpr component_enum_type component_plain_function = component_enum_type::plain_function#
+
+ +
+
+constexpr component_enum_type component_base_lco = component_enum_type::base_lco#
+
+ +
+
+constexpr component_enum_type component_base_lco_with_value_unmanaged = component_enum_type::base_lco_with_value_unmanaged#
+
+ +
+
+constexpr component_enum_type component_base_lco_with_value = component_enum_type::base_lco_with_value#
+
+ +
+
+constexpr component_enum_type component_latch = component_enum_type::latch#
+
+ +
+
+constexpr component_enum_type component_barrier = component_enum_type::barrier#
+
+ +
+
+constexpr component_enum_type component_promise = component_enum_type::promise#
+
+ +
+
+constexpr component_enum_type component_agas_locality_namespace = component_enum_type::agas_locality_namespace#
+
+ +
+
+constexpr component_enum_type component_agas_primary_namespace = component_enum_type::agas_primary_namespace#
+
+ +
+
+constexpr component_enum_type component_agas_component_namespace = component_enum_type::agas_component_namespace#
+
+ +
+
+constexpr component_enum_type component_agas_symbol_namespace = component_enum_type::agas_symbol_namespace#
+
+ +
+
+constexpr component_enum_type component_last = component_enum_type::last#
+
+ +
+
+constexpr component_enum_type component_first_dynamic = component_enum_type::first_dynamic#
+
+ +
+
+constexpr factory_state factory_enabled = factory_state::enabled#
+
+ +
+
+constexpr factory_state factory_disabled = factory_state::disabled#
+
+ +
+
+constexpr factory_state factory_check = factory_state::check#
+
+ +
+
+ +
+ +
+
+
hpx::components::component, hpx::components::component_base#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+

Typedefs

+
+
+using instead = abstract_component_base<Component>#
+
+ +
+
+
+template<typename Component = void>
class abstract_component_base#
+
+ +
+
+template<typename Component, typename Derived = void>
class abstract_managed_component_base#
+
+ +
+
+template<typename Component>
class component#
+
+#include <components_base_fwd.hpp>
+

The component class wraps around a given component type, adding additional type aliases and constructors. It inherits from the specified component type.

+
+ +
+
+template<typename Component = void>
class component_base#
+
+#include <components_base_fwd.hpp>
+

component_base serves as a base class for components. It provides common functionality needed by components, such as address and ID retrieval. The template parameter Component specifies the derived component type.

+
+ +
+
+template<typename Component>
class fixed_component#
+
+ +
+
+template<typename Component>
class fixed_component_base#
+
+ +
+
+template<typename Component, typename Derived>
class managed_component#
+
+#include <managed_component_base.hpp>
+

The managed_component template is used as an indirection layer for components allowing to gracefully handle the access to non-existing components.

+

Additionally, it provides memory management capabilities for the wrapping instances, and it integrates the memory management with the AGAS service. Every instance of a managed_component gets assigned a global id. The provided memory management allocates the managed_component instances from a special heap, ensuring fast allocation and avoids a full network round trip to the AGAS service for each of the allocated instances.

+
+
Template Parameters
+
    +
  • Component – Component type

  • +
  • Derived – Most derived component type

  • +
+
+
+
+ +
+
+template<typename Component, typename Wrapper, typename CtorPolicy, typename DtorPolicy>
class managed_component_base#
+
+ +
+ +
+ +
+
+
hpx/components_base/get_lva.hpp#
+

Defined in header hpx/components_base/get_lva.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+template<typename Component, typename Enable = void>
struct get_lva#
+
+#include <get_lva.hpp>
+

The get_lva template is a helper structure allowing to convert a local virtual address as stored in a local address (returned from the function resolver_client::resolve) to the address of the component implementing the action.

+

The default implementation uses the template argument Component to deduce the type wrapping the component implementing the action. This is used to get the needed address.

+
+
Template Parameters
+

Component – This is the type of the component implementing the action to execute.

+
+
+
+

Public Static Functions

+
+
+static inline constexpr Component *call(naming::address_type lva) noexcept#
+
+ +
+
+ +
+ +
+
+
hpx/components_base/server/fixed_component_base.hpp#
+

Defined in header hpx/components_base/server/fixed_component_base.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+
+template<typename Component>
class fixed_component
+
+ +
+
+template<typename Component>
class fixed_component_base
+
+ +
+ +
+ +
+
+
hpx/components_base/server/managed_component_base.hpp#
+

Defined in header hpx/components_base/server/managed_component_base.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+template<>
struct hpx::components::detail_adl_barrier::init<traits::construct_with_back_ptr>#
+
+

Public Static Functions

+
+
+template<typename Component, typename Managed>
static inline constexpr void call(Component*, Managed*) noexcept#
+
+ +
+
+template<typename Component, typename Managed, typename ...Ts>
static inline void call_new(Component *&component, Managed *this_, Ts&&... vs)#
+
+ +
+
+ +
+
+template<>
struct hpx::components::detail_adl_barrier::init<traits::construct_without_back_ptr>#
+
+

Public Static Functions

+
+
+template<typename Component, typename Managed>
static inline void call(Component *component, Managed *this_)#
+
+ +
+
+template<typename Component, typename Managed, typename ...Ts>
static inline void call_new(Component *&component, Managed *this_, Ts&&... vs)#
+
+ +
+
+ +
+
+template<>
struct hpx::components::detail_adl_barrier::destroy_backptr<traits::managed_object_is_lifetime_controlled>#
+
+

Public Static Functions

+
+
+template<typename BackPtr>
static inline void call(BackPtr *back_ptr)#
+
+ +
+
+ +
+
+template<>
struct hpx::components::detail_adl_barrier::destroy_backptr<traits::managed_object_controls_lifetime>#
+
+

Public Static Functions

+
+
+template<typename BackPtr>
static inline constexpr void call(BackPtr*) noexcept#
+
+ +
+
+ +
+
+template<>
struct hpx::components::detail_adl_barrier::manage_lifetime<traits::managed_object_is_lifetime_controlled>#
+
+

Public Static Functions

+
+
+template<typename Component>
static inline constexpr void call(Component*) noexcept#
+
+ +
+
+template<typename Component>
static inline void addref(Component *component) noexcept#
+
+ +
+
+template<typename Component>
static inline void release(Component *component) noexcept#
+
+ +
+
+ +
+
+template<>
struct hpx::components::detail_adl_barrier::manage_lifetime<traits::managed_object_controls_lifetime>#
+
+

Public Static Functions

+
+
+template<typename Component>
static inline void call(Component *component) noexcept(noexcept(component->finalize()))#
+
+ +
+
+template<typename Component>
static inline constexpr void addref(Component*) noexcept#
+
+ +
+
+template<typename Component>
static inline constexpr void release(Component*) noexcept#
+
+ +
+
+ +
+
+namespace hpx
+
+
+namespace components
+
+

Functions

+
+
+template<typename Component, typename Derived>
void intrusive_ptr_add_ref(managed_component<Component, Derived> *p) noexcept#
+
+ +
+
+template<typename Component, typename Derived>
void intrusive_ptr_release(managed_component<Component, Derived> *p) noexcept#
+
+ +
+
+
+template<typename Component, typename Derived>
class managed_component
+
+#include <managed_component_base.hpp>
+
+ +
+
+template<typename Component, typename Wrapper, typename CtorPolicy, typename DtorPolicy>
class managed_component_base
+
+ +
+
+namespace detail_adl_barrier#
+
+
+template<typename DtorTag>
struct destroy_backptr#
+
+ +
+
+template<> managed_object_controls_lifetime >
+
+

Public Static Functions

+
+
+template<typename BackPtr>
static inline constexpr void call(BackPtr*) noexcept#
+
+ +
+
+ +
+
+template<> managed_object_is_lifetime_controlled >
+
+

Public Static Functions

+
+
+template<typename BackPtr>
static inline void call(BackPtr *back_ptr)
+
+ +
+
+ +
+
+template<typename BackPtrTag>
struct init#
+
+ +
+
+template<> construct_with_back_ptr >
+
+

Public Static Functions

+
+
+template<typename Component, typename Managed>
static inline constexpr void call(Component*, Managed*) noexcept#
+
+ +
+
+template<typename Component, typename Managed, typename ...Ts>
static inline void call_new(Component *&component, Managed *this_, Ts&&... vs)#
+
+ +
+
+ +
+
+template<> construct_without_back_ptr >
+
+

Public Static Functions

+
+
+template<typename Component, typename Managed>
static inline void call(Component *component, Managed *this_)
+
+ +
+
+template<typename Component, typename Managed, typename ...Ts>
static inline void call_new(Component *&component, Managed *this_, Ts&&... vs)
+
+ +
+
+ +
+
+template<typename DtorTag>
struct manage_lifetime#
+
+ +
+
+template<> managed_object_controls_lifetime >
+
+

Public Static Functions

+
+
+template<typename Component>
static inline void call(Component *component) noexcept(noexcept(component->finalize()))#
+
+ +
+
+template<typename Component>
static inline constexpr void addref(Component*) noexcept#
+
+ +
+
+template<typename Component>
static inline constexpr void release(Component*) noexcept#
+
+ +
+
+ +
+
+template<> managed_object_is_lifetime_controlled >
+
+

Public Static Functions

+
+
+template<typename Component>
static inline constexpr void call(Component*) noexcept
+
+ +
+
+template<typename Component>
static inline void addref(Component *component) noexcept
+
+ +
+
+template<typename Component>
static inline void release(Component *component) noexcept
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/components_base/server/migration_support.hpp#
+

Defined in header hpx/components_base/server/migration_support.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+
+template<typename BaseComponent, typename Mutex = hpx::spinlock>
struct migration_support : public BaseComponent#
+
+#include <migration_support.hpp>
+

This hook has to be inserted into the derivation chain of any component for it to support migration.

+
+

Public Types

+
+
+using decorates_action = void#
+
+ +
+
+

Public Functions

+
+
+inline migration_support()#
+
+ +
+
+template<typename T, typename ...Ts, typename = std::enable_if_t<!std::is_same_v<std::decay_t<T>, migration_support>>>
inline explicit migration_support(T &&t, Ts&&... ts)#
+
+ +
+
+migration_support(migration_support const&) = default#
+
+ +
+
+migration_support(migration_support&&) = default#
+
+ +
+
+migration_support &operator=(migration_support const&) = default#
+
+ +
+
+migration_support &operator=(migration_support&&) = default#
+
+ +
+
+~migration_support() = default#
+
+ +
+
+inline naming::gid_type get_base_gid(naming::gid_type const &assign_gid = naming::invalid_gid) const#
+
+ +
+
+inline void pin() noexcept#
+
+ +
+
+inline bool unpin()#
+
+ +
+
+inline std::uint32_t pin_count() const noexcept#
+
+ +
+
+inline void mark_as_migrated()#
+
+ +
+
+inline hpx::future<void> mark_as_migrated(hpx::id_type const &to_migrate)#
+
+ +
+
+inline void unmark_as_migrated(hpx::id_type const &to_migrate)#
+
+ +
+
+

Public Static Functions

+
+
+static inline constexpr bool supports_migration() noexcept#
+
+ +
+
+static inline constexpr void on_migrated() noexcept#
+
+ +
+
+template<typename F>
static inline threads::thread_function_type decorate_action(naming::address_type lva, F &&f)#
+
+ +
+
+static inline std::pair<bool, components::pinned_ptr> was_object_migrated(hpx::naming::gid_type const &id, naming::address_type lva)#
+
+ +
+
+

Protected Functions

+
+
+inline threads::thread_result_type thread_function(threads::thread_function_type &&f, components::pinned_ptr, threads::thread_restart_state state)#
+
+ +
+
+

Private Types

+
+
+using base_type = BaseComponent#
+
+ +
+
+using this_component_type = typename base_type::this_component_type#
+
+ +
+
+

Private Members

+
+
+hpx::intrusive_ptr<detail::migration_support_data<Mutex>> data_#
+
+ +
+
+hpx::promise<void> trigger_migration_#
+
+ +
+
+bool started_migration_ = false#
+
+ +
+
+bool was_marked_for_migration_ = false#
+
+ +
+
+ +
+ +
+ +
+
+
+
+
compute#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/compute/host/target_distribution_policy.hpp#
+

Defined in header hpx/compute/host/target_distribution_policy.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
+
+
distribution_policies#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/distribution_policies/binpacking_distribution_policy.hpp#
+

Defined in header hpx/distribution_policies/binpacking_distribution_policy.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+

Variables

+
+
+constexpr char const *const default_binpacking_counter_name = "/runtime{locality/total}/count/component@"#
+
+ +
+
+static const binpacking_distribution_policy binpacked = {}#
+

A predefined instance of the binpacking distribution_policy. It will represent the local locality and will place all items to create here.

+
+ +
+
+
+struct binpacking_distribution_policy#
+
+#include <binpacking_distribution_policy.hpp>
+

This class specifies the parameters for a binpacking distribution policy to use for creating a given number of items on a given set of localities. The binpacking policy will distribute the new objects in a way such that each of the localities will equalize the number of overall objects of this type based on a given criteria (by default this criteria is the overall number of objects of this type).

+
+

Public Functions

+
+
+inline binpacking_distribution_policy()#
+

Default-construct a new instance of a binpacking_distribution_policy. This policy will represent one locality (the local locality).

+
+ +
+
+inline binpacking_distribution_policy operator()(std::vector<id_type> const &locs, char const *perf_counter_name = default_binpacking_counter_name) const#
+

Create a new default_distribution policy representing the given set of localities.

+
+
Parameters
+
    +
  • locs – [in] The list of localities the new instance should represent

  • +
  • perf_counter_name – [in] The name of the performance counter which should be used as the distribution criteria (by default the overall number of existing instances of the given component type will be used).

  • +
+
+
+
+ +
+
+inline binpacking_distribution_policy operator()(std::vector<id_type> &&locs, char const *perf_counter_name = default_binpacking_counter_name) const#
+

Create a new default_distribution policy representing the given set of localities.

+
+
Parameters
+
    +
  • locs – [in] The list of localities the new instance should represent

  • +
  • perf_counter_name – [in] The name of the performance counter which should be used as the distribution criteria (by default the overall number of existing instances of the given component type will be used).

  • +
+
+
+
+ +
+
+inline binpacking_distribution_policy operator()(id_type const &loc, char const *perf_counter_name = default_binpacking_counter_name) const#
+

Create a new default_distribution policy representing the given locality

+
+
Parameters
+
    +
  • loc – [in] The locality the new instance should represent

  • +
  • perf_counter_name – [in] The name of the performance counter that should be used as the distribution criteria (by default the overall number of existing instances of the given component type will be used).

  • +
+
+
+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::future<hpx::id_type> create(Ts&&... vs) const#
+

Create one object on one of the localities associated by this policy instance

+
+
Parameters
+

vs – [in] The arguments which will be forwarded to the constructor of the new object.

+
+
Returns
+

A future holding the global address which represents the newly created object

+
+
+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::future<std::vector<bulk_locality_result>> bulk_create(std::size_t count, Ts&&... vs) const#
+

Create multiple objects on the localities associated by this policy instance

+
+
Parameters
+
    +
  • count – [in] The number of objects to create

  • +
  • vs – [in] The arguments which will be forwarded to the constructors of the new objects.

  • +
+
+
Returns
+

A future holding the list of global addresses which represent the newly created objects

+
+
+
+ +
+
+inline std::string const &get_counter_name() const#
+

Returns the name of the performance counter associated with this policy instance.

+
+ +
+
+inline std::size_t get_num_localities() const#
+

Returns the number of associated localities for this distribution policy

+
+

Note

+

This function is part of the creation policy implemented by this class

+
+
+ +
+
+ +
+ +
+ +
+
+
hpx/distribution_policies/colocating_distribution_policy.hpp#
+

Defined in header hpx/distribution_policies/colocating_distribution_policy.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+

Variables

+
+
+static const colocating_distribution_policy colocated = {}#
+

A predefined instance of the co-locating distribution_policy. It will represent the local locality and will place all items to create here.

+
+ +
+
+
+struct colocating_distribution_policy#
+
+#include <colocating_distribution_policy.hpp>
+

This class specifies the parameters for a distribution policy to use for creating a given number of items on the locality where a given object is currently placed.

+
+

Public Functions

+
+
+constexpr colocating_distribution_policy() = default#
+

Default-construct a new instance of a colocating_distribution_policy. This policy will represent the local locality.

+
+ +
+
+inline colocating_distribution_policy operator()(id_type const &id) const#
+

Create a new colocating_distribution_policy representing the locality where the given object is current located

+
+
Parameters
+

id – [in] The global address of the object with which the new instances should be colocated on

+
+
+
+ +
+
+template<typename Client, typename Stub, typename Data>
inline colocating_distribution_policy operator()(client_base<Client, Stub, Data> const &client) const#
+

Create a new colocating_distribution_policy representing the locality where the given object is current located

+
+
Parameters
+

client – [in] The client side representation of the object with which the new instances should be colocated on

+
+
+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::future<hpx::id_type> create(Ts&&... vs) const#
+

Create one object on the locality of the object this distribution policy instance is associated with

+
+

Note

+

This function is part of the placement policy implemented by this class

+
+
+
Parameters
+

vs – [in] The arguments which will be forwarded to the constructor of the new object.

+
+
Returns
+

A future holding the global address which represents the newly created object

+
+
+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::future<std::vector<bulk_locality_result>> bulk_create(std::size_t count, Ts&&... vs) const#
+

Create multiple objects colocated with the object represented by this policy instance

+
+

Note

+

This function is part of the placement policy implemented by this class

+
+
+
Parameters
+
    +
  • count – [in] The number of objects to create

  • +
  • vs – [in] The arguments which will be forwarded to the constructors of the new objects.

  • +
+
+
Returns
+

A future holding the list of global addresses which represent the newly created objects

+
+
+
+ +
+
+template<typename Action, typename ...Ts>
inline async_result<Action>::type async(launch policy, Ts&&... vs) const#
+
+ +
+
+template<typename Action, typename Callback, typename ...Ts>
inline async_result<Action>::type async_cb(launch policy, Callback &&cb, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename Continuation, typename ...Ts>
inline bool apply(Continuation &&c, launch policy, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename ...Ts>
inline bool apply(launch policy, Ts&&... vs) const#
+
+ +
+
+template<typename Action, typename Continuation, typename Callback, typename ...Ts>
inline bool apply_cb(Continuation &&c, launch policy, Callback &&cb, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename Callback, typename ...Ts>
inline bool apply_cb(launch policy, Callback &&cb, Ts&&... vs) const#
+
+ +
+
+inline hpx::id_type get_next_target() const#
+

Returns the locality which is anticipated to be used for the next async operation

+
+ +
+
+

Public Static Functions

+
+
+static inline std::size_t get_num_localities()#
+

Returns the number of associated localities for this distribution policy

+
+

Note

+

This function is part of the creation policy implemented by this class

+
+
+ +
+
+
+template<typename Action>
struct async_result#
+
+#include <colocating_distribution_policy.hpp>
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+

Public Types

+
+
+using type = hpx::future<typename traits::promise_local_result<typename hpx::traits::extract_action<Action>::remote_result_type>::type>#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/distribution_policies/default_distribution_policy.hpp#
+

Defined in header hpx/distribution_policies/default_distribution_policy.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+

Variables

+
+
+static const default_distribution_policy default_layout = {}#
+

A predefined instance of the default distribution_policy. It will represent the local locality and will place all items to create here.

+
+ +
+
+
+struct default_distribution_policy#
+
+#include <default_distribution_policy.hpp>
+

This class specifies the parameters for a simple distribution policy to use for creating (and evenly distributing) a given number of items on a given set of localities.

+
+

Public Functions

+
+
+constexpr default_distribution_policy() = default#
+

Default-construct a new instance of a default_distribution_policy. This policy will represent one locality (the local locality).

+
+ +
+
+inline default_distribution_policy operator()(std::vector<id_type> const &locs) const#
+

Create a new default_distribution policy representing the given set of localities.

+
+
Parameters
+

locs – [in] The list of localities the new instance should represent

+
+
+
+ +
+
+inline default_distribution_policy operator()(std::vector<id_type> &&locs) const#
+

Create a new default_distribution policy representing the given set of localities.

+
+
Parameters
+

locs – [in] The list of localities the new instance should represent

+
+
+
+ +
+
+inline default_distribution_policy operator()(id_type const &loc) const#
+

Create a new default_distribution policy representing the given locality

+
+
Parameters
+

loc – [in] The locality the new instance should represent

+
+
+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::future<hpx::id_type> create(Ts&&... vs) const#
+

Create one object on one of the localities associated by this policy instance

+
+

Note

+

This function is part of the placement policy implemented by this class

+
+
+
Parameters
+

vs – [in] The arguments which will be forwarded to the constructor of the new object.

+
+
Returns
+

A future holding the global address which represents the newly created object

+
+
+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::future<std::vector<bulk_locality_result>> bulk_create(std::size_t count, Ts&&... vs) const#
+

Create multiple objects on the localities associated by this policy instance

+
+

Note

+

This function is part of the placement policy implemented by this class

+
+
+
Parameters
+
    +
  • count – [in] The number of objects to create

  • +
  • vs – [in] The arguments which will be forwarded to the constructors of the new objects.

  • +
+
+
Returns
+

A future holding the list of global addresses that represent the newly created objects

+
+
+
+ +
+
+template<typename Action, typename ...Ts>
inline async_result<Action>::type async(launch policy, Ts&&... vs) const#
+
+ +
+
+template<typename Action, typename Callback, typename ...Ts>
inline async_result<Action>::type async_cb(launch policy, Callback &&cb, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename Continuation, typename ...Ts>
inline bool apply(Continuation &&c, launch policy, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename ...Ts>
inline bool apply(threads::thread_priority priority, Ts&&... vs) const#
+
+ +
+
+template<typename Action, typename Continuation, typename Callback, typename ...Ts>
inline bool apply_cb(Continuation &&c, launch policy, Callback &&cb, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename Callback, typename ...Ts>
inline bool apply_cb(launch policy, Callback &&cb, Ts&&... vs) const#
+
+ +
+
+inline std::size_t get_num_localities() const#
+

Returns the number of associated localities for this distribution policy

+
+

Note

+

This function is part of the creation policy implemented by this class

+
+
+ +
+
+inline hpx::id_type get_next_target() const#
+

Returns the locality which is anticipated to be used for the next async operation

+
+ +
+
+
+template<typename Action>
struct async_result#
+
+#include <default_distribution_policy.hpp>
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+

Public Types

+
+
+using type = hpx::future<typename traits::promise_local_result<typename hpx::traits::extract_action<Action>::remote_result_type>::type>#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/distribution_policies/target_distribution_policy.hpp#
+

Defined in header hpx/distribution_policies/target_distribution_policy.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+

Variables

+
+
+static const target_distribution_policy target = {}#
+

A predefined instance of the target_distribution_policy. It will represent the local locality and will place all items to create here.

+
+ +
+
+
+struct target_distribution_policy#
+
+#include <target_distribution_policy.hpp>
+

This class specifies the parameters for a simple distribution policy to use for creating (and evenly distributing) a given number of items on a given set of localities.

+
+

Public Functions

+
+
+target_distribution_policy() = default#
+

Default-construct a new instance of a target_distribution_policy. This policy will represent one locality (the local locality).

+
+ +
+
+inline target_distribution_policy operator()(id_type const &id) const#
+

Create a new target_distribution_policy representing the given locality

+
+
Parameters
+

loc – [in] The locality the new instance should represent

+
+
+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::future<hpx::id_type> create(Ts&&... vs) const#
+

Create one object on one of the localities associated by this policy instance

+
+

Note

+

This function is part of the placement policy implemented by this class

+
+
+
Parameters
+

vs – [in] The arguments which will be forwarded to the constructor of the new object.

+
+
Returns
+

A future holding the global address which represents the newly created object

+
+
+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::future<std::vector<bulk_locality_result>> bulk_create(std::size_t count, Ts&&... vs) const#
+

Create multiple objects on the localities associated by this policy instance

+
+

Note

+

This function is part of the placement policy implemented by this class

+
+
+
Parameters
+
    +
  • count – [in] The number of objects to create

  • +
  • vs – [in] The arguments which will be forwarded to the constructors of the new objects.

  • +
+
+
Returns
+

A future holding the list of global addresses which represent the newly created objects

+
+
+
+ +
+
+template<typename Action, typename ...Ts>
inline async_result<Action>::type async(launch policy, Ts&&... vs) const#
+
+ +
+
+template<typename Action, typename Callback, typename ...Ts>
inline async_result<Action>::type async_cb(launch policy, Callback &&cb, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename Continuation, typename ...Ts>
inline bool apply(Continuation &&c, launch policy, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename ...Ts>
inline bool apply(launch policy, Ts&&... vs) const#
+
+ +
+
+template<typename Action, typename Continuation, typename Callback, typename ...Ts>
inline bool apply_cb(Continuation &&c, launch policy, Callback &&cb, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename Callback, typename ...Ts>
inline bool apply_cb(launch policy, Callback &&cb, Ts&&... vs) const#
+
+ +
+
+inline std::size_t get_num_localities() const#
+

Returns the number of associated localities for this distribution policy

+
+

Note

+

This function is part of the creation policy implemented by this class

+
+
+ +
+
+inline hpx::id_type get_next_target() const#
+

Returns the locality which is anticipated to be used for the next async operation

+
+ +
+
+
+template<typename Action>
struct async_result#
+
+#include <target_distribution_policy.hpp>
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+

Public Types

+
+
+using type = hpx::future<typename traits::promise_local_result<typename hpx::traits::extract_action<Action>::remote_result_type>::type>#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
hpx/distribution_policies/unwrapping_result_policy.hpp#
+

Defined in header hpx/distribution_policies/unwrapping_result_policy.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+
+struct unwrapping_result_policy#
+
+#include <unwrapping_result_policy.hpp>
+

This class is a distribution policy that can be using with actions that return futures. For those actions it is possible to apply certain optimizations if the action is invoked synchronously.

+
+

Public Functions

+
+
+inline explicit unwrapping_result_policy(id_type const &id)#
+
+ +
+
+template<typename Client, typename Stub, typename Data>
inline explicit unwrapping_result_policy(client_base<Client, Stub, Data> const &client)#
+
+ +
+
+template<typename Action, typename ...Ts>
inline async_result<Action>::type async(launch policy, Ts&&... vs) const#
+
+ +
+
+template<typename Action, typename ...Ts>
inline async_result<Action>::type async(launch::sync_policy, Ts&&... vs) const#
+
+ +
+
+template<typename Action, typename Callback, typename ...Ts>
inline async_result<Action>::type async_cb(launch policy, Callback &&cb, Ts&&... vs) const#
+
+ +
+
+template<typename Action, typename Continuation, typename ...Ts>
inline bool apply(Continuation &&c, launch policy, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename ...Ts>
inline bool apply(launch policy, Ts&&... vs) const#
+
+ +
+
+template<typename Action, typename Continuation, typename Callback, typename ...Ts>
inline bool apply_cb(Continuation &&c, launch policy, Callback &&cb, Ts&&... vs) const#
+
+

Note

+

This function is part of the invocation policy implemented by this class

+
+
+ +
+
+template<typename Action, typename Callback, typename ...Ts>
inline bool apply_cb(launch policy, Callback &&cb, Ts&&... vs) const#
+
+ +
+
+inline hpx::id_type const &get_next_target() const#
+
+ +
+
+
+template<typename Action>
struct async_result#
+
+

Public Types

+
+
+using type = typename traits::promise_local_result<typename hpx::traits::extract_action<Action>::remote_result_type>::type#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
+
+
executors_distributed#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/executors_distributed/distribution_policy_executor.hpp#
+

Defined in header hpx/executors_distributed/distribution_policy_executor.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+
+namespace execution
+
+

Functions

+
+
+template<typename DistPolicy>
distribution_policy_executor(DistPolicy&&) -> distribution_policy_executor<std::decay_t<DistPolicy>>#
+
+ +
+
+template<typename DistPolicy>  HPX_DEPRECATED_V (1, 9, "hpx::parallel::execution::make_distribution_policy_executor is " "deprecated, use " "hpx::parallel::execution::distribution_policy_executor instead") distribution_policy_executor< std
+

Create a new distribution_policy_executor from the given distribution_policy.

+
+
Parameters
+

policy – The distribution_policy to create an executor from

+
+
+
+ +
+
+
+template<typename DistPolicy>
class distribution_policy_executor
+
+#include <distribution_policy_executor.hpp>
+

A distribution_policy_executor creates groups of parallel execution agents that execute in threads implicitly created by the executor and placed on any of the associated localities.

+
+
Template Parameters
+

DistPolicy – The distribution policy type for which an executor should be created. The expression hpx::traits::is_distribution_policy_v<DistPolicy> must evaluate to true.

+
+
+
+ +
+ +
+ +
+ +
+
+
+
+
init_runtime#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx::finalize, hpx::disconnect#
+

Defined in header hpx/init.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+int finalize(double shutdown_timeout, double localwait = -1.0, error_code &ec = throws)#
+

Main function to gracefully terminate the HPX runtime system.

+

The function hpx::finalize is the main way to (gracefully) exit any HPX application. It must be called at least once, but can be called multiple times as well. However, only the first invocation will have effect. It will notify all connected localities to finish execution. Only after all other localities have exited this function will return, allowing to exit the console locality as well.

+

During the execution of this function the runtime system will invoke all registered shutdown functions (see hpx::init) on all localities.

+

+The default value (-1.0) will try to find a globally set timeout value (can be set as the configuration parameter hpx.shutdown_timeout), and if that is not set or -1.0 as well, it will disable any timeout, each connected locality will wait for all existing HPX-threads to terminate.

+

+The default value (-1.0) will try to find a globally set wait time value (can be set as the configuration parameter “hpx.finalize_wait_time”), and if this is not set or -1.0 as well, it will disable any addition local wait time before proceeding.

+

+This function will block and wait for all connected localities to exit before returning to the caller. It should be the last HPX-function called by any application.

+

Using this function is an alternative to hpx::disconnect, these functions do not need to be called both.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • shutdown_timeout – This parameter allows to specify a timeout (in microseconds), specifying how long any of the connected localities should wait for pending tasks to be executed. After this timeout, all suspended HPX-threads will be aborted. Note, that this function will not abort any running HPX-threads. In any case the shutdown will not proceed as long as there is at least one pending/running HPX-thread.

  • +
  • localwait – This parameter allows to specify a local wait time (in microseconds) before the connected localities will be notified and the overall shutdown process starts.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function will always return zero.

+
+
+
+ +
+
+inline int finalize(error_code &ec = throws)#
+

Main function to gracefully terminate the HPX runtime system.

+

The function hpx::finalize is the main way to (gracefully) exit any HPX application. It must be called at least once, but can be called multiple times as well. However, only the first invocation will have effect. It will notify all connected localities to finish execution. Only after all other localities have exited this function will return, allowing to exit the console locality as well.

+

During the execution of this function the runtime system will invoke all registered shutdown functions (see hpx::init) on all localities.

+

+This function will block and wait for all connected localities to exit before returning to the caller. It should be the last HPX-function called by any application.

+

Using this function is an alternative to hpx::disconnect, these functions do not need to be called both.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
Returns
+

This function will always return zero.

+
+
+
+ +
+
+void terminate()#
+

Terminate any application non-gracefully.

+

The function hpx::terminate is the non-graceful way to exit any application immediately. It can be called from any locality and will terminate all localities currently used by the application.

+
+

Note

+

This function will cause HPX to call std::terminate() on all localities associated with this application. If the function is called not from an HPX thread it will fail and return an error using the argument ec.

+
+
+ +
+
+int disconnect(double shutdown_timeout, double localwait = -1.0, error_code &ec = throws)#
+

Disconnect this locality from the application.

+

The function hpx::disconnect can be used to disconnect a locality from a running HPX application.

+

During the execution of this function the runtime system will invoke all registered shutdown functions (see hpx::init

) on this locality.

+

The default value (

+-1.0) will try to find a globally set timeout value (can be set as the configuration parameter “hpx.shutdown_timeout”), and if that is not set or -1.0 as well, it will disable any timeout, each connected locality will wait for all existing HPX-threads to terminate.

+

+The default value (-1.0) will try to find a globally set wait time value (can be set as the configuration parameter hpx.finalize_wait_time), and if this is not set or -1.0 as well, it will disable any addition local wait time before proceeding.

+

+This function will block and wait for this locality to finish executing before returning to the caller. It should be the last HPX-function called by any locality being disconnected.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • shutdown_timeout – This parameter allows to specify a timeout (in microseconds), specifying how long this locality should wait for pending tasks to be executed. After this timeout, all suspended HPX-threads will be aborted. Note, that this function will not abort any running HPX-threads. In any case the shutdown will not proceed as long as there is at least one pending/running HPX-thread.

  • +
  • localwait – This parameter allows to specify a local wait time (in microseconds) before the connected localities will be notified and the overall shutdown process starts.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

This function will always return zero.

+
+
+
+ +
+
+inline int disconnect(error_code &ec = throws)#
+

Disconnect this locality from the application.

+

The function hpx::disconnect can be used to disconnect a locality from a running HPX application.

+

During the execution of this function the runtime system will invoke all registered shutdown functions (see hpx::init) on this locality.

+

+This function will block and wait for this locality to finish executing before returning to the caller. It should be the last HPX-function called by any locality being disconnected.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
Returns
+

This function will always return zero.

+
+
+
+ +
+
+int stop(error_code &ec = throws)#
+

Stop the runtime system.

+

+This function will block and wait for this locality to finish executing before returning to the caller. It should be the last HPX-function called on every locality. This function should be used only if the runtime system was started using hpx::start.

+
+
Returns
+

The function returns the value, which has been returned from the user supplied main HPX function (usually hpx_main).

+
+
+
+ +
+
+ +
+
+
hpx/hpx_init.hpp#
+

Defined in header hpx/hpx_init.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+ +
+
+
hpx::init#
+

Defined in header hpx/init.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx_startup#
+
+

Variables

+
+
+std::function<int(hpx::program_options::variables_map&)> const &get_main_func()#
+
+ +
+
+ +
+
+namespace hpx
+
+

Functions

+
+
+inline int init(std::function<int(hpx::program_options::variables_map&)> f, int argc, char **argv, init_params const &params = init_params())#
+

Main entry point for launching the HPX runtime system.

+

This is the main entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread. This overload will not call hpx_main.

+

+This is the main entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread.

+
+

Note

+

If the parameter mode is not given (defaulted), the created runtime system instance will be executed in console or worker mode depending on the command line arguments passed in argc/argv. Otherwise it will be executed as specified by the parametermode.

+
+
+
Parameters
+
    +
  • f – [in] The function to be scheduled as an HPX thread. Usually this function represents the main entry point of any HPX application. If f is nullptr the HPX runtime environment will be started without invoking f.

  • +
  • argc – [in] The number of command line arguments passed in argv. This is usually the unchanged value as passed by the operating system (to main()).

  • +
  • argv – [in] The command line arguments for this application, usually that is the value as passed by the operating system (to main()).

  • +
  • params – [in] The parameters to the hpx::init function (See documentation of hpx::init_params)

  • +
+
+
Returns
+

The function returns the value, which has been returned from the user supplied f.

+
+
+
+ +
+
+inline int init(std::function<int(int, char**)> f, int argc, char **argv, init_params const &params = init_params())#
+

Main entry point for launching the HPX runtime system.

+

This is the main entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread. This overload will not call hpx_main.

+

+This is the main entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread.

+
+

Note

+

If the parameter mode is not given (defaulted), the created runtime system instance will be executed in console or worker mode depending on the command line arguments passed in argc/argv. Otherwise it will be executed as specified by the parametermode.

+
+
+
Parameters
+
    +
  • f – [in] The function to be scheduled as an HPX thread. Usually this function represents the main entry point of any HPX application. If f is nullptr the HPX runtime environment will be started without invoking f.

  • +
  • argc – [in] The number of command line arguments passed in argv. This is usually the unchanged value as passed by the operating system (to main()).

  • +
  • argv – [in] The command line arguments for this application, usually that is the value as passed by the operating system (to main()).

  • +
  • params – [in] The parameters to the hpx::init function (See documentation of hpx::init_params)

  • +
+
+
Returns
+

The function returns the value, which has been returned from the user supplied f.

+
+
+
+ +
+
+inline int init(int argc, char **argv, init_params const &params = init_params())#
+

Main entry point for launching the HPX runtime system.

+

This is the main entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread. This overload will not call hpx_main.

+

+This is the main entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread.

+
+

Note

+

If the parameter mode is not given (defaulted), the created runtime system instance will be executed in console or worker mode depending on the command line arguments passed in argc/argv. Otherwise it will be executed as specified by the parametermode.

+
+
+
Parameters
+
    +
  • argc – [in] The number of command line arguments passed in argv. This is usually the unchanged value as passed by the operating system (to main()).

  • +
  • argv – [in] The command line arguments for this application, usually that is the value as passed by the operating system (to main()).

  • +
  • params – [in] The parameters to the hpx::init function (See documentation of hpx::init_params)

  • +
+
+
Returns
+

The function returns the value, which has been returned from the user supplied f.

+
+
+
+ +
+
+inline int init(std::nullptr_t f, int argc, char **argv, init_params const &params = init_params())#
+

Main entry point for launching the HPX runtime system.

+

This is the main entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread. This overload will not call hpx_main.

+

+This is the main entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread.

+
+

Note

+

If the parameter mode is not given (defaulted), the created runtime system instance will be executed in console or worker mode depending on the command line arguments passed in argc/argv. Otherwise it will be executed as specified by the parametermode.

+
+
+
Parameters
+
    +
  • f – [in] The function to be scheduled as an HPX thread. Usually this function represents the main entry point of any HPX application. If f is nullptr the HPX runtime environment will be started without invoking f.

  • +
  • argc – [in] The number of command line arguments passed in argv. This is usually the unchanged value as passed by the operating system (to main()).

  • +
  • argv – [in] The command line arguments for this application, usually that is the value as passed by the operating system (to main()).

  • +
  • params – [in] The parameters to the hpx::init function (See documentation of hpx::init_params)

  • +
+
+
Returns
+

The function returns the value, which has been returned from the user supplied f.

+
+
+
+ +
+
+inline int init(init_params const &params = init_params())#
+

Main entry point for launching the HPX runtime system.

+

This is a simplified main entry point, which can be used to set up the runtime for an HPX application (the runtime system will be set up in console mode or worker mode depending on the command line settings).

+

+This is a simplified main entry point, which can be used to set up the runtime for an HPX application (the runtime system will be set up in console mode or worker mode depending on the command line settings).

+
+

Note

+

The created runtime system instance will be executed in console or worker mode depending on the command line arguments passed in argc/argv. If not command line arguments are passed, console mode is assumed.

+
+
+

Note

+

If no command line arguments are passed the HPX runtime system will not support any of the default command line options as described in the section ‘HPX Command Line Options’.

+
+
+
Parameters
+

params – [in] The parameters to the hpx::init function (See documentation of hpx::init_params)

+
+
Returns
+

The function returns the value, which has been returned from hpx_main (or 0 when executed in worker mode).

+
+
+
+ +
+
+ +
+
+
hpx::init_params#
+

Defined in header hpx/init.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+struct init_params#
+
+#include <hpx_init_params.hpp>
+

Parameters used to initialize the HPX runtime through hpx::init and hpx::start.

+
+

Public Functions

+
+
+inline init_params()#
+
+ +
+
+

Public Members

+
+
+std::reference_wrapper<hpx::program_options::options_description const> desc_cmdline = hpx::local::detail::default_desc(HPX_APPLICATION_STRING)#
+
+ +
+
+std::vector<std::string> cfg#
+
+ +
+
+mutable startup_function_type startup#
+
+ +
+
+mutable shutdown_function_type shutdown#
+
+ +
+
+hpx::runtime_mode mode = ::hpx::runtime_mode::default_#
+
+ +
+
+hpx::resource::partitioner_mode rp_mode = ::hpx::resource::partitioner_mode::default_#
+
+ +
+
+hpx::resource::rp_callback_type rp_callback#
+
+ +
+
+ +
+ +
+
+
hpx/hpx_start.hpp#
+

Defined in header hpx/hpx_start.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+ +
+
+
hpx::start#
+

Defined in header hpx/init.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx_startup
+
+ +
+
+namespace hpx
+
+

Functions

+
+
+inline bool start(std::function<int(hpx::program_options::variables_map&)> f, int argc, char **argv, init_params const &params = init_params())#
+

Main non-blocking entry point for launching the HPX runtime system.

+

This is the main, non-blocking entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread. It will return immediately after that. Use hpx::wait and hpx::stop to synchronize with the runtime system’s execution. This overload will not call hpx_main.

+

+This is the main, non-blocking entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as an HPX thread. It will return immediately after that. Use hpx::wait and hpx::stop to synchronize with the runtime system’s execution.

+
+

Note

+

If the parameter mode is not given (defaulted), the created runtime system instance will be executed in console or worker mode depending on the command line arguments passed in argc/argv. Otherwise it will be executed as specified by the parametermode.

+
+
+
Parameters
+
    +
  • f – [in] The function to be scheduled as an HPX thread. Usually this function represents the main entry point of any HPX application. If f is nullptr the HPX runtime environment will be started without invoking f.

  • +
  • argc – [in] The number of command line arguments passed in argv. This is usually the unchanged value as passed by the operating system (to main()).

  • +
  • argv – [in] The command line arguments for this application, usually that is the value as passed by the operating system (to main()).

  • +
  • params – [in] The parameters to the hpx::start function (See documentation of hpx::init_params)

  • +
+
+
Returns
+

The function returns true if command line processing succeeded and the runtime system was started successfully. It will return false otherwise.

+
+
+
+ +
+
+inline bool start(std::function<int(int, char**)> f, int argc, char **argv, init_params const &params = init_params())#
+

Main non-blocking entry point for launching the HPX runtime system.

+

This is the main, non-blocking entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread. It will return immediately after that. Use hpx::wait and hpx::stop to synchronize with the runtime system’s execution. This overload will not call hpx_main.

+

+This is the main, non-blocking entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as an HPX thread. It will return immediately after that. Use hpx::wait and hpx::stop to synchronize with the runtime system’s execution.

+
+

Note

+

If the parameter mode is not given (defaulted), the created runtime system instance will be executed in console or worker mode depending on the command line arguments passed in argc/argv. Otherwise it will be executed as specified by the parametermode.

+
+
+
Parameters
+
    +
  • f – [in] The function to be scheduled as an HPX thread. Usually this function represents the main entry point of any HPX application. If f is nullptr the HPX runtime environment will be started without invoking f.

  • +
  • argc – [in] The number of command line arguments passed in argv. This is usually the unchanged value as passed by the operating system (to main()).

  • +
  • argv – [in] The command line arguments for this application, usually that is the value as passed by the operating system (to main()).

  • +
  • params – [in] The parameters to the hpx::start function (See documentation of hpx::init_params)

  • +
+
+
Returns
+

The function returns true if command line processing succeeded and the runtime system was started successfully. It will return false otherwise.

+
+
+
+ +
+
+inline bool start(int argc, char **argv, init_params const &params = init_params())#
+

Main non-blocking entry point for launching the HPX runtime system.

+

This is the main, non-blocking entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread. It will return immediately after that. Use hpx::wait and hpx::stop to synchronize with the runtime system’s execution. This overload will not call hpx_main.

+

+This is the main, non-blocking entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as an HPX thread. It will return immediately after that. Use hpx::wait and hpx::stop to synchronize with the runtime system’s execution.

+
+

Note

+

If the parameter mode is not given (defaulted), the created runtime system instance will be executed in console or worker mode depending on the command line arguments passed in argc/argv. Otherwise it will be executed as specified by the parametermode.

+
+
+
Parameters
+
    +
  • argc – [in] The number of command line arguments passed in argv. This is usually the unchanged value as passed by the operating system (to main()).

  • +
  • argv – [in] The command line arguments for this application, usually that is the value as passed by the operating system (to main()).

  • +
  • params – [in] The parameters to the hpx::start function (See documentation of hpx::init_params)

  • +
+
+
Returns
+

The function returns true if command line processing succeeded and the runtime system was started successfully. It will return false otherwise.

+
+
+
+ +
+
+inline bool start(std::nullptr_t f, int argc, char **argv, init_params const &params = init_params())#
+

Main non-blocking entry point for launching the HPX runtime system.

+

This is the main, non-blocking entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as a HPX thread. It will return immediately after that. Use hpx::wait and hpx::stop to synchronize with the runtime system’s execution. This overload will not call hpx_main.

+

+This is the main, non-blocking entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as an HPX thread. It will return immediately after that. Use hpx::wait and hpx::stop to synchronize with the runtime system’s execution.

+
+

Note

+

If the parameter mode is not given (defaulted), the created runtime system instance will be executed in console or worker mode depending on the command line arguments passed in argc/argv. Otherwise it will be executed as specified by the parametermode.

+
+
+
Parameters
+
    +
  • f – [in] The function to be scheduled as an HPX thread. Usually this function represents the main entry point of any HPX application. If f is nullptr the HPX runtime environment will be started without invoking f.

  • +
  • argc – [in] The number of command line arguments passed in argv. This is usually the unchanged value as passed by the operating system (to main()).

  • +
  • argv – [in] The command line arguments for this application, usually that is the value as passed by the operating system (to main()).

  • +
  • params – [in] The parameters to the hpx::start function (See documentation of hpx::init_params)

  • +
+
+
Returns
+

The function returns true if command line processing succeeded and the runtime system was started successfully. It will return false otherwise.

+
+
+
+ +
+
+inline bool start(init_params const &params = init_params())#
+

Main non-blocking entry point for launching the HPX runtime system.

+

This is a simplified main, non-blocking entry point, which can be used to set up the runtime for an HPX application (the runtime system will be set up in console mode or worker mode depending on the command line settings). It will return immediately after that. Use hpx::wait and hpx::stop to synchronize with the runtime system’s execution.

+

+This is the main, non-blocking entry point for any HPX application. This function (or one of its overloads below) should be called from the users main() function. It will set up the HPX runtime environment and schedule the function given by f as an HPX thread. It will return immediately after that. Use hpx::wait and hpx::stop to synchronize with the runtime system’s execution.

+
+

Note

+

The created runtime system instance will be executed in console or worker mode depending on the command line arguments passed in argc/argv. If not command line arguments are passed, console mode is assumed.

+
+
+

Note

+

If no command line arguments are passed the HPX runtime system will not support any of the default command line options as described in the section ‘HPX Command Line Options’.

+
+
+
Parameters
+

params – [in] The parameters to the hpx::start function (See documentation of hpx::init_params)

+
+
Returns
+

The function returns true if command line processing succeeded and the runtime system was started successfully. It will return false otherwise.

+
+
+
+ +
+
+ +
+
+
hpx::suspend, hpx::resume#
+

Defined in header hpx/init.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+int suspend(error_code &ec = throws)#
+

Suspend the runtime system.

+

The function hpx::suspend is used to suspend the HPX runtime system. It can only be used when running HPX on a single locality. It will block waiting for all thread pools to be empty. This function only be called when the runtime is running, or already suspended in which case this function will do nothing.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
Returns
+

This function will always return zero.

+
+
+
+ +
+
+int resume(error_code &ec = throws)#
+

Resume the HPX runtime system.

+

The function hpx::resume is used to resume the HPX runtime system. It can only be used when running HPX on a single locality. It will block waiting for all thread pools to be resumed. This function only be called when the runtime suspended, or already running in which case this function will do nothing.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
Returns
+

This function will always return zero.

+
+
+
+ +
+
+ +
+
+
+
+
naming_base#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/naming_base/unmanaged.hpp#
+

Defined in header hpx/naming_base/unmanaged.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+hpx::id_type unmanaged(hpx::id_type const &id)#
+

The helper function hpx::unmanaged can be used to generate a global identifier which does not participate in the automatic garbage collection.

+
+

Note

+

This function allows to apply certain optimizations to the process of memory management in HPX. It however requires the user to take full responsibility for keeping the referenced objects alive long enough.

+
+
+
Parameters
+

id – [in] The id to generated the unmanaged global id from This parameter can be itself a managed or a unmanaged global id.

+
+
Returns
+

This function returns a new global id referencing the same object as the parameter id. The only difference is that the returned global identifier does not participate in the automatic garbage collection.

+
+
+
+ +
+
+
+namespace naming#
+
+ +
+ +
+
+
+
+
parcelset#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/parcelset/connection_cache.hpp#
+

Defined in header hpx/parcelset/connection_cache.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/parcelset/message_handler_fwd.hpp#
+

Defined in header hpx/parcelset/message_handler_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/parcelset/parcelhandler.hpp#
+

Defined in header hpx/parcelset/parcelhandler.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/parcelset/parcelset_fwd.hpp#
+

Defined in header hpx/parcelset/parcelset_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
+
+
parcelset_base#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/parcelset_base/parcelport.hpp#
+

Defined in header hpx/parcelset_base/parcelport.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/parcelset_base/parcelset_base_fwd.hpp#
+

Defined in header hpx/parcelset_base/parcelset_base_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_PARCELPORT_BACKGROUND_MODE_ENUM_DEPRECATION_MSG#
+
+ +
+
+
+namespace hpx
+
+
+namespace parcelset#
+
+

Typedefs

+
+
+using parcel_write_handler_type = hpx::function<void(std::error_code const&, parcelset::parcel const&)>#
+

The type of the function that can be registered as a parcel write handler using the function hpx::set_parcel_write_handler.

+
+

Note

+

A parcel write handler is a function which is called by the parcel layer whenever a parcel has been sent by the underlying networking library and if no explicit parcel handler function was specified for the parcel.

+
+
+ +
+
+

Enums

+
+
+enum class parcelport_background_mode : std::uint8_t#
+

Type of background work to perform.

+

Values:

+
+
+enumerator flush_buffers#
+

perform buffer flush operations

+
+ +
+
+enumerator send#
+

perform send operations (includes buffer flush)

+
+ +
+
+enumerator receive#
+

perform receive operations

+
+ +
+
+enumerator all#
+

perform all operations

+
+ +
+ +
+
+

Functions

+
+
+inline bool operator&(parcelport_background_mode lhs, parcelport_background_mode rhs)#
+
+ +
+
+char const *get_parcelport_background_mode_name(parcelport_background_mode mode)#
+
+ +
+
+

Variables

+
+
+parcel empty_parcel#
+
+ +
+
+constexpr parcelport_background_mode parcelport_background_mode_flush_buffers = parcelport_background_mode::flush_buffers#
+
+ +
+
+constexpr parcelport_background_mode parcelport_background_mode_send = parcelport_background_mode::send#
+
+ +
+
+constexpr parcelport_background_mode parcelport_background_mode_receive = parcelport_background_mode::receive#
+
+ +
+
+constexpr parcelport_background_mode parcelport_background_mode_all = parcelport_background_mode::all#
+
+ +
+
+ +
+ +
+
+
hpx/parcelset_base/set_parcel_write_handler.hpp#
+

Defined in header hpx/parcelset_base/set_parcel_write_handler.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
+
+
performance_counters#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/performance_counters/counter_creators.hpp#
+

Defined in header hpx/performance_counters/counter_creators.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace performance_counters#
+
+

Functions

+
+
+bool default_counter_discoverer(counter_info const&, discover_counter_func const&, discover_counters_mode, error_code&)#
+

Default discovery function for performance counters; to be registered with the counter types. It will pass the counter_info and the error_code to the supplied function.

+
+ +
+
+bool locality_counter_discoverer(counter_info const&, discover_counter_func const&, discover_counters_mode, error_code&)#
+

Default discoverer function for performance counters; to be registered with the counter types. It is suitable to be used for all counters following the naming scheme:

+

/<objectname>(locality#<locality_id>/total)/<instancename>

+
+ +
+
+bool locality_pool_counter_discoverer(counter_info const&, discover_counter_func const&, discover_counters_mode, error_code&)#
+

Default discoverer function for performance counters; to be registered with the counter types. It is suitable to be used for all counters following the naming scheme:

+

/<objectname>(locality#<locality_id>/pool#<pool_name>/total)/<instancename>

+
+ +
+
+bool locality0_counter_discoverer(counter_info const&, discover_counter_func const&, discover_counters_mode, error_code&)#
+

Default discoverer function for AGAS performance counters; to be registered with the counter types. It is suitable to be used for all counters following the naming scheme:

+

/<objectname>{locality#0/total}/<instancename>

+
+ +
+
+bool locality_thread_counter_discoverer(counter_info const&, discover_counter_func const&, discover_counters_mode, error_code&)#
+

Default discoverer function for performance counters; to be registered with the counter types. It is suitable to be used for all counters following the naming scheme:

+

/<objectname>(locality#<locality_id>/worker-thread#<threadnum>)/<instancename>

+
+ +
+
+bool locality_pool_thread_counter_discoverer(counter_info const &info, discover_counter_func const &f, discover_counters_mode mode, error_code &ec)#
+

Default discoverer function for performance counters; to be registered with the counter types. It is suitable to be used for all counters following the naming scheme:

+

/<objectname>{locality#<locality_id>/pool#<poolname>/thread#<threadnum>}/<instancename>

+
+ +
+
+bool locality_pool_thread_no_total_counter_discoverer(counter_info const &info, discover_counter_func const &f, discover_counters_mode mode, error_code &ec)#
+

Default discoverer function for performance counters; to be registered with the counter types. It is suitable to be used for all counters following the naming scheme:

+

/<objectname>{locality#<locality_id>/pool#<poolname>/thread#<threadnum>}/<instancename>

+

This is essentially the same as above just that locality#*/total is not supported.

+
+ +
+
+bool locality_numa_counter_discoverer(counter_info const&, discover_counter_func const&, discover_counters_mode, error_code&)#
+

Default discoverer function for performance counters; to be registered with the counter types. It is suitable to be used for all counters following the naming scheme:

+

/<objectname>(locality#<locality_id>/numa-node#<threadnum>)/<instancename>

+
+ +
+
+naming::gid_type locality_raw_counter_creator(counter_info const&, hpx::function<std::int64_t(bool)> const&, error_code&)#
+

Creation function for raw counters. The passed function is encapsulating the actual value to monitor. This function checks the validity of the supplied counter name, it has to follow the scheme:

+

/<objectname>(locality#<locality_id>/total)/<instancename>

+
+ +
+
+naming::gid_type locality_raw_values_counter_creator(counter_info const&, hpx::function<std::vector<std::int64_t>(bool)> const&, error_code&)#
+
+ +
+
+naming::gid_type agas_raw_counter_creator(counter_info const&, error_code&, char const*const)#
+

Creation function for raw counters. The passed function is encapsulating the actual value to monitor. This function checks the validity of the supplied counter name, it has to follow the scheme:

+

/agas(<objectinstance>/total)/<instancename>

+
+ +
+
+bool agas_counter_discoverer(counter_info const&, discover_counter_func const&, discover_counters_mode, error_code&)#
+

Default discoverer function for performance counters; to be registered with the counter types. It is suitable to be used for all counters following the naming scheme:

+

/agas(<objectinstance>/total)/<instancename>

+
+ +
+
+naming::gid_type local_action_invocation_counter_creator(counter_info const&, error_code&)#
+
+ +
+
+bool local_action_invocation_counter_discoverer(counter_info const&, discover_counter_func const&, discover_counters_mode, error_code&)#
+
+ +
+
+ +
+ +
+
+
hpx/performance_counters/counters.hpp#
+

Defined in header hpx/performance_counters/counters.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace performance_counters
+
+

Typedefs

+
+
+typedef hpx::function<naming::gid_type(counter_info const&, error_code&)> create_counter_func#
+

This declares the type of a function, which will be called by HPX whenever a new performance counter instance of a particular type needs to be created.

+
+ +
+
+typedef hpx::function<bool(counter_info const&, error_code&)> discover_counter_func#
+

This declares a type of a function, which will be passed to a discover_counters_func in order to be called for each discovered performance counter instance.

+
+ +
+
+typedef hpx::function<bool(counter_info const&, discover_counter_func const&, discover_counters_mode, error_code&)> discover_counters_func#
+

This declares the type of a function, which will be called by HPX whenever it needs to discover all performance counter instances of a particular type.

+
+ +
+
+

Enums

+
+
+enum class counter_type#
+

Values:

+
+
+enumerator text#
+

text shows a variable-length text string. It does not deliver calculated values.

+

Formula: None Average: None Type: Text

+
+ +
+
+enumerator raw#
+

raw shows the last observed value only. It does not deliver an average.

+

Formula: None. Shows raw data as collected. Average: None Type: Instantaneous

+
+ +
+
+enumerator monotonically_increasing#
+

monotonically_increasing shows the cumulatively accumulated observed value. It does not deliver an average.

+

Formula: None. Shows cumulatively accumulated data as collected. Average: None Type: Instantaneous

+
+ +
+
+enumerator average_base#
+

average_base is used as the base data (denominator) in the computation of time or count averages for the counter_type::average_count and counter_type::average_timer counter types. This counter type collects the last observed value only.

+

Formula: None. This counter uses raw data in factional calculations without delivering an output. Average: SUM (N) / x Type: Instantaneous

+
+ +
+
+enumerator average_count#
+

average_count shows how many items are processed, on average, during an operation. Counters of this type display a ratio of the items processed (such as bytes sent) to the number of operations completed. The ratio is calculated by comparing the number of items processed during the last interval to the number of operations completed during the last interval.

+

Formula: (N1 - N0) / (D1 - D0), where the numerator (N) represents the number of items processed during the last sample interval, and the denominator (D) represents the number of operations completed during the last two sample intervals. Average: (Nx - N0) / (Dx - D0) Type: Average

+
+ +
+
+enumerator aggregating#
+

aggregating applies a function to an embedded counter instance. The embedded counter is usually evaluated repeatedly after a fixed (but configurable) time interval.

+

Formula: F(Nx)

+
+ +
+
+enumerator average_timer#
+

average_timer measures the average time it takes to complete a process or operation. Counters of this type display a ratio of the total elapsed time of the sample interval to the number of processes or operations completed during that time. This counter type measures time in ticks of the system clock. The variable F represents the number of ticks per second. The value of F is factored into the equation so that the result is displayed in seconds.

+

Formula: ((N1 - N0) / F) / (D1 - D0), where the numerator (N) represents the number of ticks counted during the last sample interval, the variable F represents the frequency of the ticks, and the denominator (D) represents the number of operations completed during the last sample interval. Average: ((Nx - N0) / F) / (Dx - D0) Type: Average

+
+ +
+
+enumerator elapsed_time#
+

elapsed_time shows the total time between when the component or process started and the time when this value is calculated. The variable F represents the number of time units that elapse in one second. The value of F is factored into the equation so that the result is displayed in seconds.

+

Formula: (D0 - N0) / F, where the nominator (D) represents the current time, the numerator (N) represents the time the object was started, and the variable F represents the number of time units that elapse in one second. Average: (Dx - N0) / F Type: Difference

+
+ +
+
+enumerator histogram#
+

histogram exposes a histogram of the measured values instead of a single value as many of the other counter types. Counters of this type expose a counter_value_array instead of a counter_value. Those will also not implement the get_counter_value() functionality. The results are exposed through a separate get_counter_values_array() function.

+

The first three values in the returned array represent the lower and upper boundaries, and the size of the histogram buckets. All remaining values in the returned array represent the number of measurements for each of the buckets in the histogram.

+
+ +
+
+enumerator raw_values#
+

raw_values exposes an array of measured values instead of a single value as many of the other counter types. Counters of this type expose a counter_value_array instead of a counter_value. Those will also not implement the get_counter_value() functionality. The results are exposed through a separate get_counter_values_array() function.

+
+ +
+
+enumerator text
+
+ +
+
+enumerator raw
+
+ +
+
+enumerator monotonically_increasing
+
+ +
+
+enumerator average_base
+
+ +
+
+enumerator average_count
+
+ +
+
+enumerator aggregating
+
+ +
+
+enumerator average_timer
+
+ +
+
+enumerator elapsed_time
+
+ +
+
+enumerator histogram
+
+ +
+
+enumerator raw_values
+

raw_values counter exposes an array of measured values instead of a single value as many of the other counter types. Counters of this type expose a counter_value_array instead of a counter_value. Those will also not implement the get_counter_value() functionality. The results are exposed through a separate get_counter_values_array() function.

+
+ +
+ +
+
+enum class counter_status#
+

Status and error codes used by the functions related to performance counters.

+

Values:

+
+
+enumerator valid_data#
+

No error occurred, data is valid.

+
+ +
+
+enumerator new_data#
+

Data is valid and different from last call.

+
+ +
+
+enumerator invalid_data#
+

Some error occurred, data is not value.

+
+ +
+
+enumerator already_defined#
+

The type or instance already has been defined.

+
+ +
+
+enumerator counter_unknown#
+

The counter instance is unknown.

+
+ +
+
+enumerator counter_type_unknown#
+

The counter type is unknown.

+
+ +
+
+enumerator generic_error#
+

A unknown error occurred.

+
+ +
+
+enumerator valid_data
+
+ +
+
+enumerator new_data
+
+ +
+
+enumerator invalid_data
+
+ +
+
+enumerator already_defined
+
+ +
+
+enumerator counter_unknown
+
+ +
+
+enumerator counter_type_unknown
+
+ +
+
+enumerator generic_error
+
+ +
+ +
+
+

Functions

+
+
+inline std::string &ensure_counter_prefix(std::string &name)#
+
+ +
+
+inline std::string ensure_counter_prefix(std::string const &counter)#
+
+ +
+
+inline std::string &remove_counter_prefix(std::string &name)#
+
+ +
+
+inline std::string remove_counter_prefix(std::string const &counter)#
+
+ +
+
+char const *get_counter_type_name(counter_type state)#
+

Return the readable name of a given counter type.

+
+ +
+
+inline bool status_is_valid(counter_status s)#
+
+ +
+
+inline counter_status add_counter_type(counter_info const &info, error_code &ec)#
+
+ +
+
+inline hpx::id_type get_counter(std::string const &name, error_code &ec)#
+
+ +
+
+inline hpx::id_type get_counter(counter_info const &info, error_code &ec)#
+
+ +
+
+

Variables

+
+
+constexpr const char counter_prefix[] = "/counters"#
+
+ +
+
+constexpr std::size_t counter_prefix_len = std::size(counter_prefix) - 1#
+
+ +
+
+
+struct counter_info#
+
+

Public Functions

+
+
+inline explicit counter_info(counter_type type = counter_type::raw)#
+
+ +
+
+inline explicit counter_info(std::string const &name)#
+
+ +
+
+inline counter_info(counter_type type, std::string const &name, std::string const &helptext = "", std::uint32_t version = HPX_PERFORMANCE_COUNTER_V1, std::string const &uom = "")#
+
+ +
+
+

Public Members

+
+
+counter_type type_#
+

The type of the described counter.

+
+ +
+
+std::uint32_t version_#
+

The version of the described counter using the 0xMMmmSSSS scheme

+
+ +
+
+counter_status status_#
+

The status of the counter object.

+
+ +
+
+std::string fullname_#
+

The full name of this counter.

+
+ +
+
+std::string helptext_#
+

The full descriptive text for this counter.

+
+ +
+
+std::string unit_of_measure_#
+

The unit of measure for this counter.

+
+ +
+
+

Private Functions

+
+
+void serialize(serialization::output_archive &ar, unsigned int) const#
+
+ +
+
+void serialize(serialization::input_archive &ar, unsigned int)#
+
+ +
+
+

Friends

+
+
+friend class hpx::serialization::access
+
+ +
+
+ +
+
+struct counter_path_elements : public hpx::performance_counters::counter_type_path_elements#
+
+#include <counters.hpp>
+

A counter_path_elements holds the elements of a full name for a counter instance. Generally, a full name of a counter instance has the structure:

+

/objectname{parentinstancename::parentindex/instancename#instanceindex} /countername#parameters

+

i.e. /queue{localityprefix/thread#2}/length

+
+

Public Types

+
+
+using base_type = counter_type_path_elements#
+
+ +
+
+

Public Functions

+
+
+inline counter_path_elements()#
+
+ +
+
+inline counter_path_elements(std::string const &objectname, std::string const &countername, std::string const &parameters, std::string const &parentname, std::string const &instancename, std::int64_t parentindex = -1, std::int64_t instanceindex = -1, bool parentinstance_is_basename = false)#
+
+ +
+
+inline counter_path_elements(std::string const &objectname, std::string const &countername, std::string const &parameters, std::string const &parentname, std::string const &instancename, std::string const &subinstancename, std::int64_t parentindex = -1, std::int64_t instanceindex = -1, std::int64_t subinstanceindex = -1, bool parentinstance_is_basename = false)#
+
+ +
+
+

Public Members

+
+
+std::string parentinstancename_#
+

the name of the parent instance

+
+ +
+
+std::string instancename_#
+

the name of the object instance

+
+ +
+
+std::string subinstancename_#
+

the name of the object sub-instance

+
+ +
+
+std::int64_t parentinstanceindex_#
+

the parent instance index

+
+ +
+
+std::int64_t instanceindex_#
+

the instance index

+
+ +
+
+std::int64_t subinstanceindex_#
+

the sub-instance index

+
+ +
+
+bool parentinstance_is_basename_#
+

the parentinstancename_

+
+ +
+
+

Private Functions

+
+
+void serialize(serialization::output_archive &ar, unsigned int)#
+
+ +
+
+void serialize(serialization::input_archive &ar, unsigned int)#
+
+ +
+
+

Friends

+
+
+friend class hpx::serialization::access
+
+ +
+
+ +
+
+struct counter_type_path_elements#
+
+#include <counters.hpp>
+

A counter_type_path_elements holds the elements of a full name for a counter type. Generally, a full name of a counter type has the structure:

+

/objectname/countername

+

i.e. /queue/length

+

Subclassed by hpx::performance_counters::counter_path_elements

+
+

Public Functions

+
+
+counter_type_path_elements() = default#
+
+ +
+
+inline counter_type_path_elements(std::string const &objectname, std::string const &countername, std::string const &parameters)#
+
+ +
+
+

Public Members

+
+
+std::string objectname_#
+

the name of the performance object

+
+ +
+
+std::string countername_#
+

contains the counter name

+
+ +
+
+std::string parameters_#
+

optional parameters for the counter instance

+
+ +
+
+

Protected Functions

+
+
+void serialize(serialization::output_archive &ar, unsigned int) const#
+
+ +
+
+void serialize(serialization::input_archive &ar, unsigned int)#
+
+ +
+
+

Friends

+
+
+friend class hpx::serialization::access
+
+ +
+
+ +
+ +
+ +
+
+
hpx/performance_counters/counters_fwd.hpp#
+

Defined in header hpx/performance_counters/counters_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_COUNTER_TYPE_UNSCOPED_ENUM_DEPRECATION_MSG#
+
+ +
+
+HPX_COUNTER_STATUS_UNSCOPED_ENUM_DEPRECATION_MSG#
+
+ +
+
+HPX_PERFORMANCE_COUNTER_V1#
+
+ +
+
+HPX_DISCOVER_COUNTERS_MODE_UNSCOPED_ENUM_DEPRECATION_MSG#
+
+ +
+
+
+namespace hpx
+
+
+namespace performance_counters
+
+

Enums

+
+
+enum class counter_type
+

Values:

+
+
+enumerator text
+

text shows a variable-length text string. It does not deliver calculated values.

+

Formula: None Average: None Type: Text

+
+ +
+
+enumerator raw
+

raw shows the last observed value only. It does not deliver an average.

+

Formula: None. Shows raw data as collected. Average: None Type: Instantaneous

+
+ +
+
+enumerator monotonically_increasing
+

monotonically_increasing shows the cumulatively accumulated observed value. It does not deliver an average.

+

Formula: None. Shows cumulatively accumulated data as collected. Average: None Type: Instantaneous

+
+ +
+
+enumerator average_base
+

average_base is used as the base data (denominator) in the computation of time or count averages for the counter_type::average_count and counter_type::average_timer counter types. This counter type collects the last observed value only.

+

Formula: None. This counter uses raw data in factional calculations without delivering an output. Average: SUM (N) / x Type: Instantaneous

+
+ +
+
+enumerator average_count
+

average_count shows how many items are processed, on average, during an operation. Counters of this type display a ratio of the items processed (such as bytes sent) to the number of operations completed. The ratio is calculated by comparing the number of items processed during the last interval to the number of operations completed during the last interval.

+

Formula: (N1 - N0) / (D1 - D0), where the numerator (N) represents the number of items processed during the last sample interval, and the denominator (D) represents the number of operations completed during the last two sample intervals. Average: (Nx - N0) / (Dx - D0) Type: Average

+
+ +
+
+enumerator aggregating
+

aggregating applies a function to an embedded counter instance. The embedded counter is usually evaluated repeatedly after a fixed (but configurable) time interval.

+

Formula: F(Nx)

+
+ +
+
+enumerator average_timer
+

average_timer measures the average time it takes to complete a process or operation. Counters of this type display a ratio of the total elapsed time of the sample interval to the number of processes or operations completed during that time. This counter type measures time in ticks of the system clock. The variable F represents the number of ticks per second. The value of F is factored into the equation so that the result is displayed in seconds.

+

Formula: ((N1 - N0) / F) / (D1 - D0), where the numerator (N) represents the number of ticks counted during the last sample interval, the variable F represents the frequency of the ticks, and the denominator (D) represents the number of operations completed during the last sample interval. Average: ((Nx - N0) / F) / (Dx - D0) Type: Average

+
+ +
+
+enumerator elapsed_time
+

elapsed_time shows the total time between when the component or process started and the time when this value is calculated. The variable F represents the number of time units that elapse in one second. The value of F is factored into the equation so that the result is displayed in seconds.

+

Formula: (D0 - N0) / F, where the nominator (D) represents the current time, the numerator (N) represents the time the object was started, and the variable F represents the number of time units that elapse in one second. Average: (Dx - N0) / F Type: Difference

+
+ +
+
+enumerator histogram
+

histogram exposes a histogram of the measured values instead of a single value as many of the other counter types. Counters of this type expose a counter_value_array instead of a counter_value. Those will also not implement the get_counter_value() functionality. The results are exposed through a separate get_counter_values_array() function.

+

The first three values in the returned array represent the lower and upper boundaries, and the size of the histogram buckets. All remaining values in the returned array represent the number of measurements for each of the buckets in the histogram.

+
+ +
+
+enumerator raw_values
+

raw_values exposes an array of measured values instead of a single value as many of the other counter types. Counters of this type expose a counter_value_array instead of a counter_value. Those will also not implement the get_counter_value() functionality. The results are exposed through a separate get_counter_values_array() function.

+
+ +
+
+enumerator text
+
+ +
+
+enumerator raw
+
+ +
+
+enumerator monotonically_increasing
+
+ +
+
+enumerator average_base
+
+ +
+
+enumerator average_count
+
+ +
+
+enumerator aggregating
+
+ +
+
+enumerator average_timer
+
+ +
+
+enumerator elapsed_time
+
+ +
+
+enumerator histogram
+
+ +
+
+enumerator raw_values
+

raw_values counter exposes an array of measured values instead of a single value as many of the other counter types. Counters of this type expose a counter_value_array instead of a counter_value. Those will also not implement the get_counter_value() functionality. The results are exposed through a separate get_counter_values_array() function.

+
+ +
+ +
+
+enum class counter_status
+

Values:

+
+
+enumerator valid_data
+

No error occurred, data is valid.

+
+ +
+
+enumerator new_data
+

Data is valid and different from last call.

+
+ +
+
+enumerator invalid_data
+

Some error occurred, data is not value.

+
+ +
+
+enumerator already_defined
+

The type or instance already has been defined.

+
+ +
+
+enumerator counter_unknown
+

The counter instance is unknown.

+
+ +
+
+enumerator counter_type_unknown
+

The counter type is unknown.

+
+ +
+
+enumerator generic_error
+

A unknown error occurred.

+
+ +
+
+enumerator valid_data
+
+ +
+
+enumerator new_data
+
+ +
+
+enumerator invalid_data
+
+ +
+
+enumerator already_defined
+
+ +
+
+enumerator counter_unknown
+
+ +
+
+enumerator counter_type_unknown
+
+ +
+
+enumerator generic_error
+
+ +
+ +
+
+enum class discover_counters_mode#
+

Values:

+
+
+enumerator minimal#
+
+ +
+
+enumerator full#
+
+ +
+ +
+
+

Functions

+
+
+inline constexpr bool operator<(counter_type lhs, counter_type rhs) noexcept#
+
+ +
+
+inline constexpr bool operator>(counter_type lhs, counter_type rhs) noexcept#
+
+ +
+
+std::ostream &operator<<(std::ostream &os, counter_status rhs)#
+
+ +
+
+counter_status get_counter_type_name(counter_type_path_elements const &path, std::string &result, error_code &ec = throws)#
+

Create a full name of a counter type from the contents of the given counter_type_path_elements instance.The generated counter type name will not contain any parameters.

+
+ +
+
+counter_status get_full_counter_type_name(counter_type_path_elements const &path, std::string &result, error_code &ec = throws)#
+

Create a full name of a counter type from the contents of the given counter_type_path_elements instance. The generated counter type name will contain all parameters.

+
+ +
+
+counter_status get_counter_name(counter_path_elements const &path, std::string &result, error_code &ec = throws)#
+

Create a full name of a counter from the contents of the given counter_path_elements instance.

+
+ +
+
+counter_status get_counter_instance_name(counter_path_elements const &path, std::string &result, error_code &ec = throws)#
+

Create a name of a counter instance from the contents of the given counter_path_elements instance.

+
+ +
+
+counter_status get_counter_type_path_elements(std::string const &name, counter_type_path_elements &path, error_code &ec = throws)#
+

Fill the given counter_type_path_elements instance from the given full name of a counter type.

+
+ +
+
+counter_status get_counter_path_elements(std::string const &name, counter_path_elements &path, error_code &ec = throws)#
+

Fill the given counter_path_elements instance from the given full name of a counter.

+
+ +
+
+counter_status get_counter_name(std::string const &name, std::string &countername, error_code &ec = throws)#
+

Return the canonical counter instance name from a given full instance name.

+
+ +
+
+counter_status get_counter_type_name(std::string const &name, std::string &type_name, error_code &ec = throws)#
+

Return the canonical counter type name from a given (full) instance name.

+
+ +
+
+HPX_DEPRECATED_V (1, 9, HPX_DISCOVER_COUNTERS_MODE_UNSCOPED_ENUM_DEPRECATION_MSG) inline const expr discover_counters_mode discover_counters_minimal
+
+ +
+
+counter_status complement_counter_info(counter_info &info, counter_info const &type_info, error_code &ec = throws)#
+

Complement the counter info if parent instance name is missing.

+
+ +
+
+counter_status complement_counter_info(counter_info &info, error_code &ec = throws)#
+
+ +
+
+counter_status add_counter_type(counter_info const &info, create_counter_func const &create_counter, discover_counters_func const &discover_counters, error_code &ec = throws)#
+
+ +
+
+counter_status discover_counter_types(discover_counter_func const &discover_counter, discover_counters_mode mode = discover_counters_mode::minimal, error_code &ec = throws)#
+

Call the supplied function for each registered counter type.

+
+ +
+
+counter_status discover_counter_types(std::vector<counter_info> &counters, discover_counters_mode mode = discover_counters_mode::minimal, error_code &ec = throws)#
+

Return a list of all available counter descriptions.

+
+ +
+
+counter_status discover_counter_type(std::string const &name, discover_counter_func const &discover_counter, discover_counters_mode mode = discover_counters_mode::minimal, error_code &ec = throws)#
+

Call the supplied function for the given registered counter type.

+
+ +
+
+counter_status discover_counter_type(counter_info const &info, discover_counter_func const &discover_counter, discover_counters_mode mode = discover_counters_mode::minimal, error_code &ec = throws)#
+
+ +
+
+counter_status discover_counter_type(std::string const &name, std::vector<counter_info> &counters, discover_counters_mode mode = discover_counters_mode::minimal, error_code &ec = throws)#
+

Return a list of matching counter descriptions for the given registered counter type.

+
+ +
+
+counter_status discover_counter_type(counter_info const &info, std::vector<counter_info> &counters, discover_counters_mode mode = discover_counters_mode::minimal, error_code &ec = throws)#
+
+ +
+
+bool expand_counter_info(counter_info const&, discover_counter_func const&, error_code&)#
+

call the supplied function will all expanded versions of the supplied counter info.

+

This function expands all locality#* and worker-thread#* wild cards only.

+
+ +
+
+counter_status remove_counter_type(counter_info const &info, error_code &ec = throws)#
+

Remove an existing counter type from the (local) registry.

+
+

Note

+

This doesn’t remove existing counters of this type, it just inhibits defining new counters using this type.

+
+
+ +
+
+counter_status get_counter_type(std::string const &name, counter_info &info, error_code &ec = throws)#
+

Retrieve the counter type for the given counter name from the (local) registry.

+
+ +
+
+hpx::future<hpx::id_type> get_counter_async(std::string name, error_code &ec = throws)#
+

Get the global id of an existing performance counter, if the counter does not exist yet, the function attempts to create the counter based on the given counter name.

+
+ +
+
+hpx::future<hpx::id_type> get_counter_async(counter_info const &info, error_code &ec = throws)#
+

Get the global id of an existing performance counter, if the counter does not exist yet, the function attempts to create the counter based on the given counter info.

+
+ +
+
+void get_counter_infos(counter_info const &info, counter_type &type, std::string &helptext, std::uint32_t &version, error_code &ec = throws)#
+

Retrieve the meta data specific for the given counter instance.

+
+ +
+
+void get_counter_infos(std::string name, counter_type &type, std::string &helptext, std::uint32_t &version, error_code &ec = throws)#
+

Retrieve the meta data specific for the given counter instance.

+
+ +
+
+

Variables

+
+
+constexpr counter_type counter_text = counter_type::text#
+
+ +
+
+constexpr counter_type counter_raw = counter_type::raw#
+
+ +
+
+constexpr counter_type counter_monotonically_increasing = counter_type::monotonically_increasing#
+
+ +
+
+constexpr counter_type counter_average_base = counter_type::average_base#
+
+ +
+
+constexpr counter_type counter_average_count = counter_type::average_count#
+
+ +
+
+constexpr counter_type counter_aggregating = counter_type::aggregating#
+
+ +
+
+constexpr counter_type counter_average_timer = counter_type::average_timer#
+
+ +
+
+constexpr counter_type counter_elapsed_time = counter_type::elapsed_time#
+
+ +
+
+constexpr counter_type counter_raw_values = counter_type::raw_values#
+
+ +
+
+constexpr counter_type counter_histogram = counter_type::histogram#
+
+ +
+
+constexpr counter_status status_valid_data = counter_status::valid_data#
+
+ +
+
+constexpr counter_status status_new_data = counter_status::new_data#
+
+ +
+
+constexpr counter_status status_invalid_data = counter_status::invalid_data#
+
+ +
+
+constexpr counter_status status_already_defined = counter_status::already_defined#
+
+ +
+
+constexpr counter_status status_counter_unknown = counter_status::counter_unknown#
+
+ +
+
+constexpr counter_status status_counter_type_unknown = counter_status::counter_type_unknown#
+
+ +
+
+constexpr counter_status status_generic_error = counter_status::generic_error#
+
+ +
+
+
+struct counter_value#
+
+

Public Functions

+
+
+inline counter_value(std::int64_t value = 0, std::int64_t scaling = 1, bool scale_inverse = false)#
+
+ +
+
+template<typename T>
inline T get_value(error_code &ec = throws) const#
+

Retrieve the ‘real’ value of the counter_value, converted to the requested type T.

+
+ +
+
+

Public Members

+
+
+std::uint64_t time_#
+

The local time when data was collected.

+
+ +
+
+std::uint64_t count_#
+

The invocation counter for the data.

+
+ +
+
+std::int64_t value_#
+

The current counter value.

+
+ +
+
+std::int64_t scaling_#
+

The scaling of the current counter value.

+
+ +
+
+counter_status status_#
+

The status of the counter value.

+
+ +
+
+bool scale_inverse_#
+

If true, value_ needs to be divided by scaling_, otherwise it has to be multiplied.

+
+ +
+
+

Private Functions

+
+
+void serialize(serialization::output_archive &ar, const unsigned int) const#
+
+ +
+
+void serialize(serialization::input_archive &ar, const unsigned int)#
+
+ +
+
+

Friends

+
+
+friend class hpx::serialization::access
+
+ +
+
+ +
+
+struct counter_values_array#
+
+

Public Functions

+
+
+inline counter_values_array(std::int64_t scaling = 1, bool scale_inverse = false)#
+
+ +
+
+inline counter_values_array(std::vector<std::int64_t> &&values, std::int64_t scaling = 1, bool scale_inverse = false)#
+
+ +
+
+inline counter_values_array(std::vector<std::int64_t> const &values, std::int64_t scaling = 1, bool scale_inverse = false)#
+
+ +
+
+template<typename T>
inline T get_value(std::size_t index, error_code &ec = throws) const#
+

Retrieve the ‘real’ value of the counter_value, converted to the requested type T.

+
+ +
+
+

Public Members

+
+
+std::uint64_t time_#
+

The local time when data was collected.

+
+ +
+
+std::uint64_t count_#
+

The invocation counter for the data.

+
+ +
+
+std::vector<std::int64_t> values_#
+

The current counter values.

+
+ +
+
+std::int64_t scaling_#
+

The scaling of the current counter values.

+
+ +
+
+counter_status status_#
+

The status of the counter value.

+
+ +
+
+bool scale_inverse_#
+

If true, value_ needs to be divided by scaling_, otherwise it has to be multiplied.

+
+ +
+
+

Private Functions

+
+
+void serialize(serialization::output_archive &ar, const unsigned int) const#
+
+ +
+
+void serialize(serialization::input_archive &ar, const unsigned int)#
+
+ +
+
+

Friends

+
+
+friend class hpx::serialization::access
+
+ +
+
+ +
+ +
+ +
+
+
hpx/performance_counters/manage_counter_type.hpp#
+

Defined in header hpx/performance_counters/manage_counter_type.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace performance_counters
+
+

Functions

+
+
+counter_status install_counter_type(std::string const &name, hpx::function<std::int64_t(bool)> const &counter_value, std::string const &helptext = "", std::string const &uom = "", counter_type type = counter_type::raw, error_code &ec = throws)#
+

Install a new generic performance counter type in a way, which will uninstall it automatically during shutdown.

+

The function install_counter_type will register a new generic counter type based on the provided function. The counter type will be automatically unregistered during system shutdown. Any consumer querying any instance of this this counter type will cause the provided function to be called and the returned value to be exposed as the counter value.

+

The counter type is registered such that there can be one counter instance per locality. The expected naming scheme for the counter instances is: '/objectname{locality#<*>/total}/countername' where ‘<*>’ is a zero based integer identifying the locality the counter is created on.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

The counter type registry is a locality based service. You will have to register each counter type on every locality where a corresponding performance counter will be created.

+
+
+
Parameters
+
    +
  • name – [in] The global virtual name of the counter type. This name is expected to have the format /objectname/countername.

  • +
  • counter_value – [in] The function to call whenever the counter value is requested by a consumer.

  • +
  • helptext – [in, optional] A longer descriptive text shown to the user to explain the nature of the counters created from this type.

  • +
  • uom – [in] The unit of measure for the new performance counter type.

  • +
  • type – [in] Type for the new performance counter type.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

If successful, this function returns valid_data, otherwise it will either throw an exception or return an error_code from the enum counter_status (also, see note related to parameter ec).

+
+
+
+ +
+
+counter_status install_counter_type(std::string const &name, hpx::function<std::vector<std::int64_t>(bool)> const &counter_value, std::string const &helptext = "", std::string const &uom = "", error_code &ec = throws)#
+

Install a new generic performance counter type returning an array of values in a way, that will uninstall it automatically during shutdown.

+

The function install_counter_type will register a new generic counter type that returns an array of values based on the provided function. The counter type will be automatically unregistered during system shutdown. Any consumer querying any instance of this this counter type will cause the provided function to be called and the returned array value to be exposed as the counter value.

+

The counter type is registered such that there can be one counter instance per locality. The expected naming scheme for the counter instances is: '/objectname{locality#<*>/total}/countername' where ‘<*>’ is a zero based integer identifying the locality the counter is created on.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

The counter type registry is a locality based service. You will have to register each counter type on every locality where a corresponding performance counter will be created.

+
+
+
Parameters
+
    +
  • name – [in] The global virtual name of the counter type. This name is expected to have the format /objectname/countername.

  • +
  • counter_value – [in] The function to call whenever the counter value (array of values) is requested by a consumer.

  • +
  • helptext – [in, optional] A longer descriptive text shown to the user to explain the nature of the counters created from this type.

  • +
  • uom – [in] The unit of measure for the new performance counter type.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

If successful, this function returns valid_data, otherwise it will either throw an exception or return an error_code from the enum counter_status (also, see note related to parameter ec).

+
+
+
+ +
+
+void install_counter_type(std::string const &name, counter_type type, error_code &ec = throws)#
+

Install a new performance counter type in a way, which will uninstall it automatically during shutdown.

+

The function install_counter_type will register a new counter type based on the provided counter_type_info. The counter type will be automatically unregistered during system shutdown.

+
+

Note

+

The counter type registry is a locality based service. You will have to register each counter type on every locality where a corresponding performance counter will be created.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • name – [in] The global virtual name of the counter type. This name is expected to have the format /objectname/countername.

  • +
  • type – [in] The type of the counters of this counter_type.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

If successful, this function returns valid_data, otherwise it will either throw an exception or return an error_code from the enum counter_status (also, see note related to parameter ec).

+
+
+
+ +
+
+counter_status install_counter_type(std::string const &name, counter_type type, std::string const &helptext, std::string const &uom = "", std::uint32_t version = HPX_PERFORMANCE_COUNTER_V1, error_code &ec = throws)#
+

Install a new performance counter type in a way, which will uninstall it automatically during shutdown.

+

The function install_counter_type will register a new counter type based on the provided counter_type_info. The counter type will be automatically unregistered during system shutdown.

+
+

Note

+

The counter type registry is a locality based service. You will have to register each counter type on every locality where a corresponding performance counter will be created.

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+
Parameters
+
    +
  • name – [in] The global virtual name of the counter type. This name is expected to have the format /objectname/countername.

  • +
  • type – [in] The type of the counters of this counter_type.

  • +
  • helptext – [in] A longer descriptive text shown to the user to explain the nature of the counters created from this type.

  • +
  • uom – [in] The unit of measure for the new performance counter type.

  • +
  • version – [in] The version of the counter type. This is currently expected to be set to HPX_PERFORMANCE_COUNTER_V1.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

If successful, this function returns valid_data, otherwise it will either throw an exception or return an error_code from the enum counter_status (also, see note related to parameter ec).

+
+
+
+ +
+
+counter_status install_counter_type(std::string const &name, counter_type type, std::string const &helptext, create_counter_func const &create_counter, discover_counters_func const &discover_counters, std::uint32_t version = HPX_PERFORMANCE_COUNTER_V1, std::string const &uom = "", error_code &ec = throws)#
+

Install a new generic performance counter type in a way, which will uninstall it automatically during shutdown.

+

The function install_counter_type will register a new generic counter type based on the provided counter_type_info. The counter type will be automatically unregistered during system shutdown.

+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

The counter type registry is a locality based service. You will have to register each counter type on every locality where a corresponding performance counter will be created.

+
+
+
Parameters
+
    +
  • name – [in] The global virtual name of the counter type. This name is expected to have the format /objectname/countername.

  • +
  • type – [in] The type of the counters of this counter_type.

  • +
  • helptext – [in] A longer descriptive text shown to the user to explain the nature of the counters created from this type.

  • +
  • version – [in] The version of the counter type. This is currently expected to be set to HPX_PERFORMANCE_COUNTER_V1.

  • +
  • create_counter – [in] The function which will be called to create a new instance of this counter type.

  • +
  • discover_counters – [in] The function will be called to discover counter instances which can be created.

  • +
  • uom – [in] The unit of measure of the counter type (default: “”)

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

If successful, this function returns valid_data, otherwise it will either throw an exception or return an error_code from the enum counter_status (also, see note related to parameter ec).

+
+
+
+ +
+
+ +
+ +
+
+
hpx/performance_counters/registry.hpp#
+

Defined in header hpx/performance_counters/registry.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace performance_counters
+
+
+class registry#
+
+

Public Functions

+
+
+registry() = default#
+
+ +
+
+void clear()#
+

Reset registry by deleting all stored counter types.

+
+ +
+
+counter_status add_counter_type(counter_info const &info, create_counter_func const &create_counter, discover_counters_func const &discover_counters, error_code &ec = throws)#
+

Add a new performance counter type to the (local) registry.

+
+ +
+
+counter_status discover_counter_types(discover_counter_func discover_counter, discover_counters_mode mode, error_code &ec = throws) const#
+

Call the supplied function for all registered counter types.

+
+ +
+
+counter_status discover_counter_type(std::string const &fullname, discover_counter_func discover_counter, discover_counters_mode mode, error_code &ec = throws)#
+

Call the supplied function for the given registered counter type.

+
+ +
+
+inline counter_status discover_counter_type(counter_info const &info, discover_counter_func const &f, discover_counters_mode mode, error_code &ec = throws)#
+
+ +
+
+counter_status get_counter_create_function(counter_info const &info, create_counter_func &create_counter, error_code &ec = throws) const#
+

Retrieve the counter creation function which is associated with a given counter type.

+
+ +
+
+counter_status get_counter_discovery_function(counter_info const &info, discover_counters_func &func, error_code &ec) const#
+

Retrieve the counter discovery function which is associated with a given counter type.

+
+ +
+
+counter_status remove_counter_type(counter_info const &info, error_code &ec = throws)#
+

Remove an existing counter type from the (local) registry.

+
+

Note

+

This doesn’t remove existing counters of this type, it just inhibits defining new counters using this type.

+
+
+ +
+
+counter_status create_raw_counter_value(counter_info const &info, std::int64_t *countervalue, naming::gid_type &id, error_code &ec = throws)#
+

Create a new performance counter instance of type raw_counter based on given counter value.

+
+ +
+
+counter_status create_raw_counter(counter_info const &info, hpx::function<std::int64_t()> const &f, naming::gid_type &id, error_code &ec = throws)#
+

Create a new performance counter instance of type raw_counter based on given function returning the counter value.

+
+ +
+
+counter_status create_raw_counter(counter_info const &info, hpx::function<std::int64_t(bool)> const &f, naming::gid_type &id, error_code &ec = throws)#
+

Create a new performance counter instance of type raw_counter based on given function returning the counter value.

+
+ +
+
+counter_status create_raw_counter(counter_info const &info, hpx::function<std::vector<std::int64_t>()> const &f, naming::gid_type &id, error_code &ec = throws)#
+

Create a new performance counter instance of type raw_counter based on given function returning the counter value.

+
+ +
+
+counter_status create_raw_counter(counter_info const &info, hpx::function<std::vector<std::int64_t>(bool)> const &f, naming::gid_type &id, error_code &ec = throws)#
+

Create a new performance counter instance of type raw_counter based on given function returning the counter value.

+
+ +
+
+counter_status create_counter(counter_info const &info, naming::gid_type &id, error_code &ec = throws)#
+

Create a new performance counter instance based on given counter info.

+
+ +
+
+counter_status create_statistics_counter(counter_info const &info, std::string const &base_counter_name, std::vector<std::size_t> const &parameters, naming::gid_type &id, error_code &ec = throws)#
+

Create a new statistics performance counter instance based on given base counter name and given base time interval (milliseconds).

+
+ +
+
+counter_status create_arithmetics_counter(counter_info const &info, std::vector<std::string> const &base_counter_names, naming::gid_type &id, error_code &ec = throws)#
+

Create a new arithmetics performance counter instance based on given base counter names.

+
+ +
+
+counter_status create_arithmetics_counter_extended(counter_info const &info, std::vector<std::string> const &base_counter_names, naming::gid_type &id, error_code &ec = throws)#
+

Create a new extended arithmetics performance counter instance based on given base counter names.

+
+ +
+
+counter_status add_counter(hpx::id_type const &id, counter_info const &info, error_code &ec = throws)#
+

Add an existing performance counter instance to the registry.

+
+ +
+
+counter_status remove_counter(counter_info const &info, hpx::id_type const &id, error_code &ec = throws)#
+

remove the existing performance counter from the registry

+
+ +
+
+counter_status get_counter_type(std::string const &name, counter_info &info, error_code &ec = throws)#
+

Retrieve counter type information for given counter name.

+
+ +
+
+

Public Static Functions

+
+
+static registry &instance()#
+
+ +
+
+

Protected Functions

+
+
+counter_type_map_type::iterator locate_counter_type(std::string const &type_name)#
+
+ +
+
+counter_type_map_type::const_iterator locate_counter_type(std::string const &type_name) const#
+
+ +
+
+

Private Types

+
+
+using counter_type_map_type = std::map<std::string, counter_data>#
+
+ +
+
+

Private Members

+
+
+counter_type_map_type countertypes_#
+
+ +
+
+
+struct counter_data#
+
+

Public Functions

+
+
+inline counter_data(counter_info const &info, create_counter_func const &create_counter, discover_counters_func const &discover_counters)#
+
+ +
+
+

Public Members

+
+
+counter_info info_#
+
+ +
+
+create_counter_func create_counter_#
+
+ +
+
+discover_counters_func discover_counters_#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
+
+
plugin_factories#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/plugin_factories/binary_filter_factory.hpp#
+

Defined in header hpx/plugin_factories/binary_filter_factory.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_BINARY_FILTER_FACTORY(BinaryFilter, pluginname)#
+

This macro is used create and to register a minimal component factory with Hpx.Plugin.

+
+ +
+
+
+namespace hpx
+
+
+namespace plugins
+
+
+template<typename BinaryFilter>
struct binary_filter_factory : public binary_filter_factory_base#
+
+#include <binary_filter_factory.hpp>
+

The message_handler_factory provides a minimal implementation of a message handler’s factory. If no additional functionality is required this type can be used to implement the full set of minimally required functions to be exposed by a message handler’s factory instance.

+
+
Template Parameters
+

BinaryFilter – The message handler type this factory should be responsible for.

+
+
+
+

Public Functions

+
+
+inline binary_filter_factory(util::section const *global, util::section const *local, bool isenabled)#
+

Construct a new factory instance.

+
+

Note

+

The contents of both sections has to be cloned in order to save the configuration setting for later use.

+
+
+
Parameters
+
    +
  • global – [in] The pointer to a hpx::util::section instance referencing the settings read from the [settings] section of the global configuration file (hpx.ini) This pointer may be nullptr if no such section has been found.

  • +
  • local – [in] The pointer to a hpx::util::section instance referencing the settings read from the section describing this component type: [hpx.components.<name>], where <name> is the instance name of the component as given in the configuration files.

  • +
  • isenabled

  • +
+
+
+
+ +
+
+~binary_filter_factory() override = default#
+
+ +
+
+inline serialization::binary_filter *create(bool compress, serialization::binary_filter *next_filter = nullptr) override#
+

Create a new instance of a message handler

+

return Returns the newly created instance of the message handler supported by this factory

+
+ +
+
+

Protected Attributes

+
+
+util::section global_settings_#
+
+ +
+
+util::section local_settings_#
+
+ +
+
+bool isenabled_#
+
+ +
+
+ +
+ +
+ +
+
+
hpx/plugin_factories/message_handler_factory.hpp#
+

Defined in header hpx/plugin_factories/message_handler_factory.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/plugin_factories/parcelport_factory.hpp#
+

Defined in header hpx/plugin_factories/parcelport_factory.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/plugin_factories/plugin_registry.hpp#
+

Defined in header hpx/plugin_factories/plugin_registry.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_PLUGIN_REGISTRY(...)#
+

This macro is used create and to register a minimal plugin registry with Hpx.Plugin.

+
+ +
+
+HPX_REGISTER_PLUGIN_REGISTRY_(...)#
+
+ +
+
+HPX_REGISTER_PLUGIN_REGISTRY_2(PluginType, pluginname)#
+
+ +
+
+HPX_REGISTER_PLUGIN_REGISTRY_4(PluginType, pluginname, pluginsection, pluginsuffix)#
+
+ +
+
+HPX_REGISTER_PLUGIN_REGISTRY_5(PluginType, pluginname, pluginstring, pluginsection, pluginsuffix)#
+
+ +
+
+
+namespace hpx
+
+
+namespace plugins
+
+
+template<typename Plugin, char const *const Name, char const *const Section, char const *const Suffix>
struct plugin_registry : public plugin_registry_base#
+
+#include <plugin_registry.hpp>
+

The plugin_registry provides a minimal implementation of a plugin’s registry. If no additional functionality is required this type can be used to implement the full set of minimally required functions to be exposed by a plugin’s registry instance.

+
+
Template Parameters
+

Plugin – The plugin type this registry should be responsible for.

+
+
+
+

Public Functions

+
+
+inline bool get_plugin_info(std::vector<std::string> &fillini) override#
+

Return the ini-information for all contained components.

+
+
Parameters
+

fillini – [in] The module is expected to fill this vector with the ini-information (one line per vector element) for all components implemented in this module.

+
+
Returns
+

Returns true if the parameter fillini has been successfully initialized with the registry data of all implemented in this module.

+
+
+
+ +
+
+ +
+ +
+ +
+
+
+
+
runtime_components#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
HPX_REGISTER_COMPONENT#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_COMPONENT(type, name, mode)#
+

Define a component factory for a component type.

+

This macro is used create and to register a minimal component factory for a component type which allows it to be remotely created using the hpx::new_<> function.

+

This macro can be invoked with one, two or three arguments

+
+
Parameters
+
    +
  • type – The type parameter is a (fully decorated) type of the component type for which a factory should be defined.

  • +
  • name – The name parameter specifies the name to use to register the factory. This should uniquely (system-wide) identify the component type. The name parameter must conform to the C++ identifier rules (without any namespace). If this parameter is not given, the first parameter is used.

  • +
  • mode – The mode parameter has to be one of the defined enumeration values of the enumeration hpx::components::factory_state. The default for this parameter is hpx::components::factory_state::enabled.

  • +
+
+
+
+ +
+
+
+
hpx/runtime_components/component_registry.hpp#
+

Defined in header hpx/runtime_components/component_registry.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_MINIMAL_COMPONENT_REGISTRY(...)#
+

This macro is used create and to register a minimal component registry with Hpx.Plugin.

+
+ +
+
+HPX_REGISTER_MINIMAL_COMPONENT_REGISTRY_(...)#
+
+ +
+
+HPX_REGISTER_MINIMAL_COMPONENT_REGISTRY_2(ComponentType, componentname)#
+
+ +
+
+HPX_REGISTER_MINIMAL_COMPONENT_REGISTRY_3(ComponentType, componentname, state)#
+
+ +
+
+HPX_REGISTER_MINIMAL_COMPONENT_REGISTRY_DYNAMIC(...)#
+
+ +
+
+HPX_REGISTER_MINIMAL_COMPONENT_REGISTRY_DYNAMIC_(...)#
+
+ +
+
+HPX_REGISTER_MINIMAL_COMPONENT_REGISTRY_DYNAMIC_2(ComponentType, componentname)#
+
+ +
+
+HPX_REGISTER_MINIMAL_COMPONENT_REGISTRY_DYNAMIC_3(ComponentType, componentname, state)#
+
+ +
+
+
+namespace hpx
+
+
+namespace components
+
+
+template<typename Component, factory_state state>
struct component_registry : public component_registry_base#
+
+#include <component_registry.hpp>
+

The component_registry provides a minimal implementation of a component’s registry. If no additional functionality is required this type can be used to implement the full set of minimally required functions to be exposed by a component’s registry instance.

+
+
Template Parameters
+

Component – The component type this registry should be responsible for.

+
+
+
+

Public Functions

+
+
+inline bool get_component_info(std::vector<std::string> &fillini, std::string const &filepath, bool is_static = false) override#
+

Return the ini-information for all contained components.

+
+
Parameters
+
    +
  • fillini – [in] The module is expected to fill this vector with the ini-information (one line per vector element) for all components implemented in this module.

  • +
  • filepath

  • +
  • is_static

  • +
+
+
Returns
+

Returns true if the parameter fillini has been successfully initialized with the registry data of all implemented in this module.

+
+
+
+ +
+
+inline void register_component_type() override#
+

Return the unique identifier of the component type this factory is responsible for.

+
+
Parameters
+
    +
  • locality – [in] The id of the locality this factory is responsible for.

  • +
  • agas_client – [in] The AGAS client to use for component id registration (if needed).

  • +
+
+
Returns
+

Returns the unique identifier of the component type this factory instance is responsible for. This function throws on any error.

+
+
+
+ +
+
+ +
+ +
+ +
+
+
hpx/runtime_components/components_fwd.hpp#
+

Defined in header hpx/runtime_components/components_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+components::server::runtime_support *get_runtime_support_ptr()#
+
+ +
+
+
+namespace components
+
+
+template<typename Component>
struct component_factory#
+
+ +
+
+namespace server#
+
+ +
+
+namespace stubs#
+
+ +
+ +
+ +
+
+namespace components#
+
+ +
+
+
hpx/runtime_components/derived_component_factory.hpp#
+

Defined in header hpx/runtime_components/derived_component_factory.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+

Defines

+
+
+HPX_REGISTER_DERIVED_COMPONENT_FACTORY(...)#
+

This macro is used create and to register a minimal component factory with Hpx.Plugin. This macro may be used if the registered component factory is the only factory to be exposed from a particular module. If more than one factory needs to be exposed the HPX_REGISTER_COMPONENT_FACTORY and HPX_REGISTER_COMPONENT_MODULE macros should be used instead.

+
+ +
+
+HPX_REGISTER_DERIVED_COMPONENT_FACTORY_(...)#
+
+ +
+
+HPX_REGISTER_DERIVED_COMPONENT_FACTORY_3(ComponentType, componentname, basecomponentname)#
+
+ +
+
+HPX_REGISTER_DERIVED_COMPONENT_FACTORY_4(ComponentType, componentname, basecomponentname, state)#
+
+ +
+
+HPX_REGISTER_DERIVED_COMPONENT_FACTORY_DYNAMIC(...)#
+
+ +
+
+HPX_REGISTER_DERIVED_COMPONENT_FACTORY_DYNAMIC_(...)#
+
+ +
+
+HPX_REGISTER_DERIVED_COMPONENT_FACTORY_DYNAMIC_3(ComponentType, componentname, basecomponentname)#
+
+ +
+
+HPX_REGISTER_DERIVED_COMPONENT_FACTORY_DYNAMIC_4(ComponentType, componentname, basecomponentname, state)#
+
+ +
+
+
+
hpx::new_#
+

Defined in header hpx/components.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+template<typename Component, typename ...Ts>
auto new_(id_type const &locality, Ts&&... vs)#
+

Create one or more new instances of the given Component type on the specified locality.

+

This function creates one or more new instances of the given Component type on the specified locality and returns a future object for the global address which can be used to reference the new component instance.

+
+

Note

+

This function requires to specify an explicit template argument which will define what type of component(s) to create, for instance:

hpx::future<hpx::id_type> f =
+   hpx::new_<some_component>(hpx::find_here(), ...);
+hpx::id_type id = f.get();
+
+
+

+
+
+
Parameters
+
    +
  • locality – [in] The global address of the locality where the new instance should be created on.

  • +
  • vs – [in] Any number of arbitrary arguments (passed by value, by const reference or by rvalue reference) which will be forwarded to the constructor of the created component instance.

  • +
+
+
Returns
+

The function returns different types depending on its use:

    +
  • If the explicit template argument Component represents a component type (traits::is_component<Component>::value evaluates to true), the function will return an hpx::future object instance which can be used to retrieve the global address of the newly created component.

  • +
  • If the explicit template argument Component represents a client side object (traits::is_client<Component>::value evaluates to true), the function will return a new instance of that type which can be used to refer to the newly created component instance.

  • +
+

+
+
+
+ +
+
+template<typename Component, typename ...Ts>
auto local_new(Ts&&... vs)#
+

Create one new instance of the given Component type on the current locality.

+

This function creates one new instance of the given Component type on the current locality and returns a future object for the global address which can be used to reference the new component instance.

+
+

Note

+

This function requires to specify an explicit template argument which will define what type of component(s) to create, for instance:

hpx::future<hpx::id_type> f =
+   hpx::local_new<some_component>(...);
+hpx::id_type id = f.get();
+
+
+

+
+
+

Note

+

The difference of this function to hpx::new_ is that it can be used in cases where the supplied arguments are non-copyable and non-movable. All operations are guaranteed to be local only.

+
+
+
Parameters
+

vs – [in] Any number of arbitrary arguments (passed by value, by const reference or by rvalue reference) which will be forwarded to the constructor of the created component instance.

+
+
Returns
+

The function returns different types depending on its use:

    +
  • If the explicit template argument Component represents a component type (traits::is_component<Component>::value evaluates to true), the function will return an hpx::future object instance which can be used to retrieve the global address of the newly created component. If the first argument is hpx::launch::sync the function will directly return an hpx::id_type.

  • +
  • If the explicit template argument Component represents a client side object (traits::is_client<Component>::value evaluates to true), the function will return a new instance of that type which can be used to refer to the newly created component instance.

  • +
+

+
+
+
+ +
+
+template<typename Component, typename ...Ts>
auto new_(id_type const &locality, std::size_t count, Ts&&... vs)#
+

Create multiple new instances of the given Component type on the specified locality.

+

This function creates multiple new instances of the given Component type on the specified locality and returns a future object for the global address which can be used to reference the new component instance.

+
+

Note

+

This function requires to specify an explicit template argument which will define what type of component(s) to create, for instance:

hpx::future<std::vector<hpx::id_type> > f =
+   hpx::new_<some_component[]>(hpx::find_here(), 10, ...);
+hpx::id_type id = f.get();
+
+
+

+
+
+
Parameters
+
    +
  • locality – [in] The global address of the locality where the new instance should be created on.

  • +
  • count – [in] The number of component instances to create

  • +
  • vs – [in] Any number of arbitrary arguments (passed by value, by const reference or by rvalue reference) which will be forwarded to the constructor of the created component instance.

  • +
+
+
Returns
+

The function returns different types depending on its use:

    +
  • If the explicit template argument Component represents an array of a component type (i.e. Component[], where traits::is_component<Component>::value evaluates to true), the function will return an hpx::future object instance which holds a std::vector<hpx::id_type>, where each of the items in this vector is a global address of one of the newly created components.

  • +
  • If the explicit template argument Component represents an array of a client side object type (i.e. Component[], where traits::is_client<Component>::value evaluates to true), the function will return an hpx::future object instance which holds a std::vector<hpx::id_type>, where each of the items in this vector is a client side instance of the given type, each representing one of the newly created components.

  • +
+

+
+
+
+ +
+
+template<typename Component, typename DistPolicy, typename ...Ts>
auto new_(DistPolicy const &policy, Ts&&... vs)#
+

Create one or more new instances of the given Component type based on the given distribution policy.

+

This function creates one or more new instances of the given Component type on the localities defined by the given distribution policy and returns a future object for global address which can be used to reference the new component instance(s).

+
+

Note

+

This function requires to specify an explicit template argument which will define what type of component(s) to create, for instance:

hpx::future<hpx::id_type> f =
+   hpx::new_<some_component>(hpx::default_layout, ...);
+hpx::id_type id = f.get();
+
+
+

+
+
+
Parameters
+
    +
  • policy – [in] The distribution policy used to decide where to place the newly created.

  • +
  • vs – [in] Any number of arbitrary arguments (passed by value, by const reference or by rvalue reference) which will be forwarded to the constructor of the created component instance.

  • +
+
+
Returns
+

The function returns different types depending on its use:

    +
  • If the explicit template argument Component represents a component type (traits::is_component<Component>::value evaluates to true), the function will return an hpx::future object instance which can be used to retrieve the global address of the newly created component.

  • +
  • If the explicit template argument Component represents a client side object (traits::is_client<Component>::value evaluates to true), the function will return a new instance of that type which can be used to refer to the newly created component instance.

  • +
+

+
+
+
+ +
+
+template<typename Component, typename DistPolicy, typename ...Ts>
auto new_(DistPolicy const &policy, std::size_t count, Ts&&... vs)#
+

Create multiple new instances of the given Component type on the localities as defined by the given distribution policy.

+

This function creates multiple new instances of the given Component type on the localities defined by the given distribution policy and returns a future object for the global address which can be used to reference the new component instance.

+
+

Note

+

This function requires to specify an explicit template argument which will define what type of component(s) to create, for instance:

hpx::future<std::vector<hpx::id_type> > f =
+   hpx::new_<some_component[]>(hpx::default_layout, 10, ...);
+hpx::id_type id = f.get();
+
+
+

+
+
+
Parameters
+
    +
  • policy – [in] The distribution policy used to decide where to place the newly created.

  • +
  • count – [in] The number of component instances to create

  • +
  • vs – [in] Any number of arbitrary arguments (passed by value, by const reference or by rvalue reference) which will be forwarded to the constructor of the created component instance.

  • +
+
+
Returns
+

The function returns different types depending on its use:

    +
  • If the explicit template argument Component represents an array of a component type (i.e. Component[], where traits::is_component<Component>::value evaluates to true), the function will return an hpx::future object instance which holds a std::vector<hpx::id_type>, where each of the items in this vector is a global address of one of the newly created components.

  • +
  • If the explicit template argument Component represents an array of a client side object type (i.e. Component[], where traits::is_client<Component>::value evaluates to true), the function will return an hpx::future object instance which holds a std::vector<hpx::id_type>, where each of the items in this vector is a client side instance of the given type, each representing one of the newly created components.

  • +
+

+
+
+
+ +
+
+ +
+
+
+
+
runtime_distributed#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/runtime_distributed.hpp#
+

Defined in header hpx/runtime_distributed.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+class runtime_distributed : public runtime#
+
+#include <runtime_distributed.hpp>
+

The runtime class encapsulates the HPX runtime system in a simple to use way. It makes sure all required parts of the HPX runtime system are properly initialized.

+
+

Public Functions

+
+
+explicit runtime_distributed(util::runtime_configuration &rtcfg, int (*pre_main)(runtime_mode) = nullptr, void (*post_main)() = nullptr)#
+

Construct a new HPX runtime instance

+
+
Parameters
+

locality_mode – [in] This is the mode the given runtime instance should be executed in.

+
+
+
+ +
+
+~runtime_distributed()#
+

The destructor makes sure all HPX runtime services are properly shut down before exiting.

+
+ +
+
+int start(hpx::function<hpx_main_function_type> const &func, bool blocking = false) override#
+

Start the runtime system.

+
+
Parameters
+
    +
  • func – [in] This is the main function of an HPX application. It will be scheduled for execution by the thread manager as soon as the runtime has been initialized. This function is expected to expose an interface as defined by the typedef hpx_main_function_type.

  • +
  • blocking – [in] This allows to control whether this call blocks until the runtime system has been stopped. If this parameter is true the function runtime::start will call runtime::wait internally.

  • +
+
+
Returns
+

If a blocking is a true, this function will return the value as returned as the result of the invocation of the function object given by the parameter func. Otherwise it will return zero.

+
+
+
+ +
+
+int start(bool blocking = false) override#
+

Start the runtime system.

+
+
Parameters
+

blocking – [in] This allows to control whether this call blocks until the runtime system has been stopped. If this parameter is true the function runtime::start will call runtime::wait internally .

+
+
Returns
+

If a blocking is a true, this function will return the value as returned as the result of the invocation of the function object given by the parameter func. Otherwise it will return zero.

+
+
+
+ +
+
+int wait() override#
+

Wait for the shutdown action to be executed.

+
+
Returns
+

This function will return the value as returned as the result of the invocation of the function object given by the parameter func.

+
+
+
+ +
+
+void stop(bool blocking = true) override#
+

Initiate termination of the runtime system.

+
+
Parameters
+

blocking – [in] This allows to control whether this call blocks until the runtime system has been fully stopped. If this parameter is false then this call will initiate the stop action but will return immediately. Use a second call to stop with this parameter set to true to wait for all internal work to be completed.

+
+
+
+ +
+
+int finalize(double shutdown_timeout) override#
+
+ +
+
+void stop_helper(bool blocking, std::condition_variable &cond, std::mutex &mtx)#
+

Stop the runtime system, wait for termination.

+
+
Parameters
+

blocking – [in] This allows to control whether this call blocks until the runtime system has been fully stopped. If this parameter is false then this call will initiate the stop action but will return immediately. Use a second call to stop with this parameter set to true to wait for all internal work to be completed.

+
+
+
+ +
+
+int suspend() override#
+

Suspend the runtime system.

+
+ +
+
+int resume() override#
+

Resume the runtime system.

+
+ +
+
+bool report_error(std::size_t num_thread, std::exception_ptr const &e, bool terminate_all = true) override#
+

Report a non-recoverable error to the runtime system.

+
+
Parameters
+
    +
  • num_thread – [in] The number of the operating system thread the error has been detected in.

  • +
  • e – [in] This is an instance encapsulating an exception which lead to this function call.

  • +
  • terminate_all – [in] Kill all localities attached to the currently running application (default: true)

  • +
+
+
+
+ +
+
+bool report_error(std::exception_ptr const &e, bool terminate_all = true) override#
+

Report a non-recoverable error to the runtime system.

+
+

Note

+

This function will retrieve the number of the current shepherd thread and forward to the report_error function above.

+
+
+
Parameters
+
    +
  • e – [in] This is an instance encapsulating an exception which lead to this function call.

  • +
  • terminate_all – [in] Kill all localities attached to the currently running application (default: true)

  • +
+
+
+
+ +
+
+int run(hpx::function<hpx_main_function_type> const &func) override#
+

Run the HPX runtime system, use the given function for the main thread and block waiting for all threads to finish.

+
+

Note

+

The parameter func is optional. If no function is supplied, the runtime system will simply wait for the shutdown action without explicitly executing any main thread.

+
+
+
Parameters
+

func – [in] This is the main function of an HPX application. It will be scheduled for execution by the thread manager as soon as the runtime has been initialized. This function is expected to expose an interface as defined by the typedef hpx_main_function_type. This parameter is optional and defaults to none main thread function, in which case all threads have to be scheduled explicitly.

+
+
Returns
+

This function will return the value as returned as the result of the invocation of the function object given by the parameter func.

+
+
+
+ +
+
+int run() override#
+

Run the HPX runtime system, initially use the given number of (OS) threads in the thread-manager and block waiting for all threads to finish.

+
+
Returns
+

This function will always return 0 (zero).

+
+
+
+ +
+
+bool is_networking_enabled() override#
+
+ +
+
+template<typename F>
inline components::server::console_error_dispatcher::sink_type set_error_sink(F &&sink)#
+
+ +
+
+performance_counters::registry &get_counter_registry()#
+

Allow access to the registry counter registry instance used by the HPX runtime.

+
+ +
+
+performance_counters::registry const &get_counter_registry() const#
+

Allow access to the registry counter registry instance used by the HPX runtime.

+
+ +
+
+void register_query_counters(std::shared_ptr<util::query_counters> const &active_counters)#
+
+ +
+
+void start_active_counters(error_code &ec = throws) const#
+
+ +
+
+void stop_active_counters(error_code &ec = throws) const#
+
+ +
+
+void reset_active_counters(error_code &ec = throws) const#
+
+ +
+
+void reinit_active_counters(bool reset = true, error_code &ec = throws) const#
+
+ +
+
+void evaluate_active_counters(bool reset = false, char const *description = nullptr, error_code &ec = throws) const#
+
+ +
+
+void stop_evaluating_counters(bool terminate = false) const#
+
+ +
+
+naming::resolver_client &get_agas_client()#
+

Allow access to the AGAS client instance used by the HPX runtime.

+
+ +
+
+hpx::threads::threadmanager &get_thread_manager() override#
+

Allow access to the thread manager instance used by the HPX runtime.

+
+ +
+
+applier::applier &get_applier()#
+

Allow access to the applier instance used by the HPX runtime.

+
+ +
+
+std::string here() const override#
+

Returns a string of the locality endpoints (usable in debug output)

+
+ +
+
+naming::address_type get_runtime_support_lva() const#
+
+ +
+
+naming::gid_type get_next_id(std::size_t count = 1)#
+
+ +
+
+void init_id_pool_range()#
+
+ +
+
+util::unique_id_ranges &get_id_pool()#
+
+ +
+
+void initialize_agas()#
+

Initialize AGAS operation.

+
+ +
+
+void add_pre_startup_function(startup_function_type f) override#
+

Add a function to be executed inside a HPX thread before hpx_main but guaranteed to be executed before any startup function registered with add_startup_function.

+
+

Note

+

The difference to a startup function is that all pre-startup functions will be (system-wide) executed before any startup function.

+
+
+
Parameters
+

f – The function ‘f’ will be called from inside a HPX thread before hpx_main is executed. This is very useful to setup the runtime environment of the application (install performance counters, etc.)

+
+
+
+ +
+
+void add_startup_function(startup_function_type f) override#
+

Add a function to be executed inside a HPX thread before hpx_main

+
+
Parameters
+

f – The function ‘f’ will be called from inside a HPX thread before hpx_main is executed. This is very useful to setup the runtime environment of the application (install performance counters, etc.)

+
+
+
+ +
+
+void add_pre_shutdown_function(shutdown_function_type f) override#
+

Add a function to be executed inside a HPX thread during hpx::finalize, but guaranteed before any of the shutdown functions is executed.

+
+

Note

+

The difference to a shutdown function is that all pre-shutdown functions will be (system-wide) executed before any shutdown function.

+
+
+
Parameters
+

f – The function ‘f’ will be called from inside a HPX thread while hpx::finalize is executed. This is very useful to tear down the runtime environment of the application (uninstall performance counters, etc.)

+
+
+
+ +
+
+void add_shutdown_function(shutdown_function_type f) override#
+

Add a function to be executed inside a HPX thread during hpx::finalize

+
+
Parameters
+

f – The function ‘f’ will be called from inside a HPX thread while hpx::finalize is executed. This is very useful to tear down the runtime environment of the application (uninstall performance counters, etc.)

+
+
+
+ +
+
+hpx::util::io_service_pool *get_thread_pool(char const *name) override#
+

Access one of the internal thread pools (io_service instances) HPX is using to perform specific tasks. The three possible values for the argument name are “main_pool”, “io_pool”, “parcel_pool”, and “timer_pool”. For any other argument value the function will return zero.

+
+ +
+
+bool register_thread(char const *name, std::size_t num = 0, bool service_thread = true, error_code &ec = throws) override#
+

Register an external OS-thread with HPX.

+
+ +
+
+notification_policy_type get_notification_policy(char const *prefix, runtime_local::os_thread_type type) override#
+

Generate a new notification policy instance for the given thread name prefix

+
+ +
+
+std::uint32_t get_locality_id(error_code &ec) const override#
+
+ +
+
+std::size_t get_num_worker_threads() const override#
+
+ +
+
+std::uint32_t get_num_localities(hpx::launch::sync_policy, error_code &ec) const override#
+
+ +
+
+std::uint32_t get_initial_num_localities() const override#
+
+ +
+
+hpx::future<std::uint32_t> get_num_localities() const override#
+
+ +
+
+std::string get_locality_name() const override#
+
+ +
+
+std::uint32_t get_num_localities(hpx::launch::sync_policy, components::component_type type, error_code &ec) const#
+
+ +
+
+hpx::future<std::uint32_t> get_num_localities(components::component_type type) const#
+
+ +
+
+std::uint32_t assign_cores(std::string const &locality_basename, std::uint32_t num_threads) override#
+
+ +
+
+std::uint32_t assign_cores() override#
+
+ +
+
+

Public Static Functions

+
+
+static void register_counter_types()#
+

Install all performance counters related to this runtime instance.

+
+ +
+
+

Private Types

+
+
+using used_cores_map_type = std::map<std::string, std::uint32_t>#
+
+ +
+
+

Private Functions

+
+
+threads::thread_result_type run_helper(hpx::function<runtime::hpx_main_function_type> const &func, int &result)#
+
+ +
+
+void init_global_data()#
+
+ +
+
+void deinit_global_data()#
+
+ +
+
+void wait_helper(std::mutex &mtx, std::condition_variable &cond, bool &running)#
+
+ +
+
+void init_tss_helper(char const *context, runtime_local::os_thread_type type, std::size_t local_thread_num, std::size_t global_thread_num, char const *pool_name, char const *postfix, bool service_thread)#
+
+ +
+
+void deinit_tss_helper(char const *context, std::size_t num) const#
+
+ +
+
+void init_tss_ex(std::string const &locality, char const *context, runtime_local::os_thread_type type, std::size_t local_thread_num, std::size_t global_thread_num, char const *pool_name, char const *postfix, bool service_thread, error_code &ec) const#
+
+ +
+
+

Private Members

+
+
+runtime_mode mode_#
+
+ +
+
+util::unique_id_ranges id_pool_#
+
+ +
+
+naming::resolver_client agas_client_#
+
+ +
+
+applier::applier applier_#
+
+ +
+
+used_cores_map_type used_cores_map_#
+
+ +
+
+std::unique_ptr<components::server::runtime_support> runtime_support_#
+
+ +
+
+std::shared_ptr<util::query_counters> active_counters_#
+
+ +
+
+int (*pre_main_)(runtime_mode)#
+
+ +
+
+void (*post_main_)()#
+
+ +
+
+

Private Static Functions

+
+
+static void default_errorsink(std::string const&)#
+
+ +
+
+ +
+ +
+
+
hpx/runtime_distributed/applier.hpp#
+

Defined in header hpx/runtime_distributed/applier.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace applier#
+
+
+class applier#
+
+#include <applier.hpp>
+

The applier class is used to decide whether a particular action has to be issued on a local or a remote resource. If the target component is local a new thread will be created, if the target is remote a parcel will be sent.

+
+

Public Functions

+
+
+HPX_NON_COPYABLE(applier)#
+
+ +
+
+applier()#
+
+ +
+
+void init(threads::threadmanager &tm)#
+
+ +
+
+~applier() = default#
+
+ +
+
+void initialize(std::uint64_t rts)#
+
+ +
+
+threads::threadmanager &get_thread_manager()#
+

Access the thread-manager instance associated with this applier.

+

This function returns a reference to the thread manager this applier instance has been created with.

+
+ +
+
+naming::gid_type const &get_raw_locality(error_code &ec = throws) const#
+

Allow access to the locality of the locality this applier instance is associated with.

+

This function returns a reference to the locality this applier instance is associated with.

+
+ +
+
+std::uint32_t get_locality_id(error_code &ec = throws) const#
+

Allow access to the id of the locality this applier instance is associated with.

+

This function returns a reference to the id of the locality this applier instance is associated with.

+
+ +
+
+bool get_raw_remote_localities(std::vector<naming::gid_type> &locality_ids, components::component_type type = to_int(hpx::components::component_enum_type::invalid), error_code &ec = throws) const#
+

Return list of localities of all remote localities registered with the AGAS service for a specific component type.

+

This function returns a list of all remote localities (all localities known to AGAS except the local one) supporting the given component type.

+
+
Parameters
+
    +
  • locality_ids – [out] The reference to a vector of id_types filled by the function.

  • +
  • type – [in] The type of the component which needs to exist on the returned localities.

  • +
+
+
Returns
+

The function returns true if there is at least one remote locality known to the AGAS service (!prefixes.empty()).

+
+
+
+ +
+
+bool get_remote_localities(std::vector<hpx::id_type> &locality_ids, components::component_type type = to_int(hpx::components::component_enum_type::invalid), error_code &ec = throws) const#
+
+ +
+
+bool get_raw_localities(std::vector<naming::gid_type> &locality_ids, components::component_type type = to_int(hpx::components::component_enum_type::invalid)) const#
+

Return list of locality_ids of all localities registered with the AGAS service for a specific component type.

+

This function returns a list of all localities (all localities known to AGAS except the local one) supporting the given component type.

+
+
Parameters
+
    +
  • locality_ids – [out] The reference to a vector of id_types filled by the function.

  • +
  • type – [in] The type of the component which needs to exist on the returned localities.

  • +
+
+
Returns
+

The function returns true if there is at least one remote locality known to the AGAS service (!prefixes.empty()).

+
+
+
+ +
+
+bool get_localities(std::vector<hpx::id_type> &locality_ids, error_code &ec = throws) const#
+
+ +
+
+bool get_localities(std::vector<hpx::id_type> &locality_ids, components::component_type type, error_code &ec = throws) const#
+
+ +
+
+inline naming::gid_type const &get_runtime_support_raw_gid() const#
+

By convention the runtime_support has a gid identical to the prefix of the locality the runtime_support is responsible for

+
+ +
+
+inline hpx::id_type const &get_runtime_support_gid() const#
+

By convention the runtime_support has a gid identical to the prefix of the locality the runtime_support is responsible for

+
+ +
+
+

Private Members

+
+
+threads::threadmanager *thread_manager_#
+
+ +
+
+hpx::id_type runtime_support_id_#
+
+ +
+
+ +
+ +
+ +
+
+
hpx/runtime_distributed/applier_fwd.hpp#
+

Defined in header hpx/runtime_distributed/applier_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace applier
+
+

Functions

+
+
+applier &get_applier()#
+

The function get_applier returns a reference to the (thread specific) applier instance.

+
+ +
+
+applier *get_applier_ptr()#
+

The function get_applier returns a pointer to the (thread specific) applier instance. The returned pointer is NULL if the current thread is not known to HPX or if the runtime system is not active.

+
+ +
+
+ +
+ +
+
+namespace applier#
+

The namespace applier contains all definitions needed for the class hpx::applier::applier and its related functionality. This namespace is part of the HPX core module.

+
+ +
+
+
hpx/runtime_distributed/copy_component.hpp#
+

Defined in header hpx/runtime_distributed/copy_component.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+

Functions

+
+
+template<typename Component>
future<hpx::id_type> copy(hpx::id_type const &to_copy)#
+

Copy given component to the specified target locality.

+

The function copy<Component> will create a copy of the component referenced by to_copy on the locality specified with target_locality. It returns a future referring to the newly created component instance.

+
+

Note

+

The new component instance is created on the locality of the component instance which is to be copied.

+
+
+
Parameters
+

to_copy – [in] The global id of the component to copy

+
+
Template Parameters
+

The – only template argument specifies the component type to create.

+
+
Returns
+

A future representing the global id of the newly (copied) component instance.

+
+
+
+ +
+
+template<typename Component>
future<hpx::id_type> copy(hpx::id_type const &to_copy, hpx::id_type const &target_locality)#
+

Copy given component to the specified target locality.

+

The function copy<Component> will create a copy of the component referenced by to_copy on the locality specified with target_locality. It returns a future referring to the newly created component instance.

+
+
Parameters
+
    +
  • to_copy – [in] The global id of the component to copy

  • +
  • target_locality – [in ] The locality where the copy should be created.

  • +
+
+
Template Parameters
+

The – only template argument specifies the component type to create.

+
+
Returns
+

A future representing the global id of the newly (copied) component instance.

+
+
+
+ +
+
+template<typename Derived, typename Stub, typename Data>
Derived copy(client_base<Derived, Stub, Data> const &to_copy, hpx::id_type const &target_locality = hpx::invalid_id)#
+

Copy given component to the specified target locality.

+

The function copy will create a copy of the component referenced by the client side object to_copy on the locality specified with target_locality. It returns a new client side object future referring to the newly created component instance.

+
+

Note

+

If the second argument is omitted (or is invalid_id) the new component instance is created on the locality of the component instance which is to be copied.

+
+
+
Parameters
+
    +
  • to_copy – [in] The client side object representing the component to copy

  • +
  • target_locality – [in, optional] The locality where the copy should be created (default is same locality as source).

  • +
+
+
Template Parameters
+

The – only template argument specifies the component type to create.

+
+
Returns
+

A future representing the global id of the newly (copied) component instance.

+
+
+
+ +
+
+ +
+ +
+
+
hpx::find_root_locality, hpx::find_all_localities, hpx::find_remote_localities#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+hpx::id_type find_root_locality(error_code &ec = throws)#
+

Return the global id representing the root locality.

+

The function find_root_locality() can be used to retrieve the global id usable to refer to the root locality. The root locality is the locality where the main AGAS service is hosted.

+

+

+
+

Note

+

Generally, the id of a locality can be used for instance to create new instances of components and to invoke plain actions (global functions).

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return hpx::invalid_id otherwise.

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
Returns
+

The global id representing the root locality for this application.

+
+
+
+ +
+
+std::vector<hpx::id_type> find_all_localities(error_code &ec = throws)#
+

Return the list of global ids representing all localities available to this application.

+

The function find_all_localities() can be used to retrieve the global ids of all localities currently available to this application.

+

+

+
+

Note

+

Generally, the id of a locality can be used for instance to create new instances of components and to invoke plain actions (global functions).

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return an empty vector otherwise.

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
Returns
+

The global ids representing the localities currently available to this application.

+
+
+
+ +
+
+std::vector<hpx::id_type> find_remote_localities(error_code &ec = throws)#
+

Return the list of locality ids of remote localities supporting the given component type. By default this function will return the list of all remote localities (all but the current locality).

+

The function find_remote_localities() can be used to retrieve the global ids of all remote localities currently available to this application (i.e. all localities except the current one).

+

+

+
+

Note

+

Generally, the id of a locality can be used for instance to create new instances of components and to invoke plain actions (global functions).

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return an empty vector otherwise.

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
Returns
+

The global ids representing the remote localities currently available to this application.

+
+
+
+ +
+
+ +
+
+
hpx/runtime_distributed/find_here.hpp#
+

Defined in header hpx/runtime_distributed/find_here.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+hpx::id_type find_here(error_code &ec = throws)#
+

Return the global id representing this locality.

+

The function find_here() can be used to retrieve the global id usable to refer to the current locality.

+

+

+
+

Note

+

Generally, the id of a locality can be used for instance to create new instances of components and to invoke plain actions (global functions).

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return hpx::invalid_id otherwise.

+
+
+
Parameters
+

ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

+
+
Returns
+

The global id representing the locality this function has been called on.

+
+
+
+ +
+
+ +
+
+
hpx::find_locality#
+

Defined in header hpx/runtime.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+std::vector<hpx::id_type> find_all_localities(components::component_type type, error_code &ec = throws)#
+

Return the list of global ids representing all localities available to this application which support the given component type.

+

The function find_all_localities() can be used to retrieve the global ids of all localities currently available to this application which support the creation of instances of the given component type.

+

+

+
+

Note

+

Generally, the id of a locality can be used for instance to create new instances of components and to invoke plain actions (global functions).

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return an empty vector otherwise.

+
+
+
Parameters
+
    +
  • type – [in] The type of the components for which the function should return the available localities.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

The global ids representing the localities currently available to this application which support the creation of instances of the given component type. If no localities supporting the given component type are currently available, this function will return an empty vector.

+
+
+
+ +
+
+std::vector<hpx::id_type> find_remote_localities(components::component_type type, error_code &ec = throws)#
+

Return the list of locality ids of remote localities supporting the given component type. By default this function will return the list of all remote localities (all but the current locality).

+

The function find_remote_localities() can be used to retrieve the global ids of all remote localities currently available to this application (i.e. all localities except the current one) which support the creation of instances of the given component type.

+

+

+
+

Note

+

Generally, the id of a locality can be used for instance to create new instances of components and to invoke plain actions (global functions).

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return an empty vector otherwise.

+
+
+
Parameters
+
    +
  • type – [in] The type of the components for which the function should return the available remote localities.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

The global ids representing the remote localities currently available to this application.

+
+
+
+ +
+
+hpx::id_type find_locality(components::component_type type, error_code &ec = throws)#
+

Return the global id representing an arbitrary locality which supports the given component type.

+

The function find_locality() can be used to retrieve the global id of an arbitrary locality currently available to this application which supports the creation of instances of the given component type.

+

+

+
+

Note

+

Generally, the id of a locality can be used for instance to create new instances of components and to invoke plain actions (global functions).

+
+
+

Note

+

As long as ec is not pre-initialized to hpx::throws this function doesn’t throw but returns the result code using the parameter ec. Otherwise it throws an instance of hpx::exception.

+
+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return hpx::invalid_id otherwise.

+
+
+
Parameters
+
    +
  • type – [in] The type of the components for which the function should return any available locality.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
Returns
+

The global id representing an arbitrary locality currently available to this application which supports the creation of instances of the given component type. If no locality supporting the given component type is currently available, this function will return hpx::invalid_id.

+
+
+
+ +
+
+ +
+
+
hpx/runtime_distributed/get_locality_name.hpp#
+

Defined in header hpx/runtime_distributed/get_locality_name.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+future<std::string> get_locality_name(hpx::id_type const &id)#
+

Return the name of the referenced locality.

+

This function returns a future referring to the name for the locality of the given id.

+

+

See also

+

std::string get_locality_name()

+
+

+
+
Parameters
+

id – [in] The global id of the locality for which the name should be retrieved

+
+
Returns
+

This function returns the name for the locality of the given id. The name is retrieved from the underlying networking layer and may be different for different parcel ports.

+
+
+
+ +
+
+ +
+
+
hpx/runtime_distributed/get_num_localities.hpp#
+

Defined in header hpx/runtime_distributed/get_num_localities.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+

Functions

+
+
+hpx::future<std::uint32_t> get_num_localities(components::component_type t)#
+

Asynchronously return the number of localities which are currently registered for the running application.

+

The function get_num_localities asynchronously returns the number of localities currently connected to the console which support the creation of the given component type. The returned future represents the actual result.

+

+

See also

+

hpx::find_all_localities, hpx::get_num_localities

+
+

+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return 0 otherwise.

+
+
+
Parameters
+

t – The component type for which the number of connected localities should be retrieved.

+
+
+
+ +
+
+std::uint32_t get_num_localities(launch::sync_policy, components::component_type t, error_code &ec = throws)#
+

Synchronously return the number of localities which are currently registered for the running application.

+

The function get_num_localities returns the number of localities currently connected to the console which support the creation of the given component type. The returned future represents the actual result.

+

+

See also

+

hpx::find_all_localities, hpx::get_num_localities

+
+

+
+

Note

+

This function will return meaningful results only if called from an HPX-thread. It will return 0 otherwise.

+
+
+
Parameters
+
    +
  • t – The component type for which the number of connected localities should be retrieved.

  • +
  • ec – [in,out] this represents the error status on exit, if this is pre-initialized to hpx::throws the function will throw on error instead.

  • +
+
+
+
+ +
+
+ +
+
+
hpx/runtime_distributed/migrate_component.hpp#
+

Defined in header hpx/runtime_distributed/migrate_component.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+

Functions

+
+
+template<typename Component, typename DistPolicy>
future<hpx::id_type> migrate(hpx::id_type const &to_migrate, [[maybe_unused]] DistPolicy const &policy)#
+

Migrate the given component to the specified target locality

+

The function migrate<Component> will migrate the component referenced by to_migrate to the locality specified with target_locality. It returns a future referring to the migrated component instance.

+
+
Parameters
+
    +
  • to_migrate – [in] The client side representation of the component to migrate.

  • +
  • policy – [in] A distribution policy which will be used to determine the locality to migrate this object to.

  • +
+
+
Template Parameters
+
    +
  • Component – Specifies the component type of the component to migrate.

  • +
  • DistPolicy – Specifies the distribution policy to use to determine the destination locality.

  • +
+
+
Returns
+

A future representing the global id of the migrated component instance. This should be the same as migrate_to.

+
+
+
+ +
+
+template<typename Derived, typename Stub, typename Data, typename DistPolicy>
Derived migrate(client_base<Derived, Stub, Data> const &to_migrate, DistPolicy const &policy)#
+

Migrate the given component to the specified target locality

+

The function migrate<Component> will migrate the component referenced by to_migrate to the locality specified with target_locality. It returns a future referring to the migrated component instance.

+
+
Parameters
+
    +
  • to_migrate – [in] The client side representation of the component to migrate.

  • +
  • policy – [in] A distribution policy which will be used to determine the locality to migrate this object to.

  • +
+
+
Template Parameters
+
    +
  • Derived – Specifies the component type of the component to migrate.

  • +
  • DistPolicy – Specifies the distribution policy to use to determine the destination locality.

  • +
+
+
Returns
+

A future representing the global id of the migrated component instance. This should be the same as migrate_to.

+
+
+
+ +
+
+template<typename Component>
future<hpx::id_type> migrate(hpx::id_type const &to_migrate, hpx::id_type const &target_locality)#
+

Migrate the component with the given id to the specified target locality

+

The function migrate<Component> will migrate the component referenced by to_migrate to the locality specified with target_locality. It returns a future referring to the migrated component instance.

+
+
Parameters
+
    +
  • to_migrate – [in] The global id of the component to migrate.

  • +
  • target_locality – [in] The locality where the component should be migrated to.

  • +
+
+
Template Parameters
+

Component – Specifies the component type of the component to migrate.

+
+
Returns
+

A future representing the global id of the migrated component instance. This should be the same as migrate_to.

+
+
+
+ +
+
+template<typename Derived, typename Stub, typename Data>
Derived migrate(client_base<Derived, Stub, Data> const &to_migrate, hpx::id_type const &target_locality)#
+

Migrate the given component to the specified target locality

+

The function migrate<Component> will migrate the component referenced by to_migrate to the locality specified with target_locality. It returns a future referring to the migrated component instance.

+
+
Parameters
+
    +
  • to_migrate – [in] The client side representation of the component to migrate.

  • +
  • target_locality – [in] The id of the locality to migrate this object to.

  • +
+
+
Template Parameters
+

Derived – Specifies the component type of the component to migrate.

+
+
Returns
+

A client side representation of representing of the migrated component instance. This should be the same as migrate_to.

+
+
+
+ +
+
+ +
+ +
+
+
hpx/runtime_distributed/runtime_fwd.hpp#
+

Defined in header hpx/runtime_distributed/runtime_fwd.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/runtime_distributed/runtime_support.hpp#
+

Defined in header hpx/runtime_distributed/runtime_support.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace agas
+
+

Functions

+
+
+struct runtime_components_init_interface_functions &runtime_components_init()#
+
+ +
+
+ +
+
+namespace components
+
+

Functions

+
+
+struct counter_interface_functions &counter_init()#
+
+ +
+
+
+class runtime_support : public hpx::components::stubs::runtime_support#
+
+#include <runtime_support.hpp>
+

The runtime_support class is the client side representation of a server::runtime_support component

+
+

Public Functions

+
+
+inline runtime_support(hpx::id_type const &gid = hpx::invalid_id)#
+

Create a client side representation for the existing server::runtime_support instance with the given global id gid.

+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::id_type create_component(Ts&&... vs)#
+

Create a new component type using the runtime_support.

+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::future<hpx::id_type> create_component_async(Ts&&... vs)#
+

Asynchronously create a new component using the runtime_support.

+
+ +
+
+template<typename Component, typename ...Ts>
inline std::vector<hpx::id_type> bulk_create_component(std::size_t, Ts&&... vs)#
+

Asynchronously create N new default constructed components using the runtime_support

+
+ +
+
+template<typename Component, typename ...Ts>
inline hpx::future<std::vector<hpx::id_type>> bulk_create_components_async(std::size_t, Ts&&... vs)#
+

Asynchronously create a new component using the runtime_support.

+
+ +
+
+inline hpx::future<int> load_components_async()#
+
+ +
+
+inline int load_components()#
+
+ +
+
+inline hpx::future<void> call_startup_functions_async(bool pre_startup)#
+
+ +
+
+inline void call_startup_functions(bool pre_startup)#
+
+ +
+
+inline hpx::future<void> shutdown_async(double timeout = -1)#
+

Shutdown the given runtime system.

+
+ +
+
+inline void shutdown(double timeout = -1)#
+
+ +
+
+inline void shutdown_all(double timeout = -1)#
+

Shutdown the runtime systems of all localities.

+
+ +
+
+inline hpx::future<void> terminate_async()#
+

Terminate the given runtime system.

+
+ +
+
+inline void terminate()#
+
+ +
+
+inline void terminate_all()#
+

Terminate the runtime systems of all localities.

+
+ +
+
+inline void get_config(util::section &ini)#
+

Retrieve configuration information.

+
+ +
+
+inline hpx::id_type const &get_id() const#
+
+ +
+
+inline naming::gid_type const &get_raw_gid() const#
+
+ +
+
+

Private Types

+
+
+typedef stubs::runtime_support base_type#
+
+ +
+
+

Private Members

+
+
+hpx::id_type gid_#
+
+ +
+
+ +
+ +
+ +
+
+
hpx/runtime_distributed/server/copy_component.hpp#
+

Defined in header hpx/runtime_distributed/server/copy_component.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+
+namespace server
+
+

Functions

+
+
+template<typename Component>
future<hpx::id_type> copy_component_here(hpx::id_type const &to_copy)#
+
+ +
+
+template<typename Component>
future<hpx::id_type> copy_component(hpx::id_type const &to_copy, hpx::id_type const &target_locality)#
+
+ +
+
+
+template<typename Component>
struct copy_component_action : public hpx::actions::action<future<hpx::id_type> (*)(hpx::id_type const&, hpx::id_type const&), &copy_component<Component>, copy_component_action<Component>>#
+
+ +
+
+template<typename Component>
struct copy_component_action_here : public hpx::actions::action<future<hpx::id_type> (*)(hpx::id_type const&), &copy_component_here<Component>, copy_component_action_here<Component>>#
+
+ +
+ +
+ +
+ +
+
+
hpx/runtime_distributed/server/runtime_support.hpp#
+

Defined in header hpx/runtime_distributed/server/runtime_support.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+
+namespace server
+
+
+class runtime_support#
+
+

Public Types

+
+
+typedef runtime_support type_holder#
+
+ +
+
+

Public Functions

+
+
+explicit runtime_support(hpx::util::runtime_configuration &cfg)#
+
+ +
+
+inline ~runtime_support()#
+
+ +
+
+void delete_function_lists()#
+
+ +
+
+void tidy()#
+
+ +
+
+template<typename Component>
naming::gid_type create_component()#
+

Actions to create new objects.

+
+ +
+
+template<typename Component, typename T, typename ...Ts>
naming::gid_type create_component(T v, Ts... vs)#
+
+ +
+
+template<typename Component>
std::vector<naming::gid_type> bulk_create_component(std::size_t count)#
+
+ +
+
+template<typename Component, typename T, typename ...Ts>
std::vector<naming::gid_type> bulk_create_component(std::size_t count, T v, Ts... vs)#
+
+ +
+
+template<typename Component>
naming::gid_type copy_create_component(std::shared_ptr<Component> const &p, bool)#
+
+ +
+
+template<typename Component>
naming::gid_type migrate_component_to_here(std::shared_ptr<Component> const &p, hpx::id_type)#
+
+ +
+
+void shutdown(double timeout, hpx::id_type const &respond_to)#
+

Gracefully shutdown this runtime system instance.

+
+ +
+
+void shutdown_all(double timeout)#
+

Gracefully shutdown runtime system instances on all localities.

+
+ +
+
+void terminate(hpx::id_type const &respond_to)#
+

Shutdown this runtime system instance.

+
+ +
+
+inline void terminate_act(hpx::id_type const &id)#
+
+ +
+
+void terminate_all()#
+

Shutdown runtime system instances on all localities.

+
+ +
+
+inline void terminate_all_act()#
+
+ +
+
+util::section get_config()#
+

Retrieve configuration information.

+
+ +
+
+int load_components()#
+

Load all components on this locality.

+
+ +
+
+void call_startup_functions(bool pre_startup)#
+
+ +
+
+void call_shutdown_functions(bool pre_shutdown)#
+
+ +
+
+void garbage_collect()#
+

Force a garbage collection operation in the AGAS layer.

+
+ +
+
+naming::gid_type create_performance_counter(performance_counters::counter_info const &info)#
+

Create the given performance counter instance.

+
+ +
+
+void remove_from_connection_cache(naming::gid_type const &gid, parcelset::endpoints_type const &eps)#
+

Remove the given locality from our connection cache.

+
+ +
+
+HPX_DEFINE_COMPONENT_ACTION (runtime_support, terminate_act, terminate_action) HPX_DEFINE_COMPONENT_ACTION(runtime_support
+

termination detection

+
+ +
+
+terminate_all_action HPX_DEFINE_COMPONENT_ACTION (runtime_support, remove_from_connection_cache) void run()
+

Start the runtime_support component.

+
+ +
+
+void wait()#
+

Wait for the runtime_support component to notify the calling thread.

+

This function will be called from the main thread, causing it to block while the HPX functionality is executed. The main thread will block until the shutdown_action is executed, which in turn notifies all waiting threads.

+
+ +
+
+void stop(double timeout, hpx::id_type const &respond_to, bool remove_from_remote_caches)#
+

Notify all waiting (blocking) threads allowing the system to be properly stopped.

+
+

Note

+

This function can be called from any thread.

+
+
+ +
+
+void stopped()#
+

called locally only

+
+ +
+
+void notify_waiting_main()#
+
+ +
+
+inline bool was_stopped() const#
+
+ +
+
+void add_pre_startup_function(startup_function_type f)#
+
+ +
+
+void add_startup_function(startup_function_type f)#
+
+ +
+
+void add_pre_shutdown_function(shutdown_function_type f)#
+
+ +
+
+void add_shutdown_function(shutdown_function_type f)#
+
+ +
+
+void remove_here_from_connection_cache()#
+
+ +
+
+void remove_here_from_console_connection_cache()#
+
+ +
+
+

Public Members

+
+
+terminate_all_act
+
+ +
+
+

Public Static Functions

+
+
+static inline component_type get_component_type()#
+
+ +
+
+static inline void set_component_type(component_type t)#
+
+ +
+
+static inline constexpr void finalize()#
+

finalize() will be called just before the instance gets destructed

+
+
Parameters
+
    +
  • self – [in] The HPX thread used to execute this function.

  • +
  • appl – [in] The applier to be used for finalization of the component instance.

  • +
+
+
+
+ +
+
+static inline bool is_target_valid(hpx::id_type const &id)#
+
+ +
+
+

Protected Functions

+
+
+int load_components(util::section &ini, naming::gid_type const &prefix, naming::resolver_client &agas_client, hpx::program_options::options_description &options, std::set<std::string> &startup_handled)#
+
+ +
+
+bool load_component(hpx::util::plugin::dll &d, util::section &ini, std::string const &instance, std::string const &component, filesystem::path const &lib, naming::gid_type const &prefix, naming::resolver_client &agas_client, bool isdefault, bool isenabled, hpx::program_options::options_description &options, std::set<std::string> &startup_handled)#
+
+ +
+
+bool load_component_dynamic(util::section &ini, std::string const &instance, std::string const &component, filesystem::path lib, naming::gid_type const &prefix, naming::resolver_client &agas_client, bool isdefault, bool isenabled, hpx::program_options::options_description &options, std::set<std::string> &startup_handled)#
+
+ +
+
+bool load_startup_shutdown_functions(hpx::util::plugin::dll &d, error_code &ec)#
+
+ +
+
+bool load_commandline_options(hpx::util::plugin::dll &d, hpx::program_options::options_description &options, error_code &ec)#
+
+ +
+
+bool load_component_static(util::section &ini, std::string const &instance, std::string const &component, filesystem::path const &lib, naming::gid_type const &prefix, naming::resolver_client &agas_client, bool isdefault, bool isenabled, hpx::program_options::options_description &options, std::set<std::string> &startup_handled)#
+
+ +
+
+bool load_startup_shutdown_functions_static(std::string const &mod, error_code &ec)#
+
+ +
+
+bool load_commandline_options_static(std::string const &mod, hpx::program_options::options_description &options, error_code &ec)#
+
+ +
+
+bool load_plugins(util::section &ini, hpx::program_options::options_description &options, std::set<std::string> &startup_handled)#
+
+ +
+
+bool load_plugin(hpx::util::plugin::dll &d, util::section &ini, std::string const &instance, std::string const &component, filesystem::path const &lib, bool isenabled, hpx::program_options::options_description &options, std::set<std::string> &startup_handled)#
+
+ +
+
+bool load_plugin_dynamic(util::section &ini, std::string const &instance, std::string const &component, filesystem::path lib, bool isenabled, hpx::program_options::options_description &options, std::set<std::string> &startup_handled)#
+
+ +
+
+std::size_t dijkstra_termination_detection(std::vector<hpx::id_type> const &locality_ids)#
+
+ +
+
+

Private Types

+
+
+typedef hpx::spinlock plugin_map_mutex_type#
+
+ +
+
+typedef plugin_factory plugin_factory_type#
+
+ +
+
+typedef std::map<std::string, plugin_factory_type> plugin_map_type#
+
+ +
+
+typedef std::map<std::string, hpx::util::plugin::dll> modules_map_type#
+
+ +
+
+typedef std::vector<static_factory_load_data_type> static_modules_type#
+
+ +
+
+

Private Members

+
+
+std::mutex mtx_#
+
+ +
+
+std::condition_variable wait_condition_#
+
+ +
+
+std::condition_variable stop_condition_#
+
+ +
+
+bool stop_called_#
+
+ +
+
+bool stop_done_#
+
+ +
+
+bool terminated_#
+
+ +
+
+std::thread::id main_thread_id_#
+
+ +
+
+std::atomic<bool> shutdown_all_invoked_#
+
+ +
+
+plugin_map_mutex_type p_mtx_#
+
+ +
+
+plugin_map_type plugins_#
+
+ +
+
+modules_map_type &modules_#
+
+ +
+
+static_modules_type static_modules_#
+
+ +
+
+hpx::spinlock globals_mtx_#
+
+ +
+
+std::list<startup_function_type> pre_startup_functions_#
+
+ +
+
+std::list<startup_function_type> startup_functions_#
+
+ +
+
+std::list<shutdown_function_type> pre_shutdown_functions_#
+
+ +
+
+std::list<shutdown_function_type> shutdown_functions_#
+
+ +
+
+
+struct plugin_factory#
+
+

Public Functions

+
+
+inline plugin_factory(std::shared_ptr<plugins::plugin_factory_base> const &f, hpx::util::plugin::dll const &d, bool enabled)#
+
+ +
+
+

Public Members

+
+
+std::shared_ptr<plugins::plugin_factory_base> first#
+
+ +
+
+hpx::util::plugin::dll const &second#
+
+ +
+
+bool isenabled#
+
+ +
+
+ +
+ +
+ +
+ +
+ +
+
+
hpx/runtime_distributed/stubs/runtime_support.hpp#
+

Defined in header hpx/runtime_distributed/stubs/runtime_support.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace components
+
+
+namespace stubs
+
+
+struct runtime_support#
+

Subclassed by hpx::components::runtime_support

+
+

Public Static Functions

+
+
+template<typename Component, typename ...Ts>
static inline hpx::future<hpx::id_type> create_component_async(hpx::id_type const &gid, Ts&&... vs)#
+

Create a new component type using the runtime_support with the given targetgid. This is a non-blocking call. The caller needs to call future::get on the result of this function to obtain the global id of the newly created object.

+
+ +
+
+template<typename Component, typename ...Ts>
static inline hpx::id_type create_component(hpx::id_type const &gid, Ts&&... vs)#
+

Create a new component type using the runtime_support with the given targetgid. Block for the creation to finish.

+
+ +
+
+template<typename Component, typename ...Ts>
static inline hpx::future<std::vector<hpx::id_type>> bulk_create_component_colocated_async(hpx::id_type const &gid, std::size_t count, Ts&&... vs)#
+

Create multiple new components type using the runtime_support colocated with the with the given targetgid. This is a non-blocking call.

+
+ +
+
+template<typename Component, typename ...Ts>
static inline std::vector<hpx::id_type> bulk_create_component_colocated(hpx::id_type const &gid, std::size_t count, Ts&&... vs)#
+

Create multiple new components type using the runtime_support colocated with the with the given targetgid. Block for the creation to finish.

+
+ +
+
+template<typename Component, typename ...Ts>
static inline hpx::future<std::vector<hpx::id_type>> bulk_create_component_async(hpx::id_type const &gid, std::size_t count, Ts&&... vs)#
+

Create multiple new components type using the runtime_support on the given locality. This is a non-blocking call.

+
+ +
+
+template<typename Component, typename ...Ts>
static inline std::vector<hpx::id_type> bulk_create_component(hpx::id_type const &gid, std::size_t count, Ts&&... vs)#
+

Create multiple new components type using the runtime_support on the given locality. Block for the creation to finish.

+
+ +
+
+template<typename Component, typename ...Ts>
static inline hpx::future<hpx::id_type> create_component_colocated_async(hpx::id_type const &gid, Ts&&... vs)#
+

Create a new component type using the runtime_support with the given targetgid. This is a non-blocking call. The caller needs to call future::get on the result of this function to obtain the global id of the newly created object.

+
+ +
+
+template<typename Component, typename ...Ts>
static inline hpx::id_type create_component_colocated(hpx::id_type const &gid, Ts&&... vs)#
+

Create a new component type using the runtime_support with the given targetgid. Block for the creation to finish.

+
+ +
+
+template<typename Component>
static inline hpx::future<hpx::id_type> copy_create_component_async(hpx::id_type const &gid, std::shared_ptr<Component> const &p, bool local_op)#
+
+ +
+
+template<typename Component>
static inline hpx::id_type copy_create_component(hpx::id_type const &gid, std::shared_ptr<Component> const &p, bool local_op)#
+
+ +
+
+template<typename Component>
static inline hpx::future<hpx::id_type> migrate_component_async(hpx::id_type const &target_locality, std::shared_ptr<Component> const &p, hpx::id_type const &to_migrate)#
+
+ +
+
+template<typename Component, typename DistPolicy>
static inline hpx::future<hpx::id_type> migrate_component_async(DistPolicy const &policy, std::shared_ptr<Component> const &p, hpx::id_type const &to_migrate)#
+
+ +
+
+template<typename Component, typename Target>
static inline hpx::id_type migrate_component(Target const &target, hpx::id_type const &to_migrate, std::shared_ptr<Component> const &p)#
+
+ +
+
+static hpx::future<int> load_components_async(hpx::id_type const &gid)#
+
+ +
+
+static int load_components(hpx::id_type const &gid)#
+
+ +
+
+static hpx::future<void> call_startup_functions_async(hpx::id_type const &gid, bool pre_startup)#
+
+ +
+
+static void call_startup_functions(hpx::id_type const &gid, bool pre_startup)#
+
+ +
+
+static hpx::future<void> shutdown_async(hpx::id_type const &targetgid, double timeout = -1)#
+

Shutdown the given runtime system.

+
+ +
+
+static void shutdown(hpx::id_type const &targetgid, double timeout = -1)#
+
+ +
+
+static void shutdown_all(hpx::id_type const &targetgid, double timeout = -1)#
+

Shutdown the runtime systems of all localities.

+
+ +
+
+static void shutdown_all(double timeout = -1)#
+
+ +
+
+static hpx::future<void> terminate_async(hpx::id_type const &targetgid)#
+

Retrieve configuration information.

+

Terminate the given runtime system

+
+ +
+
+static void terminate(hpx::id_type const &targetgid)#
+
+ +
+
+static void terminate_all(hpx::id_type const &targetgid)#
+

Terminate the runtime systems of all localities.

+
+ +
+
+static void terminate_all()#
+
+ +
+
+static void garbage_collect_non_blocking(hpx::id_type const &targetgid)#
+
+ +
+
+static hpx::future<void> garbage_collect_async(hpx::id_type const &targetgid)#
+
+ +
+
+static void garbage_collect(hpx::id_type const &targetgid)#
+
+ +
+
+static hpx::future<hpx::id_type> create_performance_counter_async(hpx::id_type targetgid, performance_counters::counter_info const &info)#
+
+ +
+
+static hpx::id_type create_performance_counter(hpx::id_type targetgid, performance_counters::counter_info const &info, error_code &ec = throws)#
+
+ +
+
+static hpx::future<util::section> get_config_async(hpx::id_type const &targetgid)#
+

Retrieve configuration information.

+
+ +
+
+static void get_config(hpx::id_type const &targetgid, util::section &ini)#
+
+ +
+
+static void remove_from_connection_cache_async(hpx::id_type const &target, naming::gid_type const &gid, parcelset::endpoints_type const &endpoints)#
+
+ +
+
+ +
+ +
+ +
+ +
+
+
+
+
segmented_algorithms#
+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/parallel/segmented_algorithms/adjacent_difference.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/adjacent_difference.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented#
+
+

Functions

+
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Op>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, FwdIter2> tag_invoke(hpx::adjacent_difference_t, ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Op &&op)#
+
+ +
+
+template<typename InIter1, typename InIter2, typename Op>
InIter2 tag_invoke(hpx::adjacent_difference_t, InIter1 first, InIter1 last, InIter2 dest, Op &&op)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/adjacent_find.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/adjacent_find.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented
+
+

Functions

+
+
+template<typename InIter, typename Pred>
InIter tag_invoke(hpx::adjacent_find_t, InIter first, InIter last, Pred &&pred = Pred())#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename Pred>
hpx::parallel::util::detail::algorithm_result<ExPolicy, SegIter>::type tag_invoke(hpx::adjacent_find_t, ExPolicy &&policy, SegIter first, SegIter last, Pred &&pred)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/all_any_none.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/all_any_none.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented
+
+

Functions

+
+
+template<typename InIter, typename F>
bool tag_invoke(hpx::none_of_t, InIter first, InIter last, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename F>
hpx::parallel::util::detail::algorithm_result<ExPolicy, bool>::type tag_invoke(hpx::none_of_t, ExPolicy &&policy, SegIter first, SegIter last, F &&f)#
+
+ +
+
+template<typename InIter, typename F>
bool tag_invoke(hpx::any_of_t, InIter first, InIter last, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename F>
hpx::parallel::util::detail::algorithm_result<ExPolicy, bool>::type tag_invoke(hpx::any_of_t, ExPolicy &&policy, SegIter first, SegIter last, F &&f)#
+
+ +
+
+template<typename InIter, typename F>
bool tag_invoke(hpx::all_of_t, InIter first, InIter last, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename F>
hpx::parallel::util::detail::algorithm_result<ExPolicy, bool>::type tag_invoke(hpx::all_of_t, ExPolicy &&policy, SegIter first, SegIter last, F &&f)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/count.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/count.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented
+
+

Functions

+
+
+template<typename InIter, typename T>
std::iterator_traits<InIter>::difference_type tag_invoke(hpx::count_t, InIter first, InIter last, T const &value)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename T>
hpx::parallel::util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<SegIter>::difference_type>::type tag_invoke(hpx::count_t, ExPolicy &&policy, SegIter first, SegIter last, T const &value)#
+
+ +
+
+template<typename InIter, typename F>
std::iterator_traits<InIter>::difference_type tag_invoke(hpx::count_if_t, InIter first, InIter last, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename F>
hpx::parallel::util::detail::algorithm_result<ExPolicy, typename std::iterator_traits<SegIter>::difference_type>::type tag_invoke(hpx::count_if_t, ExPolicy &&policy, SegIter first, SegIter last, F &&f)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/exclusive_scan.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/exclusive_scan.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented
+
+

Functions

+
+
+template<typename InIter, typename OutIter, typename T, typename Op = std::plus<T>>
OutIter tag_invoke(hpx::exclusive_scan_t, InIter first, InIter last, OutIter dest, T init, Op &&op = Op())#
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename T, typename Op = std::plus<T>>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter2>::type tag_invoke(hpx::exclusive_scan_t, ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, T init, Op &&op = Op())#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/fill.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/fill.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+
hpx/parallel/segmented_algorithms/for_each.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/for_each.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented
+
+

Functions

+
+
+template<typename InIter, typename F>
InIter tag_invoke(hpx::for_each_t, InIter first, InIter last, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename F>
hpx::parallel::util::detail::algorithm_result<ExPolicy, SegIter>::type tag_invoke(hpx::for_each_t, ExPolicy &&policy, SegIter first, SegIter last, F &&f)#
+
+ +
+
+template<typename InIter, typename Size, typename F>
InIter tag_invoke(hpx::for_each_n_t, InIter first, Size count, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename Size, typename F>
hpx::parallel::util::detail::algorithm_result<ExPolicy, SegIter>::type tag_invoke(hpx::for_each_n_t, ExPolicy &&policy, SegIter first, Size count, F &&f)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/generate.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/generate.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented
+
+

Functions

+
+
+template<typename SegIter, typename F>
SegIter tag_invoke(hpx::generate_t, SegIter first, SegIter last, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename F>
parallel::util::detail::algorithm_result<ExPolicy, SegIter>::type tag_invoke(hpx::generate_t, ExPolicy &&policy, SegIter first, SegIter last, F &&f)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/inclusive_scan.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/inclusive_scan.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented
+
+

Functions

+
+
+template<typename InIter, typename OutIter, typename Op = std::plus<typename std::iterator_traits<InIter>::value_type>>
OutIter tag_invoke(hpx::inclusive_scan_t, InIter first, InIter last, OutIter dest, Op &&op = Op())#
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Op = std::plus<typename std::iterator_traits<FwdIter1>::value_type>>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter2>::type tag_invoke(hpx::inclusive_scan_t, ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Op &&op = Op())#
+
+ +
+
+template<typename InIter, typename OutIter, typename Op, typename T>
OutIter tag_invoke(hpx::inclusive_scan_t, InIter first, InIter last, OutIter dest, Op &&op, T &&init)#
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Op, typename T>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter2>::type tag_invoke(hpx::inclusive_scan_t, ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Op &&op, T &&init)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/minmax.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/minmax.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+

Typedefs

+
+
+template<typename T>
using minmax_element_result = hpx::parallel::util::min_max_result<T>#
+
+ +
+
+ +
+
+namespace segmented
+
+

Typedefs

+
+
+template<typename T>
using minmax_element_result = hpx::parallel::util::min_max_result<T>#
+
+ +
+
+

Functions

+
+
+template<typename SegIter, typename F>
SegIter tag_invoke(hpx::min_element_t, SegIter first, SegIter last, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename F>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, SegIter> tag_invoke(hpx::min_element_t, ExPolicy &&policy, SegIter first, SegIter last, F &&f)#
+
+ +
+
+template<typename SegIter, typename F>
SegIter tag_invoke(hpx::max_element_t, SegIter first, SegIter last, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename F>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, SegIter> tag_invoke(hpx::max_element_t, ExPolicy &&policy, SegIter first, SegIter last, F &&f)#
+
+ +
+
+template<typename SegIter, typename F>
minmax_element_result<SegIter> tag_invoke(hpx::minmax_element_t, SegIter first, SegIter last, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename F>
hpx::parallel::util::detail::algorithm_result_t<ExPolicy, minmax_element_result<SegIter>> tag_invoke(hpx::minmax_element_t, ExPolicy &&policy, SegIter first, SegIter last, F &&f)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/reduce.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/reduce.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented
+
+

Functions

+
+
+template<typename InIterB, typename InIterE, typename T, typename F>
T tag_invoke(hpx::reduce_t, InIterB first, InIterE last, T init, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename InIterB, typename InIterE, typename T, typename F>
parallel::util::detail::algorithm_result<ExPolicy, T>::type tag_invoke(hpx::reduce_t, ExPolicy &&policy, InIterB first, InIterE last, T init, F &&f)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/transform.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/transform.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented
+
+

Functions

+
+
+template<typename SegIter, typename OutIter, typename F>
hpx::parallel::util::in_out_result<SegIter, OutIter> tag_invoke(hpx::transform_t, SegIter first, SegIter last, OutIter dest, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename OutIter, typename F>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::parallel::util::in_out_result<SegIter, OutIter>>::type tag_invoke(hpx::transform_t, ExPolicy &&policy, SegIter first, SegIter last, OutIter dest, F &&f)#
+
+ +
+
+template<typename InIter1, typename InIter2, typename OutIter, typename F>
hpx::parallel::util::in_in_out_result<InIter1, InIter2, OutIter> tag_invoke(hpx::transform_t, InIter1 first1, InIter1 last1, InIter2 first2, OutIter dest, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename InIter1, typename InIter2, typename OutIter, typename F>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::parallel::util::in_in_out_result<InIter1, InIter2, OutIter>>::type tag_invoke(hpx::transform_t, ExPolicy &&policy, InIter1 first1, InIter1 last1, InIter2 first2, OutIter dest, F &&f)#
+
+ +
+
+template<typename InIter1, typename InIter2, typename OutIter, typename F>
hpx::parallel::util::in_in_out_result<InIter1, InIter2, OutIter> tag_invoke(hpx::transform_t, InIter1 first1, InIter1 last1, InIter2 first2, InIter2 last2, OutIter dest, F &&f)#
+
+ +
+
+template<typename ExPolicy, typename InIter1, typename InIter2, typename OutIter, typename F>
hpx::parallel::util::detail::algorithm_result<ExPolicy, hpx::parallel::util::in_in_out_result<InIter1, InIter2, OutIter>>::type tag_invoke(hpx::transform_t, ExPolicy &&policy, InIter1 first1, InIter1 last1, InIter2 first2, InIter2 last2, OutIter dest, F &&f)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/transform_exclusive_scan.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/transform_exclusive_scan.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace segmented
+
+

Functions

+
+
+template<typename InIter, typename OutIter, typename T, typename Op, typename Conv>
OutIter tag_invoke(hpx::transform_exclusive_scan_t, InIter first, InIter last, OutIter dest, T init, Op &&op, Conv &&conv)#
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename T, typename Op, typename Conv>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter2>::type tag_invoke(hpx::transform_exclusive_scan_t, ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, T init, Op &&op, Conv &&conv)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/transform_inclusive_scan.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/transform_inclusive_scan.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace segmented
+
+

Functions

+
+
+template<typename InIter, typename OutIter, typename Op, typename Conv>
OutIter tag_invoke(hpx::transform_inclusive_scan_t, InIter first, InIter last, OutIter dest, Op &&op, Conv &&conv)#
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename Op, typename Conv>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter2>::type tag_invoke(hpx::transform_inclusive_scan_t, ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Op &&op, Conv &&conv)#
+
+ +
+
+template<typename InIter, typename OutIter, typename T, typename Op, typename Conv>
OutIter tag_invoke(hpx::transform_inclusive_scan_t, InIter first, InIter last, OutIter dest, Op &&op, Conv &&conv, T init)#
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename T, typename Op, typename Conv>
parallel::util::detail::algorithm_result<ExPolicy, FwdIter2>::type tag_invoke(hpx::transform_inclusive_scan_t, ExPolicy &&policy, FwdIter1 first, FwdIter1 last, FwdIter2 dest, Op &&op, Conv &&conv, T init)#
+
+ +
+
+ +
+ +
+
+
hpx/parallel/segmented_algorithms/transform_reduce.hpp#
+

Defined in header hpx/parallel/segmented_algorithms/transform_reduce.hpp.

+

See Public API for a list of names and headers that are part of the public +HPX API.

+
+
+namespace hpx
+
+
+namespace parallel
+
+ +
+
+namespace segmented
+
+

Functions

+
+
+template<typename SegIter, typename T, typename Reduce, typename Convert>
std::decay<T> tag_invoke(hpx::transform_reduce_t, SegIter first, SegIter last, T &&init, Reduce &&red_op, Convert &&conv_op)#
+
+ +
+
+template<typename ExPolicy, typename SegIter, typename T, typename Reduce, typename Convert>
parallel::util::detail::algorithm_result<ExPolicy, typename std::decay<T>::type>::type tag_invoke(hpx::transform_reduce_t, ExPolicy &&policy, SegIter first, SegIter last, T &&init, Reduce &&red_op, Convert &&conv_op)#
+
+ +
+
+template<typename FwdIter1, typename FwdIter2, typename T, typename Reduce, typename Convert>
T tag_invoke(hpx::transform_reduce_t, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, T init, Reduce &&red_op, Convert &&conv_op)#
+
+ +
+
+template<typename ExPolicy, typename FwdIter1, typename FwdIter2, typename T, typename Reduce, typename Convert>
parallel::util::detail::algorithm_result<ExPolicy, T>::type tag_invoke(hpx::transform_reduce_t, ExPolicy &&policy, FwdIter1 first1, FwdIter1 last1, FwdIter2 first2, T init, Reduce &&red_op, Convert &&conv_op)#
+
+ +
+
+ +
+ +
+
+
+
+
+
+
+
+
+
+

Contributing to HPX#

+

HPX development happens on Github. The following sections are a +collection of useful information related to HPX development.

+
+
+

Contributing to HPX#

+

The main source of information to understand the process of how to contribute +to HPX can be found in +this document. +This is a living document that is constantly updated with relevant information.

+
+
+

HPX governance model#

+

The HPX project is a meritocratic, consensus-based community project. Anyone +with an interest in the project can join the community, contribute to the +project design and participate in the decision making process. +This document describes +how that participation takes place and how to set about earning merit within +the project community.

+
+
+

Release procedure for HPX#

+

Below is a step by step procedure for making an HPX release. We aim to produce two +releases per year: one in March-April, and one in September-October.

+

This is a living document and may not be totally current or accurate. It is an +attempt to capture current practices in making an HPX release. Please update it +as appropriate.

+

One way to use this procedure is to print a copy and check off the lines as they +are completed to avoid confusion.

+
    +
  1. Notify developers that a release is imminent.

  2. +
  3. For minor and major releases: create and check out a new branch at an +appropriate point on master with the name release-major.minor.X. +major and minor should be the major and minor versions of the +release. For patch releases: check out the corresponding +release-major.minor.X branch.

  4. +
  5. Write release notes in docs/sphinx/releases/whats_new_$VERSION.rst. Keep +adding merged PRs and closed issues to this until just before the release is +made. Use tools/generate_pr_issue_list.sh to generate the lists. Add the +new release notes to the table of contents in docs/sphinx/releases.rst.

  6. +
  7. Build the docs, and proof-read them. Update any documentation that may have +changed, and correct any typos. Pay special attention to:

    +
      +
    • $HPX_SOURCE/README.rst

      +
        +
      • Update grant information

      • +
      +
    • +
    • docs/sphinx/releases/whats_new_$VERSION.rst

    • +
    • docs/sphinx/about_hpx/people.rst

      +
        +
      • Update collaborators

      • +
      • Update grant information

      • +
      +
    • +
    +
  8. +
  9. This step does not apply to patch releases. For APEX:

    +
      +
    • Change the release branch to be the most current release tag available in +the APEX git_external section in the main CMakeLists.txt. +Please contact the maintainers of the respective packages to generate a new +release to synchronize with the HPX release (APEX).

    • +
    +
  10. +
  11. Make sure HPX_VERSION_MAJOR/MINOR/SUBMINOR in CMakeLists.txt contain +the correct values. Change them if needed.

  12. +
  13. Change version references in CITATION.cff. There are two occurrences. Change +year in the copyright file under /libs/core/version/src/version.cpp.

  14. +
  15. This step does not apply to patch releases. Remove features which have been +deprecated for at least 2 releases. This involves removing build options +which enable those features from the main CMakeLists.txt and also deleting +all related code and tests from the main source tree.

    +

    The general deprecation policy involves a three-step process we have to go +through in order to introduce a breaking change:

    +
      +
    1. First release cycle: add a build option that allows for explicitly disabling +any old (now deprecated) code.

    2. +
    3. Second release cycle: turn this build option OFF by default.

    4. +
    5. Third release cycle: completely remove the old code.

    6. +
    +

    The main CMakeLists.txt contains a comment indicating for which version +the breaking change was introduced first. +In the case of deprecated features which don’t have a replacement yet, we +keep them around in case (like Vc for example).

    +
  16. +
  17. Update the minimum required versions if necessary (compilers, dependencies, +etc.) in prerequisites.rst.

  18. +
  19. Verify that the Jenkins setups for the release branch on Rostam and Piz Daint +are running and do not display any errors.

  20. +
  21. Repeat the following steps until satisfied with the release.

    +
      +
    1. Change HPX_VERSION_TAG in CMakeLists.txt to -rcN, where N +is the current iteration of this step. Start with -rc1.

    2. +
    3. Create a pre-release on GitHub using the script tools/roll_release.sh. +This script automatically tag with the corresponding release number. +The script requires that you have the STE||AR Group signing key.

    4. +
    5. This step is not necessary for patch releases. Notify +hpx-users@stellar-group.org of the +availability of the release candidate. Ask users to test the candidate by +checking out the release candidate tag.

    6. +
    7. Allow at least a week for testing of the release candidate.

      +
        +
      • Use git merge when possible, and fall back to git cherry-pick +when needed. For patch releases git cherry-pick is most likely your +only choice if there have been significant unrelated changes on master +since the previous release.

      • +
      • Go back to the first step when enough patches have been added.

      • +
      • If there are no more patches, continue to make the final release.

      • +
      +
    8. +
    +
  22. +
  23. Update any occurrences of the latest stable release to refer to the version +about to be released. For example, quickstart.rst contains instructions +to check out the latest stable tag. Make sure that refers to the new version.

  24. +
  25. Add a new entry to the RPM changelog (cmake/packaging/rpm/Changelog.txt) +with the new version number and a link to the corresponding changelog.

  26. +
  27. Change HPX_VERSION_TAG in CMakeLists.txt to an empty string.

  28. +
  29. Add the release date to the caption of the current “What’s New” section in +the docs, and change the value of HPX_VERSION_DATE in +CMakeLists.txt.

  30. +
  31. Create a release on GitHub using the script tools/roll_release.sh. This +script automatically tag the with the corresponding release number. The +script requires that you have the STE||AR Group signing key.

  32. +
  33. Update the websites (hpx.stellar-group.org +and stellar-group.org <https://stellar-group.org>). You can login on +wordpress through this page <https://hpx.stellar-group.org/wp-login.php>. +You can update the pages with the following:

    +
      +
    • Update links on the downloads page. Link to the release on GitHub.

    • +
    • Documentation links on the docs page (link to generated documentation on +GitHub Pages). Follow the style of previous releases.

    • +
    • A new blog post announcing the release, which links to downloads and the +“What’s New” section in the documentation (see previous releases for +examples).

    • +
    +
  34. +
  35. Merge release branch into master.

  36. +
  37. Post-release cleanup. Create a new pull request against master with the +following changes:

    +
      +
    1. Modify the release procedure if necessary.

    2. +
    3. Change HPX_VERSION_TAG in CMakeLists.txt back to -trunk.

    4. +
    5. Increment HPX_VERSION_MINOR in CMakeLists.txt.

    6. +
    +
  38. +
  39. Update Vcpkg (https://github.com/Microsoft/vcpkg) to pull from latest +release.

    +
      +
    • Update version number in CONTROL

    • +
    • Update tag and SHA512 to that of the new release

    • +
    +
  40. +
  41. Update spack (https://github.com/spack/spack) with the latest HPX package.

    +
      +
    • Update version number in hpx/package.py and SHA256 to that of the new +release

    • +
    +
  42. +
  43. Announce the release on hpx-users@stellar-group.org, stellar@cct.lsu.edu, +allcct@cct.lsu.edu, faculty@csc.lsu.edu, faculty@ece.lsu.edu, +the HPX Slack channel, the IRC channel, +our list of external collaborators, isocpp.org, reddit.com, HPC Wire, Inside +HPC, Heise Online, and a CCT press release.

  44. +
  45. Beer and pizza.

  46. +
+
+
+

Testing HPX#

+

To ensure correctness of HPX, we ship a large variety of unit and regression +tests. The tests are driven by the CTest tool and are executed automatically +on each commit to the HPX Github repository. In addition, it is encouraged +to run the test suite manually to ensure proper operation on your target system. +If a test fails for your platform, we highly recommend submitting an issue on our +HPX Issues tracker with detailed information about the target system.

+
+
Running tests manually#
+

Running the tests manually is as easy as typing make tests && make test. +This will build all tests and run them once the tests are built successfully. +After the tests have been built, you can invoke separate tests with the help of +the ctest command. You can list all available test targets using make help +| grep tests. Please see the CTest Documentation for further details.

+
+
+
Running performance tests#
+

We run performance tests on Piz Daint for each pull request using Jenkins. To +run those performance tests locally or on Piz Daint, a script is provided under +tools/perftests_ci/local_run.sh (to be run in the build directory specifying +the HPX source directory as the argument to the script, default is +$HOME/projects/hpx_perftests_ci.

+
+
+
Adding new performance tests#
+

To add a new performance test, you need to wrap the portion of code to benchmark +with hpx::util::perftests_report, passing the test name, the executor name +and the function to time (can be a lambda). This facility is used to output the +time results in a json format (format needed to compare the results and plot +them). To effectively print them at the end of your test, call +hpx::util::perftests_print_times. To see an example of use, see +future_overhead_report.cpp. Finally, you can add the test to the CI report +editing the hpx_targets variable for the executable name and the +hpx_test_options variable for the corresponding options to use for the run +in the performance test script .jenkins/cscs-perftests/launch_perftests.sh. +And then run the tools/perftests_ci/local_run.sh script to get a reference +json run (use the name of the test) to be added in the +tools/perftests_ci/perftest/references/daint_default directory.

+
+
+
Issue tracker#
+

If you stumble over a bug or missing feature in HPX, please +submit an issue to our HPX Issues page. For more information on how to +submit support requests or other means of getting in contact with the developers, +please see the Support Website page.

+
+
+
Continuous testing#
+

In addition to manual testing, we run automated tests on various platforms. We also +run tests on all pull requests using both CircleCI and a combination of CDash +and pycicle. You can see the dashboards here: CircleCI HPX dashboard and CDash HPX dashboard .

+
+
+
+

Using docker for development#

+

Although it can often be useful to set up a local development environment with +system-provided or self-built dependencies, Docker provides a convenient +alternative to quickly get all the dependencies needed to start development of +HPX. Our testing setup on CircleCI uses a docker image to run all tests.

+

To get started you need to install Docker using whatever means is most +convenient on your system. Once you have Docker installed, you can pull or +directly run the docker image. The image is based on Debian and Clang, and can +be found on Docker Hub. To start a container using the HPX build +environment, run:

+
$ docker run --interactive --tty stellargroup/build_env:latest bash
+
+
+

You are now in an environment where all the HPX build and runtime dependencies +are present. You can install additional packages according to your own needs. +Please see the Docker Documentation for more information on using Docker.

+
+

Warning

+

All changes made within the container are lost when the container is closed. +If you want files to persist (e.g., the HPX source tree) after closing the +container, you can bind directories from the host system into the container +(see Docker Documentation (Bind mounts)).

+
+
+
+

Documentation#

+

This documentation is built using Sphinx, and an automatically generated API +reference using Doxygen and Breathe.

+

We always welcome suggestions on how to improve our documentation, as well as +pull requests with corrections and additions.

+
+
Prerequisites#
+

To build the HPX documentation, you need recent versions of the following +packages:

+
    +
  • python3

  • +
  • sphinx 4.5.0 (Python package)

  • +
  • sphinx-book-theme (Python package)

  • +
  • breathe 4.33.1 (Python package)

  • +
  • doxygen

  • +
  • sphinxcontrib-bibtex

  • +
  • sphinx-copybutton

  • +
+

If the Python dependencies are not available through your system package +manager, you can install them using the Python package manager pip:

+
pip install --user "sphinx<5" sphinx-book-theme breathe sphinxcontrib-bibtex sphinx-copybutton
+
+
+

You may need to set the following CMake variables to make sure CMake can +find the required dependencies.

+
+
+Doxygen_ROOT:PATH#
+

Specifies where to look for the installation of the Doxygen tool.

+
+ +
+
+Sphinx_ROOT:PATH#
+

Specifies where to look for the installation of the Sphinx tool.

+
+ +
+
+Breathe_APIDOC_ROOT:PATH#
+

Specifies where to look for the installation of the Breathe tool.

+
+ +
+
+
Building documentation#
+

Enable building of the documentation by setting HPX_WITH_DOCUMENTATION=ON +during CMake configuration. To build the documentation, build the docs +target using your build tool. The default output format is HTML documentation. +You can choose alternative output formats (single-page HTML, PDF, and man) with +the HPX_WITH_DOCUMENTATION_OUTPUT_FORMATS CMake option.

+
+

Note

+

If you add new source files to the Sphinx documentation, you have to run +CMake again to have the files included in the build.

+
+
+
+
Style guide#
+

The documentation is written using reStructuredText. These are the conventions +used for formatting the documentation:

+
    +
  • Use, at most, 80 characters per line.

  • +
  • Top-level headings use over- and underlines with =.

  • +
  • Sub-headings use only underlines with characters in decreasing level of +importance: =, - and ..

  • +
  • Use sentence case in headings.

  • +
  • Refer to common terminology using :term:`Component`.

  • +
  • Indent content of directives (.. directive::) by three spaces.

  • +
  • For C++ code samples at the end of paragraphs, use :: and indent the code +sample by 4 spaces.

    +
      +
    • For other languages (or if you don’t want a colon at the end of the +paragraph), use .. code-block:: language and indent by three spaces as +with other directives.

    • +
    +
  • +
  • Use .. list-table:: to wrap tables with a lot of text in cells.

  • +
+
+
+
API documentation#
+

The source code is documented using Doxygen. If you add new API documentation +either to existing or new source files, make sure that you add the documented +source files to the doxygen_dependencies variable in +docs/CMakeLists.txt.

+
+
+
+

Module structure#

+

This section explains the structure of an HPX module.

+

The tool create_library_skeleton.py +can be used to generate a basic skeleton. To create a library skeleton, run the +tool in the libs subdirectory with the module name as an argument:

+
$ ./create_library_skeleton <lib_name>
+
+
+

This creates a skeleton with the necessary files for an HPX module. It will not create any actual source files. The structure of this skeleton is as follows:

+
    +
  • <lib_name>/

    +
      +
    • README.rst

    • +
    • CMakeLists.txt

    • +
    • cmake

    • +
    • docs/

      +
        +
      • index.rst

      • +
      +
    • +
    • examples/

      +
        +
      • CMakeLists.txt

      • +
      +
    • +
    • include/

      +
        +
      • hpx/

        +
          +
        • <lib_name>

        • +
        +
      • +
      +
    • +
    • src/

      +
        +
      • CMakeLists.txt

      • +
      +
    • +
    • tests/

      +
        +
      • CMakeLists.txt

      • +
      • unit/

        +
          +
        • CMakeLists.txt

        • +
        +
      • +
      • regressions/

        +
          +
        • CMakeLists.txt

        • +
        +
      • +
      • performance/

        +
          +
        • CMakeLists.txt

        • +
        +
      • +
      +
    • +
    +
  • +
+

A README.rst should be always included which explains the basic purpose of +the library and a link to the generated documentation.

+

A main CMakeLists.txt is created in the root directory of the module. By +default it contains a call to add_hpx_module which takes care of most of the +boilerplate required for a module. You only need to fill in the source and +header files in most cases.

+

add_hpx_module requires a module name. Optional flags are:

+

Optional single-value arguments are:

+
    +
  • INSTALL_BINARIES: Install the resulting library.

  • +
+

Optional multi-value arguments-are:

+
    +
  • SOURCES: List of source files.

  • +
  • HEADERS: List of header files.

  • +
  • COMPAT_HEADERS: List of compatibility header files.

  • +
  • DEPENDENCIES: Libraries that this module depends on, such as other modules.

  • +
  • CMAKE_SUBDIRS: List of subdirectories to add to the module.

  • +
+

The include directory should contain only headers that other libraries need. +For each of those headers, an automatic header test to check for self +containment will be generated. Private headers should be placed under the +src directory. This allows for clear separation. The cmake subdirectory +may include additional CMake scripts needed to generate the respective build +configurations.

+

Compatibility headers (forwarding headers for headers whose location is changed +when creating a module, if moving them from the main library) should be placed +in an include_compatibility directory. This directory is not created by +default.

+

Documentation is placed in the docs folder. A empty skeleton for the index +is created, which is picked up by the main build system and will be part of the +generated documentation. Each header inside the include directory will +automatically be processed by Doxygen and included into the documentation.

+

Tests are placed in suitable subdirectories of tests.

+

When in doubt, consult existing modules for examples on how to structure the +module.

+
+
Finding circular dependencies#
+

Our CI will perform a check to see if there are circular dependencies between +modules. In cases where it’s not clear what is causing the circular dependency, +running the cpp-dependencies tool manually can be helpful. It can give you +detailed information on exactly which files are causing the circular dependency. +If you do not have the cpp-dependencies tool already installed, one way of +obtaining it is by using our docker image. This way you will have exactly the +same environment as on the CI. See Using docker for development for details on how to use +the docker image.

+

To produce the graph produced by CI run the following command (HPX_SOURCE is +assumed to hold the path to the HPX source directory):

+
$ cpp-dependencies --dir $HPX_SOURCE/libs --graph-cycles circular_dependencies.dot
+
+
+

This will produce a dot file in the current directory. You can inspect this +manually with a text editor. You can also convert this to an image if you have +graphviz installed:

+
$ dot circular_dependencies.dot -Tsvg -o circular_dependencies.svg
+
+
+

This produces an svg file in the current directory which shows the circular +dependencies. Note that if there are no cycles the image will be empty.

+

You can use cpp-dependencies to print the include paths between two modules.

+
$ cpp-dependencies --dir $HPX_SOURCE/libs --shortest <from> <to>
+
+
+

prints all possible paths from the module <from> to the module <to>. For +example, as most modules depend on config, the following should give you a +long list of paths from algorithms to config:

+
$ cpp-dependencies --dir $HPX_SOURCE/libs --shortest algorithms config
+
+
+

The following should report that it can’t find a path between the two modules:

+
$ cpp-dependencies --dir $HPX_SOURCE/libs --shortest config algorithms
+
+
+
+
+
+
+
+
+
+

Releases#

+
+

List of releases#

+
+
+
HPX V1.10.0 (May 29, 2024)#
+
+
General changes#
+
    +
  • The HPX documentation has seen a major overhaul for this release. We finished +documenting the public local HPX API, we have added migration guides from widely +used parallelization platforms to HPX (OpenMP, TBB, and MPI).

  • +
  • We have added facilities enabling optimizations for trivially-relocatable types +(see P1144 for more details).

  • +
  • We have added (and use) the scope_xxx helper facilities as specified by the +C++ library fundamentals TS v3 (see: N4948).

  • +
  • We have added configuration options that allow to build HPX without pre-installing +any prerequisites. Use HPX_WITH_FETCH_HWLOC=On to have Portable Hardware Locality (HWLOC) installed for +you. Similarly, setting HPX_WITH_FETCH_BOOST=On during configuration time will +install the necessary Boost libraries (currently V1.84.0).

  • +
  • We have performed a lot of code cleanup and refactoring to improve the overall +code quality and decrease compile times.

  • +
  • The collective operations APIs have seen an unification, we have fixed issues and +performance problems for the collectives.

  • +
  • The HPX executors have seen a streamlining and some consistency changes. We have +applied many performance improvements to the executor implementations that directly +positively impact the performance of our parallel algorithms.

  • +
  • We have added a new parcelport allowing to use Gasnet as a communication platform.

  • +
  • We have added optimizations to various parcelports improving overall communication +performance. This includes - amongst other things - send immediate optimizations and +receiver-side zero-copy optimizations.

  • +
  • Futures will now execute the associated task eagerly and inline on any wait +operation if the task has not started running yet. This feature can be enabled +using the HPX_COROUTINES_WITH_THREAD_SCHEDULE_HINT_RUNS_AS_CHILD=On configuration +setting (which is Off by default).

  • +
  • We have enabled using json files to supply configuration information through the +command line. This feature can be enabled with the configuration option +HPX_COMMAND_LINE_HANDLING_WITH_JSON_CONFIGURATION_FILES=On. This functionality +depends on the external JSon library, which +can be built at configuration time by supplying HPX_WITH_FETCH_JSON=On to +CMake.

  • +
  • We have applied many fixes to our CUDA, ROCm, and SYCL build environments.

  • +
+
+
+
Breaking changes#
+
    +
  • The CMake configuration keys SOMELIB_ROOT (e.g., BOOST_ROOT) have been +renamed to Somelib_ROOT (e.g., Boost_ROOT) to avoid warnings when using +newer versions of CMake. Please update your scripts accordingly. For now, the +old variable names are re-assigned to the new names and unset in the CMake +cache.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #6466 - No access limitations to Wiki

  • +
  • Issue #6461 - handle_received_parcels may never return

  • +
  • Issue #6459 - Building HPX

  • +
  • Issue #6451 - HPX hangs at the very end

  • +
  • Issue #6446 - Issue on page /manual/getting_hpx.html

  • +
  • Issue #6443 - PR #6435 (parcel_layer_tweaks) broke Octo-Tiger

  • +
  • Issue #6440 - HPX does not compile with MSVC of Visual Studio 2022 17.9+

  • +
  • Issue #6437 - HPX 1.9.1 does not compile on Fedora with ‘#pragma message: [Parallel STL message]: “Vectorized algorithm unimplemented, redirected to serial

  • +
  • Issue #6419 - Enhancement of the macro functionalities within hpx

  • +
  • Issue #6417 - The current HPX master branch is still not compatible with Kokkos 4.0.1

  • +
  • Issue #6414 - Current HPX master causes segfaults within Octo-Tiger

  • +
  • Issue #6412 - Clangd (Language Server) throws error for __integer_pack at pack.hpp

  • +
  • Issue #6407 - Cannot build Kokkos 4.0.01 with current HPX master

  • +
  • Issue #6405 - Spack Build Error with ROCm 5.7.0

  • +
  • Issue #6398 - HPX sets affinity wrong with multiple processes per node and LCI parcelport enabled

  • +
  • Issue #6392 - [Feature] Install dependencies using CMake

  • +
  • Issue #6388 - HPX error: “Host not found” when running on Expanse with 128 nodes

  • +
  • Issue #6366 - serialize_buffer allocator support needs adjustments

  • +
  • Issue #6361 - HPX 1.9.1 does not compile on Fedora 40

  • +
  • Issue #6355 - Single page documentation is broken

  • +
  • Issue #6334 - Segmentation fault after adding a padding in one_size_heap_list

  • +
  • Issue #6329 - Log hpx threads on forced shutdown

  • +
  • Issue #6316 - Build breaks on FreeBSD

  • +
  • Issue #6299 - HPX does not use distributed localities on Fugaku

  • +
  • Issue #6298 - Update config for coroutines on ARM

  • +
  • Issue #6291 - Zero-copy receive optimization disabled the invocation of direct actions

  • +
  • Issue #6261 - Add optional reading of json files for command line options

  • +
  • Issue #6087 - Support for vcpkg on Linux is broken

  • +
  • Issue #5921 - hpx::info claims that async_mpi was not built, while cmake assures its existence

  • +
  • Issue #5893 - Tests fail on FreeBSD: Executable copyn_test does not exist

  • +
  • Issue #5833 - barrier lockup

  • +
  • Issue #5799 - Investigate CUDA compilation problems

  • +
  • Issue #5340 - Examples do not run on Mac OSX using the M1 chip

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #6493 - Fix distributed latch documentation

  • +
  • PR #6492 - Fix kokkos hpx nvcc compilation

  • +
  • PR #6491 - More fixes to handling bool arguments for collective operations

  • +
  • PR #6490 - Remove the default max cpu count

  • +
  • PR #6489 - Ensure TCP parcelport is deactivated if not needed

  • +
  • PR #6488 - Fixing handling of bool value type for collective operations

  • +
  • PR #6485 - Destructive interference size

  • +
  • PR #6484 - Improve performance counter error handling

  • +
  • PR #6482 - Generalize the notion of bitwise serialization

  • +
  • PR #6481 - Fixing use of HPX_WITH_CXX_STANDARD

  • +
  • PR #6480 - Remove equal_to from hpx::any

  • +
  • PR #6479 - Remove optimizations for certain built-in compiler intrinsics

  • +
  • PR #6478 - Fixing issues on MacOS

  • +
  • PR #6477 - lci pp: lci’s github repo name changed from LC to lci

  • +
  • PR #6476 - Fixing binary filter test target names

  • +
  • PR #6475 - Fix mac os github actions

  • +
  • PR #6472 - Troubleshoot CI hangs

  • +
  • PR #6469 - improve(lci pp): more options to control the LCI parcelport

  • +
  • PR #6467 - Bump jwlawson/actions-setup-cmake from 1.14 to 2.0

  • +
  • PR #6464 - Update docs of “Writing distributed applications” page

  • +
  • PR #6463 - Revert “Always return outermost thread id”

  • +
  • PR #6458 - Reduce test workload to fix CI/CD time-out

  • +
  • PR #6457 - replace boost::array with std::array and update file name

  • +
  • PR #6456 - Move APEX CI to rostam

  • +
  • PR #6455 - Fixing compilation if HPX_HAVE_THREAD_QUEUE_WAITTIME is defined

  • +
  • PR #6454 - Update perftests reference measurements

  • +
  • PR #6453 - Update supported platforms of Manual/Prerequisites page

  • +
  • PR #6452 - Fix nvcc crashes in transform_stream.cu and synchronize.cu

  • +
  • PR #6450 - Fix git tag name in Getting HPX page

  • +
  • PR #6449 - LCI parcelport: add yield to potentially infinite retry loop

  • +
  • PR #6447 - Use compressed ptr in schedulers when 128 atomics are not lockfree

  • +
  • PR #6445 - Fix agas addressing cache

  • +
  • PR #6444 - Update CTestConfig.cmake

  • +
  • PR #6442 - Update CMakeLists.txt

  • +
  • PR #6441 - Minor documentation fixes

  • +
  • PR #6439 - Optimizing use of certain #includes

  • +
  • PR #6438 - Bump jwlawson/actions-setup-cmake from 1.14 to 2.0

  • +
  • PR #6436 - Update docs

  • +
  • PR #6435 - Parcel layer tweaks

  • +
  • PR #6434 - improve termination detection: removing lock from critical path

  • +
  • PR #6433 - Use shared mutex for resolve_locality procedure

  • +
  • PR #6432 - Module cleanup up to level 30

  • +
  • PR #6429 - Making sure HPX_WITH_ASYNC_MPI is reported properly

  • +
  • PR #6427 - Modifying CMakeLists to copy libhwloc-15.dll to the binary folder in Windows, independently

  • +
  • PR #6425 - Fix macOS failing test

  • +
  • PR #6424 - Adding option for downloading Boost using CMake FetchContent

  • +
  • PR #6423 - Move adjacent_difference to numeric header file

  • +
  • PR #6422 - Adding steal-half functionalities to work-requesting scheduler

  • +
  • PR #6421 - Bump actions/checkout from 2 to 4

  • +
  • PR #6418 - Working around nvcc problems to use CTAD

  • +
  • PR #6416 - Change run_as_os_thread deprecation forwarding due to hipcc compilation issue

  • +
  • PR #6415 - Attempting to avoid segfault in OctoTiger during initialization

  • +
  • PR #6413 - Always return outermost thread id

  • +
  • PR #6411 - Minor refactoring and fixes to the LCI parcelport and pingpong_performance2 benchmark

  • +
  • PR #6410 - Adding scope_xxx from library fundamentals TS v3

  • +
  • PR #6409 - Working around CUDA issue

  • +
  • PR #6408 - Tightening up collective operation semantics

  • +
  • PR #6406 - Working around ROCm compiler issue

  • +
  • PR #6404 - Allow to disable use of [[no_unique_address]] attribute

  • +
  • PR #6403 - Fixing copyright year

  • +
  • PR #6402 - fix(lci pp): fix deadlocks with too many failed sends

  • +
  • PR #6401 - fix(lci pp): fix the null_thread_id bug in the LCI parcelport

  • +
  • PR #6400 - Fix the affinity setting bug when using LCI pp and multiple localities per node

  • +
  • PR #6397 - Change API header titles and info

  • +
  • PR #6396 - Making is_bitwise_serializable SFINAE-friendly

  • +
  • PR #6395 - Adapt amount of collective testing

  • +
  • PR #6394 - Adding option for installing Hwloc using CMake FetchContent

  • +
  • PR #6393 - Optionally disable caching allocator

  • +
  • PR #6391 - Cleaning up collective operations

  • +
  • PR #6390 - Making function local constexpr variables non-static

  • +
  • PR #6389 - Disable resolving hostnames if TCP is disabled

  • +
  • PR #6387 - Need to break out of the loop when searching the suffixes.

  • +
  • PR #6384 - Fixing allocation/deallocation mismatch in serialize_buffer

  • +
  • PR #6383 - Enable fork_join_executor to handle return values from scheduled functions

  • +
  • PR #6381 - Consistently treat conflicting parameters provided by executors and parameter objects

  • +
  • PR #6380 - Fixing setting an annotation for an execution policy

  • +
  • PR #6378 - Allowing to disable signal handlers

  • +
  • PR #6377 - Fix gasnet-related test failures

  • +
  • PR #6375 - Update LSU Jenkins with 2023-10 libraries

  • +
  • PR #6374 - Investigate builder gasnet failure

  • +
  • PR #6373 - Fixing communicator API, adding docs

  • +
  • PR #6372 - Fix resource partitioner tests for small thread count

  • +
  • PR #6371 - Fix jacobi omp examples.

  • +
  • PR #6370 - improve one_size_heap_list: use rwlock to speedup the allocation/free

  • +
  • PR #6369 - working issue with MPI_CC / CC conflict in automake

  • +
  • PR #6368 - Making sure serialize_buffer properly destroys buffer, if needed.

  • +
  • PR #6367 - Fix parallel relocation test

  • +
  • PR #6364 - Relocation variants

  • +
  • PR #6363 - Update the lci parcelport to use LCI v1.7.6

  • +
  • PR #6362 - Fixing compilation problems on 32 Linux systems

  • +
  • PR #6360 - Fix broken links in docs: PDF, Single HTML page, Dependency report

  • +
  • PR #6359 - Fix header file links in Public API page

  • +
  • PR #6358 - Fix CMake find_library for HWLOC

  • +
  • PR #6357 - Replace Custom Benchmarking Code with Nanobench

  • +
  • PR #6356 - Fixed matrix multiplication example output

  • +
  • PR #6354 - Fix broken links for header files in Public API page

  • +
  • PR #6353 - Enable using std::reference_wrapper with executor parameters

  • +
  • PR #6352 - Add Public distributed API documentation

  • +
  • PR #6350 - Make coverage work with Jenkins Github Branch Source plugin

  • +
  • PR #6349 - Moving hpx::threads::run_as_xxx to namespace hpx

  • +
  • PR #6348 - Adding –exclusive to launching tests on rostam

  • +
  • PR #6346 - changed chat link to discord

  • +
  • PR #6344 - uninitialized_relocate w/ type_support primitive

  • +
  • PR #6343 - Bump actions/checkout from 3 to 4

  • +
  • PR #6342 - Fix HPX-APEX cmake integration

  • +
  • PR #6341 - Fix shared_future_continuation_order regression test

  • +
  • PR #6340 - Log alive hpx threads on exit

  • +
  • PR #6339 - Add coverage testing on Jenkins

  • +
  • PR #6338 - Fixing HPX_CURRENT_SOURCE_LOCATION when std::source_location exists

  • +
  • PR #6337 - Remove aurianer, biddisco, and msimberg from codeowners

  • +
  • PR #6336 - More cleaning up for module levels 19-20

  • +
  • PR #6335 - Finalize the MPI docs of the Migration Guide

  • +
  • PR #6332 - More fixes for CMake V3.27

  • +
  • PR #6330 - Adding basic logging to collective operations

  • +
  • PR #6328 - Cleanup previous patch adapting to CMake V3.27

  • +
  • PR #6327 - Modernize modules in level 17 and 18

  • +
  • PR #6324 - P1144 Relocation primitives

  • +
  • PR #6321 - Ensure hpx_main is a proper thread_function

  • +
  • PR #6320 - Fixing cyclic dependencies in naming and agas modules

  • +
  • PR #6319 - Generate git tag if needed but it is not available

  • +
  • PR #6317 - Fixing linker problem on FreeBSD

  • +
  • PR #6315 - acknowledge triv-rel and nothrow-rel types

  • +
  • PR #6314 - Relocation algorithms Clean

  • +
  • PR #6313 - Trivial relocation of c-v-ref-array types

  • +
  • PR #6312 - Fixing warning/error

  • +
  • PR #6311 - Adding executor parallel invoke CPOs

  • +
  • PR #6310 - Define HPX_COMPUTE_CODE in builds with SYCL

  • +
  • PR #6309 - Making sure changed number of cores is propagated to executor

  • +
  • PR #6308 - openshmem-parcelport initial import

  • +
  • PR #6306 - The hpxcxx script was broken such that it could only compile for _release

  • +
  • PR #6305 - Adapting build system for CMake V3.27

  • +
  • PR #6304 - Fixing an integral type mismatch warning

  • +
  • PR #6303 - omp for default vectorization

  • +
  • PR #6301 - Add MPI migration guide

  • +
  • PR #6294 - Add internal reference counting to semaphores

  • +
  • PR #6286 - Simd helpers

  • +
  • PR #6280 - Add TBB to HPX documentation in Migration Guide

  • +
  • PR #6276 - Add dependabot.yml

  • +
  • PR #6275 - Revert “Move dependabot.yml into correct directory”

  • +
  • PR #6272 - set thread name for linux

  • +
  • PR #6271 - Uninitialised algorithms, move using std::memcpy

  • +
  • PR #6270 - Bump jwlawson/actions-setup-cmake from 1.9 to 1.14

  • +
  • PR #6269 - Bump actions/checkout from 2 to 3

  • +
  • PR #6268 - Move dependabot.yml into correct directory

  • +
  • PR #6265 - Create dependabot.yml

  • +
  • PR #6264 - hpx::is_trivially_relocatable trait implementation

  • +
  • PR #6263 - Adding support for reading json configuration files for command line options

  • +
  • PR #6249 - Implement the send immediate optimization for the MPI parcelport.

  • +
  • PR #6237 - Improve compilation performance

  • +
  • PR #6234 - Adding release notes page for next release

  • +
  • PR #6233 - Moving is_relocatable to namespace hpx

  • +
  • PR #6230 - gasnet based parcelport

  • +
  • PR #6226 - Re-enable dependency on segmented algorithms on CircleCI

  • +
  • PR #6220 - Add execution on

  • +
  • PR #6212 - Initial trait definition for relocatable

  • +
  • PR #6199 - added support for unseq, par_unseq for hpx::make_heap algorithm

  • +
  • PR #6173 - C++ modules

  • +
  • PR #6122 - Add Module support

  • +
  • PR #6099 - Futures attempt to execute threads directly if those have not started executing

  • +
  • PR #6050 - Investigating partitioned_vector problems

  • +
  • PR #5988 - Adding CI configuration for DGX-A100 at LSU

  • +
  • PR #5910 - Improve MPI initialization

  • +
  • PR #5845 - Adding local work requesting scheduler that is based on message passing internally

  • +
+
+
+
+
HPX V1.9.1 (August 4, 2023)#
+
+
General changes#
+

This point release fixes a couple of problems reported for the V1.9.0 release. +Most importantly, we fixed various occasional hanging during startup and shutdown +in distributed scenarios. We also added support for zero-copy serialization on +the receiving side to the TCP, MPI, and LCI parcelports. Last but not least, we +have added support for Visual Studio 2019 and gcc using MINGW on Windows, and +also support for gcc V13 and clang V15.

+

HPX headers are now made consistently named the same as their standard library +counterparts, e.g. #include <thread> now corresponds to #include <hpx/thread.hpp>. +This significantly simplifies porting existing standards conforming codes to HPX.

+

A lot of work has been done to improve and optimize our network communication +layers. Primary focus of this work was on the LCI parcelport, but we have also +cleaned up and improved the MPI parcelport.

+

Additionally, we have continued working on our documentation. The main focus +here was on completing the API documentation of the most important API functions. +We have started adding migration guides for people interested in moving their +codes away from other, commonplace parallelization frameworks like OpenMP.

+
+
+
Breaking changes#
+

None

+
+
+
Closed issues#
+
    +
  • Issue #6155 - hpxcxx and hpxrun.py do not work if HPX_WITH_TESTS=OFF

  • +
  • Issue #6164 - HPX_WITH_DATAPAR_BACKEND=EVE causes compile errors with C++17

  • +
  • Issue #6175 - Make sure all our parallel algorithms accept the predicates by value

  • +
  • Issue #6194 - tests.regressions.threads.threads_all_1422 failed at Perlmutter

  • +
  • Issue #6198 - set_intersection/set_difference fails when run with execution::par

  • +
  • Issue #6214 - Broken Links to the Documentation page in readme.rst

  • +
  • Issue #6217 - hpx::make_heap does not terminate when exPolicy is par (or par_unseq) and size of vector is 4

  • +
  • Issue #6246 - HPX fails to compile under cxx 20 (fresh system)

  • +
  • Issue #6247 - HPX 1.9.0 does not compile with GCC on Windows

  • +
  • Issue #6282 - The “attach-debugger” option is broken on the current master branch.

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #6219 - Cleaning up #includes in hpx/ folder

  • +
  • PR #6223 - Move documentation from README.rst to index.rst files under libs directory

  • +
  • PR #6229 - Adding zero-copy support on the receiving end of the TCP and MPI parcel ports

  • +
  • PR #6231 - Remove deprecated email from release procedure

  • +
  • PR #6235 - Modernize more modules (levels 12-16)

  • +
  • PR #6236 - Attempt to resolve occasional shutdown hangs in distributed operation

  • +
  • PR #6239 - Fix Optimizing HPX applications page of Manual

  • +
  • PR #6241 - LCI parcelport: Refactor, add more variants, zero copy receives.

  • +
  • PR #6242 - updated deprecated headers

  • +
  • PR #6243 - Adding github action builders using VS2019

  • +
  • PR #6248 - Fix CUDA/HIP Jenkins pipelines

  • +
  • PR #6250 - Resolve gcc problems on Windows

  • +
  • PR #6251 - Attempting to fix problems in barrier causing hangs

  • +
  • PR #6253 - Modernize set_thread_name on Windows

  • +
  • PR #6256 - Fix nvcc/gcc-10 (Octo-Tiger) compilation issue

  • +
  • PR #6257 - Cmake Tests: Delete operator check for size_t arg

  • +
  • PR #6258 - Rewriting wait_some to circumvent data races causing hangs

  • +
  • PR #6260 - Add migration guide to manual

  • +
  • PR #6262 - Fixing wrong command line options in local command line handling

  • +
  • PR #6266 - Attempt to resolve occasional hang in run_loop

  • +
  • PR #6267 - Attempting to fix migration tests

  • +
  • PR #6278 - Making sure the future’s shared state doesn’t go out of scope prematurely

  • +
  • PR #6279 - Re-expose error names

  • +
  • PR #6281 - Creating directory for file copy

  • +
  • PR #6283 - Consistently #include unistd.h for _POSIX_VERSION

  • +
+
+
+
+
HPX V1.9.0 (May 2, 2023)#
+
+
General changes#
+
    +
  • Added RISC-V 64bit support. HPX is now compatible with RISC-V +architectures which have revolutionized the HPC world.

  • +
  • LCI parcelport has been optimized to transfer parcels with +fewer messages and use the HPX resource partitioner for +its progress thread allocation. It should generally provide +better performance than before. It also removes its dependency +on the MPI library.

  • +
  • HPX dependency on Boost was further relaxed by replacing headers +from Boost.Range, Boost.Tokenizer and Boost.Lockfree.

  • +
  • Improvements took place on our parallel algorithms implementation.

  • +
  • Our Senders/Receivers (P2300) integration was extended:

    +
      +
    • Coroutines were integrated with senders/receivers.

    • +
    +

    get_completion_signatures now works with awaitable senders. +- with_awaitable_senders allows the passed senders to +retrieve the value i.e. senders are transparently +awaitable from within a coroutine. +- when_all_vector was added.

    +
  • +
  • sync_wait and sync_wait_with_variant sender consumers were +added. The user can now initiate the execution of +their asynchronous pipeline by blocking the current thread that +executes the main() function until the result is retrieved.

  • +
  • The combinators for futures (a.k.a. async_combinators) when_*, +wait_*, wait_*_nothrow were turned into CPOs allowing for +end-user customization. For more information on the async_combinators +refer to the documentation, +https://hpx-docs.stellar-group.org/latest/html/libs/core/async_combinators/docs/index.html?highlight=combinators.

  • +
  • The new datapar backend SVE allows simd and par_simd execution policies +to exploit dataparalleism in the processors that have SVE vector +registers like A64FX and Neoverse V1.

  • +
  • The documentation for parallel algorithms, container algorithms was +further improved. The Public API page was vastly enriched.

  • +
  • Copy button shortkey was added at the top-right of code-blocks.

  • +
  • Pragma directive that reports warnings as errors on MSVC was fixed.

  • +
  • Command line argument --hpx:loopback_network was added to +facilitie debugging with networks.

  • +
  • We added an HPX-SYCL integration, allowing users to obtain HPX futures +for SYCL events. This effectively enables the integration of arbitrary +asynchronous SYCL operations into the HPX task graph. Bolted on top +of this integration, we further added an HPX-SYCL executor for ease of use.

  • +
+
+
+
Breaking changes#
+
    +
  • Stopped supporting Clang V8, the minimal version supported is now Clang V10.

  • +
  • Stopped supporting gcc V8, the minimal version supported is now gcc V9.

  • +
  • Stopped supporting Visual Studio 2015, the minimal version supported is +now Visual Studio 2019.

  • +
  • tag_policy_tag et.al. were re-added after HPX V1.8.1 depracation.

  • +
  • get_chunk_size and processing_units_count API is now expecting +the time for one iteration as an argument.

  • +
  • The list of all the namespace changes can be found here: HPX V1.9.0 Namespace changes.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #6203 - Compilation error with -mcpu=a64fx on Ookami

  • +
  • Issue #6196 - Incorrect log destination

  • +
  • Issue #6191 - installing HPX

  • +
  • Issue #6184 - Wrong processing_units_count of restricted_thread_pool_executor

  • +
  • Issue #6171 - Release Tag Name Request

  • +
  • Issue #6162 - Current master does not compile on ROSTAM

  • +
  • Issue #6156 - hpxcxx does not work if HPX_WITH_PKGCONFIG=OFF

  • +
  • Issue #6108 - cxx17_aligned_new.cpp on msvc fails due to wrong pragma directive

  • +
  • Issue #6045 - Can’t call nullary callables wrapped with hpx::unwrapping

  • +
  • Issue #6013 - Unable to build subprojects hpx_collectives/hpx_compute with MSVC

  • +
  • Issue #6008 - Missing constexpr default constructor for hpx::mutex

  • +
  • Issue #5999 - Add HPX Conda package to conda-forge

  • +
  • Issue #5998 - Serializing multiple arguments when applying distributed action results in segfault

  • +
  • Issue #5958 - HPX 1.8.0 and Blaze issues

  • +
  • Issue #5908 - Windows: duplicated symbols in static builds

  • +
  • Issue #5802 - Lost status is_ready from future

  • +
  • Issue #5767 - Performance drop on Piz Daint

  • +
  • Issue #5752 - Implement stride_view from P1899 (experimental)

  • +
  • Issue #5744 - HPX_WITH_FETCH_ASIO not working on Ookami

  • +
  • Issue #5561 - Possible race condition in helper thread / hpx::cout

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #6228 - Fixing algorithms for zero length sequences when run with s/r scheduler

  • +
  • PR #6227 - Reliably disable background work when no networking is enabled

  • +
  • PR #6225 - Make heap fails in par for small sized heaps #6217

  • +
  • PR #6222 - Add documentation for hpx::post

  • +
  • PR #6221 - Fix segmented algorithms tests

  • +
  • PR #6218 - Creating INSTALL component ‘runtime’ to enable installing binaries only

  • +
  • PR #6216 - added tests for set_difference, updated set_operation.hpp to fix #6198

  • +
  • PR #6213 - Modernize and streamline MPI parcelport

  • +
  • PR #6211 - Modernize modules of level 11, 12, and 13

  • +
  • PR #6210 - Fixing MPI parcelport initialization if MPI is initialized outside of HPX

  • +
  • PR #6209 - Prevent thread stealing during scheduler shutdown

  • +
  • PR #6208 - Fix the compilation warning in the MPI parcelport with gcc 11.2

  • +
  • PR #6207 - Automatically enable Boost.Context when compiling for arm64.

  • +
  • PR #6206 - Update CMakeLists.txt

  • +
  • PR #6205 - Do not generate hpxcxx if support for pkgconfig was disabled

  • +
  • PR #6204 - Use LRT_ instead of LAPP_ logging in barrier implementation

  • +
  • PR #6202 - Fixing Fedora build errors on Power systems

  • +
  • PR #6201 - Update the LCI parcelport documents

  • +
  • PR #6200 - Par link jobs

  • +
  • PR #6197 - LCI parcelport: add doc, upgrade to v1.7.4, refactor cmake autofetch.

  • +
  • PR #6195 - Change the default tag of autofetch LCI to v1.7.3.

  • +
  • PR #6192 - Fix page Writing single-node applications

  • +
  • PR #6189 - Making sure restricted_thread_pool_executor properly reports used number of cores

  • +
  • PR #6187 - Enable using for_loop with range generators

  • +
  • PR #6186 - thread_support/CMakeLists: Fix build issue

  • +
  • PR #6185 - Fix EVE datapar with cxx_standard less than 20

  • +
  • PR #6183 - Update CI integration for EVE

  • +
  • PR #6182 - Fixing performance regressions

  • +
  • PR #6181 - LCI parcelport: backlog queue, aggregation, separate devices, and more

  • +
  • PR #6180 - Fixing use of for_loop with rebound execution policy (using .with())

  • +
  • PR #6179 - Taking predicates for algorithms by value

  • +
  • PR #6178 - Changes needed to make chapel_hpx examples work

  • +
  • PR #6176 - Fixing warnings that were generated by PVS Studio

  • +
  • PR #6174 - Replace boost::integer::gcd with std::gcd

  • +
  • PR #6172 - [Docs] Fix example of how to run single/specific test(s)

  • +
  • PR #6170 - Adding missing fallback for processing_units_count customization point

  • +
  • PR #6169 - LCI parcelport: bypass the parcel queue and connection cache.

  • +
  • PR #6167 - Add create_local_communicator API function

  • +
  • PR #6166 - Add missing header for std::intmax_t

  • +
  • PR #6165 - Attempt to work around MSVC problem

  • +
  • PR #6161 - Update EVE integration

  • +
  • PR #6160 - More cleanup for module levels 0 to 10

  • +
  • PR #6159 - Fix minor spelling mistake in generate_issue_pr_list.sh

  • +
  • PR #6158 - Update documentation in writing single-node applications page

  • +
  • PR #6157 - Improve index_queue_spawning

  • +
  • PR #6154 - Avoid performing late command line handling twice in distributed runtime

  • +
  • PR #6152 - The -rd and -mr options didn’t work, and they should have been –rd and –mr

  • +
  • PR #6151 - Refactoring the Manual page in documentation

  • +
  • PR #6148 - Investigate the failure of the LCI parcelport.

  • +
  • PR #6147 - Make posix co-routine stacks non-executable

  • +
  • PR #6146 - Avoid ambiguities wrt tag_invoke

  • +
  • PR #6144 - General improvements to scheduling and related fixes

  • +
  • PR #6143 - Add list of new namespaces for new release

  • +
  • PR #6140 - Fixing background scheduler to properly exit in the end

  • +
  • PR #6139 - [P2300] execution: Cleanup coroutines integration and improve ADL isolation

  • +
  • PR #6137 - Adding example of a simple master/slave distributed application

  • +
  • PR #6136 - Deprecate execution::experimental::task_group in favor of experimental::task_group

  • +
  • PR #6135 - Fixing warnings reported by MSVC analysis

  • +
  • PR #6134 - Adding notification function for parcelports to be called after early parcel handling

  • +
  • PR #6132 - Fixing to_non_par() for parallel simd policies

  • +
  • PR #6131 - modernize modules from level 25

  • +
  • PR #6130 - Remove the mutex lock in the critical path of get_partitioner.

  • +
  • PR #6129 - Modernize module from levels 22, 23

  • +
  • PR #6127 - Working around gccV9 problem that prevent us from storing enum classes in bit fields

  • +
  • PR #6126 - Deprecate hpx::parallel::task_block in favor of hpx::experimental::ta…

  • +
  • PR #6125 - Making sure sync_wait compiles when used with an lvalue sender involving bulk

  • +
  • PR #6124 - Fixing use of any_sender in combination with when_all

  • +
  • PR #6123 - Fixed issues found by PVS-Studio

  • +
  • PR #6121 - Modernize modules of level 21, 22

  • +
  • PR #6120 - Use index_queue for parallel executors bulk_async_execute

  • +
  • PR #6119 - Update CMakeLists.txt

  • +
  • PR #6118 - Modernize modules from level 17, 18, 19, and 20

  • +
  • PR #6117 - Initialize buffer_allocate_time_ to 0

  • +
  • PR #6116 - Add new command line argument –hpx:loopback_network

  • +
  • PR #6115 - Modernize modules of levels 14, 15, and 16

  • +
  • PR #6114 - Enhance the formatting of the documentation

  • +
  • PR #6113 - Modernize modules in module level 11, 12, and 13

  • +
  • PR #6112 - Modernize modules from levels 9 and 10

  • +
  • PR #6111 - Modernize all modules from module level 8

  • +
  • PR #6110 - Use pragma error directive to report warnings as errors on msvc

  • +
  • PR #6109 - Modernize serialization module

  • +
  • PR #6107 - Modernize error module

  • +
  • PR #6106 - Modernizing modules of levels 0 to 5

  • +
  • PR #6105 - Optimizations on LCI parcelport: merge small messages; remove sender mutex lock.

  • +
  • PR #6104 - Adding parameters API: measure_iteration

  • +
  • PR #6103 - Document task_group and include in Public API

  • +
  • PR #6102 - Prevent warnings generated by clang-cl

  • +
  • PR #6101 - Using more fold expressions

  • +
  • PR #6100 - Deprecate hpx::parallel::reduce_by_key in favor of hpx::experimental::reduce_by_key

  • +
  • PR #6098 - Forking Boost.Lockfree

  • +
  • PR #6096 - Forking Boost.Tokenizer

  • +
  • PR #6095 - Replacing facilities from Boost.Range

  • +
  • PR #6094 - Removing object_semaphore

  • +
  • PR #6093 - Replace boost::string_ref with std::string_view

  • +
  • PR #6092 - Use C++17 static_assert where possible

  • +
  • PR #6091 - Replace artificial sequencing with fold expressions

  • +
  • PR #6090 - Fixing use of get_chunk_size customization point

  • +
  • PR #6088 - Add/fix Public API documentation

  • +
  • PR #6086 - Deprecate hpx::util::unlock_guard in favor of hpx::unlock_guard

  • +
  • PR #6085 - Add experimental sycl integration/executor

  • +
  • PR #6084 - Renaming hpx::apply and friends to hpx::post

  • +
  • PR #6083 - Using if constexpr instead of tag-dispatching, where possible

  • +
  • PR #6082 - Replace util::always_void_t with std::void_t

  • +
  • PR #6081 - Update github actions to avoid warnings

  • +
  • PR #6080 - Disable some tests that fail on LCI

  • +
  • PR #6079 - Adding more natvis files, correct existing

  • +
  • PR #6078 - Changing target name of memory_counters component

  • +
  • PR #6077 - Making default constructor of hpx::mutex constexpr

  • +
  • PR #6076 - Cleaning up functionality that was deprecated in V1.7

  • +
  • PR #6075 - Remove conditional code for gcc V7 and below

  • +
  • PR #6074 - Fixing compilation issues on gcc V8

  • +
  • PR #6073 - Fixing PAPI counter component compilation

  • +
  • PR #6072 - Adding ex::when_all_vector

  • +
  • PR #6071 - Making get_forward_progress_guarantee_t specializations constexpr

  • +
  • PR #6070 - Implement P2690 for our algorithms

  • +
  • PR #6069 - Do not check for cancellation during each iteration but only once per partition

  • +
  • PR #6068 - Prevent using task and non_task as a CPO

  • +
  • PR #6067 - Deprecated hpx::util::mem_fn in favor of hpx::mem_fn

  • +
  • PR #6066 - Create codeql.yml

  • +
  • PR #6064 - Adapting adjacent_difference for S/R execution

  • +
  • PR #6063 - Modernize iterator_support module

  • +
  • PR #6062 - Make sure wrapping executor does not go out of scope prematurely

  • +
  • PR #6061 - Minor fix in small_vector (from upstream)

  • +
  • PR #6060 - Allow to disable registering signal handlers

  • +
  • PR #6059 - [P2300] Fix: declval cannot be ODR used

  • +
  • PR #6058 - Avoid ambiguity for hpx::get used with std::variant

  • +
  • PR #6057 - Create a dedicated thread pool to run LCI_progress.

  • +
  • PR #6056 - Fix coroutine test for clang

  • +
  • PR #6055 - Patches needed to be able to build HPX 1.8.1 on various platforms

  • +
  • PR #6054 - Use MSVC specific attribute [[msvc::no_unique_address]]

  • +
  • PR #6052 - Deprecated hpx::util::invoke_fused in favor of hpx::invoke_fused

  • +
  • PR #6051 - Add non-contiguous index queue and use it in thread_pool_bulk_scheduler

  • +
  • PR #6049 - Crosscompile arm sve

  • +
  • PR #6048 - Deprecated hpx::util::invoke in favor of hpx::invoke

  • +
  • PR #6047 - Separating binary_semaphore into its own file

  • +
  • PR #6046 - Support using unwrapping with nullary function objects

  • +
  • PR #6044 - Generalize the use of then() and dataflow

  • +
  • PR #6043 - Clean up scan_partitioner

  • +
  • PR #6042 - Modernize dataflow API

  • +
  • PR #6041 - docs: document semaphores

  • +
  • PR #6040 - Add/Fix documentation of Public API page

  • +
  • PR #6039 - remove MPI dependency when only using LCI parcelport

  • +
  • PR #6038 - Clean up command line handling

  • +
  • PR #6037 - Avoid performing parcel related background work if networking is disabled

  • +
  • PR #6036 - Support new datapar backend : SVE

  • +
  • PR #6035 - Simplify datapar replace copy if

  • +
  • PR #6034 - Add/Fix documentation of Public API

  • +
  • PR #6033 - Support for data-parallelism for replace, replace_if, replace_copy, replace_copy_if algorithms

  • +
  • PR #6032 - Add documentation in public API

  • +
  • PR #6031 - Expose available cache sizes from topology object

  • +
  • PR #6030 - Adding parcelport initialization hook for resource partitioner operation

  • +
  • PR #6029 - Simplify startup code

  • +
  • PR #6027 - Add/Fix documentation in Public API page

  • +
  • PR #6026 - add option hpx:force_ipv4 to force resolving hostnames to ipv4 adresses

  • +
  • PR #6025 - build(docs): remove leftover sections

  • +
  • PR #6023 - Minor fixes on “How to build on Windows”

  • +
  • PR #6022 - build(doxy): don’t extract private members

  • +
  • PR #6021 - Adding pu_mask to thread_pool_bulk_scheduler

  • +
  • PR #6020 - docs: add cppref NamedRequirements support

  • +
  • PR #6018 - Unseq adaptation for for_each, transform, reduce, transform_reduce, etc.

  • +
  • PR #6017 - loop and transform_loop unseq adaptation

  • +
  • PR #6016 - Config and structural updates to support unseq implementation

  • +
  • PR #6015 - Integrating sync_wait & sync_wait_with_variant

  • +
  • PR #6012 - docs: add missing links to public api

  • +
  • PR #6009 - Fixing sender&receiver integration with for_each and for_loop

  • +
  • PR #6007 - docs: add docs for mutex.hpp

  • +
  • PR #6006 - Relax future::is_ready where possible

  • +
  • PR #6005 - reshuffle header tests to different instances

  • +
  • PR #6004 - Add documentation Public API

  • +
  • PR #6003 - Always exporting get_component_name implementations

  • +
  • PR #6002 - Making sure that default constructble arguments are properly constructed during deserialization

  • +
  • PR #5996 - Add back explicit template parameters to lock_guards for nvcc

  • +
  • PR #5994 - Fix CTRL+C on windows

  • +
  • PR #5993 - Using EVE requires C++20

  • +
  • PR #5992 - This properly terminates an application on Ctrl-C on Windows

  • +
  • PR #5991 - Support IPV6 on command line for explicit network initialization

  • +
  • PR #5990 - P2300 enhancements

  • +
  • PR #5989 - Fix missing documentation in Public API page

  • +
  • PR #5987 - Attempting to fix timed executor API

  • +
  • PR #5986 - Fix warnings when building docs

  • +
  • PR #5985 - Re-add deprecated tag_policy_tag et.al. types that were removed in V1.8.1

  • +
  • PR #5981 - docs: add docs for condition_variable.hpp

  • +
  • PR #5980 - More work on execution::read

  • +
  • PR #5979 - Unsupport clang-v8 and clang-v9, switch LSU clang-v13 to C++17

  • +
  • PR #5977 - fix: Compilation errors for -std=c++17 builders

  • +
  • PR #5975 - docs: fix & improve parallel algorithms documentation 5

  • +
  • PR #5974 - [P2300] Adapt get completion signatures for awaitable senders

  • +
  • PR #5973 - defaults boost.context on riscv64

  • +
  • PR #5972 - Fix documentation for container algorithms

  • +
  • PR #5971 - added logic to detect riscv compiler configured for 64 bit target

  • +
  • PR #5968 - adds risc-v 64 bit support

  • +
  • PR #5967 - Adding missing pieces to sync_wait, adding run_loop

  • +
  • PR #5966 - docs: fix & improve parallel algorithms documentation 4

  • +
  • PR #5965 - Fixing inspect problems, adding missing header file

  • +
  • PR #5962 - Changes in html page of documentation

  • +
  • PR #5961 - Prevent stalling during shutdown when running hello_world_distributed

  • +
  • PR #5955 - Fix documentation for container algorithms

  • +
  • PR #5952 - docs: fix & improve parallel algorithms documentation 3

  • +
  • PR #5950 - Change executors to directly implement the executor CPOs

  • +
  • PR #5949 - Converting async combinators into CPOs

  • +
  • PR #5948 - Adding support for pure sender/receiver based executors to parallel algorithms

  • +
  • PR #5945 - [P2300] Added fundamental coroutine_traits for S/R

  • +
  • PR #5883 - Optimization on LCI parcelport: uses LCI_putva

  • +
  • PR #5872 - Block fork join executor

  • +
  • PR #5855 - Adding performance test Jenkins builder at LSU

  • +
+
+
+
+
HPX V1.8.1 (Aug 5, 2022)#
+

This is a bugfix release with a few minor additions and resolved problems.

+
+
General changes#
+

This patch release adds a number of small new features and fixes a handful of +problems discovered since the last release, in particular:

+
    +
  • A lot of work has been done to improve vectorization support for our parallel +algorithms. HPX now supports using EVE - the Expressive Vector Engine as a vectorization backend.

  • +
  • Added a simple average power consumption performance counter.

  • +
  • Added performance counters related to the use of zero-copy chunks in the +networking layer.

  • +
  • More work was done towards full compatibility with the sender/receivers +proposal P2300.

  • +
  • Fixing sync_wait to decay the result types

  • +
  • Fixed collective operations to properly avoid overalapping consecutive +operations on the same communicator.

  • +
  • Simplified the implementation of our execution policies and added mapping +functions between those.

  • +
  • Fixed performance issues with our implementation of small_vector.

  • +
  • Serialization now works with buffers of unsigned characters.

  • +
  • Fixing dangling reference in serialization of non-default constructible types

  • +
  • Fixed static linking on Windows.

  • +
  • Fixed support for M1/MacOS based architectures.

  • +
  • Fixed support for gentoo/musl.

  • +
  • Fixed hpx::counting_semaphore_var.

  • +
  • Properly check start and end bounds for hpx::for_loop

  • +
  • A lot of changes and fixes to the documentation (see +https://hpx-docs.stellar-group.org).

  • +
+
+
+
Breaking changes#
+
    +
  • No breaking changes have been introduced.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #5964 - component with multiple inheritance

  • +
  • Issue #5946 - dll_dlopen.hpp: error: RTLD_DI_ORIGIN was not declared in this scope with musl libc

  • +
  • Issue #5925 - Simplify implementation of execution policies

  • +
  • Issue #5924 - {what}: mmap() failed to allocate thread stack: HPX(unhandled_exception)

  • +
  • Issue #5912 - collectives all gather hangs if rank 0 is not involved

  • +
  • Issue #5902 - MPI parcelport issue on Fugaku

  • +
  • Issue #5900 - Unable to build hello_world_distributed.cpp.

  • +
  • Issue #5892 - Problems with HPX serialization as a standalone feature. Testcase provided.

  • +
  • Issue #5886 - Segfault when serializing non default constructible class with stl containers data members

  • +
  • Issue #5832 - Distributed execution crash

  • +
  • Issue #5768 - HPX hangs on Perlmutter

  • +
  • Issue #5735 - hpx::for_loop executes without checking start and end bounds

  • +
  • Issue #5700 - HPX(serialization_error)

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #5970 - Fixing component multiple inheritance

  • +
  • PR #5969 - Fixing sync_wait to avoid dangling references

  • +
  • PR #5963 - Fixing sync_wait to decay the result types

  • +
  • PR #5960 - docs: added name to documentation contributors list

  • +
  • PR #5959 - Fixing sync_wait to decay the result types

  • +
  • PR #5954 - refactor: rename itr to correct type (reduce)

  • +
  • PR #5954 - refactor: rename itr to correct type (reduce)

  • +
  • PR #5953 - Fixed property handling in hierarchical_spawning

  • +
  • PR #5951 - Fixing static linking (for Windows)

  • +
  • PR #5947 - Fix building on musl.

  • +
  • PR #5944 - added adaptive_static_chunk_size

  • +
  • PR #5943 - Fix sync_wait

  • +
  • PR #5942 - Fix doc warnings

  • +
  • PR #5941 - Fix sync_wait

  • +
  • PR #5940 - Protect collective operations against std::vector<bool> idiosyncrasies

  • +
  • PR #5939 - docs: fix & improve parallel algorithms documentation 2

  • +
  • PR #5938 - Properly implement generation support for collective operations

  • +
  • PR #5937 - Remove leftover files from PMR based small_vector

  • +
  • PR #5936 - Adding mapping functions between execution policies

  • +
  • PR #5935 - Fixing serialization to work with buffers of unsigned chars

  • +
  • PR #5934 - Attempting to fix datapar issues on CircleCI

  • +
  • PR #5933 - Fix documentation for ranges algorithms

  • +
  • PR #5932 - Remove mimalloc version constraint

  • +
  • PR #5931 - docs: fix & improve parallel algorithms documentation

  • +
  • PR #5930 - Add boost to hip builder

  • +
  • PR #5929 - Apply fixes to M1/MacOS related stack allocation to all relevant spots

  • +
  • PR #5928 - updated context_generic_context to accommodate arm64_arch_8/Apple architecture

  • +
  • PR #5927 - Public derivation for counting_semaphore_var

  • +
  • PR #5926 - Fix doxygen warnings when building documentation

  • +
  • PR #5923 - Fixing git checkout to reflect latest version tag

  • +
  • PR #5922 - A couple of unrelated changes in support of implementing P1673

  • +
  • PR #5920 - [P2300] enhancements: receiver_of, sender_of improvements

  • +
  • PR #5917 - Fixing various ‘held lock while suspending’ problems

  • +
  • PR #5916 - Fix minor doxygen parsing typo

  • +
  • PR #5915 - docs: fix broken api algo links

  • +
  • PR #5914 - Remove CSS rules - update sphinx version

  • +
  • PR #5911 - Removed references to hpx::vector in comments

  • +
  • PR #5909 - Remove stuff which is defined in the header

  • +
  • PR #5906 - Use BUILD_SHARED_LIBS correctly

  • +
  • PR #5905 - Fix incorrect usage of generator expressions

  • +
  • PR #5904 - Delete FindBZip2.cmake

  • +
  • PR #5901 - Fix #5900

  • +
  • PR #5899 - Replace PMR based version of small_vector

  • +
  • PR #5897 - Add missing “”

  • +
  • PR #5896 - Docs: Add serialization tutorial.

  • +
  • PR #5895 - Update to V1.9.0 on master

  • +
  • PR #5894 - Fix executor_with_thread_hooks example

  • +
  • PR #5890 - Adding simple average power consumption performance counter

  • +
  • PR #5889 - Par unseq/unseq adding

  • +
  • PR #5888 - Support for data-parallelism for reduce, transform reduce, transform_binary_reduce algorithms

  • +
  • PR #5887 - Fixing dangling reference in serialization of non-default constructible types

  • +
  • PR #5879 - New performance counters related to zero-copy chunks.

  • +
+
+
+
+
HPX V1.8.0 (May 18, 2022)#
+

With HPX parallel algorithms been fully adapted to C++20 the new release +achieves full conformance with C++20 concurrency and parallelism facilities. HPX +now supports all of the algorithms as specified by C++20. We have added support +for vectorization to more of our algorithms. Much work has been done towards +implementing P2300 (“std::execution”) and implementing the underlying +senders/receivers facilities. Finally, The new release comes with a brand new +documentation interface!

+
+
General changes#
+
    +
  • The new documentation can now be found on our webpage: https://hpx-docs.stellar-group.org. +This includes a completely new and user-friendly interface environment along with +restructuring of certain components. The content in the “Quick start”, “Manual” and +“Examples” was improved, while the “Build system” page was adapted to include necessary +information for newcommers.

  • +
  • With the vectorization support available in modern hardware architectures HPX +now provides new data-parallel vector execution policies +hpx::execution::simd and hpx::execution::par_simd that enable +significant speed-up of our parallel algorithm implementations. The following +algorithms now support SIMD execution:

    +
      +
    • copy, copy_n

    • +
    • generate

    • +
    • adjacent_difference, adjacent_find

    • +
    • all_of, any_of, none_of

    • +
    • equal, mismatch,

    • +
    • inner_product

    • +
    • count, count_if

    • +
    • fill, fill_n

    • +
    • find, find_end, find_first_of, find_if, find_if_not

    • +
    • for_each, for_each_n

    • +
    • generate, generate_n.

    • +
    +
  • +
  • Based on top of P2300 the HPX parallel algorithms now support the pipeline +syntax towards an effort to unify their usage along with senders/receivers. +The HPX parallel algorithms can now bind with senders/receivers using the +pipeline operator.

  • +
  • Several changes took place on the executors provided by HPX:

  • +
  • The executors now support the num_cores options in order for the user to +be able to specify the desired number of cores to be used in the correspodning +execution.

  • +
  • The scheduler executor was implemented on top of senders/receivers and can +be used with all HPX facilities that schedule new work, such as parallel +algorithms, hpx::async, hpx::dataflow, etc.

  • +
  • The performance of fork_join_executor was improved.

  • +
  • The following algorithms have been added/adapted to be C++20 conformant:

    +
      +
    • min_element

    • +
    • max_element

    • +
    • minmax_element

    • +
    • starts_with

    • +
    • ends_with

    • +
    • swap_ranges

    • +
    • unique

    • +
    • unique_copy

    • +
    • rotate

    • +
    • rotate_copy

    • +
    • sort

    • +
    • shift_left

    • +
    • shift_right

    • +
    • stable_sort

    • +
    • partition

    • +
    • partition_copy

    • +
    • stable_partition

    • +
    • adjacent_difference

    • +
    • nth_element

    • +
    • partial_sort

    • +
    • partial_sort_copy.

    • +
    +
  • +
  • HPX_FORWARD/HPX_MOVE macros were introduced that replaced the +std::move and std::forward facilities that in the library code.

  • +
  • Hangs on distributed barrier were fixed.

  • +
  • The performance of scan_partitioner was improved.

  • +
  • Support was added for thread_priority to the parallel_execution_policy

  • +
  • Regarding senders/receivers and the P2300 proposal various actions took place. +stop_token was adapted to the recent proposal version +(in_place_stop_token was introduced). Also hint, annotation, priority and +stacksize properties were added to the scheduler executor. Stop support was +added to when_all. Support for completion signatures was added. The +following schedulers and algorithms were added:

    +
      +
    • get_completion_scheduler

    • +
    • any_sender and unique_any_sender

    • +
    • split sender

    • +
    • transform_mpi sender

    • +
    • transfer sender

    • +
    • let_error, let_stopped

    • +
    • get_env and related environment queries

    • +
    • schedule, set_value, set_error, set_done, start and +connect are now proper customization points as defined in P2300.

    • +
    +
  • +
  • Several namespaces were altered towards conformance with C++20. Compatibility layers +have been added and the old versions will be removed in next releases. The namespace +changes are the following:

    +
      +
    • hpx::parallel::induction/reduction were movied into namespace hpx::experimental

    • +
    • for_loop and friends were moved into namespace hpx::experimental.

    • +
    • hpx::util::optional and friends were moved into namespace hpx.

    • +
    • hpx::lcos::barrier has been moved into the hpx::distributed namespace and +hpx::lcos::local::cpp20_barrier has been renamed to barrier and moved into +the hpx namespace.

    • +
    • hpx::lcos::latch has been moved into the hpx::distributed namespace and +lcos::local::latch has been moved into the hpx namespace. The +count_down_and_wait() functionality of latch has been renamed to +arrive_and_wait().

    • +
    • hpx::util::unique_function_nonser has been renamed to hpx::move_only_function.

    • +
    • hpx::util::unique_function has been renamed to hpx::distributed::move_only_function.

    • +
    • hpx::util::function has been renamed to hpx::distributed::function.

    • +
    • hpx::util::function_nonser has been renamed to hpx::function.

    • +
    • hpx::util::function_ref have been moved to namespace hpx.

    • +
    • hpx::lcos::split_future changed namespace and is now used as hpx::split_future.

    • +
    • hpx::lcos::local::counting_semaphore has been deprecated and +hpx::lcos::local::cpp20_counting_semaphore has been renamed to +hpx::counting_semaphore.

    • +
    • hpx::lcos::local::cpp20_binary_semaphore has been renamed to hpx::binary_semaphore.

    • +
    • hpx::lcos::local::sliding_semaphore has been renamed to hpx::sliding_semaphore and

    • +
    • hpx::lcos::local::sliding_semaphore_var has been renamed to hpx::sliding_semaphore_var.

    • +
    • hpx::lcos::local::spinlock has been renamed to hpx::spinlock.

    • +
    • hpx::lcos::local::mutex has been renamed to hpx::mutex.

    • +
    • hpx::lcos::local::timed_mutex has been renamed to hpx::timed_mutex.

    • +
    • hpx::lcos::local::no_mutex has been renamed to hpx::no_mutex.

    • +
    • hpx::lcos::local::recursive_mutex has been renamed to hpx::recursive_mutex.

    • +
    • hpx::lcos::local::shared_mutex has been renamed to hpx::shared_mutex.

    • +
    • hpx::lcos::local::upgrade_lock has been renamed to hpx::upgrade_lock.

    • +
    • hpx::lcos::local::upgrade_to_unique_lock has been renamed to hpx::upgrade_to_unique_lock.

    • +
    • hpx::lcos::local::condition_variable has been renamed to hpx::condition_variable. +hpx::lcos::local::condition_variable_var has been renamed to +hpx::condition_variable_var.

    • +
    • hpx::lcos::local::once_flag has been renamed to hpx::once_flag, and . +hpx::lcos::local::call_once has been renamed to hpx::call_once.

    • +
    +
  • +
  • The new LCI (Lightweight Communication Interface) parcelport was added that supports +irregular and asynchronous applications like graph analysis, sparce linear algebra, +modern parallel architectures etc. Major features include:

    +
      +
    • Support for advanced communication primitives like two sided send/recv and +one sided remote put.

    • +
    • Better multi-threaded performance.

    • +
    • Explicit user control of communication resource.

    • +
    • Flexible signaling mechanisms (synchronizer, completion queue, active message handler).

    • +
    +
  • +
  • The following CMake flags were added, mostly to support using HPX as a backend +for SHAD (https://github.com/pnnl/SHAD). Please note that these options enable +questionable functionalities, partially they even enable undefined behavior. +Please only use any of them if you know what you’re doing:

    +
      +
    • HPX_SERIALIZATION_WITH_ALLOW_RAW_POINTER_SERIALIZATION

    • +
    • HPX_SERIALIZATION_WITH_ALL_TYPES_ARE_BITWISE_SERIALIZABLE

    • +
    • HPX_SERIALIZATION_WITH_ALLOW_CONST_TUPLE_MEMBERS

    • +
    +
  • +
+
+
+
Breaking changes#
+
    +
  • Minimum required C++ standard library is C++17.

  • +
  • Support for GCC 7 and Clang 8.0.0 and below has been removed.

  • +
  • CUDA version required updated to 11.4.

  • +
  • CMake version required updated to 3.18.

  • +
  • The default version of Asio used was updated to 1.20.0.

  • +
  • The default version of APEX used was updated to 2.5.1.

  • +
  • APEX version was updated to 2.5.1.

  • +
  • tagged_pair and tagged_tuple were removed.

  • +
  • tag_dispatch was renamed to tag_invoke.

  • +
  • hpx.max_backgroud_threads was renamed to hpx.parcel.max_background_threads.

  • +
  • The following CMake flags were removed after being deprecated for at least two releases:

    +
      +
    • HPX_SCHEDULER_MAX_TERMINATED_THREADS

    • +
    • HPX_WITH_GOOGLE_PERFTOOLS

    • +
    • HPX_WITH_INIT_START_OVERLOADS_COMPATIBILITY

    • +
    • HPX_HAVE_{COROUTINE,PLUGIN}_GCC_HIDDEN_VISIBILITY

    • +
    • HPX_TOP_LEVEL

    • +
    • HPX_WITH_COMPUTE_CUDA

    • +
    • HPX_WITH_ASYNC_CUDA

    • +
    +
  • +
  • annotate_function was renamed to scoped_annotation.

  • +
  • execution::transform was renamed to execution::then.

  • +
  • execution::detach was renamed to execution::start_detached.

  • +
  • execution::on_sender was renamed to execution::schedule_on.

  • +
  • execution::just_on was renamed to execution::just_transfer.

  • +
  • execution::set_done was renamed to execution::set_stopped.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #5871 - distributed::channel.regsiter_as terminates the active task.

  • +
  • Issue #5856 - Performance counters do not compile

  • +
  • Issue #5828 - hpx::distributed:barrier errors

  • +
  • Issue #5812 - OctoTiger does not compile with HPX master and CUDA 11.5

  • +
  • Issue #5784 - HPX failing with co_await and hpx::when_all(futures)

  • +
  • Issue #5774 - CMake can’t find HPXCacheVariables.cmake

  • +
  • Issue #5764 - Fix HIP problem

  • +
  • Issue #5724 - Missing binary filter compression header

  • +
  • Issue #5721 - Cleanup after repository split

  • +
  • Issue #5701 - It seems that the tcp parcelport is running, and the MPI parcelport is ignored

  • +
  • Issue #5692 - Kokkos compilation fails when using both HPX and CUDA execution spaces with gcc 9.3.0

  • +
  • Issue #5686 - Rename annotate_function

  • +
  • Issue #5668 - HPX does not detect the C++ 20 standard using gcc 11.2

  • +
  • Issue #5666 - Compilation error using boost 1.76 and gcc 11.2.1

  • +
  • Issue #5653 - Implement P2248 for our algorithms

  • +
  • Issue #5647 - [User input needed] Remove (CUDA) compute functionality?

  • +
  • Issue #5590 - hello_world_distributed fails on startup with HPX stable, MPICH 3.3.2, on Deep Bayou

  • +
  • Issue #5570 - Rename tag_dispatch to tag_invoke

  • +
  • Issue #5566 - can’t build simple example: “Cannot use the dummy implementation of future_then_dispatch”

  • +
  • Issue #5565 - build failure: hpx::string_util::trim()

  • +
  • Issue #5553 - Github action to validate the cff file refs #5471

  • +
  • Issue #5504 - CMake does not work for HPX 1.7.0 on Piz Daint

  • +
  • Issue #5503 - Use contiguous index queue in bulk execution to reduce number of spawned tasks

  • +
  • Issue #5502 - C++20 std::coroutine cmake detection

  • +
  • Issue #5478 - hpx.dll built with vcpkg got functions pointing to the same location

  • +
  • Issue #5472 - Compilation error with cuda/11.3

  • +
  • Issue #5469 - Compiler warning about HPX_NODISCARD when building with APEX

  • +
  • Issue #5463 - Address minor comments of the C++17 PR bump

  • +
  • Issue #5456 - Use std::ranges::iter_swap where available

  • +
  • Issue #5404 - Build fails with error “Cannot open include file asio/io_context.hpp”

  • +
  • Issue #5381 - Add starts_with and ends_with algorithms

  • +
  • Issue #5344 - Further simplify tag_invoke helpers

  • +
  • Issue #5269 - Allow setting a label on executors/policies

  • +
  • Issue #5219 - (Re-)Implement executor API on top of sender/receiver infrastructure

  • +
  • Issue #5216 - Performance counter module not loading

  • +
  • Issue #5162 - Require C++17 support

  • +
  • Issue #5156 - Disentangle segmented algorithms

  • +
  • Issue #5118 - Lock held while suspending

  • +
  • Issue #5111 - Tests fail to build with binary_filter plugins enabled

  • +
  • Issue #5110 - Tests don’t get built

  • +
  • Issue #5105 - PAPI performance counters not available

  • +
  • Issue #5002 - hpx::lcos::barrier() results in deadlock

  • +
  • Issue #4992 - Clang-format the rest of the files

  • +
  • Issue #4987 - Use std::function in public APIs

  • +
  • Issue #4871 - HEP: conformance to C++20

  • +
  • Issue #4822 - Adapt parallel algorithms to C++20

  • +
  • Issue #4736 - Deprecate hpx::flush and hpx::endl

  • +
  • Issue #4558 - Prevent work-stealing from stalling

  • +
  • Issue #4495 - Add anchor links to table rows in documentation

  • +
  • Issue #4469 - New thread state: pending_low

  • +
  • Issue #4321 - After the modularization the libfabric parcelport does not compile

  • +
  • Issue #4308 - Using APEX on multinode jobs when HPX_WITH_NETWORKING = OFF

  • +
  • Issue #3995 - Use C++20 std::source_location where available, adapt ours to conform

  • +
  • Issue #3861 - Selected processor does not support ‘yield’ in ARM mode

  • +
  • Issue #3706 - Add shift_left and shift_right algorithms

  • +
  • Issue #3646 - Parallel algorithms should accept iterator/sentinel pairs

  • +
  • Issue #3636 - HPX Modularization

  • +
  • Issue #3546 - Modularization of HPX

  • +
  • Issue #3474 - Modernize CMake used in HPX

  • +
  • Issue #1836 - hpx::parallel does not have a sort implementation

  • +
  • Issue #1668 - Adapt all parallel algorithms to Ranges TS

  • +
  • Issue #1141 - Implement N4409 on top of HPX

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #5885 - Testing newer ASIO version

  • +
  • PR #5884 - Fix miscellaneous doc sections

  • +
  • PR #5882 - Fixing OctoTiger incompatibility introduced recently

  • +
  • PR #5881 - Fixing recent patch that disables ATOMIC_FLAG_INIT for C++20 and up

  • +
  • PR #5880 - refactor: convert counter_status enum to enum class

  • +
  • PR #5878 - Docs: Replaced non-existent create_reducer function with create_communicator

  • +
  • PR #5877 - Doc updates hpx runtime and resources

  • +
  • PR #5876 - Updates to documentation; grammar edits.

  • +
  • PR #5875 - Doc updates starting the hpx runtime

  • +
  • PR #5874 - Doc updates launching configuring

  • +
  • PR #5873 - Prevent certain generated files from being deleted on reconfigure

  • +
  • PR #5870 - Adding support for the PJM batch environment

  • +
  • PR #5867 - Update CMakeLists.txt

  • +
  • PR #5866 - add cmake option HPX_WITH_PARCELPORT_COUNTERS

  • +
  • PR #5864 - ATOMIC_INIT_FLAG is deprecated starting C++20

  • +
  • PR #5863 - Adding llvm 14.0.0 with boost 1.79.0 to Jenkins

  • +
  • PR #5861 - Let install step proceed on CircleCI even if the segmented algorithms fail

  • +
  • PR #5860 - Updating APEX tag

  • +
  • PR #5859 - Splitting documentation generation steps on CircleCI

  • +
  • PR #5854 - Fixing left-overs from changing counter_type to enum class

  • +
  • PR #5853 - Adding HPX dependency tool (adapted from Boostdep tool)

  • +
  • PR #5852 - Optimize LCI parcelport

  • +
  • PR #5851 - Forking dynamic_bitset from Boost

  • +
  • PR #5850 - Convert perf_counters::counter_type enum to enum class.

  • +
  • PR #5849 - Update LCI parcelport to LCI v1.7.1

  • +
  • PR #5848 - Fedora related fixes

  • +
  • PR #5847 - Fix API, troubleshooting & people

  • +
  • PR #5844 - Attempting to fix timeouts of segmented iterator tests

  • +
  • PR #5842 - change the default value of HPX_WITH_LCI_TAG to v1.7

  • +
  • PR #5841 - Move the split_future facilities into the namespace hpx

  • +
  • PR #5840 - wait_xxx_nothrow functions return whether one of the futures is exceptional

  • +
  • PR #5839 - Moving a list of synchronization primitives into namespace hpx

  • +
  • PR #5837 - Moving latch types to hpx and hpx::distributed namespaces

  • +
  • PR #5835 - Add missing compatibility layer for id_type::management_type values

  • +
  • PR #5834 - API docs changes

  • +
  • PR #5831 - Further improvement actions to rotate

  • +
  • PR #5830 - Exposing zero-copy serialization threshold through configuration option

  • +
  • PR #5829 - Attempting to fix failing barrier test

  • +
  • PR #5827 - Add back explicit template parameter to ignore_while_checking to compile with nvcc

  • +
  • PR #5826 - Reduce number of allocations while calling async_bulk_execute

  • +
  • PR #5825 - Steal from neighboring NUMA domain only

  • +
  • PR #5823 - Remove obsolete directories and adjust build system

  • +
  • PR #5822 - Clang-format remaining files

  • +
  • PR #5821 - Enable permissive- flag on Windows GitHub actions builders

  • +
  • PR #5820 - Convert throwmode enum to enum class

  • +
  • PR #5819 - Marking customization points for intrusive_ptr as noexcept

  • +
  • PR #5818 - Unconditionally use C++17 attributes

  • +
  • PR #5817 - Modernize naming modules

  • +
  • PR #5816 - Modernize cache module

  • +
  • PR #5815 - Reapply flyby changes from #5467

  • +
  • PR #5814 - Avoid test timeouts by reducing test sizes

  • +
  • PR #5813 - The CUDA problem is not fixed in V11.5 yet…

  • +
  • PR #5811 - Make sure reduction value is properly moved, when possible

  • +
  • PR #5810 - Improve error reporting during device initialization in HIP environments

  • +
  • PR #5809 - Converting scheduler enums into enum class

  • +
  • PR #5808 - Deprecate hpx::flush and friends

  • +
  • PR #5807 - Use C++20 std::source_location, if available

  • +
  • PR #5806 - Moving promise and packaged_task to new namespaces

  • +
  • PR #5805 - Attempting to fix a test failure when using the LCI parcelpor

  • +
  • PR #5803 - Attempt to fix CUDA related OctoTiger problems

  • +
  • PR #5800 - Add option to restrict MPI background work to subset of cores

  • +
  • PR #5798 - Adding MPI as a dependency to APEX

  • +
  • PR #5797 - Extend Sphinx role to support arbitrary text to display on a link

  • +
  • PR #5796 - Disable CUDA tests that cause NVCC to silently fail without error messages

  • +
  • PR #5795 - Avoid writing path and directories into HPXCacheVariables.cmake

  • +
  • PR #5793 - Remove features that are deprecated since V1.6

  • +
  • PR #5792 - Making sure num_cores is properly handled by parallel_executor

  • +
  • PR #5791 - Moving bind, bind_front, bind_back to namespace hpx

  • +
  • PR #5790 - Moving serializable function/move_only_function into namespace hpx::distributed

  • +
  • PR #5787 - Remove unneeded (and commented) tests

  • +
  • PR #5786 - Attempting to fix hangs in distributed barrier

  • +
  • PR #5785 - add cmake code to detect arm64 on macOS

  • +
  • PR #5783 - Moving function and function_ref into namespace hpx

  • +
  • PR #5781 - Updating used version of Visual Studio

  • +
  • PR #5780 - Update Piz Daint Jenkins configurations from gcc/clang 7 to 8

  • +
  • PR #5778 - Updated for_loop.hpp

  • +
  • PR #5777 - Update reference for foreach benchmark

  • +
  • PR #5775 - Move optional into namespace hpx

  • +
  • PR #5773 - Moving barrier to consolidated namespaces

  • +
  • PR #5772 - Adding missing docs for ranges::find_if and find_if_not algorithms

  • +
  • PR #5771 - Moving for_loop into namespace hpx::experimental

  • +
  • PR #5770 - Fixing HIP issues

  • +
  • PR #5769 - Slight improvement of small_vector performance

  • +
  • PR #5766 - Fixing a integral conversion warning

  • +
  • PR #5765 - Adding a sphinx role allowing to link to a file directly in github

  • +
  • PR #5763 - add num_cores facility

  • +
  • PR #5762 - Fix Public API main page

  • +
  • PR #5761 - Add missing inline to mpi_exception.hpp error_message function

  • +
  • PR #5760 - Update cdash build url

  • +
  • PR #5759 - Switch to use generic rostam SLURM partitions

  • +
  • PR #5758 - Adding support for P2300 completion signatures

  • +
  • PR #5757 - Fix missing links in Public API

  • +
  • PR #5756 - Add stop support to when_all

  • +
  • PR #5755 - Support for data-parallelism for mismatch algorithm

  • +
  • PR #5754 - Support for data-parallelism for equal algorithm

  • +
  • PR #5751 - Propagate MPI dependencies to command line handling

  • +
  • PR #5750 - Make sure required MPI initialization flags are properly applied and supported

  • +
  • PR #5749 - P2300 stop token

  • +
  • PR #5748 - Adding environmental query CPOs

  • +
  • PR #5747 - Renaming set_done to set_stopped (as per P2300)

  • +
  • PR #5745 - Modernize serialization module

  • +
  • PR #5743 - Add check for MPICH and set the correct env to support multi-threaded

  • +
  • PR #5742 - Remove obsolete files related to cpuid, etc.

  • +
  • PR #5741 - Support for data-parallelism for adjacent find

  • +
  • PR #5740 - Support for data-parallelism for find algorithms

  • +
  • PR #5739 - Enable the option to attach a debugger on a segmentation fault (linux)

  • +
  • PR #5738 - Fixing spell-checking errors

  • +
  • PR #5737 - Attempt to fix migrate_component issue

  • +
  • PR #5736 - Set commit status from Jenkins also for special branches

  • +
  • PR #5734 - Revert #5586

  • +
  • PR #5732 - Attempt to improve build-id reporting to cdash

  • +
  • PR #5731 - Randomly delay execution of bash scripts launched by Jenkins

  • +
  • PR #5729 - Workaround for CMake/Ninja generator OOM problem

  • +
  • PR #5727 - Moving compression plugins to components directory

  • +
  • PR #5726 - Moving/consolidating parcel coalescing plugin sources

  • +
  • PR #5725 - Making sure headers for serialization filters are being installed

  • +
  • PR #5723 - Moving more tests to modules

  • +
  • PR #5722 - Removing superfluous semicolons

  • +
  • PR #5720 - Moving parcelports into modules

  • +
  • PR #5719 - Moving more files to parcelset module

  • +
  • PR #5718 - build: refactor sphinx config file

  • +
  • PR #5717 - Creating parcelset modules

  • +
  • PR #5716 - Avoid duplicate definition error

  • +
  • PR #5715 - The new LCI parcelport for HPX

  • +
  • PR #5714 - Refine propagation of HPX_WITH_… options

  • +
  • PR #5713 - Significantly reduce CI jobs run on Piz Daint

  • +
  • PR #5712 - Updating jenkins configuration for Rostam2.2

  • +
  • PR #5711 - Refactor manual sections

  • +
  • PR #5710 - Making task_group serializable

  • +
  • PR #5709 - Update the MPI cmake setup

  • +
  • PR #5707 - Better diagnose parcel bootstrap problems

  • +
  • PR #5704 - Test with hwloc 2.7.0 with GCC 11

  • +
  • PR #5703 - Fix counting_iterator container tests

  • +
  • PR #5702 - Attempting to fix CircleCI timeouts

  • +
  • PR #5699 - Update CI to use Boost 1.78.0

  • +
  • PR #5697 - Adding fork_join_executor to foreach_benchmark

  • +
  • PR #5696 - Modernize when_all and friends (when_any, when_some, when_each)

  • +
  • PR #5693 - Fix test errors with _GLIBCXX_DEBUG defined

  • +
  • PR #5691 - Rename annotate_function to scoped_annotation

  • +
  • PR #5690 - Replace tag_dispatch with tag_invoke in minmax segmented

  • +
  • PR #5688 - Remove more deprecated macros

  • +
  • PR #5687 - Add most important CMake options

  • +
  • PR #5685 - Fix future API

  • +
  • PR #5684 - Move lock registration to separate module and remove global lock registration

  • +
  • PR #5683 - Make hpx::wait_all etc. throw exceptions when waited futures hold exceptions and deprecate hpx::lcos::wait_all[_n] in favor of hpx::wait_all[_n]

  • +
  • PR #5682 - Fix macOS test exceptions

  • +
  • PR #5681 - docs: add links to hpx recepies

  • +
  • PR #5680 - Embed base execution policies to datapar execution policies

  • +
  • PR #5679 - Fix fork_join_executor with dynamic schedule

  • +
  • PR #5678 - Fix compilation of service executors with nvcc

  • +
  • PR #5677 - Remove compute_cuda module

  • +
  • PR #5676 - Don’t require up-to-date approvals for bors

  • +
  • PR #5675 - Add default template type parameters for algorithms

  • +
  • PR #5674 - Allow using any_sender in global variables

  • +
  • PR #5671 - Making sure task_group can be reused

  • +
  • PR #5670 - Relax constraints on execution::when_all

  • +
  • PR #5669 - Use HPX_WITH_CXX_STANDARD for controlling C++ version

  • +
  • PR #5667 - Attempt to fix compilation issues with Boost V1.76

  • +
  • PR #5664 - Change logging errors to warnings in schedulers

  • +
  • PR #5663 - Use dynamic bitsets by default for CPU masks

  • +
  • PR #5662 - Disambiguate namespace for MSVC

  • +
  • PR #5660 - Replacing remaining std::forward and std::move with HPX_FORWARD and HPX_MOVE

  • +
  • PR #5659 - Modernize hpx::future and related facilities

  • +
  • PR #5658 - Replace HPX_INLINE_CONSTEXPR_VARIABLE with inline constexpr

  • +
  • PR #5657 - Remove tagged, tagged_pair and tagged_tuple, remove tuple/pair specializations

  • +
  • PR #5656 - Rename on execution::schedule_from, rename just_on to just_transfer, and add transfer

  • +
  • PR #5655 - Avoid for module lists to grow indefinitely in cmake cache

  • +
  • PR #5649 - build: replace usage of Python’s reserved words and functions as variable names

  • +
  • PR #5648 - Modernize action modules and related code

  • +
  • PR #5646 - Fix ends_with test

  • +
  • PR #5645 - Add matrix multiplication example

  • +
  • PR #5644 - Rename execution::transform to execution::then and execution::detach to execution::start_detached

  • +
  • PR #5643 - Update performance test references

  • +
  • PR #5642 - Adapting adjacent_difference to work with proxy iterators

  • +
  • PR #5641 - Factorize perftests scripts

  • +
  • PR #5640 - Fixed links to sources in Sphinx documentation

  • +
  • PR #5639 - Fix generate datapar tests for Vc

  • +
  • PR #5638 - Simd all any none

  • +
  • PR #5637 - Use bors for merging pull requests

  • +
  • PR #5636 - Fix leftover std::holds_alternative usage

  • +
  • PR #5635 - Update container image tag in GitHub actions HIP configuration

  • +
  • PR #5633 - Moving packaged_task to module futures

  • +
  • PR #5632 - Tell Asio to use std::aligned_new only if available

  • +
  • PR #5631 - Adding tag parameter to channel communicator get/set

  • +
  • PR #5630 - Add partial_sort_copy and adapt partial sort to c++ 20

  • +
  • PR #5629 - Set HPX_WITH_FETCH_ASIO to OFF as available in the docker image

  • +
  • PR #5628 - Add Clang 13 CI configuration

  • +
  • PR #5627 - Replace alternative keyword

  • +
  • PR #5626 - docs: add support for BibTeX references in Sphinx docs

  • +
  • PR #5624 - Fix pkgconfig replacements involving CMAKE_INSTALL_PREFIX

  • +
  • PR #5623 - build: remove unused import from conf.py.in

  • +
  • PR #5622 - Remove HPX_WITH_VCPKG CMake option

  • +
  • PR #5621 - Replacing boost::container::small_vector

  • +
  • PR #5620 - Update Asio tag from 1.18.2 to 1.20.0

  • +
  • PR #5619 - Fix block_os_threads_1036 test

  • +
  • PR #5618 - Make sure condition variables are notified under a lock in the thread_pool_scheduler test

  • +
  • PR #5617 - Use advance_and_get_distance where required

  • +
  • PR #5616 - Remove separately building segmented algorithms on CircleCI

  • +
  • PR #5613 - Fix Vc datapar adjacent_difference

  • +
  • PR #5609 - docs: add anchor links to performance counter tables

  • +
  • PR #5608 - Fix header test error by adding missing numeric

  • +
  • PR #5607 - Fix simd adj diff

  • +
  • PR #5605 - Fix usage of HPX_INVOKE macro

  • +
  • PR #5604 - Make use of shell-session to allow non-copyable $

  • +
  • PR #5603 - Suppress some MSVC warnings in C++20 mode

  • +
  • PR #5602 - Test HPX_DATASTRUCTURES_WITH_ADAPT_STD_TUPLE=OFF to one CI configuration

  • +
  • PR #5601 - Test case for any_sender should use hpx::tuple

  • +
  • PR #5600 - Rename tag_dispatch back to tag_invoke

  • +
  • PR #5599 - Change theme, fix Quickstart & Examples

  • +
  • PR #5596 - Use precompiled headers in tests

  • +
  • PR #5595 - Drop semicolons for macro calls

  • +
  • PR #5594 - Adapt datapar generate

  • +
  • PR #5593 - Update any_sender to use tag_dispatch for execution customizations

  • +
  • PR #5592 - Add nth_element

  • +
  • PR #5591 - Remove unnecessary checks for C++17 for tests

  • +
  • PR #5589 - Add HPX_FORWARD/HPX_MOVE macros

  • +
  • PR #5588 - Fixing the output formatting for id_types

  • +
  • PR #5586 - Remove local functionality

  • +
  • PR #5585 - Delete GitExternal.cmake

  • +
  • PR #5584 - Serialization of hpx::tuple must use hpx::get

  • +
  • PR #5583 - fix coroutine_traits allocate calls, add unhandled_exception() implementation.

  • +
  • PR #5582 - Make more examples work with local runtime

  • +
  • PR #5581 - Add support for several performance tests in CI

  • +
  • PR #5580 - Adapt simd adj diff

  • +
  • PR #5579 - Split absolute paths for generated pkg-config files into -L/-l parts

  • +
  • PR #5577 - fix unit fill test for datapar with Vc

  • +
  • PR #5576 - Update forgotten “Full” names

  • +
  • PR #5575 - Change scan partitioner implementation

  • +
  • PR #5574 - Remove a few deprecated and unused CMake options

  • +
  • PR #5572 - Remove more guards for the distributed runtime

  • +
  • PR #5571 - Add workaround for libstc++ in string_util trim

  • +
  • PR #5569 - Use no_unique_address in sender adaptors

  • +
  • PR #5568 - Change try catch block to try_catch_exception_ptr

  • +
  • PR #5567 - Make default_agent::yield actually yield

  • +
  • PR #5564 - Adjacent

  • +
  • PR #5562 - More changes to overcome build problems on Windows after recent module rearrangements

  • +
  • PR #5560 - Update tests and examples

  • +
  • PR #5559 - Fixing cmake folder names after module restructuring

  • +
  • PR #5558 - Fixing wrong module dependencies

  • +
  • PR #5557 - Adding an example for the new channel_communicator API

  • +
  • PR #5556 - Remove leftover thread pool os executor tests

  • +
  • PR #5555 - Add option enabling serializing raw pointers

  • +
  • PR #5554 - Make sure command line aliasing is properly handled

  • +
  • PR #5552 - Modernizing some of the async facilities

  • +
  • PR #5551 - Fixing for local executions of actions to properly set task names

  • +
  • PR #5550 - Update CUDA module in clang-cuda configuration

  • +
  • PR #5549 - Fixing agent_ref::yield_k to actually call yield_k

  • +
  • PR #5548 - Making get_action_name() noexcept

  • +
  • PR #5547 - Fixing communication set

  • +
  • PR #5546 - Fixing shutdown problems caused by missing ref-counting

  • +
  • PR #5545 - Remove wrong move in thread_pool_scheduler_bulk.hpp

  • +
  • PR #5543 - Extend launch policy to carry stack size and scheduling hint in addition to priority

  • +
  • PR #5542 - Simplify execution CPOs

  • +
  • PR #5540 - Adapt partition, partition_copy and stable_partition to C++ 20

  • +
  • PR #5539 - Adapt mismatch to support sentinels

  • +
  • PR #5538 - Document specific sphinx version required for the documentation

  • +
  • PR #5537 - Test release and debug builds on Piz Daint

  • +
  • PR #5536 - This fixes referencing stale iterators during the execution of binary mismatch

  • +
  • PR #5535 - Rename simdpar to par_simd

  • +
  • PR #5534 - Fix Quick start & Manual Docs

  • +
  • PR #5533 - Fix annotate_function for std::string

  • +
  • PR #5532 - Update two remaining apex links from khuck to UO-OACISS

  • +
  • PR #5531 - Use contiguous_index_queue in thread_pool_scheduler

  • +
  • PR #5530 - Eagerly initialize a configurable number of threads on scheduler/thread queue init

  • +
  • PR #5529 - Update benchmarks and add support for scheduler_executor

  • +
  • PR #5528 - Add missing properties to executors/schedulers

  • +
  • PR #5527 - Set local thread/pool number in local/static_queue_scheduler

  • +
  • PR #5526 - Update Rostam HIP configuration to use 4.3.0

  • +
  • PR #5525 - Fix Building HPX in Quick start

  • +
  • PR #5524 - Upload image on cdash

  • +
  • PR #5523 - Modernize facilities related to hpx::sync

  • +
  • PR #5522 - Add sender overloads for remaining algorithms

  • +
  • PR #5521 - Minor changes that improve performance

  • +
  • PR #5520 - Update reference as perftests failing regularly

  • +
  • PR #5519 - Add transform_mpi sender adapter

  • +
  • PR #5518 - Add sender overloads to rotate/rotate_copy

  • +
  • PR #5517 - Fix coroutine integration

  • +
  • PR #5515 - Avoid deadlock in ignore_while_locked_1485 test

  • +
  • PR #5514 - Add split sender adapter

  • +
  • PR #5512 - Update Rostam HIP configuration

  • +
  • PR #5511 - Fix Asio target name for precompiled headers

  • +
  • PR #5510 - Add any_sender and unique_any_sender

  • +
  • PR #5509 - Test with Boost 1.77 on gcc/clang-newest configurations

  • +
  • PR #5508 - Minor release changes from 1.7.1

  • +
  • PR #5507 - Add missing commits from scheduler_executor PR

  • +
  • PR #5506 - Fix condition for checking if we should use our own variant

  • +
  • PR #5501 - Attempt to fix thread_pool_scheduler test

  • +
  • PR #5493 - Update Jenkins GitHub token to use StellarBot GitHub account

  • +
  • PR #5490 - Fix clang-format error on master

  • +
  • PR #5487 - Add get_completion_scheduler CPO and customize bulk for thread_pool_scheduler

  • +
  • PR #5484 - Add missing header to jacobi_component/server/solver.hpp

  • +
  • PR #5481 - Changing the APEX repository to the new location

  • +
  • PR #5479 - Fix version check for CUDA noexcept/result_of bug

  • +
  • PR #5477 - Require cxx17 minor comments

  • +
  • PR #5476 - Fix cmake format error

  • +
  • PR #5475 - Require CMake 3.18 as it is already a requirement for CUDA

  • +
  • PR #5474 - Make the cuda parameters of try_compile optional

  • +
  • PR #5473 - Update cuda arch and change cuda version

  • +
  • PR #5471 - Add corrected citation.cff

  • +
  • PR #5470 - Adapt stable_sort to C++ 20

  • +
  • PR #5468 - Experimentation to make the perftest report public

  • +
  • PR #5466 - Add shift_left and shift_right algorithms

  • +
  • PR #5465 - Adapt datapar fill

  • +
  • PR #5464 - Moving tag_dispatch to separate module

  • +
  • PR #5461 - Rename HPX_WITH_CUDA_COMPUTE with HPX_WITH_COMPUTE_CUDA

  • +
  • PR #5460 - Adapt sort to C++ 20

  • +
  • PR #5459 - Adapt rotate/rotate_copy to C++20

  • +
  • PR #5458 - Adapt unique and unique_copy to C++ 20

  • +
  • PR #5455 - Remove and clean up fallback sender implementations

  • +
  • PR #5454 - Make performance plot show even if similar performance

  • +
  • PR #5453 - Post 1.7.0 version bump

  • +
  • PR #5452 - Fix find_end parallel overload

  • +
  • PR #5450 - Change the print-bind output to be more precise

  • +
  • PR #5449 - Adapt swap_ranges to C++ 20

  • +
  • PR #5446 - Use more verbose names in sender algorithms

  • +
  • PR #5443 - Properly support ASAN with MSVC

  • +
  • PR #5441 - Adding reference counting to thread_data

  • +
  • PR #5429 - Scheduler executor

  • +
  • PR #5428 - Adapt datapar copy

  • +
  • PR #5421 - Update CI base image to use clang-format 11

  • +
  • PR #5410 - Add ranges starts_with and ends_with algorithms

  • +
  • PR #5383 - Tentatively remove runtime_registration_wrapper from cuda futures

  • +
  • PR #5377 - Fewer Asio includes and more precompiled headers

  • +
  • PR #5329 - Sender overloads for parallel algorithms

  • +
  • PR #5313 - Rearrange modules between libraries

  • +
  • PR #5283 - Require minimum C++17 and change CUDA handling

  • +
  • PR #5241 - Adapt min_element, max_element and minmax_element to C++20

  • +
+
+
+
+
HPX V1.7.1 (Aug 12, 2021)#
+

This is a bugfix release with a few minor fixes.

+
+
General changes#
+
    +
  • Added a CMake option to assume that all types are bitwise serializable by +default: HPX_SERIALIZATION_WITH_ALL_TYPES_ARE_BITWISE_SERIALIZABLE. The +default value OFF corresponds to the old behaviour.

  • +
  • Added a version check for Asio. The minimum Asio version supported by HPX is +1.12.0.

  • +
  • Fixed a bug affecting usage of actions, where the internals of HPX relied on +function addresses being unique. This was fixed by relying on variable +addresses being unique instead.

  • +
  • Made hpx::util::bind more strict in checking the validity of placeholders.

  • +
  • Small performance improvement to spinlocks.

  • +
  • Adapted the following parallel algorithms to C++20: inclusive_scan, +exclusive_scan, transform_inclusive_scan, +transform_exclusive_scan.

  • +
+
+
+
Breaking changes#
+
    +
  • The experimental hpx::execution::simdpar execution policy (introduced in +1.7.0) was renamed to hpx::execution::par_simd for consistency with the +other parallel policies.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #5494 - Rename simdpar execution policy to par_simd

  • +
  • Issue #5488 - hpx::util::bind doesn’t bounds-check placeholders

  • +
  • Issue #5486 - Possible V1.7.1 release

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #5500 - Minor bug fix in transform exclusive and inclusive scan tests

  • +
  • PR #5499 - Rename simdpar to par_simd

  • +
  • PR #5489 - Adding bound-checking for bind placeholders

  • +
  • PR #5485 - Add Asio version check

  • +
  • PR #5482 - Change extra archive data to rely on uniqueness of a variable address, not a function address

  • +
  • PR #5448 - More fixes to enable for all types to be assumed to be bitwise copyable

  • +
  • PR #5445 - Improve performance of Spinlocks

  • +
  • PR #5444 - Adapt transform_inclusive_scan to C++ 20

  • +
  • PR #5440 - Adapt transform_exclusive_scan to C++ 20

  • +
  • PR #5439 - Adapt inclusive_scan to C++ 20

  • +
  • PR #5436 - Adapt exclusive_scan to C++20

  • +
+
+
+
+
HPX V1.7.0 (Jul 14, 2021)#
+

This release is again focused on C++20 conformance of algorithms. Additionally, +many new experimental sender-based algorithms have been added based on the +latest proposals.

+
+
General changes#
+
    +
  • The following algorithms have been adapted to be C++20 conformant:

    +
      +
    • remove,

    • +
    • remove_if,

    • +
    • remove_copy,

    • +
    • remove_copy_if,

    • +
    • replace,

    • +
    • replace_if,

    • +
    • reverse, and

    • +
    • lexicographical_compare.

    • +
    +
  • +
  • When the compiler and standard library support the standard execution policies +std::execution::seq, std::execution::par, and +std::execution::par_unseq they can now be used in all HPX parallel +algorithms with equivalent behaviour to the non-task policies +hpx::execution::seq, hpx::execution::par, and +hpx::execution::par_unseq.

  • +
  • Vc support has been fixed, after being broken in 1.6.0. In addition, HPX now +experimentally supports GCC’s SIMD implementation, when available. The +implementation can be used through the hpx::execution::simd and +hpx::execution::simdpar execution policies.

  • +
  • The customization points sync_execute, async_execute, +then_execute, post, bulk_sync_execute, bulk_async_execute, and +bulk_then_execute are now implemented using tag_dispatch (previously +tag_invoke). Executors can still be implemented by providing the +aforementioned functions as member functions of an executor.

  • +
  • New functionality, enhancements, and fixes based on P0443r14 (executors +proposal) and P1897 (sender-based algorithms) have been added to the +hpx::execution::experimental namespace. These can be accessed through the +hpx/execution.hpp and hpx/local/execution.hpp headers. In particular, +the following sender-based algorithms have been added:

    +
      +
    • detach,

    • +
    • ensure_started,

    • +
    • just,

    • +
    • just_on,

    • +
    • let_error,

    • +
    • let_value,

    • +
    • on,

    • +
    • transform, and

    • +
    • when_all.

    • +
    +

    Additionally, futures now implement the sender +concept. make_future can be used to turn a sender into a future. All +functionality is experimental and can change without notice.

    +
  • +
  • All hpx::init and hpx::start overloads now take std::functions +instead of hpx::util::function_nonser. No changes should be required in +user code to accommodate this change.

  • +
  • hpx::util::unwrapping and other related unwrapping functionality has been +moved up into the hpx namespace. Names in hpx::util are still usable +with a deprecation warning. This functionality can now be accessed through the +hpx/unwrap.hpp and hpx/local/unwrap.hpp headers.

  • +
  • The default tag for APEX has been update from 2.3.1 to 2.4.0. In particular, +this fixes a bug which could lead to hangs in distributed runs.

  • +
  • The dependency on Boost.Asio has been replaced with the standalone Asio +available at https://github.com/chriskohlhoff/asio. By default, a +system-installed Asio will be used. ASIO_ROOT can be given as a hint to +tell CMake where to find Asio. Alternatively, Asio can be fetched +automatically using CMake’s fetchcontent by setting +HPX_WITH_FETCH_ASIO=ON. In general, dependencies on Boost have again been +reduced.

  • +
  • Modularization of the library has continued. In this release almost all +functionality has been moved into modules. These changes do not generally +affect user code. Warnings are still issued for headers that have moved.

  • +
  • hipBLAS is now optional when compiling with hipcc. A warning instead of an +error will be printed if hipBLAS is not found during configuration.

  • +
  • Previously HPX_COMPUTE_HOST_CODE was defined in host code only if HPX was +configured with CUDA or HIP. In this release HPX_COMPUTE_HOST_CODE is +always defined in host code.

  • +
  • An experimental HPX_WITH_PRECOMPILED_HEADERS CMake option has been added +to use precompiled headers when building HPX. This option should not be used +on Windows.

  • +
  • Numerous bug fixes.

  • +
+
+
+
Breaking changes#
+
    +
  • The minimum required CMake version is now 3.17.

  • +
  • The minimum required Boost version is now 1.71.0.

  • +
  • The customization mechanism used to implement and extend sender functionality +and algorithms has been renamed from tag_invoke to tag_dispatch. All +customization of sender functionality should be done by overloading +tag_dispatch.

  • +
  • The following compatibility options have been removed, along with their +compatibility implementations: +- HPX_PROGRAM_OPTIONS_WITH_BOOST_PROGRAM_OPTIONS_COMPATIBILITY +- HPX_WITH_ACTION_BASE_COMPATIBILITY +- HPX_WITH_EMBEDDED_THREAD_POOLS_COMPATIBILITY +- HPX_WITH_POOL_EXECUTOR_COMPATIBILITY. +- HPX_WITH_PROMISE_ALIAS_COMPATIBILITY +- HPX_WITH_REGISTER_THREAD_COMPATIBILITY +- HPX_WITH_REGISTER_THREAD_OVERLOADS_COMPATIBILITY +- HPX_WITH_THREAD_AWARE_TIMER_COMPATIBILITY +- HPX_WITH_THREAD_EXECUTORS_COMPATIBILITY +- HPX_WITH_THREAD_POOL_OS_EXECUTOR_COMPATIBILITY

  • +
  • The HPX_WITH_THREAD_SCHEDULERS CMake option has been removed. All +schedulers are now enabled when possible.

  • +
  • HPX_WITH_INIT_START_OVERLOADS_COMPATIBILITY has been turned off by default.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #5423 - Fix lvalue-ref qualified connect for when_all-sender

  • +
  • Issue #5412 - Link error

  • +
  • Issue #5397 - Performance regression in thread annotations

  • +
  • Issue #5395 - HPX 1.7.0-rc1 fails to build icw APEX + OTF2

  • +
  • Issue #5385 - HPX 1.7 crashes on Piz Daint > 64 nodes

  • +
  • Issue #5380 - CMake should search for asio package installed on the +system

  • +
  • Issue #5378 - HPX 1.7.0 stopped building on Fedora

  • +
  • Issue #5369 - HPX 1.6 and master hangs on Summit for > 64 nodes

  • +
  • Issue #5358 - HPX init fails for single-core environments

  • +
  • Issue #5345 - Rename P2220 property CPOs?

  • +
  • Issue #5333 - HPX does not compile on the new Mac OSX using the M1 chip

  • +
  • Issue #5317 - Consider making hipblas optional

  • +
  • Issue #5306 - asio fails to build with CUDA 10.0

  • +
  • Issue #5294 - execution::on should be based on +execution::schedule

  • +
  • Issue #5275 - HPX V1.6.0 fails on Fedora release

  • +
  • Issue #5270 - HPX-1.6.0 fails to build on Windows 10

  • +
  • Issue #5257 - Allow triggering the output of OS thread affinity from +configuration settings

  • +
  • Issue #5246 - HPX fails to build on ppc64le

  • +
  • Issue #5232 - Annotation using hpx::util::annotated_function not +working

  • +
  • Issue #5222 - Build and link errors with ittnotify enabled

  • +
  • Issue #5204 - Move algorithms to tag_fallback_dispatch

  • +
  • Issue #5163 - Remove module-specific compatibility and deprecation +options

  • +
  • Issue #5161 - Bump required CMake version to 3.17

  • +
  • Issue #5143 - Searching for HPX-Application to generate work on multiple +Nodes

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #5438 - Delete datapar/foreach_tests.hpp

  • +
  • PR #5437 - Add back explicit -pthread flags when available

  • +
  • PR #5435 - This adds support for systems that assume all types are +bitwise serializable by default

  • +
  • PR #5434 - Update CUDA polling logging to be more verbose

  • +
  • PR #5433 - Fix when_all_sender connect for references

  • +
  • PR #5432 - Add deprecation warnings for v1.8

  • +
  • PR #5431 - Rename the new P0443/P2300 executor to +thread_pool_scheduler

  • +
  • PR #5430 - Revert “Adding the missing defined for +HPX_HAVE_DEPRECATION_WARNINGS

  • +
  • PR #5427 - Removing unneeded typedef

  • +
  • PR #5426 - Adding more concept checks for sender/receiver algorithms

  • +
  • PR #5425 - Adding the missing defined for +HPX_HAVE_DEPRECATION_WARNINGS

  • +
  • PR #5424 - Disable Vc in final docker image created in CI

  • +
  • PR #5422 - Adding execution::experimental::bulk algorithm

  • +
  • PR #5420 - Update logic to find threading library

  • +
  • PR #5418 - Reduce max size and number of files in ccache cache

  • +
  • PR #5417 - Final release notes for 1.7.0

  • +
  • PR #5416 - Adapt uninitialized_value_construct and +uninitialized_value_construct_n to C++ 20

  • +
  • PR #5415 - Adapt uninitialized_default_construct and +uninitialized_default_construct_n to C++ 20

  • +
  • PR #5414 - Improve integration of futures and senders

  • +
  • PR #5413 - Fixing sender/receiver code base to compile with MSVC

  • +
  • PR #5407 - Handle exceptions thrown during initialization of parcel +handler

  • +
  • PR #5406 - Simplify dispatching to annotation handlers

  • +
  • PR #5405 - Fetch Asio automatically in perftests CI

  • +
  • PR #5403 - Create generic executor that adds annotations to any other +executor

  • +
  • PR #5402 - Adapt uninitialized_fill and uninitialized_fill_n to +C++ 20

  • +
  • PR #5401 - Modernize a variety of facilities related to parallel +algorithms

  • +
  • PR #5400 - Fix sliding semaphore test

  • +
  • PR #5399 - Rename leftover tag_fallback_invoke to +tag_fallback_dispatch

  • +
  • PR #5398 - Improve logging in AGAS symbol namespace

  • +
  • PR #5396 - Introduce compatibility layer for collective operations

  • +
  • PR #5394 - Enable OTF2 in APEX CI configuration

  • +
  • PR #5393 - Update APEX tag

  • +
  • PR #5392 - Fixing wrong usage of std::forward

  • +
  • PR #5391 - Fix forwarding in transform_receiver constructor

  • +
  • PR #5390 - Make sure shared priority scheduler steals tasks on the +current NUMA domain when (core) stealing is enabled

  • +
  • PR #5389 - Adapt uninitialized_move and uninitialized_move_n to +C++ 20

  • +
  • PR #5388 - Fixing gather_there for used with lvalue reference +argument

  • +
  • PR #5387 - Extend thread state logging and change default stealing +parameters

  • +
  • PR #5386 - Attempt to fix the startup hang with nodes > 32

  • +
  • PR #5384 - Remove HPX 1.5.0 deprecations

  • +
  • PR #5382 - Prefer installed Asio before considering FetchContent

  • +
  • PR #5379 - Allow using pre-downloaded (not installed) versions of Asio +and/or Apex

  • +
  • PR #5376 - Remove unnecessary explicit listing of library modules.rst +files in CMakeLists.txt

  • +
  • PR #5375 - Slight performance improvement for hpx::copy and +hpx::move et.al.

  • +
  • PR #5374 - Remove unnecessary moves from future sender implementations

  • +
  • PR #5373 - More changes to clang-cuda Jenkins configuration

  • +
  • PR #5372 - Slight improvements to min/max/minmax_element algorithms

  • +
  • PR #5371 - Adapt uninitialized_copy and uninitialized_copy_n to +C++ 20

  • +
  • PR #5370 - Decay types in just_sender value_types to match +stored types

  • +
  • PR #5367 - Disable pkgconfig by default again on macOS

  • +
  • PR #5365 - Use ccache for Jenkins builds on Piz Daint

  • +
  • PR #5363 - Update cudatoolkit module name in clang-cuda Jenkins +configuration

  • +
  • PR #5362 - Adding channel_communicator

  • +
  • PR #5361 - Fix compilation with MPI enabled

  • +
  • PR #5360 - Update APEX and asio tags

  • +
  • PR #5359 - Fix check for pu-step in single-core case

  • +
  • PR #5357 - Making sure collective operations can be reused by +preallocating communicator

  • +
  • PR #5356 - Update API documentation

  • +
  • PR #5355 - Make the sequenced_executor processing_units_count +member function const

  • +
  • PR #5354 - Making sure default_stack_size is defined whenever +declared

  • +
  • PR #5353 - Add CUDA timestamp support to HPX Hardware Clock

  • +
  • PR #5352 - Adding missing includes

  • +
  • PR #5351 - Adding enable_logging/disable_logging API functions

  • +
  • PR #5350 - Adapt lexicographical_compare to C++20

  • +
  • PR #5349 - Update minimum boost version needed on the docs

  • +
  • PR #5348 - Rename tag_invoke and related facilities to +tag_dispatch

  • +
  • PR #5347 - Remove make_ prefix for executor properties

  • +
  • PR #5346 - Remove and disable compatibility options for 1.7.0

  • +
  • PR #5343 - Fix timed_executor static cast conversion

  • +
  • PR #5342 - Refactor CUDA event polling

  • +
  • PR #5341 - Adding make_with_annotation and get_annotation +properties

  • +
  • PR #5339 - Making sure hpx::util::hardware::timestamp() is always +defined

  • +
  • PR #5338 - Fixing timed_executor specializations of customization +points

  • +
  • PR #5335 - Make partial_algorithm work with any number of arguments

  • +
  • PR #5334 - Follow up iter_sent include on #5225

  • +
  • PR #5332 - Simplify tag_invoke and friends

  • +
  • PR #5331 - More work on cleaning up executor CPOs

  • +
  • PR #5330 - Add option to disable pkgconfig generation

  • +
  • PR #5328 - Adapt data parallel support using std-simd

  • +
  • PR #5327 - Fix missing ifdef HPX_SMT_PAUSE

  • +
  • PR #5326 - Adding resize() to serialize_buffer allowing to +shrink its size

  • +
  • PR #5324 - Add get member functions to async_rw_mutex proxy objects +for explicitly getting the wrapped value

  • +
  • PR #5323 - Add keep_future algorithm

  • +
  • PR #5322 - Replace executor customization point implementations with +tag_invoke

  • +
  • PR #5321 - Seperate segmented algorithms for reduce

  • +
  • PR #5320 - Fix is_sender trait and other small fixes to p0443 traits

  • +
  • PR #5319 - gcc 11.1 c++20 build fixes

  • +
  • PR #5318 - Make hipblas dependency optional as not always available

  • +
  • PR #5316 - Attempt to fix checking for libatomic

  • +
  • PR #5315 - Add explicit keyword to fixture constructor

  • +
  • PR #5314 - Fix a race condition in async mpi affecting limiting executor

  • +
  • PR #5312 - Use local runtime and local headers in local-only modules and +tests

  • +
  • PR #5311 - Add GCC 11 builder to jenkins

  • +
  • PR #5310 - Adding hpx::execution::experimental::task_group

  • +
  • PR #5309 - Seperate datapar

  • +
  • PR #5308 - Seperate segmented algorithms for find, find_if, +find_if_not

  • +
  • PR #5307 - Seperate segmented algorithms for fill and generate

  • +
  • PR #5304 - Fix compilation of sender CPOs with nvcc

  • +
  • PR #5300 - Remove PRIVATE flag that was propagated into the +LANGUAGES

  • +
  • PR #5298 - Seperate datapar

  • +
  • PR #5297 - Specify exact cmake and ninja versions when loading them in +jenkins jobs

  • +
  • PR #5295 - Update clang-newest configuration to use clang 12 and Boost +1.76.0

  • +
  • PR #5293 - Fix Clang 11 cuda_future test bug

  • +
  • PR #5292 - Add async_rw_mutex based on senders

  • +
  • PR #5291 - “Fix” termination detection

  • +
  • PR #5290 - Fixed source file line statements in examples documentation

  • +
  • PR #5289 - Allow splitting of futures holding std::tuple

  • +
  • PR #5288 - Move algorithms to tag_fallback_invoke

  • +
  • PR #5287 - Move algorithms to tag_fallback_invoke

  • +
  • PR #5285 - Fix clang-format failure on master

  • +
  • PR #5284 - Replacing util::function_nonser on std::function in +hpx_init

  • +
  • PR #5282 - Update Boost for daint 20.11 after update

  • +
  • PR #5281 - Fix Segmentation fault on foreach_datapar_zipiter

  • +
  • PR #5280 - Avoid modulo by zero in counting_iterator test

  • +
  • PR #5279 - Fix more GCC 10 deprecation warnings

  • +
  • PR #5277 - Small fixes and improvements to CUDA/MPI polling

  • +
  • PR #5276 - Fix typo in docs

  • +
  • PR #5274 - More P1897 algorithms

  • +
  • PR #5273 - Retry CDash submissions on failure

  • +
  • PR #5272 - Fix bogus deprecation warnings with GCC 10

  • +
  • PR #5271 - Correcting target ids for symbol_namespace::iterate

  • +
  • PR #5268 - Adding generic require, require_concept, and +query properties

  • +
  • PR #5267 - Support annotations in hpx::transform_reduce

  • +
  • PR #5266 - Making late command line options available for local runtime

  • +
  • PR #5265 - Leverage no_unique_address for member_pack

  • +
  • PR #5264 - Adopt format in more places

  • +
  • PR #5262 - Install HPX in Rostam Jenkins jobs

  • +
  • PR #5261 - Limit Rostam Jenkins jobs to marvin partition temporarily

  • +
  • PR #5260 - Separate segmented algorithms for transform_reduce

  • +
  • PR #5259 - Making sure late command line options are recognized as +configuration options

  • +
  • PR #5258 - Allow for HPX algorithms being invoked with std execution +policies

  • +
  • PR #5256 - Separate segmented algorithms for transform

  • +
  • PR #5255 - Future/sender adapters

  • +
  • PR #5254 - Fixing datapar

  • +
  • PR #5253 - Add utility to format ranges

  • +
  • PR #5252 - Remove uses of Boost.Bimap

  • +
  • PR #5251 - Banish <iostream> from library headers

  • +
  • PR #5250 - Try fixing vc circle ci

  • +
  • PR #5249 - Adding missing header

  • +
  • PR #5248 - Use old Piz Daint modules after upgrade

  • +
  • PR #5247 - Significantly speedup simple for_each, for_loop, and +transform

  • +
  • PR #5245 - P1897 operator| overloads

  • +
  • PR #5244 - P1897 when_all

  • +
  • PR #5243 - Make sure HPX_DEBUG is set based on HPX’s build type, not +consuming project’s build type

  • +
  • PR #5242 - Moving last files unrelated to parcel layer to modules

  • +
  • PR #5240 - change namespace for transform_loop.hpp

  • +
  • PR #5238 - Make sure annotations are used in the binary transform

  • +
  • PR #5237 - Add P1897 just, just_on, and on algorithms

  • +
  • PR #5236 - Add an example demonstrating the use of the +invoke_function_action facility

  • +
  • PR #5235 - Attempting to fix datapar compilation issues

  • +
  • PR #5234 - Fix small typo in --hpx:local option description

  • +
  • PR #5233 - Only find Boost.Iostreams if required for plugins

  • +
  • PR #5231 - Sort printed config options

  • +
  • PR #5230 - Fix C++20 replace algo adaptation misses

  • +
  • PR #5229 - Remove leftover Boost include from sync_wait.hpp

  • +
  • PR #5228 - Print module name only if it has custom configuration +settings

  • +
  • PR #5227 - Update .codespell_whitelist

  • +
  • PR #5226 - Use new docker image in all CircleCI steps

  • +
  • PR #5225 - Adapt reverse to C++20

  • +
  • PR #5224 - Separate segmented algorithms for none_of, any_of and +all_of

  • +
  • PR #5223 - Fixing build system for ittnotify

  • +
  • PR #5221 - Moving LCO related files to modules

  • +
  • PR #5220 - Seperate segmented algorithms for count and count_if

  • +
  • PR #5218 - Seperate segmented algorithms for adjacent_find

  • +
  • PR #5217 - Add a HIP github action

  • +
  • PR #5215 - Update ROCm to 4.0.1 on Rostam

  • +
  • PR #5214 - Fix clang-format error in sender.hpp

  • +
  • PR #5213 - Removing ESSENTIAL option to the doc example

  • +
  • PR #5212 - Seperate segmented algorithms for for_each_n

  • +
  • PR #5211 - Minor adapted algos fixes

  • +
  • PR #5210 - Fixing is_invocable deprecation warnings

  • +
  • PR #5209 - Moving more files into modules (actions, components, +init_runtime, etc.)

  • +
  • PR #5208 - Add examples and explanation on when +tag_fallback/priority are useful

  • +
  • PR #5207 - Always define HPX_COMPUTE_HOST_CODE for host code

  • +
  • PR #5206 - Add formatting exceptions for libhpx to +create_module_skeleton.py

  • +
  • PR #5205 - Moving all distribution policies into modules

  • +
  • PR #5203 - Move copy algorithms to tag_fallback_invoke

  • +
  • PR #5202 - Make HPX_WITH_PSEUDO_DEPENDENCIES a cache variable

  • +
  • PR #5201 - Replaced tag_invoke with tag_fallback_invoke for +adjacent_find algorithm

  • +
  • PR #5200 - Moving files to (distributed) runtime module

  • +
  • PR #5199 - Update ICC module name on Piz Daint Jenkins configuration

  • +
  • PR #5198 - Add doxygen documentation for thread_schedule_hint

  • +
  • PR #5197 - Attempt to fix compilation of context implementations with +unity build enabled

  • +
  • PR #5196 - Re-enable component tests

  • +
  • PR #5195 - Moving files related to colocation logic

  • +
  • PR #5194 - Another attempt at fixing the Fedora 35 problem

  • +
  • PR #5193 - Components module

  • +
  • PR #5192 - Adapt replace(_if) to C++20

  • +
  • PR #5190 - Set compatibility headers by default to on

  • +
  • PR #5188 - Bump Boost minimum version to 1.71.0

  • +
  • PR #5187 - Force CMake to set the -std=c++XX flag

  • +
  • PR #5186 - Remove message to print .cu extension whenever .cu files are +encountered

  • +
  • PR #5185 - Remove some minor unnecessary CMake options

  • +
  • PR #5184 - Remove some leftover HPX_WITH_*_SCHEDULER uses

  • +
  • PR #5183 - Remove dependency on boost/iterators/iterator_categories.hpp

  • +
  • PR #5182 - Fixing Fedora 35 for Power architectures

  • +
  • PR #5181 - Bump version number and tag post 1.6.0 release

  • +
  • PR #5180 - Fix htts_v2 tests linking

  • +
  • PR #5179 - Make sure --hpx:local command line option is respected +with networking is off but distributed runtime is on

  • +
  • PR #5177 - Remove module cmake options

  • +
  • PR #5176 - Starting to separate segmented algorithms: for_each

  • +
  • PR #5174 - Don’t run segmented algorithms twice on CircleCI

  • +
  • PR #5173 - Fetching APEX using cmake FetchContent

  • +
  • PR #5172 - Add separate local-only entry point

  • +
  • PR #5171 - Remove HPX_WITH_THREAD_SCHEDULERS CMake option

  • +
  • PR #5170 - Add HPX_WITH_PRECOMPILED_HEADERS option

  • +
  • PR #5166 - Moving some action tests to modules

  • +
  • PR #5165 - Require cmake 3.17

  • +
  • PR #5164 - Move thread_pool_suspension_helper files to small utility +module

  • +
  • PR #5160 - Adding checks ensuring modules are not cross-referenced from +other module categories

  • +
  • PR #5158 - Replace boost::asio with standalone asio

  • +
  • PR #5155 - Allow logging when distributed runtime is off

  • +
  • PR #5153 - Components module

  • +
  • PR #5152 - Move more files to performance counter module

  • +
  • PR #5150 - Adapt remove_copy(_if) to C++20

  • +
  • PR #5144 - AGAS module

  • +
  • PR #5125 - Adapt remove and remove_if to C++20

  • +
  • PR #5117 - Attempt to fix segfaults assumed to be caused by +future_data instances going out of scope.

  • +
  • PR #5099 - Allow mixing debug and release builds

  • +
  • PR #5092 - Replace spirit.qi with x3

  • +
  • PR #5053 - Add P0443r14 executor and a a few P1897 algorithms

  • +
  • PR #5044 - Add performance test in jenkins and reports

  • +
+
+
+
+
HPX V1.6.0 (Feb 17, 2021)#
+
+
General changes#
+

This release continues the focus on C++20 conformance with multiple new +algorithms adapted to be C++20 conformant and becoming customization point +objects (CPOs). We have also added experimental support for HIP, allowing +previous CUDA features to now be compiled with hipcc and run on AMD GPUs.

+
    +
  • The following algorithms have been adapted to be C++20 conformant: +adjacent_find, includes, inplace_merge, is_heap, +is_heap_until, is_partitioned, is_sorted, is_sorted_until, +merge, set_difference, set_intersection, +set_symmetric_difference, set_union.

  • +
  • Experimental HIP support can be enabled by compiling HPX with hipcc. All +CUDA functionality in HPX can now be used with HIP. The HIP functionality is +for the time being exposed through the same API as the CUDA functionality, +i.e. no changes are required in user code. The CUDA, and now HIP, +functionality is in the hpx::cuda namespace.

  • +
  • We have added partial_sort based on Francisco Tapia’s implementation.

  • +
  • hpx::init and hpx::start gained new overloads taking an +hpx::init_params struct in 1.5.0. All overloads not taking an +hpx::init_params are now deprecated.

  • +
  • We have added an experimental fork_join_executor. This executor can be +used for OpenMP-style fork-join parallelism, where the latency of a parallel +region is important for performance.

  • +
  • The parallel_executor now uses a hierarchical spawning scheme for bulk +execution, which improves data locality and performance.

  • +
  • hpx::dataflow can now be used with executors that inject additional +parameters into the call of the user-provided function.

  • +
  • We have added experimental support for properties as proposed in P2220. +Currently the only supported property is the scheduling hint on +parallel_executor.

  • +
  • hpx::util::annotated_function can now be passed a dynamically +generated std::string.

  • +
  • In moving functionality to new namespaces, old names have been deprecated. A +deprecation warning will be issued if you are using deprecated functionality, +with instructions on how to correct or ignore the warning.

  • +
  • We have removed all support for C and Fortran from our build system.

  • +
  • We have further reduced the use of Boost types within HPX +(boost::system::error_code and boost::detail::spinlock).

  • +
  • We have enabled more warnings in our CI builds (unused variables and unused +typedefs).

  • +
+
+
+
Breaking changes#
+
    +
  • hpxMP support has been completely removed.

  • +
  • The verbs parcelport has been removed.

  • +
  • The following compatibility options have been disabled by default: +HPX_WITH_ACTION_BASE_COMPATIBILITY, +HPX_WITH_REGISTER_THREAD_COMPATIBILITY, +HPX_WITH_PROMISE_ALIAS_COMPATIBILITY, +HPX_WITH_UNSCOPED_ENUM_COMPATIBILITY, +HPX_PROGRAM_OPTIONS_WITH_BOOST_PROGRAM_OPTIONS_COMPATIBILITY, +HPX_WITH_EMBEDDED_THREAD_POOLS_COMPATIBILITY, +HPX_WITH_THREAD_POOL_OS_EXECUTOR_COMPATIBILITY, +HPX_WITH_THREAD_EXECUTORS_COMPATIBILITY, +HPX_THREAD_AWARE_TIMER_COMPATIBILITY, +HPX_WITH_POOL_EXECUTOR_COMPATIBILITY. Unless noted here, the above +functionalities do not come with replacements. Unscoped enumerations have been +replaced by scoped enumerations. Previously deprecated unscoped enumerations +are disabled by HPX_WITH_UNSCOPED_ENUM_COMPATIBILITY. Newly deprecated +unscoped enumerations have been given deprecation warnings and replaced by +scoped enumerations. hpx::promise has been replaced with +hpx::distributed::promise. hpx::program_options is a drop-in +replacement for boost::program_options. +hpx::execution::parallel_executor now has constructors which take a thread +pool, covering the use case of hpx::threads::executors::pool_executor. A +pool can be supplied with hpx::resource::get_thread_pool.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #5148 - runtime_support.hpp does not work with newer cling

  • +
  • Issue #5147 - Wrong results with parallel reduce

  • +
  • Issue #5129 - Missing specialization for std::hash<hpx::thread::id>

  • +
  • Issue #5126 - Use std::string for task annotations

  • +
  • Issue #5115 - Don’t expect hwloc to always report Cores

  • +
  • Issue #5113 - Handle threadmanager exceptions during startup

  • +
  • Issue #5112 - libatomic problems causing unexpected fails

  • +
  • Issue #5089 - Remove non-BSL files

  • +
  • Issue #5088 - Unwrapping problem

  • +
  • Issue #5087 - Remove hpxMP support

  • +
  • Issue #5077 - PAPI counters are not accessible when HPX is installed

  • +
  • Issue #5075 - Make the structs in all iter_sent.hpp lower case

  • +
  • Issue #5067 - Bug string_util/split.hpp

  • +
  • Issue #5049 - Change back the hipcc jenkins config to the fury partition +on rostam

  • +
  • Issue #5038 - Not all examples link in the latest HPX master

  • +
  • Issue #5035 - Build with HPX_WITH_EXAMPLES fails

  • +
  • Issue #5019 - Broken help string for hpx

  • +
  • Issue #5016 - hpx::parallel::fill fails compiling

  • +
  • Issue #5014 - Rename all .cc to .cpp and .hh to .hpp

  • +
  • Issue #4988 - MPI is not finalized if running with only one locality

  • +
  • Issue #4978 - Change feature test macros to expand to zero/one

  • +
  • Issue #4949 - Crash when not enabling TCP parcelport

  • +
  • Issue #4933 - Improve test coverage for unused variable warnings etc.

  • +
  • Issue #4878 - HPX mpi async might call MPI_FINALIZE before app calls it

  • +
  • Issue #4127 - Local runtime entry-points

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #5178 - Fix parallel remove/remove_copy/transform +namespace references in docs

  • +
  • PR #5169 - Attempt to get Piz Daint jenkins setup running after +maintenance

  • +
  • PR #5168 - Remove include of itself

  • +
  • PR #5167 - Fixing deprecation warnings that slipped through the net

  • +
  • PR #5159 - Update APEX tag to 2.3.1

  • +
  • PR #5154 - Splitting unit tests on circleci to avoid timeouts

  • +
  • PR #5151 - Use C++20 on clang-newest Jenkins CI configuration

  • +
  • PR #5149 - Rename 'module' symbols to avoid keyword conflict

  • +
  • PR #5145 - Adjust handling of CUDA/HIP options in CMake

  • +
  • PR #5142 - Store annotated_function annotations as std::strings

  • +
  • PR #5140 - Scheduler mode

  • +
  • PR #5139 - Fix path problem in pre-commit hook, add summary commit line

  • +
  • PR #5138 - Add program options variable map to resource partitioner init

  • +
  • PR #5137 - Remove the use of boost::throw_exception

  • +
  • PR #5136 - Make sure codespell checks run on CircleCI

  • +
  • PR #5132 - Fixing spelling errors

  • +
  • PR #5131 - Mark counting_iterator member functions as +HPX_HOST_DEVICE

  • +
  • PR #5130 - Adding specialization for std::hash<hpx::thread::id>

  • +
  • PR #5128 - Fixing environment handling for FreeBSD

  • +
  • PR #5127 - Fix typo in fibonacci documentation

  • +
  • PR #5123 - Reduce vector sizes in partial sort benchmarks when running +in debug mode

  • +
  • PR #5122 - Making sure exceptions during runtime initialization are +correctly reported

  • +
  • PR #5121 - Working around hwloc limitation on certain platforms

  • +
  • PR #5120 - Fixing compatibility warnings in hpx::transform +implementation

  • +
  • PR #5119 - Use sequential_find and friends from separate detail +header

  • +
  • PR #5116 - Fix compilation with timer pool off

  • +
  • PR #5114 - Fix 5112 - make sure libatomic is used when needed

  • +
  • PR #5109 - Remove default runtime mode argument from init overload, +again

  • +
  • PR #5108 - Refactor iter_sent.hpp to make structs lowercase

  • +
  • PR #5107 - Relax dataflow internals

  • +
  • PR #5106 - Change initialization of property CPOs to satisfy older nvcc +versions

  • +
  • PR #5104 - Fix regeneration of two files that trigger unnecessary +rebuilds

  • +
  • PR #5103 - Remove default runtime mode argument from start/init +overloads

  • +
  • PR #5102 - Untie deprecated thread enums from the CMake option

  • +
  • PR #5101 - Update APEX tag for 1.6.0

  • +
  • PR #5100 - Bump minimum required Boost version to 1.66 and update CI +configurations

  • +
  • PR #5098 - Minor fixes to public API listing

  • +
  • PR #5097 - Remove hpxMP support

  • +
  • PR #5096 - Remove fractals examples

  • +
  • PR #5095 - Use all AMD nodes again on rostam

  • +
  • PR #5094 - Attempt to remove macOS workaround for GH actions environment

  • +
  • PR #5093 - Remove verbs parcelport

  • +
  • PR #5091 - Avoid moving from lvalues

  • +
  • PR #5090 - Adopt C++20 std::endian

  • +
  • PR #5085 - Update daint CI to use Boost 1.75.0

  • +
  • PR #5084 - Disable compatibility options for 1.6.0 release

  • +
  • PR #5083 - Remove duplicated call to the limiting_executor in +future_overhead test

  • +
  • PR #5079 - Add checks to make sure that MPI/CUDA polling is enabled/not +disabled too early

  • +
  • PR #5078 - Add install lib directory to list of component search paths

  • +
  • PR #5076 - Fix a typo in the jenkins clang-newest cmake config

  • +
  • PR #5074 - Fixing warnings generated by MSVC

  • +
  • PR #5073 - Allow using noncopyable types with unwrapping

  • +
  • PR #5072 - Fix is_convertible args in result_types

  • +
  • PR #5071 - Fix unused parameters

  • +
  • PR #5070 - Fix unused variables warnings in hipcc

  • +
  • PR #5069 - Add support for sentinels to adjacent_find

  • +
  • PR #5068 - Fix string split function

  • +
  • PR #5066 - Adapt search to C++20 and Range TS

  • +
  • PR #5065 - Fix hpx::range::adjacent_find doxygen function signatures

  • +
  • PR #5064 - Refactor runtime configuration, command line handling, and +resource partitioner

  • +
  • PR #5063 - Limit the device code guards to the distributed parts of the +future_overhead bench

  • +
  • PR #5061 - Remove hipcc guards in examples and tests

  • +
  • PR #5060 - Fix deprecation warnings generated by msvc

  • +
  • PR #5059 - Add warning about suspending/resuming the runtime in +multi-locality scenarios

  • +
  • PR #5057 - Fix unused variable warnings

  • +
  • PR #5056 - Fix hpx::util::get

  • +
  • PR #5055 - Remove hipcc guards

  • +
  • PR #5054 - Fix typo

  • +
  • PR #5051 - Adapt transform to C++20

  • +
  • PR #5050 - Replace old init overloads in tests and examples

  • +
  • PR #5048 - Limit jenkins hipcc to the reno node

  • +
  • PR #5047 - Limit cuda jenkins run to nodes with exclusively Nvidia GPUs

  • +
  • PR #5046 - Convert thread and future enums to class enums

  • +
  • PR #5043 - Improve hpxrun.py for Phylanx

  • +
  • PR #5042 - Add missing header to partial sort test

  • +
  • PR #5041 - Adding Francisco Tapia’s implementation of partial_sort

  • +
  • PR #5040 - Remove generated headers left behind from a previous +configuration

  • +
  • PR #5039 - Fix GCC 10 release builds

  • +
  • PR #5037 - Add is_invocable typedefs to top-level hpx namespace +and public API list

  • +
  • PR #5036 - Deprecate hpx::util::decay in favor of std::decay

  • +
  • PR #5034 - Use versioned container image on CircleCI

  • +
  • PR #5033 - Implement P2220 properties module

  • +
  • PR #5032 - Do codespell comparison only on files changed from common +ancestor

  • +
  • PR #5031 - Moving traits files to actions_base

  • +
  • PR #5030 - Add codespell version print in circleci

  • +
  • PR #5029 - Work around problems in GitHub actions macOS builder

  • +
  • PR #5028 - Moving move files to naming and naming_base

  • +
  • PR #5027 - Lessen constraints on certain algorithm arguments

  • +
  • PR #5025 - Adapt is_sorted and is_sorted_until to C++20

  • +
  • PR #5024 - Moving naming_base to full modules

  • +
  • PR #5022 - Remove C language from CMakeLists.txt

  • +
  • PR #5021 - Warn about unused arguments given to add_hpx_module

  • +
  • PR #5020 - Fixing help string

  • +
  • PR #5018 - Update CSCS jenkins configuration to clang 11

  • +
  • PR #5017 - Fixing broken backwards compatibility for +hpx::parallel::fill

  • +
  • PR #5015 - Detect if generated global header conflicts with explicitly +listed module headers

  • +
  • PR #5012 - Properly reset pointer tracking data in output_archive

  • +
  • PR #5011 - Inspect command line tweaks

  • +
  • PR #5010 - Creating AGAS module

  • +
  • PR #5009 - Replace boost::system::error_code with +std::error_code

  • +
  • PR #5008 - Replace uses of boost::detail::spinlock

  • +
  • PR #5007 - Bump minimal Boost version to 1.65.0

  • +
  • PR #5006 - Adapt is_partitioned to C++20

  • +
  • PR #5005 - Making sure reduce_by_key compiles again

  • +
  • PR #5004 - Fixing template specializations that make extra archive data +types unique across module boundaries

  • +
  • PR #5003 - Relax dataflow argument constraints

  • +
  • PR #5001 - Add <random> inspect check

  • +
  • PR #4999 - Attempt to fix MacOS Github action error

  • +
  • PR #4997 - Fix unused variable and typedef warnings

  • +
  • PR #4996 - Adapt adjacent_find to C++20

  • +
  • PR #4995 - Test all schedulers in cross_pool_injection test except +shared_priority_queue_scheduler

  • +
  • PR #4993 - Fix deprecation warnings

  • +
  • PR #4991 - Avoid unnecessarily including entire modules

  • +
  • PR #4990 - Fixing some warnings from HPX complaining about use of +obsolete types

  • +
  • PR #4989 - add a *destroy* trait for ParcelPort plugins

  • +
  • PR #4986 - Remove serialization to functional module dependency

  • +
  • PR #4985 - Compatibility header generation

  • +
  • PR #4980 - Add ranges overloads to for_loop (and variants)

  • +
  • PR #4979 - Actually enable unity builds on Jenkins

  • +
  • PR #4977 - Cleaning up debug::print functionalities

  • +
  • PR #4976 - Remove indirection layer in at_index_impl

  • +
  • PR #4975 - Remove indirection layer in at_index_impl

  • +
  • PR #4973 - Avoid warnings/errors for older gcc complaining about +multi-line comments

  • +
  • PR #4970 - Making set algorithms conform to C++20

  • +
  • PR #4969 - Moving is_execution_policy and friends into namespace +hpx

  • +
  • PR #4968 - Enable deprecation warnings for 1.6.0 and move any +functionality to hpx namespace

  • +
  • PR #4967 - Define deprecation macros conditionally

  • +
  • PR #4966 - Add clang-format and cmake-format version prints

  • +
  • PR #4965 - Making is_heap and is_heap_until conforming to C++20

  • +
  • PR #4964 - Adding parallel make_heap

  • +
  • PR #4962 - Fix external timer function pointer exports

  • +
  • PR #4960 - Fixing folder names for module tests and examples

  • +
  • PR #4959 - Adding communications set

  • +
  • PR #4958 - Deprecate tuple and timing functionality in hpx::util

  • +
  • PR #4957 - Fixing unity build option for parcelports

  • +
  • PR #4953 - Fixing MSVC problems after recent restructurings

  • +
  • PR #4952 - Make parallel_executor use thread_pool_executor +spawning mechanism

  • +
  • PR #4948 - Clean up old artifacts better and more aggressively on +Jenkins

  • +
  • PR #4947 - Add HIP support for AMD GPUs

  • +
  • PR #4945 - Enable HPX_WITH_UNITY_BUILD option on one of the Jenkins +configurations

  • +
  • PR #4943 - Move public hpx::parallel::execution functionality to +hpx::execution

  • +
  • PR #4938 - Post release cleanup

  • +
  • PR #4858 - Extending resilience APIs to support distributed invocations

  • +
  • PR #4744 - Fork-join executor

  • +
  • PR #4665 - Implementing sender, receiver, and operation_state +concepts in terms of P0443r13

  • +
  • PR #4649 - Split libhpx into multiple libraries

  • +
  • PR #4642 - Implementing operation_state concept in terms of P0443r13

  • +
  • PR #4640 - Implementing receiver concept in terms of P0443r13

  • +
  • PR #4622 - Sanitizer fixes

  • +
+
+
+
+
HPX V1.5.1 (Sep 30, 2020)#
+
+
General changes#
+

This is a patch release. It contains the following changes:

+
    +
  • Remove restriction on suspending runtime with multiple localities, users are +now responsible for synchronizing work between localities before suspending.

  • +
  • Fixes several compilation problems and warnings.

  • +
  • Adds notes in the documentation explaining how to cite HPX.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #4971 - Parallel sort fails to compile with C++20

  • +
  • Issue #4950 - Build with HPX_WITH_PARCELPORT_ACTION_COUNTERS ON fails

  • +
  • Issue #4940 - Codespell report for “HPX” (on fossies.org)

  • +
  • Issue #4937 - Allow suspension of runtime for multiple localities

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #4982 - Add page about citing HPX to documentation

  • +
  • PR #4981 - Adding the missing include

  • +
  • PR #4974 - Remove leftover format export hack

  • +
  • PR #4972 - Removing use of get_temporary_buffer and return_temporary_buffer

  • +
  • PR #4963 - Renaming files to avoid warnings from the vs build system

  • +
  • PR #4951 - Fixing build if HPX_WITH_PARCELPORT_ACTION_COUNTERS=On

  • +
  • PR #4946 - Allow suspension on multiple localities

  • +
  • PR #4944 - Fix typos reported by fossies codespell report

  • +
  • PR #4941 - Adding some explanation to README about how to cite HPX

  • +
  • PR #4939 - Small changes

  • +
+
+
+
+
HPX V1.5.0 (Sep 02, 2020)#
+
+
General changes#
+

The main focus of this release is on APIs and C++20 conformance. We have added +many new C++20 features and adapted multiple algorithms to be fully C++20 +conformant. As part of the modularization we have begun specifying the public +API of HPX in terms of headers and functionality, and aligning it more closely +to the C++ standard. All non-distributed modules are now in place, along with an +experimental option to completely disable distributed features in HPX. We have +also added experimental asynchronous MPI and CUDA executors. Lastly this release +introduces CMake targets for depending projects, performance improvements, +and many bug fixes.

+
    +
  • We have added the C++20 features hpx::jthread and hpx::stop_token. +hpx::condition_variable_any now exposes new functions supporting +hpx::stop_token.

  • +
  • We have added hpx::stable_sort based on Francisco Tapia’s +implementation.

  • +
  • We have adapted existing synchronization primitives to be fully conformant +C++20: hpx::barrier, hpx::latch, hpx::counting_semaphore, and +hpx::binary_semaphore.

  • +
  • We have started using customization point objects (CPOs) to make the +corresponding algorithms fully conformant to C++20 as well as to make +algorithm extension easier for the user. all_of/any_of/none_of, +copy, count, destroy, equal, fill, find, for_each, +generate, mismatch, move, reduce, transform_reduce are +using those CPOs (all in namespace hpx). We also have adapted their +corresponding hpx::ranges versions to be conforming to C++20 in this +release.

  • +
  • We have adapted support for co_await to C++20, in addition to +hpx::future it now also supports hpx::shared_future. We have also +added allocator support for futures returned by co_return. It is no longer +in the experimental namespace.

  • +
  • We added serialization support for std::variant and std::tuple.

  • +
  • result_of and is_callable are now deprecated and replaced by +invoke_result and is_invocable to conform to C++20.

  • +
  • We continued with the modularization, making it easier for us to add the new +experimental HPX_WITH_DISTRIBUTED_RUNTIME CMake option (see below) . An +significant amount of headers have been deprecated. We adapted the namespaces +and headers we could to be closer to the standard ones (Public API). +Depending code should still compile, however warnings are now generated +instructing to change the include statements accordingly.

  • +
  • It is now possible to have a basic CUDA support including a helper function to +get a future from a CUDA stream and target handling. They are available under +the hpx::cuda::experimental namespace and they can be enabled with the +-DHPX_WITH_ASYNC_CUDA=ON CMake option.

  • +
  • We added a new hpx::mpi::experimental namespace for getting futures from +an asynchronous MPI call and a new minimal MPI executor +hpx::mpi::experimental::executor. These can be enabled with the +-DHPX_WITH_ASYNC_MPI=On CMake option.

  • +
  • A polymorphic executor has been implemented to reduce compile times as a +function accepting executors can potentially be instantiated only once instead +of multiple times with different executors. It accepts the function signature +as a template argument. It needs to be constructed from any other executor. +Please note, that the function signatures that can be scheduled using +then_execute, bulk_sync_execute, bulk_async_execute and +bulk_then_execute are slightly different (See the comment in +PR #4514 for more details).

  • +
  • The underlying executor of block_executor has been updated to a newer one.

  • +
  • We have added a parameter to auto_chunk_size to control the amount of +iterations to measure.

  • +
  • All executor parameter hooks can now be exposed through the executor itself. +This will allow to deprecate the .with() functionality on execution +policies in the future. This is also a first step towards simplifying our +executor APIs in preparation for the upcoming C++23 executors +(senders/receivers).

  • +
  • We have moved all of the existing APIs related to resiliency into the +namespace hpx::resiliency::experimental. Please note this is a breaking +change without backwards-compatibility option. We have converted all of those +APIs to be based on customization point objects. Two new executors have been +added to enable easy integration of the existing resiliency features with +other facilities (like the parallel algorithms): replay_executor and +replicate_executor.

  • +
  • We have added performance counters type information (aggregating, +monotonically increasing, average count, average timer, etc.).

  • +
  • HPX threads are now re-scheduled on the same worker thread they were suspended +on to avoid cache misses from moving from one thread to the other. This +behavior doesn’t prevent the thread from being stolen, however.

  • +
  • We have added a new configuration option hpx.exception_verbosity to allow +to control the level of verbosity of the exceptions (3 levels available).

  • +
  • broadcast_to, broadcast_from, scatter_to and scatter_from have +been added to the collectives, modernization of gather_here and +gather_there with futures taken by rvalue references. See the breaking +change on all_to_all in the next section. None of the collectives need +supporting macros anymore (e.g. specifying the data types used for a +collective operation using HPX_REGISTER_ALLGATHER and similar is not +needed anymore).

  • +
  • New API functions have been added: a) to get the number of cores which are idle +(hpx::get_idle_core_count) and b) returning a bitmask +representing the currently idle cores (hpx::get_idle_core_mask).

  • +
  • We have added an experimental option to only enable the local runtime, you can +disable the distributed runtime with HPX_WITH_DISTRIBUTED_RUNTIME=OFF. You +can also enable the local runtime by using the --hpx:local runtime option.

  • +
  • We fixed task annotations for actions.

  • +
  • The alias hpx::promise to hpx::lcos::promise is now deprecated. You +can use hpx::lcos::promise directly instead. hpx::promise will refer +to the local-only promise in the future.

  • +
  • We have added a prepare_checkpoint API function that calculates the +amount of necessary buffer space for a particular set of arguments +checkpointed.

  • +
  • We have added hpx::upgrade_lock and hpx::upgrade_to_unique_lock, which +make hpx::shared_mutex (and similar) usable in more flexible ways.

  • +
  • We have changed the CMake targets exposed to the user, it now includes +HPX::hpx, HPX::wrap_main (int main as the first HPX thread of +the application, see Starting the HPX runtime), +HPX::plugin, HPX::component. The CMake variables +HPX_INCLUDE_DIRS and HPX_LIBRARIES are deprecated and will be removed +in a future release, you should now link directly to the HPX::hpx CMake +target.

  • +
  • A new example is demonstrating how to create and use a wrapping executor +(quickstart/executor_with_thread_hooks.cpp)

  • +
  • A new example is demonstrating how to disable thread stealing during the +execution of parallel algorithms +(quickstart/disable_thread_stealing_executor.cpp)

  • +
  • We now require for our CMake build system configuration files to be +formatted using cmake-format.

  • +
  • We have removed more dependencies on various Boost libraries.

  • +
  • We have added an experimental option enabling unity builds of HPX using the +-DHPX_WITH_UNITY_BUILD=On CMake option.

  • +
  • Many bug fixes.

  • +
+
+
+
Breaking changes#
+
    +
  • HPX now requires a C++14 capable compiler. We have set the HPX C++ +standard automatically to C++14 and if it needs to be set explicitly, it +should be specified through the CMAKE_CXX_STANDARD setting as mandated +by CMake. The HPX_WITH_CXX* variables are now deprecated and will be +removed in the future.

  • +
  • Building and using HPX is now supported only when using CMake V3.13 or later, +Boost V1.64 or newer, and when compiling with clang V5, gcc V7, or VS2019, or +later. Other compilers might still work but have not been tested thoroughly.

  • +
  • We have added a hpx::init_params struct to pass parameters for HPX +initialization e.g. the resource partitioner callback to initialize thread +pools (Using the resource partitioner).

  • +
  • The all_to_all algorithm is renamed to all_gather, and the new +all_to_all algorithm is not compatible with the old one.

  • +
  • We have moved all of the existing APIs related to resiliency into the +namespace hpx::resiliency::experimental.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #4918 - Rename distributed_executors module

  • +
  • Issue #4900 - Adding JOSS status badge to README

  • +
  • Issue #4897 - Compiler warning, deprecated header used by HPX itself

  • +
  • Issue #4886 - A future bound to an action executing on a different locality doesn’t capture exception state

  • +
  • Issue #4880 - Undefined reference to main build error when HPX_WITH_DYNAMIC_HPX_MAIN=OFF

  • +
  • Issue #4877 - hpx_main might not able to start hpx runtime properly

  • +
  • Issue #4850 - Issues creating templated component

  • +
  • Issue #4829 - Spack package & HPX_WITH_GENERIC_CONTEXT_COROUTINES

  • +
  • Issue #4820 - PAPI counters don’t work

  • +
  • Issue #4818 - HPX can’t be used with IO pool turned off

  • +
  • Issue #4816 - Build of HPX fails when find_package(Boost) is called before FetchContent_MakeAvailable(hpx)

  • +
  • Issue #4813 - HPX MPI Future failed

  • +
  • Issue #4811 - Remove HPX::hpx_no_wrap_main target before 1.5.0 release

  • +
  • Issue #4810 - In hpx::for_each::invoke_projected the hpx::util::decay is misguided

  • +
  • Issue #4787 - transform_inclusive_scan gives incorrect results for non-commutative operator

  • +
  • Issue #4786 - transform_inclusive_scan tries to implicitly convert between types, instead of using the provided conv function

  • +
  • Issue #4779 - HPX build error with GCC 10.1

  • +
  • Issue #4766 - Move HPX.Compute functionality to experimental namespace

  • +
  • Issue #4763 - License file name

  • +
  • Issue #4758 - CMake profiling results

  • +
  • Issue #4755 - Building HPX with support for PAPI fails

  • +
  • Issue #4754 - CMake cache creation breaks when using HPX with mimalloc

  • +
  • Issue #4752 - HPX MPI Future build failed

  • +
  • Issue #4746 - Memory leak when using dataflow icw components

  • +
  • Issue #4731 - Bug in stencil example, calculation of locality IDs

  • +
  • Issue #4723 - Build fail with NETWORKING OFF

  • +
  • Issue #4720 - Add compatibility headers for modules that had their module headers implicitly generated in 1.4.1

  • +
  • Issue #4719 - Undeprecate some module headers

  • +
  • Issue #4712 - Rename HPX_MPI_WITH_FUTURES option

  • +
  • Issue #4709 - Make deprecation warnings overridable in dependent projects

  • +
  • Issue #4691 - Suggestion to fix and enhance the thread_mapper API

  • +
  • Issue #4686 - Fix tutorials examples

  • +
  • Issue #4685 - HPX distributed map fails to compile

  • +
  • Issue #4680 - Build error with HPX_WITH_DYNAMIC_HPX_MAIN=OFF

  • +
  • Issue #4679 - Build error for hpx w/ Apex on Summit

  • +
  • Issue #4675 - build error with HPX_WITH_NETWORKING=OFF

  • +
  • Issue #4674 - Error running Quickstart tests on OS X

  • +
  • Issue #4662 - MPI initialization broken when networking off

  • +
  • Issue #4652 - How to fix distributed action annotation

  • +
  • Issue #4650 - thread descriptions are broken…again

  • +
  • Issue #4648 - Thread stacksize not properly set

  • +
  • Issue #4647 - Rename generated collective headers in modules

  • +
  • Issue #4639 - Update deprecation warnings in compatibility headers to point to collective headers

  • +
  • Issue #4628 - mpi parcelport totally broken

  • +
  • Issue #4619 - Fully document hpx_wrap behaviour and targets

  • +
  • Issue #4612 - Compilation issue with HPX 1.4.1 and 1.4.0

  • +
  • Issue #4594 - Rename modules

  • +
  • Issue #4578 - Default value for HPX_WITH_THREAD_BACKTRACE_DEPTH

  • +
  • Issue #4572 - Thread manager should be given a runtime_configuration

  • +
  • Issue #4571 - Add high-level documentation to new modules

  • +
  • Issue #4569 - Annoying warning when compiling - pls suppress or fix it.

  • +
  • Issue #4555 - HPX_HAVE_THREAD_BACKTRACE_ON_SUSPENSION compilation error

  • +
  • Issue #4543 - Segfaults in Release builds using sleep_for

  • +
  • Issue #4539 - Compilation Error when HPX_MPI_WITH_FUTURES=ON

  • +
  • Issue #4537 - Linking issue with libhpx_initd.a

  • +
  • Issue #4535 - API for checking if pool with a given name exists

  • +
  • Issue #4523 - Build of PR #4311 (git tag 9955e8e) fails

  • +
  • Issue #4519 - Documentation problem

  • +
  • Issue #4513 - HPXConfig.cmake contains ill-formed paths when library paths use backslashes

  • +
  • Issue #4507 - User-polling introduced by MPI futures module should be more generally usable

  • +
  • Issue #4506 - Make sure force_linking.hpp is not included in main module header

  • +
  • Issue #4501 - Fix compilation of PAPI tests

  • +
  • Issue #4497 - Add modules CI checks

  • +
  • Issue #4489 - Polymorphic executor

  • +
  • Issue #4476 - Use CMake targets defined by FindBoost

  • +
  • Issue #4473 - Add vcpkg installation instructions

  • +
  • Issue #4470 - Adapt hpx::future to C++20 co_await

  • +
  • Issue #4468 - Compile error on Raspberry Pi 4

  • +
  • Issue #4466 - Compile error on Windows, current stable:

  • +
  • Issue #4453 - Installing HPX on fedora with dnf is not adding cmake files

  • +
  • Issue #4448 - New std::variant serialization broken

  • +
  • Issue #4438 - Add performance counter flag is monotically increasing

  • +
  • Issue #4436 - Build problem: same code build and works with 1.4.0 but it doesn’t with 1.4.1

  • +
  • Issue #4429 - Function descriptions not supported in distributed

  • +
  • Issue #4423 - –hpx:ini=hpx.lock_detection=0 has no effect

  • +
  • Issue #4422 - Add performance counter metadata

  • +
  • Issue #4419 - Weird behavior for –hpx:print-counter-interval with large numbers

  • +
  • Issue #4401 - Create module repository

  • +
  • Issue #4400 - Command line options conflict related to performance counters

  • +
  • Issue #4349 - –hpx:use-process-mask option throw an exception on OS X

  • +
  • Issue #4345 - Move gh-pages branch out of hpx repo

  • +
  • Issue #4323 - Const-correctness error in assignment operator of compute::vector

  • +
  • Issue #4318 - ASIO breaks with C++2a concepts

  • +
  • Issue #4317 - Application runs even if –hpx:help is specified

  • +
  • Issue #4063 - Document hpxcxx compiler wrapper

  • +
  • Issue #3983 - Implement the C++20 Synchronization Library

  • +
  • Issue #3696 - C++11 constexpr support is now required

  • +
  • Issue #3623 - Modular HPX branch and an alternative project layout

  • +
  • Issue #2836 - The worst-case time complexity of parallel::sort seems to be O(N^2).

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #4936 - Minor documentation fixes part 2

  • +
  • PR #4935 - Add copyright and license to joss paper file

  • +
  • PR #4934 - Adding Semicolon in Documentation

  • +
  • PR #4932 - Fixing compiler warnings

  • +
  • PR #4931 - Small documentation formatting fixes

  • +
  • PR #4930 - Documentation Distributed HPX applications localvv with local_vv

  • +
  • PR #4929 - Add final version of the JOSS paper

  • +
  • PR #4928 - Add HPX_NODISCARD to enable_user_polling structs

  • +
  • PR #4926 - Rename distributed_executors module to executors_distributed

  • +
  • PR #4925 - Making transform_reduce conforming to C++20

  • +
  • PR #4923 - Don’t acquire lock if not needed

  • +
  • PR #4921 - Update the release notes for the release candidate 3

  • +
  • PR #4920 - Disable libcds release

  • +
  • PR #4919 - Make cuda event pool dynamic instead of fixed size

  • +
  • PR #4917 - Move chrono functionality to hpx::chrono namespace

  • +
  • PR #4916 - HPX_HAVE_DEPRECATION_WARNINGS needs to be set even when disabled

  • +
  • PR #4915 - Moving more action related files to actions modules

  • +
  • PR #4914 - Add alias targets with namespaces used for exporting

  • +
  • PR #4912 - Aggregate initialize CPOs

  • +
  • PR #4910 - Explicitly specify hwloc root on Jenkins CSCS builds

  • +
  • PR #4908 - Fix algorithms documentation

  • +
  • PR #4907 - Remove HPX::hpx_no_wrap_main target

  • +
  • PR #4906 - Fixing unused variable warning

  • +
  • PR #4905 - Adding specializations for simple for_loops

  • +
  • PR #4904 - Update boost to 1.74.0 for the newest jenkins configs

  • +
  • PR #4903 - Hide GITHUB_TOKEN environment variables from environment variable output

  • +
  • PR #4902 - Cancel previous pull requests builds before starting a new one with Jenkins

  • +
  • PR #4901 - Update public API list with updated algorithms

  • +
  • PR #4899 - Suggested changes for HPX V1.5 release notes

  • +
  • PR #4898 - Minor tweak to hpx::equal implementation

  • +
  • PR #4896 - Making generate() and generate_n conforming to C++20

  • +
  • PR #4895 - Update apex tag

  • +
  • PR #4894 - Fix exception handling for tasks

  • +
  • PR #4893 - Remove last use of std::result_of, removed in C++20

  • +
  • PR #4892 - Adding replay_executor and replicate_executor

  • +
  • PR #4889 - Restore old behaviour of not requiring linking to hpx_wrap when HPX_WITH_DYNAMIC_HPX_MAIN=OFF

  • +
  • PR #4887 - Making sure remotely thrown (non-hpx) exceptions are properly marshaled back to invocation site

  • +
  • PR #4885 - Adapting hpx::find and friends to C++20

  • +
  • PR #4884 - Adapting mismatch to C++20

  • +
  • PR #4883 - Adapting hpx::equal to be conforming to C++20

  • +
  • PR #4882 - Fixing exception handling for hpx::copy and adding missing tests

  • +
  • PR #4881 - Adds different runtime exception when registering thread with the HPX runtime

  • +
  • PR #4876 - Adding example demonstrating how to disable thread stealing during the execution of parallel algorithms

  • +
  • PR #4874 - Adding non-policy tests to all_of, any_of, and none_of

  • +
  • PR #4873 - Set CUDA compute capability on rostam Jenkins builds

  • +
  • PR #4872 - Force partitioned vector scan tests to run serially

  • +
  • PR #4870 - Making move conforming with C++20

  • +
  • PR #4869 - Making destroy and destroy_n conforming to C++20

  • +
  • PR #4868 - Fix miscellaneous header problems

  • +
  • PR #4867 - Add CPOs for for_each

  • +
  • PR #4865 - Adapting count and count_if to be conforming to C++20

  • +
  • PR #4864 - Release notes 1.5.0

  • +
  • PR #4863 - adding libcds-hpx tag to prepare for hpx1.5 release

  • +
  • PR #4862 - Adding version specific deprecation options

  • +
  • PR #4861 - Limiting executor improvements

  • +
  • PR #4860 - Making fill and fill_n compatible with C++20

  • +
  • PR #4859 - Adapting all_of, any_of, and none_of to C++20

  • +
  • PR #4857 - Improve libCDS integration

  • +
  • PR #4856 - Correct typos in the documentation of the hpx performance counters

  • +
  • PR #4854 - Removing obsolete code

  • +
  • PR #4853 - Adding test that derives component from two other components

  • +
  • PR #4852 - Fix mpi_ring test in distributed mode by ensuring all ranks run hpx_main

  • +
  • PR #4851 - Converting resiliency APIs to tag_invoke based CPOs

  • +
  • PR #4849 - Enable use of future_overhead test when DISTRIBUTED_RUNTIME is OFF

  • +
  • PR #4847 - Fixing ‘error prone’ constructs as reported by Codacy

  • +
  • PR #4846 - Disable Boost.Asio concepts support

  • +
  • PR #4845 - Fix PAPI counters

  • +
  • PR #4843 - Remove dependency on various Boost headers

  • +
  • PR #4841 - Rearrange public API headers

  • +
  • PR #4840 - Fixing TSS problems during thread termination

  • +
  • PR #4839 - Fix async_cuda build problems when distributed runtime is disabled

  • +
  • PR #4837 - Restore compatibility for old (now deprecated) copy algorithms

  • +
  • PR #4836 - Adding CPOs for hpx::reduce

  • +
  • PR #4835 - Remove using util::result_of from namespace hpx

  • +
  • PR #4834 - Fixing the calculation of the number of idle cores and the corresponding idle masks

  • +
  • PR #4833 - Allow thread function destructors to yield

  • +
  • PR #4832 - Fixing assertion in split_gids and memory leaks in 1d_stencil_7

  • +
  • PR #4831 - Making sure MPI_CXX_COMPILE_FLAGS is interpreted as a sequence of options

  • +
  • PR #4830 - Update documentation on using HPX::wrap_main

  • +
  • PR #4827 - Update clang-newest configuration to use clang 10

  • +
  • PR #4826 - Add Jenkins configuration for rostam

  • +
  • PR #4825 - Move all CUDA functionality to hpx::cuda::experimental namespace

  • +
  • PR #4824 - Add support for building master/release branches to Jenkins configuration

  • +
  • PR #4821 - Implement customization point for hpx::copy and hpx::ranges::copy

  • +
  • PR #4819 - Allow finding Boost components before finding HPX

  • +
  • PR #4817 - Adding range version of stable sort

  • +
  • PR #4815 - Fix a wrong #ifdef for IO/TIMER pools causing build errors

  • +
  • PR #4814 - Replace hpx::function_nonser with std::function in error module

  • +
  • PR #4809 - Foreach adapt

  • +
  • PR #4808 - Make internal algorithms functions const

  • +
  • PR #4807 - Add Jenkins configuration for running on Piz Daint

  • +
  • PR #4806 - Update documentation links to new domain name

  • +
  • PR #4805 - Applying changes that resolve time complexity issues in sort

  • +
  • PR #4803 - Adding implementation of stable_sort

  • +
  • PR #4802 - Fix datapar header paths

  • +
  • PR #4801 - Replace boost::shared_array<T> with std::shared_ptr<T[]> if supported

  • +
  • PR #4799 - Fixing #include paths in compatibility headers

  • +
  • PR #4798 - Include the main module header (fixes partially #4488)

  • +
  • PR #4797 - Change cmake targets

  • +
  • PR #4794 - Removing 128bit integer emulation

  • +
  • PR #4793 - Make sure global variable is handled properly

  • +
  • PR #4792 - Replace enable_if with HPX_CONCEPT_REQUIRES_ and add is_sentinel_for constraint

  • +
  • PR #4790 - Move deprecation warnings from base template to template specializations for result_of etc. structs

  • +
  • PR #4789 - Fix hangs during assertion handling and distributed runtime construction

  • +
  • PR #4788 - Fixing inclusive transform scan algorithm to properly handle initial value

  • +
  • PR #4785 - Fixing barrier test

  • +
  • PR #4784 - Fixing deleter argument bindings in serialize_buffer

  • +
  • PR #4783 - Add coveralls badge

  • +
  • PR #4782 - Make header tests parallel again

  • +
  • PR #4780 - Remove outdated comment about hpx::stop in documentation

  • +
  • PR #4776 - debug print improvements

  • +
  • PR #4775 - Checkpoint cleanup

  • +
  • PR #4771 - Fix compilation with HPX_WITH_NETWORKING=OFF

  • +
  • PR #4767 - Remove all force linking leftovers

  • +
  • PR #4765 - Fix 1d stencil index calculation

  • +
  • PR #4764 - Force some tests to run serially

  • +
  • PR #4762 - Update pointees in compatibility headers

  • +
  • PR #4761 - Fix running and building of execution module tests on CircleCI

  • +
  • PR #4760 - Storing hpx_options in global property to speed up summary report

  • +
  • PR #4759 - Reduce memory requirements for our main shared state

  • +
  • PR #4757 - Fix mimalloc linking on Windows

  • +
  • PR #4756 - Fix compilation issues

  • +
  • PR #4753 - Re-adding API functions that were lost during merges

  • +
  • PR #4751 - Revert “Create coverage reports and upload them to codecov.io”

  • +
  • PR #4750 - Fixing possible race condition during termination detection

  • +
  • PR #4749 - Deprecate result_of and friends

  • +
  • PR #4748 - Create coverage reports and upload them to codecov.io

  • +
  • PR #4747 - Changing #include for MPI parcelport

  • +
  • PR #4745 - Add is_sentinel_for trait implementation and test

  • +
  • PR #4743 - Fix init_globally example after runtime mode changes

  • +
  • PR #4742 - Update SUPPORT.md

  • +
  • PR #4741 - Fixing a warning generated for unity builds with msvc

  • +
  • PR #4740 - Rename local_lcos and basic_execution modules

  • +
  • PR #4739 - Undeprecate a couple of hpx/modulename.hpp headers

  • +
  • PR #4738 - Conditionally test schedulers in thread_stacksize_current test

  • +
  • PR #4734 - Fixing a bunch of codacy warnings

  • +
  • PR #4733 - Add experimental unity build option to CMake configuration

  • +
  • PR #4730 - Fixing compilation problems with unordered map

  • +
  • PR #4729 - Fix APEX build

  • +
  • PR #4727 - Fix missing runtime includes for distributed runtime

  • +
  • PR #4726 - Add more API headers

  • +
  • PR #4725 - Add more compatibility headers for deprecated module headers

  • +
  • PR #4724 - Fix 4723

  • +
  • PR #4721 - Attempt to fixing migration tests

  • +
  • PR #4717 - Make the compatilibility headers macro conditional

  • +
  • PR #4716 - Add hpx/runtime.hpp and hpx/distributed/runtime.hpp API headers

  • +
  • PR #4714 - Add hpx/future.hpp header

  • +
  • PR #4713 - Remove hpx/runtime/threads_fwd.hpp and hpx/util_fwd.hpp

  • +
  • PR #4711 - Make module deprecation warnings overridable

  • +
  • PR #4710 - Add compatibility headers and other fixes after module header renaming

  • +
  • PR #4708 - Add termination handler for parallel algorithms

  • +
  • PR #4707 - Use hpx::function_nonser instead of std::function internally

  • +
  • PR #4706 - Move header file to module

  • +
  • PR #4705 - Fix incorrect behaviour of cmake-format check

  • +
  • PR #4704 - Fix resource tests

  • +
  • PR #4701 - Fix missing includes for future::then specializations

  • +
  • PR #4700 - Removing obsolete memory component

  • +
  • PR #4699 - Add short descriptions to modules missing documentation

  • +
  • PR #4696 - Rename generated modules headers

  • +
  • PR #4693 - Overhauling thread_mapper for public consumption

  • +
  • PR #4688 - Fix thread stack size handling

  • +
  • PR #4687 - Adding all_gather and fixing all_to_all

  • +
  • PR #4684 - Miscellaneous compilation fixes

  • +
  • PR #4683 - Fix HPX_WITH_DYNAMIC_HPX_MAIN=OFF

  • +
  • PR #4682 - Fix compilation of pack_traversal_rebind_container.hpp

  • +
  • PR #4681 - Add missing hpx/execution.hpp includes for future::then

  • +
  • PR #4678 - Typeless communicator

  • +
  • PR #4677 - Forcing registry option to be accepted without checks.

  • +
  • PR #4676 - Adding scatter_to/scatter_from collective operations

  • +
  • PR #4673 - Fix PAPI counters compilation

  • +
  • PR #4671 - Deprecate hpx::promise alias to hpx::lcos::promise

  • +
  • PR #4670 - Explicitly instantiate get_exception

  • +
  • PR #4667 - Add stopValue in Sentinel struct instead of Iterator

  • +
  • PR #4666 - Add release build on Windows to GitHub actions

  • +
  • PR #4664 - Creating itt_notify module.

  • +
  • PR #4663 - Mpi fixes

  • +
  • PR #4659 - Making sure declarations match definitions in register_locks implementation

  • +
  • PR #4655 - Fixing task annotations for actions

  • +
  • PR #4653 - Making sure APEX is linked into every application, if needed

  • +
  • PR #4651 - Update get_function_annotation.hpp

  • +
  • PR #4646 - Runtime type

  • +
  • PR #4645 - Add a few more API headers

  • +
  • PR #4644 - Fixing support for mpirun (and similar)

  • +
  • PR #4643 - Fixing the fix for get_idle_core_count() API

  • +
  • PR #4638 - Remove HPX_API_EXPORT missed in previous cleanup

  • +
  • PR #4636 - Adding C++20 barrier

  • +
  • PR #4635 - Adding C++20 latch API

  • +
  • PR #4634 - Adding C++20 counting semaphore API

  • +
  • PR #4633 - Unify execution parameters customization points

  • +
  • PR #4632 - Adding missing bulk_sync_execute wrapper to example executor

  • +
  • PR #4631 - Updates to documentation; grammar edits.

  • +
  • PR #4630 - Updates to documentation; moved hyperlink

  • +
  • PR #4624 - Export set_self_ptr in thread_data.hpp instead of with forward declarations where used

  • +
  • PR #4623 - Clean up export macros

  • +
  • PR #4621 - Trigger an error for older boost versions on power architectures

  • +
  • PR #4617 - Ignore user-set compatibility header options if the module does not have compatibility headers

  • +
  • PR #4616 - Fix cmake-format warning

  • +
  • PR #4615 - Add handler for serializing custom exceptions

  • +
  • PR #4614 - Fix error message when HPX_IGNORE_CMAKE_BUILD_TYPE_COMPATIBILITY=OFF

  • +
  • PR #4613 - Make partitioner constructor private

  • +
  • PR #4611 - Making auto_chunk_size execute the given function using the given executor

  • +
  • PR #4610 - Making sure the thread-local lock registration data is moving to the core the suspended HPX thread is resumed on

  • +
  • PR #4609 - Adding an API function that exposes the number of idle cores

  • +
  • PR #4608 - Fixing moodycamel namespace

  • +
  • PR #4607 - Moving winsocket initialization to core library

  • +
  • PR #4606 - Local runtime module etc.

  • +
  • PR #4604 - Add config_registry module

  • +
  • PR #4603 - Deal with distributed modules in their respective CMakeLists.txt

  • +
  • PR #4602 - Small module fixes

  • +
  • PR #4598 - Making sure current_executor and service_executor functions are linked into the core library

  • +
  • PR #4597 - Adding broadcast_to/broadcast_from to collectives module

  • +
  • PR #4596 - Fix performance regression in block_executor

  • +
  • PR #4595 - Making sure main.cpp is built as a library if HPX_WITH_DYNAMIC_MAIN=OFF

  • +
  • PR #4592 - Futures module

  • +
  • PR #4591 - Adapting co_await support for C++20

  • +
  • PR #4590 - Adding missing exception test for for_loop()

  • +
  • PR #4587 - Move traits headers to hpx/modulename/traits directory

  • +
  • PR #4586 - Remove Travis CI config

  • +
  • PR #4585 - Update macOS test blacklist

  • +
  • PR #4584 - Attempting to fix missing symbols in stack trace

  • +
  • PR #4583 - Fixing bad static_cast

  • +
  • PR #4582 - Changing download url for Windows prerequisites to circumvent bandwidth limitations

  • +
  • PR #4581 - Adding missing using placeholder::_X

  • +
  • PR #4579 - Move get_stack_size_name and related functions

  • +
  • PR #4575 - Excluding unconditional definition of class backtrace from global header

  • +
  • PR #4574 - Changing return type of hardware_concurrency() to unsigned int

  • +
  • PR #4570 - Move tests to modules

  • +
  • PR #4564 - Reshuffle internal targets and add HPX::hpx_no_wrap_main target

  • +
  • PR #4563 - fix CMake option typo

  • +
  • PR #4562 - Unregister lock earlier to avoid holding it while suspending

  • +
  • PR #4561 - Adding test macros supporting custom output stream

  • +
  • PR #4560 - Making sure hash_any::operator()() is linked into core library

  • +
  • PR #4559 - Fixing compilation if HPX_WITH_THREAD_BACKTRACE_ON_SUSPENSION=On

  • +
  • PR #4557 - Improve spinlock implementation to perform better in high-contention situations

  • +
  • PR #4553 - Fix a runtime_ptr problem at shutdown when apex is enabled

  • +
  • PR #4552 - Add configuration option for making exceptions less noisy

  • +
  • PR #4551 - Clean up thread creation parameters

  • +
  • PR #4549 - Test FetchContent build on GitHub actions

  • +
  • PR #4548 - Fix stack size

  • +
  • PR #4545 - Fix header tests

  • +
  • PR #4544 - Fix a typo in sanitizer build

  • +
  • PR #4541 - Add API to check if a thread pool exists

  • +
  • PR #4540 - Making sure MPI support is enabled if MPI futures are used but networking is disabled

  • +
  • PR #4538 - Move channel documentation examples to examples directory

  • +
  • PR #4536 - Add generic allocator for execution policies

  • +
  • PR #4534 - Enable compatibility headers for thread_executors module

  • +
  • PR #4532 - Fixing broken url in README.rst

  • +
  • PR #4531 - Update scripts

  • +
  • PR #4530 - Make sure module API docs show up in correct order

  • +
  • PR #4529 - Adding missing template code to module creation script

  • +
  • PR #4528 - Make sure version module uses HPX’s binary dir, not the parent’s

  • +
  • PR #4527 - Creating actions_base and actions module

  • +
  • PR #4526 - Shared state for cv

  • +
  • PR #4525 - Changing sub-name sequencing for experimental namespace

  • +
  • PR #4524 - Add API guarantee notes to API reference documentation

  • +
  • PR #4522 - Enable and fix deprecation warnings in execution module

  • +
  • PR #4521 - Moves more miscellaneous files to modules

  • +
  • PR #4520 - Skip execution customization points when executor is known

  • +
  • PR #4518 - Module distributed lcos

  • +
  • PR #4516 - Fix various builds

  • +
  • PR #4515 - Replace backslashes by slashes in windows paths

  • +
  • PR #4514 - Adding polymorphic_executor

  • +
  • PR #4512 - Adding C++20 jthread and stop_token

  • +
  • PR #4510 - Attempt to fix APEX linking in external packages again

  • +
  • PR #4508 - Only test pull requests (not all branches) with GitHub actions

  • +
  • PR #4505 - Fix duplicate linking in tests (ODR violations)

  • +
  • PR #4504 - Fix C++ standard handling

  • +
  • PR #4503 - Add CMakelists file check

  • +
  • PR #4500 - Fix .clang-format version requirement comment

  • +
  • PR #4499 - Attempting to fix hpx_init linking on macOS

  • +
  • PR #4498 - Fix compatibility of pool_executor

  • +
  • PR #4496 - Removing superfluous SPDX tags

  • +
  • PR #4494 - Module executors

  • +
  • PR #4493 - Pack traversal module

  • +
  • PR #4492 - Update copyright year in documentation

  • +
  • PR #4491 - Add missing current_executor header

  • +
  • PR #4490 - Update GitHub actions configs

  • +
  • PR #4487 - Properly dispatch exceptions thrown from hpx_main to be rethrown from hpx::init/hpx::stop

  • +
  • PR #4486 - Fixing an initialization order problem

  • +
  • PR #4485 - Move miscellaneous files to their rightful modules

  • +
  • PR #4483 - Clean up imported CMake target naming

  • +
  • PR #4481 - Add vcpkg installation instructions

  • +
  • PR #4479 - Add hints to allow to specify MIMALLOC_ROOT

  • +
  • PR #4478 - Async modules

  • +
  • PR #4475 - Fix rp init changes

  • +
  • PR #4474 - Use #pragma once in headers

  • +
  • PR #4472 - Add more descriptive error message when using x86 coroutines on non-x86 platforms

  • +
  • PR #4467 - Add mimalloc find cmake script

  • +
  • PR #4465 - Add thread_executors module

  • +
  • PR #4464 - Include module

  • +
  • PR #4462 - Merge hpx_init and hpx_wrap into one static library

  • +
  • PR #4461 - Making thread_data test more realistic

  • +
  • PR #4460 - Suppress MPI warnings in version.cpp

  • +
  • PR #4459 - Make sure pkgconfig applications link with hpx_init

  • +
  • PR #4458 - Added example demonstrating how to create and use a wrapping executor

  • +
  • PR #4457 - Fixing execution of thread exit functions

  • +
  • PR #4456 - Move backtrace files to debugging module

  • +
  • PR #4455 - Move deadlock_detection and maintain_queue_wait_times source files into schedulers module

  • +
  • PR #4450 - Fixing compilation with std::filesystem enabled

  • +
  • PR #4449 - Fixing build system to actually build variant test

  • +
  • PR #4447 - This fixes an obsolete #include

  • +
  • PR #4446 - Resume tasks where they were suspended

  • +
  • PR #4444 - Minor CUDA fixes

  • +
  • PR #4443 - Add missing tests to CircleCI config

  • +
  • PR #4442 - Adding a tag to all auto-generated files allowing for tools to visually distinguish those

  • +
  • PR #4441 - Adding performance counter type information

  • +
  • PR #4440 - Fixing MSVC build

  • +
  • PR #4439 - Link HPX::plugin and component privately in hpx_setup_target

  • +
  • PR #4437 - Adding a test that verifies the problem can be solved using a trait specialization

  • +
  • PR #4434 - Clean up Boost dependencies and copy string algorithms to new module

  • +
  • PR #4433 - Fixing compilation issues (!) if MPI parcelport is enabled

  • +
  • PR #4431 - Ignore warnings about name mangling changing

  • +
  • PR #4430 - Add performance_counters module

  • +
  • PR #4428 - Don’t add compatibility headers to module API reference

  • +
  • PR #4426 - Add currently failing tests on GitHub actions to blacklist

  • +
  • PR #4425 - Clean up and correct minimum required versions

  • +
  • PR #4424 - Making sure hpx.lock_detection=0 works as advertized

  • +
  • PR #4421 - Making sure interval time stops underlying timer thread on termination

  • +
  • PR #4417 - Adding serialization support for std::variant (if available) and std::tuple

  • +
  • PR #4415 - Partially reverting changes applied by PR 4373

  • +
  • PR #4414 - Added documentation for the compiler-wrapper script hpxcxx.in in creating_hpx_projects.rst

  • +
  • PR #4413 - Merging from V1.4.1 release

  • +
  • PR #4412 - Making sure to issue a warning if a file specified using –hpx:options-file is not found

  • +
  • PR #4411 - Make test specific to HPX_WITH_SHARED_PRIORITY_SCHEDULER

  • +
  • PR #4407 - Adding minimal MPI executor

  • +
  • PR #4405 - Fix cross pool injection test, use default scheduler as falback

  • +
  • PR #4404 - Fix a race condition and clean-up usage of scheduler mode

  • +
  • PR #4399 - Add more threading modules

  • +
  • PR #4398 - Add CODEOWNERS file

  • +
  • PR #4395 - Adding a parameter to auto_chunk_size allowing to control the amount of iterations to measure

  • +
  • PR #4393 - Use appropriate cache-line size defaults for different platforms

  • +
  • PR #4391 - Fixing use of allocator for C++20

  • +
  • PR #4390 - Making –hpx:help behavior consistent

  • +
  • PR #4388 - Change the resource partitioner initialization

  • +
  • PR #4387 - Fix roll_release.sh

  • +
  • PR #4386 - Add warning messages for using thread binding options on macOS

  • +
  • PR #4385 - Cuda futures

  • +
  • PR #4384 - Make enabling dynamic hpx_main on non-Linux systems a configuration error

  • +
  • PR #4383 - Use configure_file for HPXCacheVariables.cmake

  • +
  • PR #4382 - Update spellchecking whitelist and fix more typos

  • +
  • PR #4380 - Add a helper function to get a future from a cuda stream

  • +
  • PR #4379 - Add Windows and macOS CI with GitHub actions

  • +
  • PR #4378 - Change C++ standard handling

  • +
  • PR #4377 - Remove Python scripts

  • +
  • PR #4374 - Adding overload for hpx::init/hpx::start for use with resource partitioner

  • +
  • PR #4373 - Adding test that verifies for 4369 to be fixed

  • +
  • PR #4372 - Another attempt at fixing the integral mismatch and conversion warnings

  • +
  • PR #4370 - Doc updates quick start

  • +
  • PR #4368 - Add a whitelist of words for weird spelling suggestions

  • +
  • PR #4366 - Suppress or fix clang-tidy-9 warnings

  • +
  • PR #4365 - Removing more Boost dependencies

  • +
  • PR #4363 - Update clang-format config file for version 9

  • +
  • PR #4362 - Fix indices typo

  • +
  • PR #4361 - Boost cleanup

  • +
  • PR #4360 - Move plugins

  • +
  • PR #4358 - Doc updates; generating documentation. Will likely need heavy editing.

  • +
  • PR #4356 - Remove some minor unused and unnecessary Boost includes

  • +
  • PR #4355 - Fix spellcheck step in CircleCI config

  • +
  • PR #4354 - Lightweight utility to hold a pack as members

  • +
  • PR #4352 - Minor fixes to the C++ standard detection for MSVC

  • +
  • PR #4351 - Move generated documentation to hpx-docs repo

  • +
  • PR #4347 - Add cmake policy - CMP0074

  • +
  • PR #4346 - Remove file committed by mistake

  • +
  • PR #4342 - Remove HCC and SYCL options from CMakeLists.txt

  • +
  • PR #4341 - Fix launch process test with APEX enabled

  • +
  • PR #4340 - Testing Cirrus CI

  • +
  • PR #4339 - Post 1.4.0 updates

  • +
  • PR #4338 - Spelling corrections and CircleCI spell check

  • +
  • PR #4333 - Flatten bound callables

  • +
  • PR #4332 - This is a collection of mostly minor (cleanup) fixes

  • +
  • PR #4331 - This adds the missing tests for async_colocated and async_continue_colocated

  • +
  • PR #4330 - Remove HPX.Compute host default_executor

  • +
  • PR #4328 - Generate global header for basic_execution module

  • +
  • PR #4327 - Use INTERNAL_FLAGS option for all examples and components

  • +
  • PR #4326 - Usage of temporary allocator in assignment operator of compute::vector

  • +
  • PR #4325 - Use hpx::threads::get_cache_line_size in prefetching.hpp

  • +
  • PR #4324 - Enable compatibility headers option for execution module

  • +
  • PR #4316 - Add clang format indentppdirectives

  • +
  • PR #4313 - Introduce index_pack alias to pack of size_t

  • +
  • PR #4312 - Fixing compatibility header for pack.hpp

  • +
  • PR #4311 - Dataflow annotations for APEX

  • +
  • PR #4309 - Update launching_and_configuring_hpx_applications.rst

  • +
  • PR #4306 - Fix schedule hint not being taken from executor

  • +
  • PR #4305 - Implementing hpx::functional::tag_invoke

  • +
  • PR #4304 - Improve pack support utilities

  • +
  • PR #4303 - Remove errors module dependency on datastructures

  • +
  • PR #4301 - Clean up thread executors

  • +
  • PR #4294 - Logging revamp

  • +
  • PR #4292 - Remove SPDX tag from Boost License file to allow for github to recognize it

  • +
  • PR #4291 - Add format support for std::tm

  • +
  • PR #4290 - Simplify compatible tuples check

  • +
  • PR #4288 - A lightweight take on boost::lexical_cast

  • +
  • PR #4287 - Forking boost::lexical_cast as a new module

  • +
  • PR #4277 - MPI_futures

  • +
  • PR #4270 - Refactor future implementation

  • +
  • PR #4265 - Threading module

  • +
  • PR #4259 - Module naming base

  • +
  • PR #4251 - Local workrequesting scheduler

  • +
  • PR #4250 - Inline execution of scoped tasks, if possible

  • +
  • PR #4247 - Add execution in module headers

  • +
  • PR #4246 - Expose CMake targets officially

  • +
  • PR #4239 - Doc updates miscellaneous (partially completed during Google Season of Docs)

  • +
  • PR #4233 - Remove project() from modules + fix CMAKE_SOURCE_DIR issue

  • +
  • PR #4231 - Module local lcos

  • +
  • PR #4207 - Command line handling module

  • +
  • PR #4206 - Runtime configuration module

  • +
  • PR #4141 - Doc updates examples local to remote (partially completed during Google Season of Docs)

  • +
  • PR #4091 - Split runtime into local and distributed parts

  • +
  • PR #4017 - Require C++14

  • +
+
+
+
+
HPX V1.4.1 (Feb 12, 2020)#
+
+
General changes#
+

This is a bugfix release. It contains the following changes:

+
    +
  • Fix compilation issues on Windows, macOS, FreeBSD, and with gcc 10

  • +
  • Install missing pdb files on Windows

  • +
  • Allow running tests using an installed version of HPX

  • +
  • Skip MPI finalization if HPX has not initialized MPI

  • +
  • Give a hard error when attempting to use IO counters on Windows

  • +
+
+
+
Closed issues#
+
    +
  • Issue #4320 - HPX 1.4.0 does not compile with gcc 10

  • +
  • Issue #4336 - Building HPX 1.4.0 with IO Counters breaks (Windows)

  • +
  • Issue #4334 - HPX Debug and RelWithDebinfo builds on Windows not +installing .pdb files

  • +
  • Issue #4322 - Undefine VT1 and VT2 after boost includes

  • +
  • Issue #4314 - Compile error on 1.4.0

  • +
  • Issue #4307 - ld: error: duplicate symbol: freebsd_environ

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #4376 - Attempt to fix some test build errors on Windows

  • +
  • PR #4357 - Adding missing #includes to fix gcc V10 linker problems

  • +
  • PR #4353 - Skip MPI_Finalize if MPI_Init is not called from HPX

  • +
  • PR #4343 - Give a hard error if IO counters are enabled on non-Linux +systems

  • +
  • PR #4337 - Installing pdb files on Windows

  • +
  • PR #4335 - Adding capability to buildsystem to use an installed version +of HPX

  • +
  • PR #4315 - Forcing exported symbols from composable_guard to be linked +into core library

  • +
  • PR #4310 - Remove environment handling from exception.cpp

  • +
+
+
+
+
HPX V1.4.0 (January 15, 2020)#
+
+
General changes#
+
    +
  • We have added the collectives all_to_all and all_reduce.

  • +
  • We have added APIs for resiliency, which allows replication and replay for +failed tasks. See the documentation for more details.

  • +
  • Components can now be checkpointed.

  • +
  • Performance improvements to schedulers and coroutines. A significant change is +the addition of stackless coroutines. These are to be used for tasks that do +not need to be suspended and can reduce overheads noticeably in applications +with short tasks. A stackless coroutine can be created with the new stack size +thread_stacksize_nostack.

  • +
  • We have added an implementation of unique_any, which is a non-copyable +version of any.

  • +
  • The shared_priority_queue_scheduler has been improved. It now has lower +overheads than the default scheduler in many situations. Unlike the default +scheduler it fully supports NUMA scheduling hints. Enable it with the command +line option --hpx:queuing=shared-priority. This scheduler +should still be considered experimental, but its use is encouraged in real +applications to help us make it production ready.

  • +
  • We have added the performance counters background-receive-duration and +background-receive-overhead for inspecting the time and overhead spent on +receiving parcels in the background.

  • +
  • Compilation time has been further improved when HPX_WITH_NETWORKING=OFF.

  • +
  • We no longer require compiled Boost dependencies in certain configurations. +This requires at least Boost 1.70, compiling on x86 with GCC 9, clang (libc++) +9, or VS2019 in C++17 mode. The dependency on Boost.Filesystem can explicitly +be turned on with HPX_FILESYSTEM_WITH_BOOST_FILESYSTEM_COMPATIBILITY=ON +(it is off by default if the standard library supports std::filesystem). +Boost.ProgramOptions has been copied into the HPX repository. We have a +compatibility layer for users who must explicitly use Boost.ProgramOptions +instead of the ProgramOptions provided by HPX. To remove the dependency +HPX_PROGRAM_OPTIONS_WITH_BOOST_PROGRAM_OPTIONS_COMPATIBILITY must be +explicitly set to OFF. This option will be removed in a future release. We +have also removed several other header-only dependencies on Boost.

  • +
  • It is now possible to use the process affinity mask set by tools like +numactl and various batch environments with the command line option +--hpx:use-process-mask. Enabling this option implies +--hpx:ignore-batch-env.

  • +
  • It is now possible to create standalone thread pools without starting the +runtime. See the standalone_thread_pool_executor.cpp test in the +execution module for an example.

  • +
  • Tasks annotated with hpx::util::annotated_function now have their +correct name when using APEX to generate OTF2 files.

  • +
  • Cloning of APEX was defective in previous releases (it required manual +intervention to check out the correct tag or branch). This has been fixed.

  • +
  • The option HPX_WITH_MORE_THAN_64_THREADS is now ignored and will be +removed in a future release. The value is instead derived directly from +HPX_WITH_MAX_CPU_COUNT option.

  • +
  • We have deprecated compiling in C++11 mode. The next release will require a +C++14 capable compiler.

  • +
  • We have deprecated support for the Vc library. This option will be replaced +with SIMD support from the standard library in a future release.

  • +
  • We have significantly refactored our CMake setup. This is intended to be a +non-breaking change and will allow for using HPX through CMake targets in the +future.

  • +
  • We have continued modularizing the HPX library. In the process we have +rearranged many header files into module-specific directories. All moved +headers have compatibility headers which forward from the old location to the +new location, together with a deprecation warning. The compatibility headers +will eventually be removed.

  • +
  • We now enforce formatting with clang-format on the majority of our source +files.

  • +
  • We have added SPDX license tags to all files.

  • +
  • Many bugfixes.

  • +
+
+
+
Breaking changes#
+
    +
  • The HPX_WITH_THREAD_COMPATIBILITY option and the associated compatibility +layer has been removed.

  • +
  • The HPX_WITH_INCLUSIVE_SCAN_COMPATIBILITY option and the associated +compatibility layer has been removed.

  • +
  • The HPX_WITH_UNWRAPPED_COMPATIBLITY option and the associated +compatibility layer has been removed.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #4282 - Build Issues with Release on Windows

  • +
  • Issue #4278 - Build Issues with CMake 3.14.4

  • +
  • Issue #4273 - Clients of HPX 1.4.0-rc2 with APEX ar not linked to +libhpx-apex

  • +
  • Issue #4269 - Building HPX 1.4.0-rc2 with support for APEX fails

  • +
  • Issue #4263 - Compilation fail on latest master

  • +
  • Issue #4232 - Configure of HPX project using CMake FetchContent fails

  • +
  • Issue #4223 - “Re-using the main() function as the main HPX entry point” +doesn’t work

  • +
  • Issue #4220 - HPX won’t compile - error building +resource_partitioner

  • +
  • Issue #4215 - HPX 1.4.0rc1 does not link on s390x

  • +
  • Issue #4204 - Trouble compiling HPX with Intel compiler

  • +
  • Issue #4199 - Refactor APEX to eliminate circular dependency

  • +
  • Issue #4187 - HPX can’t build on OSX

  • +
  • Issue #4185 - Simple debug output for development

  • +
  • Issue #4182 - @HPX_CONF_PREFIX@ is the empty string

  • +
  • Issue #4169 - HPX won’t build with APEX

  • +
  • Issue #4163 - Add back HPX_LIBRARIES and HPX_INCLUDE_DIRS

  • +
  • Issue #4161 - It should be possible to call find_package(HPX) +multiple times

  • +
  • Issue #4155 - get_self_id() for stackless threads returns +invalid_thread_id

  • +
  • Issue #4151 - build error with MPI code

  • +
  • Issue #4150 - hpx won’t build on POWER9 with clang 8

  • +
  • Issue #4148 - cacheline_data delivers poor performance with C++17 +compared to C++14

  • +
  • Issue #4144 - target general in HPX_LIBRARIES does not exist

  • +
  • Issue #4134 - CMake Error when -DHPX_WITH_HPXMP=ON

  • +
  • Issue #4132 - parallel fill leaves elements unfilled

  • +
  • Issue #4123 - PAPI performance counters are inaccessible

  • +
  • Issue #4118 - static_chunk_size is not obeyed in scan algorithms

  • +
  • Issue #4115 - dependency chaining error with APEX

  • +
  • Issue #4107 - Initializing runtime without entry point function and +command line arguments

  • +
  • Issue #4105 - Bug in hpx:bind=numa-balanced

  • +
  • Issue #4101 - Bound tasks

  • +
  • Issue #4100 - Add SPDX identifier to all files

  • +
  • Issue #4085 - hpx_topology library should depend on hwloc

  • +
  • Issue #4067 - HPX fails to build on macOS

  • +
  • Issue #4056 - Building without thread manager idle backoff fails

  • +
  • Issue #4052 - Enforce clang-format style for modules

  • +
  • Issue #4032 - Simple hello world fails to launch correctly

  • +
  • Issue #4030 - Allow threads to skip context switching

  • +
  • Issue #4029 - Add support for mimalloc

  • +
  • Issue #4005 - Can’t link HPX when APEX enabled

  • +
  • Issue #4002 - Missing header for algorithm module

  • +
  • Issue #3989 - conversion from long to unsigned int requires a +narrowing conversion on MSVC

  • +
  • Issue #3958 - /statistics/average@ perf counter can’t be created

  • +
  • Issue #3953 - CMake errors from HPX_AddPseudoDependencies

  • +
  • Issue #3941 - CMake error for APEX install target

  • +
  • Issue #3940 - Convert pseudo-doxygen function documentation into actual +doxygen documentation

  • +
  • Issue #3935 - HPX compiler match too strict?

  • +
  • Issue #3929 - Buildbot failures on latest HPX stable

  • +
  • Issue #3912 - I recommend publishing a version that does not depend on +the boost library

  • +
  • Issue #3890 - hpx.ini not working

  • +
  • Issue #3883 - cuda compilation fails because of -faligned-new

  • +
  • Issue #3879 - HPX fails to configure with -DHPX_WITH_TESTS=OFF

  • +
  • Issue #3871 - dataflow does not support void allocators

  • +
  • Issue #3867 - Latest HTML docs placed in wrong directory on GitHub pages

  • +
  • Issue #3866 - Make sure all tests use HPX_TEST* macros and not +HPX_ASSERT

  • +
  • Issue #3857 - CMake all-keyword or all-plain for +target_link_libraries

  • +
  • Issue #3856 - hpx_setup_target adds rogue flags

  • +
  • Issue #3850 - HPX fails to build on POWER8 with Clang7

  • +
  • Issue #3848 - Remove lva member from thread_init_data

  • +
  • Issue #3838 - hpx::parallel::count/count_if failing tests

  • +
  • Issue #3651 - hpx::parallel::transform_reduce with non const +reference as lambda parameter

  • +
  • Issue #3560 - Apex integration with HPX not working properly

  • +
  • Issue #3322 - No warning when mixing debug/release builds

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #4300 - Checks for MPI_Init being called twice

  • +
  • PR #4299 - Small CMake fixes

  • +
  • PR #4298 - Remove extra call to annotate function that messes up traces

  • +
  • PR #4296 - Fixing collectives locking problem

  • +
  • PR #4295 - Do not check LICENSE_1_0.txt for inspect violations

  • +
  • PR #4293 - Applying two small changes fixing carious MSVC/Windows +problems

  • +
  • PR #4285 - Delete apex.hpp

  • +
  • PR #4276 - Disable doxygen generation for hpx/debugging/print.hpp +file

  • +
  • PR #4275 - Make sure APEX is linked to even when not explicitly +referenced

  • +
  • PR #4272 - Fix pushing of documentation

  • +
  • PR #4271 - Updating APEX tag, don’t create new task_wrapper on +operator= of hpx_thread object

  • +
  • PR #4268 - Testing for noexcept function specializations in C++11/14 +mode

  • +
  • PR #4267 - Fixing MSVC warning

  • +
  • PR #4266 - Make sure macOS Travis CI fails if build step fails

  • +
  • PR #4264 - Clean up compatibility header options

  • +
  • PR #4262 - Cleanup modules CMakeLists.txt

  • +
  • PR #4261 - Fixing HPX/APEX linking and dependencies for external +projects like Phylanx

  • +
  • PR #4260 - Fix docs compilation problems

  • +
  • PR #4258 - Couple of minor changes

  • +
  • PR #4257 - Fix apex annotation for async dispatch

  • +
  • PR #4256 - Remove lambdas from assert expressions

  • +
  • PR #4255 - Ignoring lock in all_to_all and all_reduce

  • +
  • PR #4254 - Adding action specializations for noexcept functions

  • +
  • PR #4253 - Move partlit.hpp to affinity module

  • +
  • PR #4252 - Make mismatching build types a hard error in CMake

  • +
  • PR #4249 - Scheduler improvement

  • +
  • PR #4248 - update hpxmp tag to v0.3.0

  • +
  • PR #4245 - Adding high performance channels

  • +
  • PR #4244 - Ignore lock in ignore_while_locked_1485 test

  • +
  • PR #4243 - Fix PAPI command line option documentation

  • +
  • PR #4242 - Ignore lock in target_distribution_policy

  • +
  • PR #4241 - Fix start_stop_callbacks test

  • +
  • PR #4240 - Mostly fix clang CUDA compilation

  • +
  • PR #4238 - Google Season of Docs updates to documentation; grammar +edits.

  • +
  • PR #4237 - fixing annotated task to use the name, not the desc

  • +
  • PR #4236 - Move module print summary to modules

  • +
  • PR #4235 - Don’t use alignas in cache_{aligned,line}_data

  • +
  • PR #4234 - Add basic overview sentence to all modules

  • +
  • PR #4230 - Add OS X builds to Travis CI

  • +
  • PR #4229 - Remove leftover queue compatibility checks

  • +
  • PR #4226 - Fixing APEX shutdown by explicitly shutting down throttling

  • +
  • PR #4225 - Allow CMAKE_INSTALL_PREFIX to be a relative path

  • +
  • PR #4224 - Deprecate verbs parcelport

  • +
  • PR #4222 - Update register_{thread,work} namespaces

  • +
  • PR #4221 - Changing HPX_GCC_VERSION check from 70000 to +70300

  • +
  • PR #4218 - Google Season of Docs updates to documentation; grammar +edits.

  • +
  • PR #4217 - Google Season of Docs updates to documentation; grammar +edits.

  • +
  • PR #4216 - Fixing gcc warning on 32bit platforms (integer truncation)

  • +
  • PR #4214 - Apex callback refactoring

  • +
  • PR #4213 - Clean up allocator checks for dependent projects

  • +
  • PR #4212 - Google Season of Docs updates to documentation; grammar +edits.

  • +
  • PR #4211 - Google Season of Docs updates to documentation; contributing +to hpx

  • +
  • PR #4210 - Attempting to fix Intel compilation

  • +
  • PR #4209 - Fix CUDA 10 build

  • +
  • PR #4205 - Making sure that differences in CMAKE_BUILD_TYPE are not +reported on multi-configuration cmake generators

  • +
  • PR #4203 - Deprecate Vc

  • +
  • PR #4202 - Fix CUDA configuration

  • +
  • PR #4200 - Making sure hpx_wrap is not passed on to linker on +non-Linux systems

  • +
  • PR #4198 - Fix execution_agent.cpp compilation with GCC 5

  • +
  • PR #4197 - Remove deprecated options for 1.4.0 release

  • +
  • PR #4196 - minor fixes for building on OSX Darwin

  • +
  • PR #4195 - Use full clone on CircleCI for pushing stable tag

  • +
  • PR #4193 - Add scheduling hints to hello_world_distributed

  • +
  • PR #4192 - Set up CUDA in HPXConfig.cmake

  • +
  • PR #4191 - Export allocators root variables

  • +
  • PR #4190 - Don’t use constexpr in thread_data with GCC <= 6

  • +
  • PR #4189 - Only use quick_exit if available

  • +
  • PR #4188 - Google Season of Docs updates to documentation; writing +single node hpx applications

  • +
  • PR #4186 - correct vc to cuda in cuda cmake

  • +
  • PR #4184 - Resetting some cached variables to make sure those are +re-filled

  • +
  • PR #4183 - Fix hpxcxx configuration

  • +
  • PR #4181 - Rename base libraries var

  • +
  • PR #4180 - Move header left behind earlier to plugin module

  • +
  • PR #4179 - Moving zip_iterator and transform_iterator to +iterator_support module

  • +
  • PR #4178 - Move checkpointing support to its own module

  • +
  • PR #4177 - Small const fix to basic_execution module

  • +
  • PR #4176 - Add back HPX_LIBRARIES and friends to HPXConfig.cmake

  • +
  • PR #4175 - Make Vc public and add it to HPXConfig.cmake

  • +
  • PR #4173 - Wait for runtime to be running before returning from +hpx::start

  • +
  • PR #4172 - More protection against shutdown problems in error handling +scenarios.

  • +
  • PR #4171 - Ignore lock in condition_variable::wait

  • +
  • PR #4170 - Adding APEX dependency to MPI parcelport

  • +
  • PR #4168 - Adding utility include

  • +
  • PR #4167 - Add a condition to setup the external libraries

  • +
  • PR #4166 - Add an INTERNAL_FLAGS option to link to +hpx_internal_flags

  • +
  • PR #4165 - Forward HPX_* cmake cache variables to external projects

  • +
  • PR #4164 - Affinity and batch environment modules

  • +
  • PR #4162 - Handle quick exit

  • +
  • PR #4160 - Using target_link_libraries for cmake versions >= 3.12

  • +
  • PR #4159 - Make sure HPX_WITH_NATIVE_TLS is forwarded to dependent +projects

  • +
  • PR #4158 - Adding allocator imported target as a dependency of allocator +module

  • +
  • PR #4157 - Add hpx_memory as a dependency of parcelport plugins

  • +
  • PR #4156 - Stackless coroutines now can refer to themselves (through +get_self() and friends)

  • +
  • PR #4154 - Added CMake policy CMP0060 for HPX applications.

  • +
  • PR #4153 - add header iomanip to tests and tool

  • +
  • PR #4152 - Casting MPI tag value

  • +
  • PR #4149 - Add back private m_desc member variable in +program_options module

  • +
  • PR #4147 - Resource partitioner and threadmanager modules

  • +
  • PR #4146 - Google Season of Docs updates to documentation; creating hpx +projects

  • +
  • PR #4145 - Adding basic support for stackless threads

  • +
  • PR #4143 - Exclude test_client_1950 from all target

  • +
  • PR #4142 - Add a new thread_pool_executor

  • +
  • PR #4140 - Google Season of Docs updates to documentation; why hpx

  • +
  • PR #4139 - Remove runtime includes from coroutines module

  • +
  • PR #4138 - Forking boost::intrusive_ptr and adding it as +hpx::intrusive_ptr

  • +
  • PR #4137 - Fixing TSS destruction

  • +
  • PR #4136 - HPX.Compute modules

  • +
  • PR #4133 - Fix block_executor

  • +
  • PR #4131 - Applying fixes based on reports from PVS Studio

  • +
  • PR #4130 - Adding missing header to build system

  • +
  • PR #4129 - Fixing compilation if HPX_WITH_DATAPAR_VC is enabled

  • +
  • PR #4128 - Renaming moveonly_any to unique_any

  • +
  • PR #4126 - Attempt to fix basic_any constructor for gcc 7

  • +
  • PR #4125 - Changing extra_archive_data implementation

  • +
  • PR #4124 - Don’t link to Boost.System unless required

  • +
  • PR #4122 - Add kernel launch helper utility (+saxpy demo) and merge in +octotiger changes

  • +
  • PR #4121 - Fixing migration test if networking is disabled.

  • +
  • PR #4120 - Google Season of Docs updates to documentation; hpx build +system v1

  • +
  • PR #4119 - Making sure chunk_size and max_chunk are actually +applied to parallel algorithms if specified

  • +
  • PR #4117 - Make CircleCI formatting check store diff

  • +
  • PR #4116 - Fix automatically setting C++ standard

  • +
  • PR #4114 - Module serialization

  • +
  • PR #4113 - Module datastructures

  • +
  • PR #4111 - Fixing performance regression introduced earlier

  • +
  • PR #4110 - Adding missing SPDX tags

  • +
  • PR #4109 - Overload for start without entry point/argv.

  • +
  • PR #4108 - Making sure C++ standard is properly detected and propagated

  • +
  • PR #4106 - use std::round for guaranteed rounding without errors

  • +
  • PR #4104 - Extend scheduler_mode with new work_stealing and task +assignment modes

  • +
  • PR #4103 - Add this to lambda capture list

  • +
  • PR #4102 - Add spdx license and check

  • +
  • PR #4099 - Module coroutines

  • +
  • PR #4098 - Fix append module path in module CMakeLists template

  • +
  • PR #4097 - Function tests

  • +
  • PR #4096 - Removing return of thread_result_type from functions not +needing them

  • +
  • PR #4095 - Stop-gap measure until cmake overhaul is in place

  • +
  • PR #4094 - Deprecate HPX_WITH_MORE_THAN_64_THREADS

  • +
  • PR #4093 - Fix initialization of global_num_tasks in +parallel_executor

  • +
  • PR #4092 - Add support for mi-malloc

  • +
  • PR #4090 - Execution context

  • +
  • PR #4089 - Make counters in coroutines optional

  • +
  • PR #4087 - Making hpx::util::any compatible with C++17

  • +
  • PR #4084 - Making sure destination array for std::transform is +properly resized

  • +
  • PR #4083 - Adapting thread_queue_mc to behave even if no 128bit +atomics are available

  • +
  • PR #4082 - Fix compilation on GCC 5

  • +
  • PR #4081 - Adding option allowing to force using Boost.FileSystem

  • +
  • PR #4080 - Updating module dependencies

  • +
  • PR #4079 - Add missing tests for iterator_support module

  • +
  • PR #4078 - Disable parcel-layer if networking is disabled

  • +
  • PR #4077 - Add missing include that causes build fails

  • +
  • PR #4076 - Enable compatibility headers for functional module

  • +
  • PR #4075 - Coroutines module

  • +
  • PR #4073 - Use configure_file for generated files in modules

  • +
  • PR #4071 - Fixing MPI detection for PMIx

  • +
  • PR #4070 - Fix macOS builds

  • +
  • PR #4069 - Moving more facilities to the collectives module

  • +
  • PR #4068 - Adding main HPX #include directory to modules

  • +
  • PR #4066 - Switching the use of message(STATUS "...") to hpx_info

  • +
  • PR #4065 - Move Boost.Filesystem handling to filesystem module

  • +
  • PR #4064 - Fix program_options test with older boost versions

  • +
  • PR #4062 - The cpu_features tool fails to compile on anything but +x86 architectures

  • +
  • PR #4061 - Add clang-format checking step for modules

  • +
  • PR #4060 - Making sure HPX_IDLE_BACKOFF_TIME_MAX is always defined +(even if its unused)

  • +
  • PR #4059 - Renaming module hpx_parallel_executors into +hpx_execution

  • +
  • PR #4058 - Do not build networking tests when networking disabled

  • +
  • PR #4057 - Printing configuration summary for modules as well

  • +
  • PR #4055 - Google Season of Docs updates to documentation; hpx build +systems

  • +
  • PR #4054 - Add troubleshooting section to manual

  • +
  • PR #4051 - Add more variations to future_overhead test

  • +
  • PR #4050 - Creating plugin module

  • +
  • PR #4049 - Move missing modules tests

  • +
  • PR #4047 - Add boost/filesystem headers to inspect deprecated headers

  • +
  • PR #4045 - Module functional

  • +
  • PR #4043 - Fix preconditions and error messages for suspension functions

  • +
  • PR #4041 - Pass HPX_STANDARD on to dependent projects via +HPXConfig.cmake

  • +
  • PR #4040 - Program options module

  • +
  • PR #4039 - Moving non-serializable any (any_nonser) to +datastructures module

  • +
  • PR #4038 - Adding MPark’s variant (V1.4.0) to HPX

  • +
  • PR #4037 - Adding resiliency module

  • +
  • PR #4036 - Add C++17 filesystem compatibility header

  • +
  • PR #4035 - Fixing support for mpirun

  • +
  • PR #4028 - CMake to target based directives

  • +
  • PR #4027 - Remove GitLab CI configuration

  • +
  • PR #4026 - Threading refactoring

  • +
  • PR #4025 - Refactoring thread queue configuration options

  • +
  • PR #4024 - Fix padding calculation in cache_aligned_data.hpp

  • +
  • PR #4023 - Fixing Codacy issues

  • +
  • PR #4022 - Make sure process mask option is passed to affinity_data

  • +
  • PR #4021 - Warn about compiling in C++11 mode

  • +
  • PR #4020 - Module concurrency

  • +
  • PR #4019 - Module topology

  • +
  • PR #4018 - Update deprecated header in thread_queue_mc.hpp

  • +
  • PR #4015 - Avoid overwriting artifacts

  • +
  • PR #4014 - Future overheads

  • +
  • PR #4013 - Update URL to test output conversion script

  • +
  • PR #4012 - Fix CUDA compilation

  • +
  • PR #4011 - Fixing cyclic dependencies between modules

  • +
  • PR #4010 - Ignore stable tag on CircleCI

  • +
  • PR #4009 - Check circular dependencies in a circle ci step

  • +
  • PR #4008 - Extend cache aligned data to handle tuple-like data

  • +
  • PR #4007 - Fixing migration for components that have actions returning a +client

  • +
  • PR #4006 - Move is_value_proxy.hpp to algorithms module

  • +
  • PR #4004 - Shorten CTest timeout on CircleCI

  • +
  • PR #4003 - Refactoring to remove (internal) dependencies

  • +
  • PR #4001 - Exclude tests from all target

  • +
  • PR #4000 - Module errors

  • +
  • PR #3999 - Enable support for compatibility headers for logging module

  • +
  • PR #3998 - Add process thread binding option

  • +
  • PR #3997 - Export handle_assert function

  • +
  • PR #3996 - Attempt to solve issue where -latomic does not support +128bit atomics

  • +
  • PR #3993 - Make sure __LINE__ is an unsigned

  • +
  • PR #3991 - Fix dependencies and flags for header tests

  • +
  • PR #3990 - Documentation tags fixes

  • +
  • PR #3988 - Adding missing solution folder for format module test

  • +
  • PR #3987 - Move runtime-dependent functions out of command line handling

  • +
  • PR #3986 - Fix CMake configuration with PAPI on

  • +
  • PR #3985 - Module timing

  • +
  • PR #3984 - Fix default behaviour of paths in add_hpx_component

  • +
  • PR #3982 - Parallel executors module

  • +
  • PR #3981 - Segmented algorithms module

  • +
  • PR #3980 - Module logging

  • +
  • PR #3979 - Module util

  • +
  • PR #3978 - Fix clang-tidy step on CircleCI

  • +
  • PR #3977 - Fixing solution folders for moved components

  • +
  • PR #3976 - Module format

  • +
  • PR #3975 - Enable deprecation warnings on CircleCI

  • +
  • PR #3974 - Fix typos in documentation

  • +
  • PR #3973 - Fix compilation with GCC 9

  • +
  • PR #3972 - Add condition to clone apex + use of new cmake var APEX_ROOT

  • +
  • PR #3971 - Add testing module

  • +
  • PR #3968 - Remove unneeded file in hardware module

  • +
  • PR #3967 - Remove leftover PIC settings from main CMakeLists.txt

  • +
  • PR #3966 - Add missing export option in add_hpx_module

  • +
  • PR #3965 - Change current_function_helper back to non-constexpr

  • +
  • PR #3964 - Fixing merge problems

  • +
  • PR #3962 - Add a trait for std::array for unwrapping

  • +
  • PR #3961 - Making hpx::util::tuple<Ts...> and std::tuple<Ts...> +convertible

  • +
  • PR #3960 - fix compilation with CUDA 10 and GCC 6

  • +
  • PR #3959 - Fix C++11 incompatibility

  • +
  • PR #3957 - Algorithms module

  • +
  • PR #3956 - [HPX_AddModule] Fix lower name var to upper

  • +
  • PR #3955 - Fix CMake configuration with examples off and tests on

  • +
  • PR #3954 - Move components to separate subdirectory in root of +repository

  • +
  • PR #3952 - Update papi.cpp

  • +
  • PR #3951 - Exclude modules header tests from all target

  • +
  • PR #3950 - Adding all_reduce facility to collectives module

  • +
  • PR #3949 - This adds a configuration file that will cause for stale +issues to be automatically closed

  • +
  • PR #3948 - Fixing ALPS environment

  • +
  • PR #3947 - Add major compiler version check for building hpx as a binary +package

  • +
  • PR #3946 - [Modules] Move the location of the generated headers

  • +
  • PR #3945 - Simplify tests and examples cmake

  • +
  • PR #3943 - Remove example module

  • +
  • PR #3942 - Add NOEXPORT option to add_hpx_{component,library}

  • +
  • PR #3938 - Use https for CDash submissions

  • +
  • PR #3937 - Add HPX_WITH_BUILD_BINARY_PACKAGE to the compiler check +(refs #3935)

  • +
  • PR #3936 - Fixing installation of binaries on windows

  • +
  • PR #3934 - Add set function for sliding_semaphore max_difference

  • +
  • PR #3933 - Remove cudadevrt from compile/link flags as it breaks +downstream projects

  • +
  • PR #3932 - Fixing 3929

  • +
  • PR #3931 - Adding all_to_all

  • +
  • PR #3930 - Add test demonstrating the use of broadcast with component +actions

  • +
  • PR #3928 - fixed number of tasks and number of threads for heterogeneous +slurm environments

  • +
  • PR #3927 - Moving Cache module’s tests into separate solution folder

  • +
  • PR #3926 - Move unit tests to cache module

  • +
  • PR #3925 - Move version check to config module

  • +
  • PR #3924 - Add schedule hint executor parameters

  • +
  • PR #3923 - Allow aligning objects bigger than the cache line size

  • +
  • PR #3922 - Add Windows builds with Travis CI

  • +
  • PR #3921 - Add ccls cache directory to gitignore

  • +
  • PR #3920 - Fix git_external fetching of tags

  • +
  • PR #3905 - Correct rostambod url. Fix typo in doc

  • +
  • PR #3904 - Fix bug in context_base.hpp

  • +
  • PR #3903 - Adding new performance counters

  • +
  • PR #3902 - Add add_hpx_module function

  • +
  • PR #3901 - Factoring out container remapping into a separate trait

  • +
  • PR #3900 - Making sure errors during command line processing are +properly reported and will not cause assertions

  • +
  • PR #3899 - Remove old compatibility bases from make_action

  • +
  • PR #3898 - Make parameter size be of type size_t

  • +
  • PR #3897 - Making sure all tests are disabled if HPX_WITH_TESTS=OFF

  • +
  • PR #3895 - Add documentation for annotated_function

  • +
  • PR #3894 - Working around VS2019 problem with make_action

  • +
  • PR #3892 - Avoid MSVC compatibility warning in internal allocator

  • +
  • PR #3891 - Removal of the default intel config include

  • +
  • PR #3888 - Fix async_customization dataflow example and Clarify +what’s being tested

  • +
  • PR #3887 - Add Doxygen documentation

  • +
  • PR #3882 - Minor docs fixes

  • +
  • PR #3880 - Updating APEX version tag

  • +
  • PR #3878 - Making sure symbols are properly exported from modules +(needed for Windows/MacOS)

  • +
  • PR #3877 - Documentation

  • +
  • PR #3876 - Module hardware

  • +
  • PR #3875 - Converted typedefs in actions submodule to using directives

  • +
  • PR #3874 - Allow one to suppress target keywords in hpx_setup_target +for backwards compatibility

  • +
  • PR #3873 - Add scripts to create releases and generate lists of PRs and +issues

  • +
  • PR #3872 - Fix latest HTML docs location

  • +
  • PR #3870 - Module cache

  • +
  • PR #3869 - Post 1.3.0 version bumps

  • +
  • PR #3868 - Replace the macro HPX_ASSERT by HPX_TEST in tests

  • +
  • PR #3845 - Assertion module

  • +
  • PR #3839 - Make tuple serialization non-intrusive

  • +
  • PR #3832 - Config module

  • +
  • PR #3799 - Remove compat namespace and its contents

  • +
  • PR #3701 - MoodyCamel lockfree

  • +
  • PR #3496 - Disabling MPI’s (deprecated) C++ interface

  • +
  • PR #3192 - Move type info into hpx::debug namespace and add print +helper functions

  • +
  • PR #3159 - Support Checkpointing Components

  • +
+
+
+
+
HPX V1.3.0 (May 23, 2019)#
+
+
General changes#
+
    +
  • Performance improvements: the schedulers have significantly reduced overheads +from removing false sharing and the parallel executor has been updated to +create fewer futures.

  • +
  • HPX now defaults to not turning on networking when running on one locality. +This means that you can run multiple instances on the same system without +adding command line options.

  • +
  • Multiple issues reported by Clang sanitizers have been fixed.

  • +
  • We have added (back) single-page HTML documentation and PDF documentation.

  • +
  • We have started modularizing the HPX library. This is useful both for +developers and users. In the long term users will be able to consume only +parts of the HPX libraries if they do not require all the functionality that +HPX currently provides.

  • +
  • We have added an implementation of function_ref.

  • +
  • The barrier and latch classes have gained a few additional member +functions.

  • +
+
+
+
Breaking changes#
+
    +
  • Executable and library targets are now created without the _exe and +_lib suffix respectively. For example, the target 1d_stencil_1_exe is +now simply called 1d_stencil_1.

  • +
  • We have removed the following deprecated functionality: queue, +scoped_unlock, and support for input iterators in algorithms.

  • +
  • We have turned off the compatibility layer for unwrapped by default. The +functionality will be removed in the next release. The option can still be +turned on using the CMake option HPX_WITH_UNWRAPPED_SUPPORT. Likewise, +inclusive_scan compatibility overloads have been turned off by default. +They can still be turned on with HPX_WITH_INCLUSIVE_SCAN_COMPATIBILITY.

  • +
  • The minimum compiler and dependency versions have been updated. We now support +GCC from version 5 onwards, Clang from version 4 onwards, and Boost from +version 1.61.0 onwards.

  • +
  • The headers for preprocessor macros have moved as a result of the +functionality being moved to a separate module. The old headers are deprecated +and will be removed in a future version of HPX. You can turn off the warnings +by setting HPX_PREPROCESSOR_WITH_DEPRECATION_WARNINGS=OFF or turn off the +compatibility headers completely with +HPX_PREPROCESSOR_WITH_COMPATIBILITY_HEADERS=OFF.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #3863 - shouldn’t “-faligned-new” be a usage requirement?

  • +
  • Issue #3841 - Build error with msvc 19 caused by SFINAE and C++17

  • +
  • Issue #3836 - master branch does not build with idle rate counters +enabled

  • +
  • Issue #3819 - Add debug suffix to modules built in debug mode

  • +
  • Issue #3817 - HPX_INCLUDE_DIRS contains non-existent directory

  • +
  • Issue #3810 - Source groups are not created for files in modules

  • +
  • Issue #3805 - HPX won’t compile with -DHPX_WITH_APEX=TRUE

  • +
  • Issue #3792 - Barrier Hangs When Locality Zero not included

  • +
  • Issue #3778 - Replace throw() with noexcept

  • +
  • Issue #3763 - configurable sort limit per task

  • +
  • Issue #3758 - dataflow doesn’t convert future<future<T>> to +future<T>

  • +
  • Issue #3757 - When compiling undefined reference to +hpx::hpx_check_version_1_2 HPX V1.2.1, Ubuntu 18.04.01 Server Edition

  • +
  • Issue #3753 - --hpx:list-counters=full crashes

  • +
  • Issue #3746 - Detection of MPI with pmix

  • +
  • Issue #3744 - Separate spinlock from same cacheline as internal data for +all LCOs

  • +
  • Issue #3743 - hpxcxx’s shebang doesn’t specify the python version

  • +
  • Issue #3738 - Unable to debug parcelport on a single node

  • +
  • Issue #3735 - Latest master: Can’t compile in MSVC

  • +
  • Issue #3731 - util::bound seems broken on Clang with older libstdc++

  • +
  • Issue #3724 - Allow to pre-set command line options through environment

  • +
  • Issue #3723 - examples/resource_partitioner build issue on master branch +/ ubuntu 18

  • +
  • Issue #3721 - faced a building error

  • +
  • Issue #3720 - Hello World example fails to link

  • +
  • Issue #3719 - pkg-config produces invalid output: -l-pthread

  • +
  • Issue #3718 - Please make the python executable configurable through +cmake

  • +
  • Issue #3717 - interested to contribute to the organisation

  • +
  • Issue #3699 - Remove ‘HPX runtime’ executable

  • +
  • Issue #3698 - Ignore all locks while handling asserts

  • +
  • Issue #3689 - Incorrect and inconsistent website structure +http://stellar.cct.lsu.edu/downloads/.

  • +
  • Issue #3681 - Broken links on +http://stellar.cct.lsu.edu/2015/05/hpx-archives-now-on-gmane/

  • +
  • Issue #3676 - HPX master built from source, cmake fails to link main.cpp +example in docs

  • +
  • Issue #3673 - HPX build fails with std::atomic missing error

  • +
  • Issue #3670 - Generate PDF again from documentation (with Sphinx)

  • +
  • Issue #3643 - Warnings when compiling HPX 1.2.1 with gcc 9

  • +
  • Issue #3641 - Trouble with using ranges-v3 and hpx::parallel::reduce

  • +
  • Issue #3639 - util::unwrapping does not work well with member +functions

  • +
  • Issue #3634 - The build fails if shared_future<>::then is called +with a thread executor

  • +
  • Issue #3622 - VTune Amplifier 2019 not working with use_itt_notify=1

  • +
  • Issue #3616 - HPX Fails to Build with CUDA 10

  • +
  • Issue #3612 - False sharing of scheduling counters

  • +
  • Issue #3609 - executor_parameters timeout with gcc <= 7 and Debug mode

  • +
  • Issue #3601 - Misleading error message on power pc for rdtsc and rdtscp

  • +
  • Issue #3598 - Build of some examples fails when using Vc

  • +
  • Issue #3594 - Error: The number of OS threads requested (20) does not +match the number of threads to bind (12): HPX(bad_parameter)

  • +
  • Issue #3592 - Undefined Reference Error

  • +
  • Issue #3589 - include could not find load file: HPX_Utils.cmake

  • +
  • Issue #3587 - HPX won’t compile on POWER8 with Clang 7

  • +
  • Issue #3583 - Fedora and openSUSE instructions missing on “Distribution +Packages” page

  • +
  • Issue #3578 - Build error when configuring with +HPX_HAVE_ALGORITHM_INPUT_ITERATOR_SUPPORT=ON

  • +
  • Issue #3575 - Merge openSUSE reproducible patch

  • +
  • Issue #3570 - Update HPX to work with the latest VC version

  • +
  • Issue #3567 - Build succeed and make failed for hpx:cout

  • +
  • Issue #3565 - Polymorphic simple component destructor not getting called

  • +
  • Issue #3559 - 1.2.0 is missing from download page

  • +
  • Issue #3554 - Clang 6.0 warning of hiding overloaded virtual function

  • +
  • Issue #3510 - Build on ppc64 fails

  • +
  • Issue #3482 - Improve error message when HPX_WITH_MAX_CPU_COUNT is +too low for given system

  • +
  • Issue #3453 - Two HPX applications can’t run at the same time.

  • +
  • Issue #3452 - Scaling issue on the change to 2 NUMA domains

  • +
  • Issue #3442 - HPX set_difference, set_intersection failure cases

  • +
  • Issue #3437 - Ensure parent_task pointer when child task is created and +child/parent are on same locality

  • +
  • Issue #3255 - Suspension with lock for --hpx:list-component-types

  • +
  • Issue #3034 - Use C++17 structured bindings for serialization

  • +
  • Issue #2999 - Change thread scheduling use of size_t for thread +indexing

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #3865 - adds hpx_target_compile_option_if_available

  • +
  • PR #3864 - Helper functions that are useful in numa binding and testing +of allocator

  • +
  • PR #3862 - Temporary fix to local_dataflow_boost_small_vector test

  • +
  • PR #3860 - Add cache line padding to intermediate results in for loop +reduction

  • +
  • PR #3859 - Remove HPX_TLL_PUBLIC and HPX_TLL_PRIVATE from CMake files

  • +
  • PR #3858 - Add compile flags and definitions to modules

  • +
  • PR #3851 - update hpxmp release tag to v0.2.0

  • +
  • PR #3849 - Correct BOOST_ROOT variable name in quick start guide

  • +
  • PR #3847 - Fix attach_debugger configuration option

  • +
  • PR #3846 - Add tests for libs header tests

  • +
  • PR #3844 - Fixing source_groups in preprocessor module to properly +handle compatibility headers

  • +
  • PR #3843 - This fixes the launch_process/launched_process pair of tests

  • +
  • PR #3842 - Fix macro call with ITTNOTIFY enabled

  • +
  • PR #3840 - Fixing SLURM environment parsing

  • +
  • PR #3837 - Fixing misplaced #endif

  • +
  • PR #3835 - make all latch members protected for consistency

  • +
  • PR #3834 - Disable transpose_block_numa example on CircleCI

  • +
  • PR #3833 - make latch counter_ protected for deriving latch in hpxmp

  • +
  • PR #3831 - Fix CircleCI config for modules

  • +
  • PR #3830 - minor fix: option HPX_WITH_TEST was not working correctly

  • +
  • PR #3828 - Avoid for binaries that depend on HPX to directly link +against internal modules

  • +
  • PR #3827 - Adding shortcut for hpx::get_ptr<>(sync, id) for a local, +non-migratable objects

  • +
  • PR #3826 - Fix and update modules documentation

  • +
  • PR #3825 - Updating default APEX version to 2.1.3 with HPX

  • +
  • PR #3823 - Fix pkgconfig libs handling

  • +
  • PR #3822 - Change includes in hpx_wrap.cpp to more specific includes

  • +
  • PR #3821 - Disable barrier_3792 test when networking is disabled

  • +
  • PR #3820 - Assorted CMake fixes

  • +
  • PR #3815 - Removing left-over debug output

  • +
  • PR #3814 - Allow setting default scheduler mode via the configuration +database

  • +
  • PR #3813 - Make the deprecation warnings issued by the old pp headers +optional

  • +
  • PR #3812 - Windows requires to handle symlinks to directories +differently from those linking files

  • +
  • PR #3811 - Clean up PP module and library skeleton

  • +
  • PR #3806 - Moving include path configuration to before APEX

  • +
  • PR #3804 - Fix latch

  • +
  • PR #3803 - Update hpxcxx to look at lib64 and use python3

  • +
  • PR #3802 - Numa binding allocator

  • +
  • PR #3801 - Remove duplicated includes

  • +
  • PR #3800 - Attempt to fix Posix context switching after lazy init +changes

  • +
  • PR #3798 - count and count_if accepts different iterator types

  • +
  • PR #3797 - Adding a couple of override keywords to overloaded +virtual functions

  • +
  • PR #3796 - Re-enable testing all schedulers in shutdown_suspended_test

  • +
  • PR #3795 - Change std::terminate to std::abort in SIGSEGV +handler

  • +
  • PR #3794 - Fixing #3792

  • +
  • PR #3793 - Extending migrate_polymorphic_component unit test

  • +
  • PR #3791 - Change throw() to noexcept

  • +
  • PR #3790 - Remove deprecated options for 1.3.0 release

  • +
  • PR #3789 - Remove Boost filesystem compatibility header

  • +
  • PR #3788 - Disabled even more spots that should not execute if +networking is disabled

  • +
  • PR #3787 - Bump minimal boost supported version to 1.61.0

  • +
  • PR #3786 - Bump minimum required versions for 1.3.0 release

  • +
  • PR #3785 - Explicitly set number of jobs for all ninja invocations on +CircleCI

  • +
  • PR #3784 - Fix leak and address sanitizer problems

  • +
  • PR #3783 - Disabled even more spots that should not execute is +networking is disabled

  • +
  • PR #3782 - Cherry-picked tuple and thread_init_data fixes from #3701

  • +
  • PR #3781 - Fix generic context coroutines after lazy stack allocation +changes

  • +
  • PR #3780 - Rename hello world examples

  • +
  • PR #3776 - Sort algorithms now use the supplied chunker to determine the +required minimal chunk size

  • +
  • PR #3775 - Disable Boost auto-linking

  • +
  • PR #3774 - Tag and push stable builds

  • +
  • PR #3773 - Enable migration of polymorphic components

  • +
  • PR #3771 - Fix link to stackoverflow in documentation

  • +
  • PR #3770 - Replacing constexpr if in brace-serialization code

  • +
  • PR #3769 - Fix SIGSEGV handler

  • +
  • PR #3768 - Adding flags to scheduler allowing to control thread stealing +and idle back-off

  • +
  • PR #3767 - Fix help formatting in hpxrun.py

  • +
  • PR #3765 - Fix a couple of bugs in the thread test

  • +
  • PR #3764 - Workaround for SFINAE regression in msvc14.2

  • +
  • PR #3762 - Prevent MSVC from prematurely instantiating things

  • +
  • PR #3761 - Update python scripts to work with python 3

  • +
  • PR #3760 - Fix callable vtable for GCC4.9

  • +
  • PR #3759 - Rename PAGE_SIZE to PAGE_SIZE_ because AppleClang

  • +
  • PR #3755 - Making sure locks are not held during suspension

  • +
  • PR #3754 - Disable more code if networking is not available/not enabled

  • +
  • PR #3752 - Move util::format implementation to source file

  • +
  • PR #3751 - Fixing problems with lcos::barrier and iostreams

  • +
  • PR #3750 - Change error message to take into account use_guard_page +setting

  • +
  • PR #3749 - Fix lifetime problem in run_as_hpx_thread

  • +
  • PR #3748 - Fixed unusable behavior of the clang code analyzer.

  • +
  • PR #3747 - Added PMIX_RANK to the defaults of +HPX_WITH_PARCELPORT_MPI_ENV.

  • +
  • PR #3745 - Introduced cache_aligned_data and cache_line_data +helper structure

  • +
  • PR #3742 - Remove more unused functionality from util/logging

  • +
  • PR #3740 - Fix includes in partitioned vector tests

  • +
  • PR #3739 - More fixes to make sure that std::flush really flushes +all output

  • +
  • PR #3737 - Fix potential shutdown problems

  • +
  • PR #3736 - Fix guided_pool_executor after dataflow changes caused +compilation fail

  • +
  • PR #3734 - Limiting executor

  • +
  • PR #3732 - More constrained bound constructors

  • +
  • PR #3730 - Attempt to fix deadlocks during component loading

  • +
  • PR #3729 - Add latch member function count_up and reset, requested +by hpxMP

  • +
  • PR #3728 - Send even empty buffers on hpx::endl and hpx::flush

  • +
  • PR #3727 - Adding example demonstrating how to customize the memory +management for a component

  • +
  • PR #3726 - Adding support for passing command line options through the +HPX_COMMANDLINE_OPTIONS environment variable

  • +
  • PR #3722 - Document known broken OpenMPI builds

  • +
  • PR #3716 - Add barrier reset function, requested by hpxMP for reusing +barrier

  • +
  • PR #3715 - More work on functions and vtables

  • +
  • PR #3714 - Generate single-page HTML, PDF, manpage from documentation

  • +
  • PR #3713 - Updating default APEX version to 2.1.2

  • +
  • PR #3712 - Update release procedure

  • +
  • PR #3710 - Fix the C++11 build, after #3704

  • +
  • PR #3709 - Move some component_registry functionality to source file

  • +
  • PR #3708 - Ignore all locks while handling assertions

  • +
  • PR #3707 - Remove obsolete hpx runtime executable

  • +
  • PR #3705 - Fix and simplify make_ready_future overload sets

  • +
  • PR #3704 - Reduce use of binders

  • +
  • PR #3703 - Ini

  • +
  • PR #3702 - Fixing CUDA compiler errors

  • +
  • PR #3700 - Added barrier::increment function to increase total +number of thread

  • +
  • PR #3697 - One more attempt to fix migration…

  • +
  • PR #3694 - Fixing component migration

  • +
  • PR #3693 - Print thread state when getting disallowed value in +set_thread_state

  • +
  • PR #3692 - Only disable constexpr with clang-cuda, not nvcc+gcc

  • +
  • PR #3691 - Link with libsupc++ if needed for thread_local

  • +
  • PR #3690 - Remove thousands separators in set_operations_3442 to comply +with C++11

  • +
  • PR #3688 - Decouple serialization from function vtables

  • +
  • PR #3687 - Fix a couple of test failures

  • +
  • PR #3686 - Make sure tests.unit.build are run after install on CircleCI

  • +
  • PR #3685 - Revise quickstart CMakeLists.txt explanation

  • +
  • PR #3684 - Provide concept emulation for Ranges-TS concepts

  • +
  • PR #3683 - Ignore uninitialized chunks

  • +
  • PR #3682 - Ignore uninitialized chunks. Check proper indices.

  • +
  • PR #3680 - Ignore uninitialized chunks. Check proper range indices

  • +
  • PR #3679 - Simplify basic action implementations

  • +
  • PR #3678 - Making sure HPX_HAVE_LIBATOMIC is unset before checking

  • +
  • PR #3677 - Fix generated full version number to be usable in expressions

  • +
  • PR #3674 - Reduce functional utilities call depth

  • +
  • PR #3672 - Change new build system to use existing macros related to +pseudo dependencies

  • +
  • PR #3669 - Remove indirection in function_ref when thread +description is disabled

  • +
  • PR #3668 - Unbreaking async_*cb* tests

  • +
  • PR #3667 - Generate version.hpp

  • +
  • PR #3665 - Enabling MPI parcelport for gitlab runners

  • +
  • PR #3664 - making clang-tidy work properly again

  • +
  • PR #3662 - Attempt to fix exception handling

  • +
  • PR #3661 - Move lcos::latch to source file

  • +
  • PR #3660 - Fix accidentally explicit gid_type default constructor

  • +
  • PR #3659 - Parallel executor latch

  • +
  • PR #3658 - Fixing execution_parameters

  • +
  • PR #3657 - Avoid dangling references in wait_all

  • +
  • PR #3656 - Avoiding lifetime problems with sync_put_parcel

  • +
  • PR #3655 - Fixing nullptr dereference inside of function

  • +
  • PR #3652 - Attempt to fix thread_map_type definition with C++11

  • +
  • PR #3650 - Allowing for end iterator being different from begin iterator

  • +
  • PR #3649 - Added architecture identification to cmake to be able to +detect timestamp support

  • +
  • PR #3645 - Enabling sanitizers on gitlab runner

  • +
  • PR #3644 - Attempt to tackle timeouts during startup

  • +
  • PR #3642 - Cleanup parallel partitioners

  • +
  • PR #3640 - Dataflow now works with functions that return a reference

  • +
  • PR #3637 - Merging the executor-enabled overloads of +shared_future<>::then

  • +
  • PR #3633 - Replace deprecated boost endian macros

  • +
  • PR #3632 - Add instructions on getting HPX to documentation

  • +
  • PR #3631 - Simplify parcel creation

  • +
  • PR #3630 - Small additions and fixes to release procedure

  • +
  • PR #3629 - Modular pp

  • +
  • PR #3627 - Implement util::function_ref

  • +
  • PR #3626 - Fix cancelable_action_client example

  • +
  • PR #3625 - Added automatic serialization for simple structs (see #3034)

  • +
  • PR #3624 - Updating the default order of priority for +thread_description

  • +
  • PR #3621 - Update copyright year and other small formatting fixes

  • +
  • PR #3620 - Adding support for gitlab runner

  • +
  • PR #3619 - Store debug logs and core dumps on CircleCI

  • +
  • PR #3618 - Various optimizations

  • +
  • PR #3617 - Fix link to the gpg key (#2)

  • +
  • PR #3615 - Fix unused variable warnings with networking off

  • +
  • PR #3614 - Restructuring counter data in scheduler to reduce false +sharing

  • +
  • PR #3613 - Adding support for gitlab runners

  • +
  • PR #3610 - Don’t wait for stop_condition in main thread

  • +
  • PR #3608 - Add inline keyword to invalid_thread_id definition for +nvcc

  • +
  • PR #3607 - Adding configuration key that allows one to explicitly add a +directory to the component search path

  • +
  • PR #3606 - Add nvcc to exclude constexpress since is it not supported by +nvcc

  • +
  • PR #3605 - Add inline to definition of checkpoint stream operators +to fix link error

  • +
  • PR #3604 - Use format for string formatting

  • +
  • PR #3603 - Improve the error message for using to less MAX_CPU_COUNT

  • +
  • PR #3602 - Improve the error message for to small values of +MAX_CPU_COUNT

  • +
  • PR #3600 - Parallel executor aggregated

  • +
  • PR #3599 - Making sure networking is disabled for default +one-locality-runs

  • +
  • PR #3596 - Store thread exit functions in forward_list instead of +deque to avoid allocations

  • +
  • PR #3590 - Fix typo/mistake in thread queue cleanup_terminated

  • +
  • PR #3588 - Fix formatting errors in +launching_and_configuring_hpx_applications.rst

  • +
  • PR #3586 - Make bind propagate value category

  • +
  • PR #3585 - Extend Cmake for building hpx as distribution packages (refs +#3575)

  • +
  • PR #3584 - Untangle function storage from object pointer

  • +
  • PR #3582 - Towards Modularized HPX

  • +
  • PR #3580 - Remove extra || in merge.hpp

  • +
  • PR #3577 - Partially revert “Remove vtable empty flag”

  • +
  • PR #3576 - Make sure empty startup/shutdown functions are not being used

  • +
  • PR #3574 - Make sure DATAPAR settings are conveyed to depending +projects

  • +
  • PR #3573 - Make sure HPX is usable with latest released version of Vc +(V1.4.1)

  • +
  • PR #3572 - Adding test ensuring ticket 3565 is fixed

  • +
  • PR #3571 - Make empty [unique_]function vtable non-dependent

  • +
  • PR #3566 - Fix compilation with dynamic bitset for CPU masks

  • +
  • PR #3563 - Drop util::[unique_]function target_type

  • +
  • PR #3562 - Removing the target suffixes

  • +
  • PR #3561 - Replace executor traits return type deduction (keep +non-SFINAE)

  • +
  • PR #3557 - Replace the last usages of boost::atomic

  • +
  • PR #3556 - Replace boost::scoped_array with std::unique_ptr

  • +
  • PR #3552 - (Re)move APEX readme

  • +
  • PR #3548 - Replace boost::scoped_ptr with std::unique_ptr

  • +
  • PR #3547 - Remove last use of Boost.Signals2

  • +
  • PR #3544 - Post 1.2.0 version bumps

  • +
  • PR #3543 - added Ubuntu dependency list to readme

  • +
  • PR #3531 - Warnings, warnings…

  • +
  • PR #3527 - Add CircleCI filter for building all tags

  • +
  • PR #3525 - Segmented algorithms

  • +
  • PR #3517 - Replace boost::regex with C++11 <regex>

  • +
  • PR #3514 - Cleaning up the build system

  • +
  • PR #3505 - Fixing type attribute warning for transfer_action

  • +
  • PR #3504 - Add support for rpm packaging

  • +
  • PR #3499 - Improving spinlock pools

  • +
  • PR #3498 - Remove thread specific ptr

  • +
  • PR #3486 - Fix comparison for expect_connecting_localities config entry

  • +
  • PR #3469 - Enable (existing) code for extracting stack pointer on Power +platform

  • +
+
+
+
+
HPX V1.2.1 (Feb 19, 2019)#
+
+
General changes#
+

This is a bugfix release. It contains the following changes:

+
    +
  • Fix compilation on ARM, s390x and 32-bit architectures.

  • +
  • Fix a critical bug in the future implementation.

  • +
  • Fix several problems in the CMake configuration which affects external +projects.

  • +
  • Add support for Boost 1.69.0.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #3638 - Build HPX 1.2 with boost 1.69

  • +
  • Issue #3635 - Non-deterministic crashing on Stampede2

  • +
  • Issue #3550 - 1>e:000workhpxsrcthrow_exception.cpp(54): error C2440: +‘<function-style-cast>’: cannot convert from ‘boost::system::error_code’ to +‘hpx::exception’

  • +
  • Issue #3549 - HPX 1.2.0 does not build on i686, but release candidate +did

  • +
  • Issue #3511 - Build on s390x fails

  • +
  • Issue #3509 - Build on armv7l fails

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #3695 - Don’t install CMake templates and packaging files

  • +
  • PR #3666 - Fixing yet another race in future_data

  • +
  • PR #3663 - Fixing race between setting and getting the value inside +future_data

  • +
  • PR #3648 - Adding timestamp option for S390x platform

  • +
  • PR #3647 - Blind attempt to fix warnings issued by gcc V9

  • +
  • PR #3611 - Include GNUInstallDirs earlier to have it available for +subdirectories

  • +
  • PR #3595 - Use GNUInstallDirs lib path in pkgconfig config file

  • +
  • PR #3593 - Add include(GNUInstallDirs) to HPXMacros.cmake

  • +
  • PR #3591 - Fix compilation error on arm7 architecture. Compiles and runs +on Fedora 29 on Pi 3.

  • +
  • PR #3558 - Adding constructor exception(boost::system::error_code +const&)

  • +
  • PR #3555 - cmake: make install locations configurable

  • +
  • PR #3551 - Fix uint64_t causing compilation fail on i686

  • +
+
+
+
+
HPX V1.2.0 (Nov 12, 2018)#
+
+
General changes#
+

Here are some of the main highlights and changes for this release:

+
    +
  • Thanks to the work of our Google Summer of Code student, Nikunj Gupta, we now +have a new implementation of hpx_main.hpp on supported platforms (Linux, +BSD and MacOS). This is intended to be a less fragile drop-in replacement for +the old implementation relying on preprocessor macros. The new implementation +does not require changes if you are using the CMake or pkg-config. The old +behaviour can be restored by setting HPX_WITH_DYNAMIC_HPX_MAIN=OFF during +CMake configuration. The implementation on Windows is unchanged.

  • +
  • We have added functionality to allow passing scheduling hints to our +schedulers. These will allow us to create executors that for example target a +specific NUMA domain or allow for HPX threads to be pinned to a particular +worker thread.

  • +
  • We have significantly improved the performance of our futures implementation +by making the shared state atomic.

  • +
  • We have replaced Boostbook by Sphinx for our documentation. This means the +documentation is easier to navigate with built-in search and table of +contents. We have also added a quick start section and restructured the +documentation to be easier to follow for new users.

  • +
  • We have added a new option to the --hpx:threads command line option. +It is now possible to use cores to tell HPX to only use one worker +thread per core, unlike the existing option all which uses one worker +thread per processing unit (processing unit can be a hyperthread if +hyperthreads are available). The default value of --hpx:threads has +also been changed to cores as this leads to better performance in most +cases.

  • +
  • All command line options can now be passed alongside configuration options +when initializing HPX. This means that some options that were previously +only available on the command line can now be set as configuration options.

  • +
  • HPXMP is a portable, scalable, and flexible application programming interface +using the OpenMP specification that supports multi-platform shared memory +multiprocessing programming in C and C++. HPXMP can be enabled within HPX by +setting DHPX_WITH_HPXMP=ON during CMake configuration.

  • +
  • Two new performance counters were added for measuring the time spent doing +background work. /threads/time/background-work-duration returns the time +spent doing background on a given thread or locality, while +/threads/time/background-overhead returns the fraction of time spent doing +background work with respect to the overall time spent running the scheduler. +The new performance counters are disabled by default and can be turned on by +setting HPX_WITH_BACKGROUND_THREAD_COUNTERS=ON during CMake +configuration.

  • +
  • The idling behaviour of HPX has been tweaked to allow for faster idling. +This is useful in interactive applications where the HPX worker threads may +not have work all the time. This behaviour can be tweaked and turned off as +before with HPX_WITH_THREAD_MANAGER_IDLE_BACKOFF=OFF during CMake +configuration.

  • +
  • It is now possible to register callback functions for HPX worker thread +events. Callbacks can be registered for starting and stopping worker threads, +and for when errors occur.

  • +
+
+
+
Breaking changes#
+
    +
  • The implementation of hpx_main.hpp has changed. If you are using custom +Makefiles you will need to make changes. Please see the documentation on +using Makefiles for more details.

  • +
  • The default value of --hpx:threads has changed from all to +cores. The new option cores only starts one worker thread per core.

  • +
  • We have dropped support for Boost 1.56 and 1.57. The minimal version of Boost +we now test is 1.58.

  • +
  • Our boost::format-based formatting implementation has been revised and +replaced with a custom implementation. This changes the formatting syntax and +requires changes if you are relying on hpx::util::format or +hpx::util::format_to. The pull request for this change contains +more information: PR #3266.

  • +
  • The following deprecated options have now been completely removed: +HPX_WITH_ASYNC_FUNCTION_COMPATIBILITY, HPX_WITH_LOCAL_DATAFLOW, +HPX_WITH_GENERIC_EXECUTION_POLICY, +HPX_WITH_BOOST_CHRONO_COMPATIBILITY, HPX_WITH_EXECUTOR_COMPATIBILITY, +HPX_WITH_EXECUTION_POLICY_COMPATIBILITY, and +HPX_WITH_TRANSFORM_REDUCE_COMPATIBILITY.

  • +
+
+
+
Closed issues#
+
    +
  • Issue #3538 - numa handling incorrect for hwloc 2

  • +
  • Issue #3533 - Cmake version 3.5.1does not work (git ff26b35 2018-11-06)

  • +
  • Issue #3526 - Failed building hpx-1.2.0-rc1 on Ubuntu16.04 x86-64 Virtualbox VM

  • +
  • Issue #3512 - Build on aarch64 fails

  • +
  • Issue #3475 - HPX fails to link if the MPI parcelport is enabled

  • +
  • Issue #3462 - CMake configuration shows a minor and inconsequential failure to create a symlink

  • +
  • Issue #3461 - Compilation Problems with the most recent Clang

  • +
  • Issue #3460 - Deadlock when create_partitioner fails (assertion fails) in debug mode

  • +
  • Issue #3455 - HPX build failing with HWLOC errors on POWER8 with hwloc 1.8

  • +
  • Issue #3438 - HPX no longer builds on IBM POWER8

  • +
  • Issue #3426 - hpx build failed on MacOS

  • +
  • Issue #3424 - CircleCI builds broken for forked repositories

  • +
  • Issue #3422 - Benchmarks in tests.performance.local are not run nightly

  • +
  • Issue #3408 - CMake Targets for HPX

  • +
  • Issue #3399 - processing unit out of bounds

  • +
  • Issue #3395 - Floating point bug in hpx/runtime/threads/policies/scheduler_base.hpp

  • +
  • Issue #3378 - compile error with lcos::communicator

  • +
  • Issue #3376 - Failed to build HPX with APEX using clang

  • +
  • Issue #3366 - Adapted Safe_Object example fails for –hpx:threads > 1

  • +
  • Issue #3360 - Segmentation fault when passing component id as parameter

  • +
  • Issue #3358 - HPX runtime hangs after multiple (~thousands) start-stop sequences

  • +
  • Issue #3352 - Support TCP provider in libfabric ParcelPort

  • +
  • Issue #3342 - undefined reference to __atomic_load_16

  • +
  • Issue #3339 - setting command line options/flags from init cfg is not obvious

  • +
  • Issue #3325 - AGAS migrates components prematurely

  • +
  • Issue #3321 - hpx bad_parameter handling is awful

  • +
  • Issue #3318 - Benchmarks fail to build with C++11

  • +
  • Issue #3304 - hpx::threads::run_as_hpx_thread does not properly handle exceptions

  • +
  • Issue #3300 - Setting pu step or offset results in no threads in default pool

  • +
  • Issue #3297 - Crash with APEX when running Phylanx lra_csv with > 1 thread

  • +
  • Issue #3296 - Building HPX with APEX configuration gives compiler warnings

  • +
  • Issue #3290 - make tests failing at hello_world_component

  • +
  • Issue #3285 - possible compilation error when “using namespace std;” is defined before including “hpx” headers files

  • +
  • Issue #3280 - HPX fails on OSX

  • +
  • Issue #3272 - CircleCI does not upload generated docker image any more

  • +
  • Issue #3270 - Error when compiling CUDA examples

  • +
  • Issue #3267 - tests.unit.host_.block_allocator fails occasionally

  • +
  • Issue #3264 - Possible move to Sphinx for documentation

  • +
  • Issue #3263 - Documentation improvements

  • +
  • Issue #3259 - set_parcel_write_handler test fails occasionally

  • +
  • Issue #3258 - Links to source code in documentation are broken

  • +
  • Issue #3247 - Rare tests.unit.host_.block_allocator test failure on 1.1.0-rc1

  • +
  • Issue #3244 - Slowing down and speeding up an interval_timer

  • +
  • Issue #3215 - Cannot build both tests and examples on MSVC with pseudo-dependencies enabled

  • +
  • Issue #3195 - Unnecessary customization point route causing performance penalty

  • +
  • Issue #3088 - A strange thing in parallel::sort.

  • +
  • Issue #2650 - libfabric support for passive endpoints

  • +
  • Issue #1205 - TSS is broken

  • +
+
+
+
Closed pull requests#
+
    +
  • PR #3542 - Fix numa lookup from pu when using hwloc 2.x

  • +
  • PR #3541 - Fixing the build system of the MPI parcelport

  • +
  • PR #3540 - Updating HPX people section

  • +
  • PR #3539 - Splitting test to avoid OOM on CircleCI

  • +
  • PR #3537 - Fix guided exec

  • +
  • PR #3536 - Updating grants which support the LSU team

  • +
  • PR #3535 - Fix hiding of docker credentials

  • +
  • PR #3534 - Fixing #3533

  • +
  • PR #3532 - fixing minor doc typo –hpx:print-counter-at arg

  • +
  • PR #3530 - Changing APEX default tag to v2.1.0

  • +
  • PR #3529 - Remove leftover security options and documentation

  • +
  • PR #3528 - Fix hwloc version check

  • +
  • PR #3524 - Do not build guided pool examples with older GCC compilers

  • +
  • PR #3523 - Fix logging regression

  • +
  • PR #3522 - Fix more warnings

  • +
  • PR #3521 - Fixing argument handling in induction and reduction clauses for parallel::for_loop

  • +
  • PR #3520 - Remove docs symlink and versioned docs folders

  • +
  • PR #3519 - hpxMP release

  • +
  • PR #3518 - Change all steps to use new docker image on CircleCI

  • +
  • PR #3516 - Drop usage of deprecated facilities removed in C++17

  • +
  • PR #3515 - Remove remaining uses of Boost.TypeTraits

  • +
  • PR #3513 - Fixing a CMake problem when trying to use libfabric

  • +
  • PR #3508 - Remove memory_block component

  • +
  • PR #3507 - Propagating the MPI compile definitions to all relevant targets

  • +
  • PR #3503 - Update documentation colors and logo

  • +
  • PR #3502 - Fix bogus `throws` bindings in scheduled_thread_pool_impl

  • +
  • PR #3501 - Split parallel::remove_if tests to avoid OOM on CircleCI

  • +
  • PR #3500 - Support NONAMEPREFIX in add_hpx_library()

  • +
  • PR #3497 - Note that cuda support requires cmake 3.9

  • +
  • PR #3495 - Fixing dataflow

  • +
  • PR #3493 - Remove deprecated options for 1.2.0 part 2

  • +
  • PR #3492 - Add CUDA_LINK_LIBRARIES_KEYWORD to allow PRIVATE keyword in linkage t…

  • +
  • PR #3491 - Changing Base docker image

  • +
  • PR #3490 - Don’t create tasks immediately with hpx::apply

  • +
  • PR #3489 - Remove deprecated options for 1.2.0

  • +
  • PR #3488 - Revert “Use BUILD_INTERFACE generator expression to fix cmake flag exports”

  • +
  • PR #3487 - Revert “Fixing type attribute warning for transfer_action”

  • +
  • PR #3485 - Use BUILD_INTERFACE generator expression to fix cmake flag exports

  • +
  • PR #3483 - Fixing type attribute warning for transfer_action

  • +
  • PR #3481 - Remove unused variables

  • +
  • PR #3480 - Towards a more lightweight transfer action

  • +
  • PR #3479 - Fix FLAGS - Use correct version of target_compile_options

  • +
  • PR #3478 - Making sure the application’s exit code is properly propagated back to the OS

  • +
  • PR #3476 - Don’t print docker credentials as part of the environment.

  • +
  • PR #3473 - Fixing invalid cmake code if no jemalloc prefix was given

  • +
  • PR #3472 - Attempting to work around recent clang test compilation failures

  • +
  • PR #3471 - Enable jemalloc on windows

  • +
  • PR #3470 - Updates readme

  • +
  • PR #3468 - Avoid hang if there is an exception thrown during startup

  • +
  • PR #3467 - Add compiler specific fallthrough attributes if C++17 attribute is not available

  • +
  • PR #3466 - - bugfix : fix compilation with llvm-7.0

  • +
  • PR #3465 - This patch adds various optimizations extracted from the thread_local_allocator work

  • +
  • PR #3464 - Check for forked repos in CircleCI docker push step

  • +
  • PR #3463 - - cmake : create the parent directory before symlinking

  • +
  • PR #3459 - Remove unused/incomplete functionality from util/logging

  • +
  • PR #3458 - Fix a problem with scope of CMAKE_CXX_FLAGS and hpx_add_compile_flag

  • +
  • PR #3457 - Fixing more size_t -> int16_t (and similar) warnings

  • +
  • PR #3456 - Add #ifdefs to topology.cpp to support old hwloc versions again

  • +
  • PR #3454 - Fixing warnings related to silent conversion of size_t –> int16_t

  • +
  • PR #3451 - Add examples as unit tests

  • +
  • PR #3450 - Constexpr-fying bind and other functional facilities

  • +
  • PR #3446 - Fix some thread suspension timeouts

  • +
  • PR #3445 - Fix various warnings

  • +
  • PR #3443 - Only enable service pool config options if pools are enabled

  • +
  • PR #3441 - Fix missing closing brackets in documentation

  • +
  • PR #3439 - Use correct MPI CXX libraries for MPI parcelport

  • +
  • PR #3436 - Add projection function to find_* (and fix very bad bug)

  • +
  • PR #3435 - Fixing 1205

  • +
  • PR #3434 - Fix threads cores

  • +
  • PR #3433 - Add Heise Online to release announcement list

  • +
  • PR #3432 - Don’t track task dependencies for distributed runs

  • +
  • PR #3431 - Circle CI setting changes for hpxMP

  • +
  • PR #3430 - Fix unused params warning

  • +
  • PR #3429 - One thread per core

  • +
  • PR #3428 - This suppresses a deprecation warning that is being issued by MSVC 19.15.26726

  • +
  • PR #3427 - Fixes #3426

  • +
  • PR #3425 - Use source cache and workspace between job steps on CircleCI

  • +
  • PR #3421 - Add CDash timing output to future overhead test (for graphs)

  • +
  • PR #3420 - Add guided_pool_executor

  • +
  • PR #3419 - Fix typo in CircleCI config

  • +
  • PR #3418 - Add sphinx documentation

  • +
  • PR #3415 - Scheduler NUMA hint and shared priority scheduler

  • +
  • PR #3414 - Adding step to synchronize the APEX release

  • +
  • PR #3413 - Fixing multiple defines of APEX_HAVE_HPX

  • +
  • PR #3412 - Fixes linking with libhpx_wrap error with BSD and Windows based systems

  • +
  • PR #3410 - Fix typo in CMakeLists.txt

  • +
  • PR #3409 - Fix brackets and indentation in existing_performance_counters.qbk

  • +
  • PR #3407 - Fix unused param and extra ; warnings emitted by gcc 8.x

  • +
  • PR #3406 - Adding thread local allocator and use it for future shared states

  • +
  • PR #3405 - Adding DHPX_HAVE_THREAD_LOCAL_STORAGE=ON to builds

  • +
  • PR #3404 - fixing multiple definition of main() in linux

  • +
  • PR #3402 - Allow debug option to be enabled only for Linux systems with dynamic main on

  • +
  • PR #3401 - Fix cuda_future_helper.h when compiling with C++11

  • +
  • PR #3400 - Fix floating point exception scheduler_base idle backoff

  • +
  • PR #3398 - Atomic future state

  • +
  • PR #3397 - Fixing code for older gcc versions

  • +
  • PR #3396 - Allowing to register thread event functions (start/stop/error)

  • +
  • PR #3394 - Fix small mistake in primary_namespace_server.cpp

  • +
  • PR #3393 - Explicitly instantiate configured schedulers

  • +
  • PR #3392 - Add performance counters background overhead and background work duration

  • +
  • PR #3391 - Adapt integration of HPXMP to latest build system changes

  • +
  • PR #3390 - Make AGAS measurements optional

  • +
  • PR #3389 - Fix deadlock during shutdown

  • +
  • PR #3388 - Add several functionalities allowing to optimize synchronous action invocation

  • +
  • PR #3387 - Add cmake option to opt out of fail-compile tests

  • +
  • PR #3386 - Adding support for boost::container::small_vector to dataflow

  • +
  • PR #3385 - Adds Debug option for hpx initializing from main

  • +
  • PR #3384 - This hopefully fixes two tests that occasionally fail

  • +
  • PR #3383 - Making sure thread local storage is enable for hpxMP

  • +
  • PR #3382 - Fix usage of HPX_CAPTURE together with default value capture [=]

  • +
  • PR #3381 - Replace undefined instantiations of uniform_int_distribution

  • +
  • PR #3380 - Add missing semicolons to uses of HPX_COMPILER_FENCE

  • +
  • PR #3379 - Fixing #3378

  • +
  • PR #3377 - Adding build system support to integrate hpxmp into hpx at the user’s machine

  • +
  • PR #3375 - Replacing wrapper for __libc_start_main with main

  • +
  • PR #3374 - Adds hpx_wrap to HPX_LINK_LIBRARIES which links only when specified.

  • +
  • PR #3373 - Forcing cache settings in HPXConfig.cmake to guarantee updated values

  • +
  • PR #3372 - Fix some more c++11 build problems

  • +
  • PR #3371 - Adds HPX_LINKER_FLAGS to HPX applications without editing their source codes

  • +
  • PR #3370 - util::format: add type_specifier<> specializations for %!s(MISSING) and %!l(MISSING)s

  • +
  • PR #3369 - Adding configuration option to allow explicit disable of the new hpx_main feature on Linux

  • +
  • PR #3368 - Updates doc with recent hpx_wrap implementation

  • +
  • PR #3367 - Adds Mac OS implementation to hpx_main.hpp

  • +
  • PR #3365 - Fix order of hpx libs in HPX_CONF_LIBRARIES.

  • +
  • PR #3363 - Apex fixing null wrapper

  • +
  • PR #3361 - Making sure all parcels get destroyed on an HPX thread (TCP pp)

  • +
  • PR #3359 - Feature/improveerrorforcompiler

  • +
  • PR #3357 - Static/dynamic executable implementation

  • +
  • PR #3355 - Reverting changes introduced by #3283 as those make applications hang

  • +
  • PR #3354 - Add external dependencies to HPX_LIBRARY_DIR

  • +
  • PR #3353 - Fix libfabric tcp

  • +
  • PR #3351 - Move obsolete header to tests directory.

  • +
  • PR #3350 - Renaming two functions to avoid problem described in #3285

  • +
  • PR #3349 - Make idle backoff exponential with maximum sleep time

  • +
  • PR #3347 - Replace simple_component* with component* in the Documentation

  • +
  • PR #3346 - Fix CMakeLists.txt example in quick start

  • +
  • PR #3345 - Fix automatic setting of HPX_MORE_THAN_64_THREADS

  • +
  • PR #3344 - Reduce amount of information printed for unknown command line options

  • +
  • PR #3343 - Safeguard HPX against destruction in global contexts

  • +
  • PR #3341 - Allowing for all command line options to be used as configuration settings

  • +
  • PR #3340 - Always convert inspect results to JUnit XML

  • +
  • PR #3336 - Only run docker push on master on CircleCI

  • +
  • PR #3335 - Update description of hpx.os_threads config parameter.

  • +
  • PR #3334 - Making sure early logging settings don’t get mixed with others

  • +
  • PR #3333 - Update CMake links and versions in documentation

  • +
  • PR #3332 - Add notes on target suffixes to CMake documentation

  • +
  • PR #3331 - Add quickstart section to documentation

  • +
  • PR #3330 - Rename resource_partitioner test to avoid conflicts with pseudodependencies

  • +
  • PR #3328 - Making sure object is pinned while executing actions, even if action returns a future

  • +
  • PR #3327 - Add missing std::forward to tuple.hpp

  • +
  • PR #3326 - Make sure logging is up and running while modules are being discovered.

  • +
  • PR #3324 - Replace C++14 overload of std::equal with C++11 code.

  • +
  • PR #3323 - Fix a missing apex thread data (wrapper) initialization

  • +
  • PR #3320 - Adding support for -std=c++2a (define HPX_WITH_CXX2A=On)

  • +
  • PR #3319 - Replacing C++14 feature with equivalent C++11 code

  • +
  • PR #3317 - Fix compilation with VS 15.7.1 and /std:c++latest

  • +
  • PR #3316 - Fix includes for 1d_stencil_*_omp examples

  • +
  • PR #3314 - Remove some unused parameter warnings

  • +
  • PR #3313 - Fix pu-step and pu-offset command line options

  • +
  • PR #3312 - Add conversion of inspect reports to JUnit XML

  • +
  • PR #3311 - Fix escaping of closing braces in format specification syntax

  • +
  • PR #3310 - Don’t overwrite user settings with defaults in registration database

  • +
  • PR #3309 - Fixing potential stack overflow for dataflow

  • +
  • PR #3308 - This updates the .clang-format configuration file to utilize newer features

  • +
  • PR #3306 - Marking migratable objects in their gid to allow not handling migration in AGAS

  • +
  • PR #3305 - Add proper exception handling to run_as_hpx_thread

  • +
  • PR #3303 - Changed std::rand to a better inbuilt PRNG Generator

  • +
  • PR #3302 - All non-migratable (simple) components now encode their lva and component type in their gid

  • +
  • PR #3301 - Add nullptr_t overloads to resource partitioner

  • +
  • PR #3298 - Apex task wrapper memory bug

  • +
  • PR #3295 - Fix mistakes after merge of CircleCI config

  • +
  • PR #3294 - Fix partitioned vector include in partitioned_vector_find tests

  • +
  • PR #3293 - Adding emplace support to promise and make_ready_future

  • +
  • PR #3292 - Add new cuda kernel synchronization with hpx::future demo

  • +
  • PR #3291 - Fixes #3290

  • +
  • PR #3289 - Fixing Docker image creation

  • +
  • PR #3288 - Avoid allocating shared state for wait_all

  • +
  • PR #3287 - Fixing /scheduler/utilization/instantaneous performance counter

  • +
  • PR #3286 - dataflow() and future::then() use sync policy where possible

  • +
  • PR #3284 - Background thread can use relaxed atomics to manipulate thread state

  • +
  • PR #3283 - Do not unwrap ready future

  • +
  • PR #3282 - Fix virtual method override warnings in static schedulers

  • +
  • PR #3281 - Disable set_area_membind_nodeset for OSX

  • +
  • PR #3279 - Add two variations to the future_overhead benchmark

  • +
  • PR #3278 - Fix circleci workspace

  • +
  • PR #3277 - Support external plugins

  • +
  • PR #3276 - Fix missing parenthesis in hello_compute.cu.

  • +
  • PR #3274 - Reinit counters synchronously in reinit_counters test

  • +
  • PR #3273 - Splitting tests to avoid compiler OOM

  • +
  • PR #3271 - Remove leftover code from context_generic_context.hpp

  • +
  • PR #3269 - Fix bulk_construct with count = 0

  • +
  • PR #3268 - Replace constexpr with HPX_CXX14_CONSTEXPR and HPX_CONSTEXPR

  • +
  • PR #3266 - Replace boost::format with custom sprintf-based implementation

  • +
  • PR #3265 - Split parallel tests on CircleCI

  • +
  • PR #3262 - Making sure documentation correctly links to source files

  • +
  • PR #3261 - Apex refactoring fix rebind

  • +
  • PR #3260 - Isolate performance counter parser into a separate TU

  • +
  • PR #3256 - Post 1.1.0 version bumps

  • +
  • PR #3254 - Adding trait for actions allowing to make runtime decision on whether to execute it directly

  • +
  • PR #3253 - Bump minimal supported Boost to 1.58.0

  • +
  • PR #3251 - Adds new feature: changing interval used in interval_timer (issue 3244)

  • +
  • PR #3239 - Changing std::rand() to a better inbuilt PRNG generator.

  • +
  • PR #3234 - Disable background thread when networking is off

  • +
  • PR #3232 - Clean up suspension tests

  • +
  • PR #3230 - Add optional scheduler mode parameter to create_thread_pool function

  • +
  • PR #3228 - Allow suspension also on static schedulers

  • +
  • PR #3163 - libfabric parcelport w/o HPX_PARCELPORT_LIBFABRIC_ENDPOINT_RDM

  • +
  • PR #3036 - Switching to CircleCI 2.0

  • +
+
+
+
+
HPX V1.1.0 (Mar 24, 2018)#
+
+
General changes#
+

Here are some of the main highlights and changes for this release (in no +particular order):

+
    +
  • We have changed the way HPX manages the processing units on a node. We do +not longer implicitly bind all available cores to a single thread pool. The +user has now full control over what processing units are bound to what thread +pool, each with a separate scheduler. It is now also possible to create your +own scheduler implementation and control what processing units this scheduler +should use. We added the hpx::resource::partitioner that manages all +available processing units and assigns resources to the used thread pools. +Thread pools can be now be suspended/resumed independently. This functionality +helps in running HPX concurrently to code that is directly relying on +OpenMP and/or MPI.

  • +
  • We have continued to implement various parallel algorithms. HPX now almost +completely implements all of the parallel algorithms as specified by the +C++17 Standard. We have also continued to implement these algorithms for the +distributed use case (for segmented data structures, such as +hpx::partitioned_vector).

  • +
  • Added a compatibility layer for std::thread, std::mutex, and +std::condition_variable allowing for the code to use those facilities +where available and to fall back to the corresponding Boost facilities +otherwise. The CMake configuration option +-DHPX_WITH_THREAD_COMPATIBILITY=On can be used to force using the Boost +equivalents.

  • +
  • The parameter sequence for the hpx::parallel::transform_inclusive_scan +overload taking one iterator range has changed (again) to match the changes +this algorithm has undergone while being moved to C++17. The old overloads can +be still enabled at configure time by passing +-DHPX_WITH_TRANSFORM_REDUCE_COMPATIBILITY=On to CMake.

  • +
  • The parameter sequence for the hpx::parallel::inclusive_scan overload +taking one iterator range has changed to match the changes this algorithm has +undergone while being moved to C++17. The old overloads can be still enabled +at configure time by passing -DHPX_WITH_INCLUSIVE_SCAN_COMPATIBILITY=On to +CMake.

  • +
  • Added a helper facility hpx::local_new which is equivalent to +hpx::new_ except that it creates components locally only. As a +consequence, the used component constructor may accept non-serializable +argument types and/or non-const references or pointers.

  • +
  • Removed the (broken) component type hpx::lcos::queue<T>. The old type is +still available at configure time by passing +-DHPX_WITH_QUEUE_COMPATIBILITY=On to CMake.

  • +
  • The parallel algorithms adopted for C++17 restrict the iterator categories +usable with those to at least forward iterators. Our implementation of the +parallel algorithms was supporting input iterators (and output iterators) as +well by simply falling back to sequential execution. We have now made our +implementations conforming by requiring at least forward iterators. In order +to enable the old behavior use the compatibility option +-DHPX_WITH_ALGORITHM_INPUT_ITERATOR_SUPPORT=On on the CMake command +line.

  • +
  • We have added the functionalities allowing for LCOs being implemented using +(simple) components. Before LCOs had to always be implemented using managed +components.

  • +
  • User defined components don’t have to be default-constructible anymore. Return +types from actions don’t have to be default-constructible anymore either. Our +serialization layer now in general supports non-default-constructible types.

  • +
  • We have added a new launch policy hpx::launch::lazy that allows oneto +defer the decision on what launch policy to use to the point of execution. +This policy is initialized with a function (object) that – when invoked – is +expected to produce the desired launch policy.

  • +
+
+
+
Breaking changes#
+
    +
  • We have dropped support for the gcc compiler version V4.8. The minimal gcc +version we now test on is gcc V4.9. The minimally required version of CMake +is now V3.3.2.

  • +
  • We have dropped support for the Visual Studio 2013 compiler version. The +minimal Visual Studio version we now test on is Visual Studio 2015.5.

  • +
  • We have dropped support for the Boost V1.51-V1.54. The minimal version of +Boost we now test is Boost V1.55.

  • +
  • We have dropped support for the hpx::util::unwrapped API. +hpx::util::unwrapped will stay functional to some degree, until it finally +gets removed in a later version of HPX. The functional usage of +hpx::util::unwrapped should be changed to the new +hpx::util::unwrapping function whereas the immediate usage should be +replaced to hpx::util::unwrap.

  • +
  • The performance counter names referring to properties as exposed by the +threading subsystem have changes as those now additionally have to specify the +thread-pool. See the corresponding documentation for more details.

  • +
  • The overloads of hpx::async that invoke an action do not perform implicit +unwrapping of the returned future anymore in case the invoked function does +return a future in the first place. In this case hpx::async now returns a +hpx::future<future<T>> making its behavior conforming to its local +counterpart.

  • +
  • We have replaced the use of boost::exception_ptr in our APIs with the +equivalent std::exception_ptr. Please change your codes accordingly. No +compatibility settings are provided.

  • +
  • We have removed the compatibility settings for +HPX_WITH_COLOCATED_BACKWARDS_COMPATIBILITY and +HPX_WITH_COMPONENT_GET_GID_COMPATIBILITY as their life-cycle has reached +its end.

  • +
  • We have removed the experimental thread schedulers hierarchy_scheduler, +periodic_priority_scheduler and throttling_scheduler in an effort to clean up +and consolidate our thread schedulers.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release.

+
    +
  • PR #3250 - Apex refactoring with guids

  • +
  • PR #3249 - Updating People.qbk

  • +
  • PR #3246 - Assorted fixes for CUDA

  • +
  • PR #3245 - Apex refactoring with guids

  • +
  • PR #3242 - Modify task counting in thread_queue.hpp

  • +
  • PR #3240 - Fixed typos

  • +
  • PR #3238 - Readding accidentally removed std::abort

  • +
  • PR #3237 - Adding Pipeline example

  • +
  • PR #3236 - Fixing memory_block

  • +
  • PR #3233 - Make schedule_thread take suspended threads into account

  • +
  • Issue #3226 - memory_block is breaking, signaling SIGSEGV on a thread on +creation and freeing

  • +
  • PR #3225 - Applying quick fix for hwloc-2.0

  • +
  • Issue #3224 - HPX counters crashing the application

  • +
  • PR #3223 - Fix returns when setting config entries

  • +
  • Issue #3222 - Errors linking libhpx.so

  • +
  • Issue #3221 - HPX on Mac OS X with HWLoc 2.0.0 fails to run

  • +
  • PR #3216 - Reorder a variadic array to satisfy VS 2017 15.6

  • +
  • PR #3214 - Changed prerequisites.qbk to avoid confusion while building +boost

  • +
  • PR #3213 - Relax locks for thread suspension to avoid holding locks when +yielding

  • +
  • PR #3212 - Fix check in sequenced_executor test

  • +
  • PR #3211 - Use preinit_array to set argc/argv in init_globally example

  • +
  • PR #3210 - Adapted parallel::{search | search_n} for Ranges TS (see +#1668)

  • +
  • PR #3209 - Fix locking problems during shutdown

  • +
  • Issue #3208 - init_globally throwing a run-time error

  • +
  • PR #3206 - Addition of new arithmetic performance counter “Count”

  • +
  • PR #3205 - Fixing return type calculation for bulk_then_execute

  • +
  • PR #3204 - Changing std::rand() to a better inbuilt PRNG generator

  • +
  • PR #3203 - Resolving problems during shutdown for VS2015

  • +
  • PR #3202 - Making sure resource partitioner is not accessed if its not +valid

  • +
  • PR #3201 - Fixing optional::swap

  • +
  • Issue #3200 - hpx::util::optional fails

  • +
  • PR #3199 - Fix sliding_semaphore test

  • +
  • PR #3198 - Set pre_main status before launching run_helper

  • +
  • PR #3197 - Update README.rst

  • +
  • PR #3194 - parallel::{fill|fill_n} updated for Ranges TS

  • +
  • PR #3193 - Updating Runtime.cpp by adding correct description of +Performance counters during register

  • +
  • PR #3191 - Fix sliding_semaphore_2338 test

  • +
  • PR #3190 - Topology improvements

  • +
  • PR #3189 - Deleting one include of median from BOOST library to +arithmetics_counter file

  • +
  • PR #3188 - Optionally disable printing of diagnostics during terminate

  • +
  • PR #3187 - Suppressing cmake warning issued by cmake > V3.11

  • +
  • PR #3185 - Remove unused scoped_unlock, unlock_guard_try

  • +
  • PR #3184 - Fix nqueen example

  • +
  • PR #3183 - Add runtime start/stop, resume/suspend and OpenMP benchmarks

  • +
  • Issue #3182 - bulk_then_execute has unexpected return type/does not +compile

  • +
  • Issue #3181 - hwloc 2.0 breaks topo class and cannot be used

  • +
  • Issue #3180 - Schedulers that don’t support suspend/resume are unusable

  • +
  • PR #3179 - Various minor changes to support FLeCSI

  • +
  • PR #3178 - Fix #3124

  • +
  • PR #3177 - Removed allgather

  • +
  • PR #3176 - Fixed Documentation for “using_hpx_pkgconfig”

  • +
  • PR #3174 - Add hpx::iostreams::ostream overload to format_to

  • +
  • PR #3172 - Fix lifo queue backend

  • +
  • PR #3171 - adding the missing unset() function to cpu_mask() for case of +more than 64 threads

  • +
  • PR #3170 - Add cmake flag -DHPX_WITH_FAULT_TOLERANCE=ON (OFF by default)

  • +
  • PR #3169 - Adapted parallel::{count|count_if} for Ranges TS (see #1668)

  • +
  • PR #3168 - Changing used namespace for seq execution policy

  • +
  • Issue #3167 - Update GSoC projects

  • +
  • Issue #3166 - Application (Octotiger) gets stuck on hpx::finalize when +only using one thread

  • +
  • Issue #3165 - Compilation of parallel algorithms with HPX_WITH_DATAPAR +is broken

  • +
  • PR #3164 - Fixing component migration

  • +
  • PR #3162 - regex_from_pattern: escape regex special characters to avoid +misinterpretation

  • +
  • Issue #3161 - Building HPX with hwloc 2.0.0 fails

  • +
  • PR #3160 - Fixing the handling of quoted command line arguments.

  • +
  • PR #3158 - Fixing a race with timed suspension (second attempt)

  • +
  • PR #3157 - Revert “Fixing a race with timed suspension”

  • +
  • PR #3156 - Fixing serialization of classes with incompatible serialize +signature

  • +
  • PR #3154 - More refactorings based on clang-tidy reports

  • +
  • PR #3153 - Fixing a race with timed suspension

  • +
  • PR #3152 - Documentation for runtime suspension

  • +
  • PR #3151 - Use small_vector only from boost version 1.59 onwards

  • +
  • PR #3150 - Avoiding more stack overflows

  • +
  • PR #3148 - Refactoring component_base and +base_action/transfer_base_action

  • +
  • PR #3147 - Move yield_while out of detail namespace and into own file

  • +
  • PR #3145 - Remove a leftover of the cxx11 std array cleanup

  • +
  • PR #3144 - Minor changes to how actions are executed

  • +
  • PR #3143 - Fix stack overhead

  • +
  • PR #3142 - Fix typo in config.hpp

  • +
  • PR #3141 - Fixing small_vector compatibility with older boost version

  • +
  • PR #3140 - is_heap_text fix

  • +
  • Issue #3139 - Error in is_heap_tests.hpp

  • +
  • PR #3138 - Partially reverting #3126

  • +
  • PR #3137 - Suspend speedup

  • +
  • PR #3136 - Revert “Fixing #2325”

  • +
  • PR #3135 - Improving destruction of threads

  • +
  • Issue #3134 - HPX_SERIALIZATION_SPLIT_FREE does not stop compiler from +looking for serialize() method

  • +
  • PR #3133 - Make hwloc compulsory

  • +
  • PR #3132 - Update CXX14 constexpr feature test

  • +
  • PR #3131 - Fixing #2325

  • +
  • PR #3130 - Avoid completion handler allocation

  • +
  • PR #3129 - Suspend runtime

  • +
  • PR #3128 - Make docbook dtd and xsl path names consistent

  • +
  • PR #3127 - Add hpx::start nullptr overloads

  • +
  • PR #3126 - Cleaning up coroutine implementation

  • +
  • PR #3125 - Replacing nullptr with hpx::threads::invalid_thread_id

  • +
  • Issue #3124 - Add hello_world_component to CI builds

  • +
  • PR #3123 - Add new constructor.

  • +
  • PR #3122 - Fixing #3121

  • +
  • Issue #3121 - HPX_SMT_PAUSE is broken on non-x86 platforms when __GNUC__ +is defined

  • +
  • PR #3120 - Don’t use boost::intrusive_ptr for thread_id_type

  • +
  • PR #3119 - Disable default executor compatibility with V1 executors

  • +
  • PR #3118 - Adding performance_counter::reinit to allow for dynamically +changing counter sets

  • +
  • PR #3117 - Replace uses of boost/experimental::optional with +util::optional

  • +
  • PR #3116 - Moving background thread APEX timer #2980

  • +
  • PR #3115 - Fixing race condition in channel test

  • +
  • PR #3114 - Avoid using util::function for thread function wrappers

  • +
  • PR #3113 - cmake V3.10.2 has changed the variable names used for MPI

  • +
  • PR #3112 - Minor fixes to exclusive_scan algorithm

  • +
  • PR #3111 - Revert “fix detection of cxx11_std_atomic”

  • +
  • PR #3110 - Suspend thread pool

  • +
  • PR #3109 - Fixing thread scheduling when yielding a thread id

  • +
  • PR #3108 - Revert “Suspend thread pool”

  • +
  • PR #3107 - Remove UB from thread::id relational operators

  • +
  • PR #3106 - Add cmake test for std::decay_t to fix cuda build

  • +
  • PR #3105 - Fixing refcount for async traversal frame

  • +
  • PR #3104 - Local execution of direct actions is now actually performed +directly

  • +
  • PR #3103 - Adding support for generic counter_raw_values performance +counter type

  • +
  • Issue #3102 - Introduce generic performance counter type returning an +array of values

  • +
  • PR #3101 - Revert “Adapting stack overhead limit for gcc 4.9”

  • +
  • PR #3100 - Fix #3068 (condition_variable deadlock)

  • +
  • PR #3099 - Fixing lock held during suspension in papi counter component

  • +
  • PR #3098 - Unbreak broadcast_wait_for_2822 test

  • +
  • PR #3097 - Adapting stack overhead limit for gcc 4.9

  • +
  • PR #3096 - fix detection of cxx11_std_atomic

  • +
  • PR #3095 - Add ciso646 header to get _LIBCPP_VERSION for testing inplace +merge

  • +
  • PR #3094 - Relax atomic operations on performance counter values

  • +
  • PR #3093 - Short-circuit all_of/any_of/none_of instantiations

  • +
  • PR #3092 - Take advantage of C++14 lambda capture initialization syntax, +where possible

  • +
  • PR #3091 - Remove more references to Boost from logging code

  • +
  • PR #3090 - Unify use of yield/yield_k

  • +
  • PR #3089 - Fix a strange thing in parallel::detail::handle_exception. +(Fix #2834.)

  • +
  • Issue #3088 - A strange thing in parallel::sort.

  • +
  • PR #3087 - Fixing assertion in default_distribution_policy

  • +
  • PR #3086 - Implement parallel::remove and parallel::remove_if

  • +
  • PR #3085 - Addressing breaking changes in Boost V1.66

  • +
  • PR #3084 - Ignore build warnings round 2

  • +
  • PR #3083 - Fix typo HPX_WITH_MM_PREFECTH

  • +
  • PR #3081 - Pre-decay template arguments early

  • +
  • PR #3080 - Suspend thread pool

  • +
  • PR #3079 - Ignore build warnings

  • +
  • PR #3078 - Don’t test inplace_merge with libc++

  • +
  • PR #3076 - Fixing 3075: Part 1

  • +
  • PR #3074 - Fix more build warnings

  • +
  • PR #3073 - Suspend thread cleanup

  • +
  • PR #3072 - Change existing symbol_namespace::iterate to return all data +instead of invoking a callback

  • +
  • PR #3071 - Fixing pack_traversal_async test

  • +
  • PR #3070 - Fix dynamic_counters_loaded_1508 test by adding dependency to +memory_component

  • +
  • PR #3069 - Fix scheduling loop exit

  • +
  • Issue #3068 - hpx::lcos::condition_variable could be suspect to +deadlocks

  • +
  • PR #3067 - #ifdef out random_shuffle deprecated in later c++

  • +
  • PR #3066 - Make coalescing test depend on coalescing library to ensure +it gets built

  • +
  • PR #3065 - Workaround for minimal_timed_async_executor_test compilation +failures, attempts to copy a deferred call (in unevaluated context)

  • +
  • PR #3064 - Fixing wrong condition in wrapper_heap

  • +
  • PR #3062 - Fix exception handling for execution::seq

  • +
  • PR #3061 - Adapt MSVC C++ mode handling to VS15.5

  • +
  • PR #3060 - Fix compiler problem in MSVC release mode

  • +
  • PR #3059 - Fixing #2931

  • +
  • Issue #3058 - minimal_timed_async_executor_test_exe fails to compile on +master (d6f505c)

  • +
  • PR #3057 - Fix stable_merge_2964 compilation problems

  • +
  • PR #3056 - Fix some build warnings caused by unused +variables/unnecessary tests

  • +
  • PR #3055 - Update documentation for running tests

  • +
  • Issue #3054 - Assertion failure when using bulk hpx::new_ in +asynchronous mode

  • +
  • PR #3052 - Do not bind test running to cmake test build rule

  • +
  • PR #3051 - Fix HPX-Qt interaction in Qt example.

  • +
  • Issue #3048 - nqueen example fails occasionally

  • +
  • PR #3047 - Fixing #3044

  • +
  • PR #3046 - Add OS thread suspension

  • +
  • PR #3042 - PyCicle - first attempt at a build toold for checking PR’s

  • +
  • PR #3041 - Fix a problem about asynchronous execution of parallel::merge +and parallel::partition.

  • +
  • PR #3040 - Fix a mistake about exception handling in asynchronous +execution of scan_partitioner.

  • +
  • PR #3039 - Consistently use executors to schedule work

  • +
  • PR #3038 - Fixing local direct function execution and lambda actions +perfect forwarding

  • +
  • PR #3035 - Make parallel unit test names match build target/folder names

  • +
  • PR #3033 - Fix setting of default build type

  • +
  • Issue #3032 - Fix partitioner arg copy found in #2982

  • +
  • Issue #3031 - Errors linking libhpx.so due to missing references (master +branch, commit 6679a8882)

  • +
  • PR #3030 - Revert “implement executor then interface with && forwarding +reference”

  • +
  • PR #3029 - Run CI inspect checks before building

  • +
  • PR #3028 - Added range version of parallel::move

  • +
  • Issue #3027 - Implement all scheduling APIs in terms of executors

  • +
  • PR #3026 - implement executor then interface with && forwarding +reference

  • +
  • PR #3025 - Fix typo unitialized to uninitialized

  • +
  • PR #3024 - Inspect fixes

  • +
  • PR #3023 - P0356 Simplified partial function application

  • +
  • PR #3022 - Master fixes

  • +
  • PR #3021 - Segfault fix

  • +
  • PR #3020 - Disable command-line aliasing for applications that use +user_main

  • +
  • PR #3019 - Adding enable_elasticity option to pool configuration

  • +
  • PR #3018 - Fix stack overflow detection configuration in header files

  • +
  • PR #3017 - Speed up local action execution

  • +
  • PR #3016 - Unify stack-overflow detection options, remove reference to +libsigsegv

  • +
  • PR #3015 - Speeding up accessing the resource partitioner and the +topology info

  • +
  • Issue #3014 - HPX does not compile on POWER8 with gcc 5.4

  • +
  • Issue #3013 - hello_world occasionally prints multiple lines from a +single OS-thread

  • +
  • PR #3012 - Silence warning about casting away qualifiers in +itt_notify.hpp

  • +
  • PR #3011 - Fix cpuset leak in hwloc_topology_info.cpp

  • +
  • PR #3010 - Remove useless decay_copy

  • +
  • PR #3009 - Fixing 2996

  • +
  • PR #3008 - Remove unused internal function

  • +
  • PR #3007 - Fixing wrapper_heap alignment problems

  • +
  • Issue #3006 - hwloc memory leak

  • +
  • PR #3004 - Silence C4251 (needs to have dll-interface) for +future_data_void

  • +
  • Issue #3003 - Suspension of runtime

  • +
  • PR #3001 - Attempting to avoid data races in async_traversal while +evaluating dataflow()

  • +
  • PR #3000 - Adding hpx::util::optional as a first step to replace +experimental::optional

  • +
  • PR #2998 - Cleanup up and Fixing component creation and deletion

  • +
  • Issue #2996 - Build fails with HPX_WITH_HWLOC=OFF

  • +
  • PR #2995 - Push more future_data functionality to source file

  • +
  • PR #2994 - WIP: Fix throttle test

  • +
  • PR #2993 - Making sure –hpx:help does not throw for required (but +missing) arguments

  • +
  • PR #2992 - Adding non-blocking (on destruction) service executors

  • +
  • Issue #2991 - run_as_os_thread locks up

  • +
  • Issue #2990 - –help will not work until all required options are +provided

  • +
  • PR #2989 - Improve error messages caused by misuse of dataflow

  • +
  • PR #2988 - Improve error messages caused by misuse of .then

  • +
  • Issue #2987 - stack overflow detection producing false positives

  • +
  • PR #2986 - Deduplicate non-dependent thread_info logging types

  • +
  • PR #2985 - Adapted parallel::{all_of|any_of|none_of} for Ranges TS (see +#1668)

  • +
  • PR #2984 - Refactor one_size_heap code to simplify code

  • +
  • PR #2983 - Fixing local_new_component

  • +
  • PR #2982 - Clang tidy

  • +
  • PR #2981 - Simplify allocator rebinding in pack traversal

  • +
  • PR #2979 - Fixing integer overflows

  • +
  • PR #2978 - Implement parallel::inplace_merge

  • +
  • Issue #2977 - Make hwloc compulsory instead of optional

  • +
  • PR #2976 - Making sure client_base instance that registered the +component does not unregister it when being destructed

  • +
  • PR #2975 - Change version of pulled APEX to master

  • +
  • PR #2974 - Fix domain not being freed at the end of scheduling loop

  • +
  • PR #2973 - Fix small typos

  • +
  • PR #2972 - Adding uintstd.h header

  • +
  • PR #2971 - Fall back to creating local components using local_new

  • +
  • PR #2970 - Improve is_tuple_like trait

  • +
  • PR #2969 - Fix HPX_WITH_MORE_THAN_64_THREADS default value

  • +
  • PR #2968 - Cleaning up dataflow overload set

  • +
  • PR #2967 - Make parallel::merge is stable. (Fix #2964.)

  • +
  • PR #2966 - Fixing a couple of held locks during exception handling

  • +
  • PR #2965 - Adding missing #include

  • +
  • Issue #2964 - parallel merge is not stable

  • +
  • PR #2963 - Making sure any function object passed to dataflow is +released after being invoked

  • +
  • PR #2962 - Partially reverting #2891

  • +
  • PR #2961 - Attempt to fix the gcc 4.9 problem with the async pack +traversal

  • +
  • Issue #2959 - Program terminates during error handling

  • +
  • Issue #2958 - HPX_PLAIN_ACTION breaks due to missing include

  • +
  • PR #2957 - Fixing errors generated by mixing different attribute +syntaxes

  • +
  • Issue #2956 - Mixing attribute syntaxes leads to compiler errors

  • +
  • Issue #2955 - Fix OS-Thread throttling

  • +
  • PR #2953 - Making sure any hpx.os_threads=N supplied through a +–hpx::config file is taken into account

  • +
  • PR #2952 - Removing wrong call to cleanup_terminated_locked

  • +
  • PR #2951 - Revert “Make sure the function vtables are initialized before +use”

  • +
  • PR #2950 - Fix a namespace compilation error when some schedulers are +disabled

  • +
  • Issue #2949 - master branch giving lockups on shutdown

  • +
  • Issue #2947 - hpx.ini is not used correctly at initialization

  • +
  • PR #2946 - Adding explicit feature test for thread_local

  • +
  • PR #2945 - Make sure the function vtables are initialized before use

  • +
  • PR #2944 - Attempting to solve affinity problems on CircleCI

  • +
  • PR #2943 - Changing channel actions to be direct

  • +
  • PR #2942 - Adding split_future for std::vector

  • +
  • PR #2941 - Add a feature test to test for CXX11 override

  • +
  • Issue #2940 - Add split_future for future<vector<T>>

  • +
  • PR #2939 - Making error reporting during problems with setting affinity +masks more verbose

  • +
  • PR #2938 - Fix this various executors

  • +
  • PR #2937 - Fix some typos in documentation

  • +
  • PR #2934 - Remove the need for “complete” SFINAE checks

  • +
  • PR #2933 - Making sure parallel::for_loop is executed in parallel if +requested

  • +
  • PR #2932 - Classify chunk_size_iterator to input iterator tag. (Fix +#2866)

  • +
  • Issue #2931 - –hpx:help triggers unusual error with clang build

  • +
  • PR #2930 - Add #include files needed to set _POSIX_VERSION for debug +check

  • +
  • PR #2929 - Fix a couple of deprecated c++ features

  • +
  • PR #2928 - Fixing execution parameters

  • +
  • Issue #2927 - CMake warning: … cycle in constraint graph

  • +
  • PR #2926 - Default pool rename

  • +
  • Issue #2925 - Default pool cannot be renamed

  • +
  • Issue #2924 - hpx:attach-debugger=startup does not work any more

  • +
  • PR #2923 - Alloc membind

  • +
  • PR #2922 - This fixes CircleCI errors when running with –hpx:bind=none

  • +
  • PR #2921 - Custom pool executor was missing priority and stacksize +options

  • +
  • PR #2920 - Adding test to trigger problem reported in #2916

  • +
  • PR #2919 - Make sure the resource_partitioner is properly destructed on +hpx::finalize

  • +
  • Issue #2918 - hpx::init calls wrong (first) callback when called +multiple times

  • +
  • PR #2917 - Adding util::checkpoint

  • +
  • Issue #2916 - Weird runtime failures when using a channel and chained +continuations

  • +
  • PR #2915 - Introduce executor parameters customization points

  • +
  • Issue #2914 - Task assignment to current Pool has unintended +consequences

  • +
  • PR #2913 - Fix rp hang

  • +
  • PR #2912 - Update contributors

  • +
  • PR #2911 - Fixing CUDA problems

  • +
  • PR #2910 - Improve error reporting for process component on POSIX +systems

  • +
  • PR #2909 - Fix typo in include path

  • +
  • PR #2908 - Use proper container according to iterator tag in benchmarks +of parallel algorithms

  • +
  • PR #2907 - Optionally force-delete remaining channel items on close

  • +
  • PR #2906 - Making sure generated performance counter names are correct

  • +
  • Issue #2905 - collecting idle-rate performance counters on multiple +localities produces an error

  • +
  • Issue #2904 - build broken for Intel 17 compilers

  • +
  • PR #2903 - Documentation Updates– Adding New People

  • +
  • PR #2902 - Fixing service_executor

  • +
  • PR #2901 - Fixing partitioned_vector creation

  • +
  • PR #2900 - Add numa-balanced mode to hpx::bind, spread cores over numa +domains

  • +
  • Issue #2899 - hpx::bind does not have a mode that balances cores over +numa domains

  • +
  • PR #2898 - Adding missing #include and missing guard for optional code +section

  • +
  • PR #2897 - Removing dependency on Boost.ICL

  • +
  • Issue #2896 - Debug build fails without -fpermissive with GCC 7.1 and +Boost 1.65

  • +
  • PR #2895 - Fixing SLURM environment parsing

  • +
  • PR #2894 - Fix incorrect handling of compile definition with value 0

  • +
  • Issue #2893 - Disabling schedulers causes build errors

  • +
  • PR #2892 - added list serializer

  • +
  • PR #2891 - Resource Partitioner Fixes

  • +
  • Issue #2890 - Destroying a non-empty channel causes an assertion failure

  • +
  • PR #2889 - Add check for libatomic

  • +
  • PR #2888 - Fix compilation problems if HPX_WITH_ITT_NOTIFY=ON

  • +
  • PR #2887 - Adapt broadcast() to non-unwrapping async<Action>

  • +
  • PR #2886 - Replace Boost.Random with C++11 <random>

  • +
  • Issue #2885 - regression in broadcast?

  • +
  • Issue #2884 - linking -latomic is not portable

  • +
  • PR #2883 - Explicitly set -pthread flag if available

  • +
  • PR #2882 - Wrap boost::format uses

  • +
  • Issue #2881 - hpx not compiling with HPX_WITH_ITTNOTIFY=On

  • +
  • Issue #2880 - hpx::bind scatter/balanced give wrong pu masks

  • +
  • PR #2878 - Fix incorrect pool usage masks setup in RP/thread manager

  • +
  • PR #2877 - Require std::array by default

  • +
  • PR #2875 - Deprecate use of BOOST_ASSERT

  • +
  • PR #2874 - Changed serialization of boost.variant to use variadic +templates

  • +
  • Issue #2873 - building with parcelport_mpi fails on cori

  • +
  • PR #2871 - Adding missing support for throttling scheduler

  • +
  • PR #2870 - Disambiguate use of base_lco_with_value macros with channel

  • +
  • Issue #2869 - Difficulty compiling +HPX_REGISTER_CHANNEL_DECLARATION(double)

  • +
  • PR #2868 - Removing unneeded assert

  • +
  • PR #2867 - Implement parallel::unique

  • +
  • Issue #2866 - The chunk_size_iterator violates multipass guarantee

  • +
  • PR #2865 - Only use sched_getcpu on linux machines

  • +
  • PR #2864 - Create redistribution archive for successful builds

  • +
  • PR #2863 - Replace casts/assignments with hard-coded memcpy operations

  • +
  • Issue #2862 - sched_getcpu not available on MacOS

  • +
  • PR #2861 - Fixing unmatched header defines and recursive inclusion of +threadmanager

  • +
  • Issue #2860 - Master program fails with assertion ‘type == +data_type_address’ failed: HPX(assertion_failure)

  • +
  • Issue #2852 - Support for ARM64

  • +
  • PR #2858 - Fix misplaced #if #endif’s that cause build failure without +THREAD_CUMULATIVE_COUNTS

  • +
  • PR #2857 - Fix some listing in documentation

  • +
  • PR #2856 - Fixing component handling for lcos

  • +
  • PR #2855 - Add documentation for coarrays

  • +
  • PR #2854 - Support ARM64 in timestamps

  • +
  • PR #2853 - Update Table 17. Non-modifying Parallel Algorithms in +Documentation

  • +
  • PR #2851 - Allowing for non-default-constructible component types

  • +
  • PR #2850 - Enable returning future<R> from actions where R is not +default-constructible

  • +
  • PR #2849 - Unify serialization of non-default-constructable types

  • +
  • Issue #2848 - Components have to be default constructible

  • +
  • Issue #2847 - Returning a future<R> where R is not default-constructable +broken

  • +
  • Issue #2846 - Unify serialization of non-default-constructible types

  • +
  • PR #2845 - Add Visual Studio 2015 to the tested toolchains in Appveyor

  • +
  • Issue #2844 - Change the appveyor build to use the minimal required MSVC +version

  • +
  • Issue #2843 - multi node hello_world hangs

  • +
  • PR #2842 - Correcting Spelling mistake in docs

  • +
  • PR #2841 - Fix usage of std::aligned_storage

  • +
  • PR #2840 - Remove constexpr from a void function

  • +
  • Issue #2839 - memcpy buffer overflow: load_construct_data() and +std::complex members

  • +
  • Issue #2835 - constexpr functions with void return type break +compilation with CUDA 8.0

  • +
  • Issue #2834 - One suspicion in parallel::detail::handle_exception

  • +
  • PR #2833 - Implement parallel::merge

  • +
  • PR #2832 - Fix a strange thing in +parallel::util::detail::handle_local_exceptions. (Fix #2818)

  • +
  • PR #2830 - Break the debugger when a test failed

  • +
  • Issue #2831 - parallel/executors/execution_fwd.hpp causes +compilation failure in C++11 mode.

  • +
  • PR #2829 - Implement an API for asynchronous pack traversal

  • +
  • PR #2828 - Split unit test builds on CircleCI to avoid timeouts

  • +
  • Issue #2827 - failure to compile hello_world example with -Werror

  • +
  • PR #2824 - Making sure promises are marked as started when used as +continuations

  • +
  • PR #2823 - Add documentation for partitioned_vector_view

  • +
  • Issue #2822 - Yet another issue with wait_for similar to #2796

  • +
  • PR #2821 - Fix bugs and improve that about +HPX_HAVE_CXX11_AUTO_RETURN_VALUE of CMake

  • +
  • PR #2820 - Support C++11 in benchmark codes of parallel::partition and +parallel::partition_copy

  • +
  • PR #2819 - Fix compile errors in unit test of container version of +parallel::partition

  • +
  • Issue #2818 - A strange thing in +parallel::util::detail::handle_local_exceptions

  • +
  • Issue #2815 - HPX fails to compile with HPX_WITH_CUDA=ON and the new +CUDA 9.0 RC

  • +
  • Issue #2814 - Using ‘gmakeN’ after ‘cmake’ produces error in +src/CMakeFiles/hpx.dir/runtime/agas/addressing_service.cpp.o

  • +
  • PR #2813 - Properly support [[noreturn]] attribute if available

  • +
  • Issue #2812 - Compilation fails with gcc 7.1.1

  • +
  • PR #2811 - Adding hpx::launch::lazy and support for async, dataflow, and +future::then

  • +
  • PR #2810 - Add option allowing to disable deprecation warning

  • +
  • PR #2809 - Disable throttling scheduler if HWLOC is not found/used

  • +
  • PR #2808 - Fix compile errors on some environments of +parallel::partition

  • +
  • Issue #2807 - Difficulty building with HPX_WITH_HWLOC=Off

  • +
  • PR #2806 - Partitioned vector

  • +
  • PR #2805 - Serializing collections with non-default constructible data

  • +
  • PR #2802 - Fix FreeBSD 11

  • +
  • Issue #2801 - Rate limiting techniques in io_service

  • +
  • Issue #2800 - New Launch Policy: async_if

  • +
  • PR #2799 - Fix a unit test failure on GCC in tuple_cat

  • +
  • PR #2798 - bump minimum required cmake to 3.0 in test

  • +
  • PR #2797 - Making sure future::wait_for et.al. work properly for action +results

  • +
  • Issue #2796 - wait_for does always in “deferred” state for calls on +remote localities

  • +
  • Issue #2795 - Serialization of types without default constructor

  • +
  • PR #2794 - Fixing test for partitioned_vector iteration

  • +
  • PR #2792 - Implemented segmented find and its variations for partitioned +vector

  • +
  • PR #2791 - Circumvent scary warning about placement new

  • +
  • PR #2790 - Fix OSX build

  • +
  • PR #2789 - Resource partitioner

  • +
  • PR #2788 - Adapt parallel::is_heap and parallel::is_heap_until to Ranges +TS

  • +
  • PR #2787 - Unwrap hotfixes

  • +
  • PR #2786 - Update CMake Minimum Version to 3.3.2 (refs #2565)

  • +
  • Issue #2785 - Issues with masks and cpuset

  • +
  • PR #2784 - Error with reduce and transform reduce fixed

  • +
  • PR #2783 - StackOverflow integration with libsigsegv

  • +
  • PR #2782 - Replace boost::atomic with std::atomic (where possible)

  • +
  • PR #2781 - Check for and optionally use [[deprecated]] attribute

  • +
  • PR #2780 - Adding empty (but non-trivial) destructor to circumvent +warnings

  • +
  • PR #2779 - Exception info tweaks

  • +
  • PR #2778 - Implement parallel::partition

  • +
  • PR #2777 - Improve error handling in gather_here/gather_there

  • +
  • PR #2776 - Fix a bug in compiler version check

  • +
  • PR #2775 - Fix compilation when HPX_WITH_LOGGING is OFF

  • +
  • PR #2774 - Removing dependency on Boost.Date_Time

  • +
  • PR #2773 - Add sync_images() method to spmd_block class

  • +
  • PR #2772 - Adding documentation for PAPI counters

  • +
  • PR #2771 - Removing boost preprocessor dependency

  • +
  • PR #2770 - Adding test, fixing deadlock in config registry

  • +
  • PR #2769 - Remove some other warnings and errors detected by clang 5.0

  • +
  • Issue #2768 - Is there iterator tag for HPX?

  • +
  • PR #2767 - Improvements to continuation annotation

  • +
  • PR #2765 - gcc split stack support for HPX threads #620

  • +
  • PR #2764 - Fix some uses of begin/end, remove unnecessary includes

  • +
  • PR #2763 - Bump minimal Boost version to 1.55.0

  • +
  • PR #2762 - hpx::partitioned_vector serializer

  • +
  • PR #2761 - Adding configuration summary to cmake output and –hpx:info

  • +
  • PR #2760 - Removing 1d_hydro example as it is broken

  • +
  • PR #2758 - Remove various warnings detected by clang 5.0

  • +
  • Issue #2757 - In case of a “raw thread” is needed per core for +implementing parallel algorithm, what is good practice in HPX?

  • +
  • PR #2756 - Allowing for LCOs to be simple components

  • +
  • PR #2755 - Removing make_index_pack_unrolled

  • +
  • PR #2754 - Implement parallel::unique_copy

  • +
  • PR #2753 - Fixing detection of [[fallthrough]] attribute

  • +
  • PR #2752 - New thread priority names

  • +
  • PR #2751 - Replace boost::exception with proposed exception_info

  • +
  • PR #2750 - Replace boost::iterator_range

  • +
  • PR #2749 - Fixing hdf5 examples

  • +
  • Issue #2748 - HPX fails to build with enabled hdf5 examples

  • +
  • Issue #2747 - Inherited task priorities break certain DAG optimizations

  • +
  • Issue #2746 - HPX segfaulting with valgrind

  • +
  • PR #2745 - Adding extended arithmetic performance counters

  • +
  • PR #2744 - Adding ability to statistics counters to reset base counter

  • +
  • Issue #2743 - Statistics counter does not support resetting

  • +
  • PR #2742 - Making sure Vc V2 builds without additional HPX configuration +flags

  • +
  • PR #2741 - Deprecate unwrapped and implement unwrap and unwrapping

  • +
  • PR #2740 - Coroutine stackoverflow detection for linux/posix; Issue +#2408

  • +
  • PR #2739 - Add files via upload

  • +
  • PR #2738 - Appveyor support

  • +
  • PR #2737 - Fixing 2735

  • +
  • Issue #2736 - 1d_hydro example doesn’t work

  • +
  • Issue #2735 - partitioned_vector_subview test failing

  • +
  • PR #2734 - Add C++11 range utilities

  • +
  • PR #2733 - Adapting iterator requirements for parallel algorithms

  • +
  • PR #2732 - Integrate C++ Co-arrays

  • +
  • PR #2731 - Adding on_migrated event handler to migratable component +instances

  • +
  • Issue #2729 - Add on_migrated() event handler to migratable components

  • +
  • Issue #2728 - Why Projection is needed in parallel algorithms?

  • +
  • PR #2727 - Cmake files for StackOverflow Detection

  • +
  • PR #2726 - CMake for Stack Overflow Detection

  • +
  • PR #2725 - Implemented segmented algorithms for partitioned vector

  • +
  • PR #2724 - Fix examples in Action documentation

  • +
  • PR #2723 - Enable lcos::channel<T>::register_as

  • +
  • Issue #2722 - channel register_as() failing on compilation

  • +
  • PR #2721 - Mind map

  • +
  • PR #2720 - reorder forward declarations to get rid of C++14-only auto +return types

  • +
  • PR #2719 - Add documentation for partitioned_vector and add features in +pack.hpp

  • +
  • Issue #2718 - Some forward declarations in execution_fwd.hpp aren’t +C++11-compatible

  • +
  • PR #2717 - Config support for fallthrough attribute

  • +
  • PR #2716 - Implement parallel::partition_copy

  • +
  • PR #2715 - initial import of icu string serializer

  • +
  • PR #2714 - initial import of valarray serializer

  • +
  • PR #2713 - Remove slashes before CMAKE_FILES_DIRECTORY variables

  • +
  • PR #2712 - Fixing wait for 1751

  • +
  • PR #2711 - Adjust code for minimal supported GCC having being bumped to +4.9

  • +
  • PR #2710 - Adding code of conduct

  • +
  • PR #2709 - Fixing UB in destroy tests

  • +
  • PR #2708 - Add inline to prevent multiple definition issue

  • +
  • Issue #2707 - Multiple defined symbols for task_block.hpp in VS2015

  • +
  • PR #2706 - Adding .clang-format file

  • +
  • PR #2704 - Add a synchronous mapping API

  • +
  • Issue #2703 - Request: Add the .clang-format file to the repository

  • +
  • Issue #2702 - STEllAR-GROUP/Vc slower than VCv1 possibly due to wrong +instructions generated

  • +
  • Issue #2701 - Datapar with STEllAR-GROUP/Vc requires obscure flag

  • +
  • Issue #2700 - Naming inconsistency in parallel algorithms

  • +
  • Issue #2699 - Iterator requirements are different from standard in +parallel copy_if.

  • +
  • PR #2698 - Properly releasing parcelport write handlers

  • +
  • Issue #2697 - Compile error in addressing_service.cpp

  • +
  • Issue #2696 - Building and using HPX statically: undefined references +from runtime_support_server.cpp

  • +
  • Issue #2695 - Executor changes cause compilation failures

  • +
  • PR #2694 - Refining C++ language mode detection for MSVC

  • +
  • PR #2693 - P0443 r2

  • +
  • PR #2692 - Partially reverting changes to parcel_await

  • +
  • Issue #2689 - HPX build fails when HPX_WITH_CUDA is enabled

  • +
  • PR #2688 - Make Cuda Clang builds pass

  • +
  • PR #2687 - Add an is_tuple_like trait for sequenceable type detection

  • +
  • PR #2686 - Allowing throttling scheduler to be used without idle backoff

  • +
  • PR #2685 - Add support of std::array to hpx::util::tuple_size and +tuple_element

  • +
  • PR #2684 - Adding new statistics performance counters

  • +
  • PR #2683 - Replace boost::exception_ptr with std::exception_ptr

  • +
  • Issue #2682 - HPX does not compile with +HPX_WITH_THREAD_MANAGER_IDLE_BACKOFF=OFF

  • +
  • PR #2681 - Attempt to fix problem in managed_component_base

  • +
  • PR #2680 - Fix bad size during archive creation

  • +
  • Issue #2679 - Mismatch between size of archive and container

  • +
  • Issue #2678 - In parallel algorithm, other tasks are executed to the end +even if an exception occurs in any task.

  • +
  • PR #2677 - Adding include check for std::addressof

  • +
  • PR #2676 - Adding parallel::destroy and destroy_n

  • +
  • PR #2675 - Making sure statistics counters work as expected

  • +
  • PR #2674 - Turning assertions into exceptions

  • +
  • PR #2673 - Inhibit direct conversion from future<future<T>> –> +future<void>

  • +
  • PR #2672 - C++17 invoke forms

  • +
  • PR #2671 - Adding uninitialized_value_construct and +uninitialized_value_construct_n

  • +
  • PR #2670 - Integrate spmd multidimensional views for +partitioned_vectors

  • +
  • PR #2669 - Adding uninitialized_default_construct and +uninitialized_default_construct_n

  • +
  • PR #2668 - Fixing documentation index

  • +
  • Issue #2667 - Ambiguity of nested hpx::future<void>’s

  • +
  • Issue #2666 - Statistics Performance counter is not working

  • +
  • PR #2664 - Adding uninitialized_move and uninitialized_move_n

  • +
  • Issue #2663 - Seg fault in managed_component::get_base_gid, possibly +cause by util::reinitializable_static

  • +
  • Issue #2662 - Crash in managed_component::get_base_gid due to problem +with util::reinitializable_static

  • +
  • PR #2665 - Hide the detail namespace in doxygen per default

  • +
  • PR #2660 - Add documentation to hpx::util::unwrapped and +hpx::util::unwrapped2

  • +
  • PR #2659 - Improve integration with vcpkg

  • +
  • PR #2658 - Unify access_data trait for use in both, serialization and +de-serialization

  • +
  • PR #2657 - Removing hpx::lcos::queue<T>

  • +
  • PR #2656 - Reduce MAX_TERMINATED_THREADS default, improve memory use on +manycore cpus

  • +
  • PR #2655 - Mainteinance for emulate-deleted macros

  • +
  • PR #2654 - Implement parallel is_heap and is_heap_until

  • +
  • PR #2653 - Drop support for VS2013

  • +
  • PR #2652 - This patch makes sure that all parcels in a batch are +properly handled

  • +
  • PR #2649 - Update docs (Table 18) - move transform to end

  • +
  • Issue #2647 - hpx::parcelset::detail::parcel_data::has_continuation_ is +uninitialized

  • +
  • Issue #2644 - Some .vcxproj in the HPX.sln fail to build

  • +
  • Issue #2641 - hpx::lcos::queue should be deprecated

  • +
  • PR #2640 - A new throttling policy with public APIs to suspend/resume

  • +
  • PR #2639 - Fix a tiny typo in tutorial.

  • +
  • Issue #2638 - Invalid return type ‘void’ of constexpr function

  • +
  • PR #2636 - Add and use HPX_MSVC_WARNING_PRAGMA for #pragma warning

  • +
  • PR #2633 - Distributed define_spmd_block

  • +
  • PR #2632 - Making sure container serialization uses size-compatible +types

  • +
  • PR #2631 - Add lcos::local::one_element_channel

  • +
  • PR #2629 - Move unordered_map out of parcelport into hpx/concurrent

  • +
  • PR #2628 - Making sure that shutdown does not hang

  • +
  • PR #2627 - Fix serialization

  • +
  • PR #2626 - Generate cmake_variables.qbk and cmake_toolchains.qbk +outside of the source tree

  • +
  • PR #2625 - Supporting -std=c++17 flag

  • +
  • PR #2624 - Fixing a small cmake typo

  • +
  • PR #2622 - Update CMake minimum required version to 3.0.2 (closes #2621)

  • +
  • Issue #2621 - Compiling hpx master fails with /usr/bin/ld: final link +failed: Bad value

  • +
  • PR #2620 - Remove warnings due to some captured variables

  • +
  • PR #2619 - LF multiple parcels

  • +
  • PR #2618 - Some fixes to libfabric that didn’t get caught before the +merge

  • +
  • PR #2617 - Adding hpx::local_new

  • +
  • PR #2616 - Documentation: Extract all entities in order to autolink +functions correctly

  • +
  • Issue #2615 - Documentation: Linking functions is broken

  • +
  • PR #2614 - Adding serialization for std::deque

  • +
  • PR #2613 - We need to link with boost.thread and boost.chrono if we use +boost.context

  • +
  • PR #2612 - Making sure for_loop_n(par, …) is actually executed in +parallel

  • +
  • PR #2611 - Add documentation to invoke_fused and friends NFC

  • +
  • PR #2610 - Added reduction templates using an identity value

  • +
  • PR #2608 - Fixing some unused vars in inspect

  • +
  • PR #2607 - Fixed build for mingw

  • +
  • PR #2606 - Supporting generic context for boost >= 1.61

  • +
  • PR #2605 - Parcelport libfabric3

  • +
  • PR #2604 - Adding allocator support to promise and friends

  • +
  • PR #2603 - Barrier hang

  • +
  • PR #2602 - Changes to scheduler to steal from one high-priority queue

  • +
  • Issue #2601 - High priority tasks are not executed first

  • +
  • PR #2600 - Compat fixes

  • +
  • PR #2599 - Compatibility layer for threading support

  • +
  • PR #2598 - V1.1

  • +
  • PR #2597 - Release V1.0

  • +
  • PR #2592 - First attempt to introduce spmd_block in hpx

  • +
  • PR #2586 - local_segment in segmented_iterator_traits

  • +
  • Issue #2584 - Add allocator support to promise, packaged_task and +friends

  • +
  • PR #2576 - Add missing dependencies of cuda based tests

  • +
  • PR #2575 - Remove warnings due to some captured variables

  • +
  • Issue #2574 - MSVC 2015 Compiler crash when building HPX

  • +
  • Issue #2568 - Remove throttle_scheduler as it has been abandoned

  • +
  • Issue #2566 - Add an inline versioning namespace before 1.0 release

  • +
  • Issue #2565 - Raise minimal cmake version requirement

  • +
  • PR #2556 - Fixing scan partitioner

  • +
  • PR #2546 - Broadcast async

  • +
  • Issue #2543 - make install fails due to a non-existing .so file

  • +
  • PR #2495 - wait_or_add_new returning thread_id_type

  • +
  • Issue #2480 - Unable to register new performance counter

  • +
  • Issue #2471 - no type named ‘fcontext_t’ in namespace

  • +
  • Issue #2456 - Re-implement hpx::util::unwrapped

  • +
  • Issue #2455 - Add more arithmetic performance counters

  • +
  • PR #2454 - Fix a couple of warnings and compiler errors

  • +
  • PR #2453 - Timed executor support

  • +
  • PR #2447 - Implementing new executor API (P0443)

  • +
  • Issue #2439 - Implement executor proposal

  • +
  • Issue #2408 - Stackoverflow detection for linux, e.g. based on +libsigsegv

  • +
  • PR #2377 - Add a customization point for put_parcel so we can override +actions

  • +
  • Issue #2368 - HPX_ASSERT problem

  • +
  • Issue #2324 - Change default number of threads used to the maximum of +the system

  • +
  • Issue #2266 - hpx_0.9.99 make tests fail

  • +
  • PR #2195 - Support for code completion in VIM

  • +
  • Issue #2137 - Hpx does not compile over osx

  • +
  • Issue #2092 - make tests should just build the tests

  • +
  • Issue #2026 - Build HPX with Apple’s clang

  • +
  • Issue #1932 - hpx with PBS fails on multiple localities

  • +
  • PR #1914 - Parallel heap algorithm implementations WIP

  • +
  • Issue #1598 - Disconnecting a locality results in segfault using +heartbeat example

  • +
  • Issue #1404 - unwrapped doesn’t work with movable only types

  • +
  • Issue #1400 - hpx::util::unwrapped doesn’t work with non-future types

  • +
  • Issue #1205 - TSS is broken

  • +
  • Issue #1126 - vector<future<T> > does not work gracefully with dataflow, +when_all and unwrapped

  • +
  • Issue #1056 - Thread manager cleanup

  • +
  • Issue #863 - Futures should not require a default constructor

  • +
  • Issue #856 - Allow runtimemode_connect to be used with security enabled

  • +
  • Issue #726 - Valgrind

  • +
  • Issue #701 - Add RCR performance counter component

  • +
  • Issue #528 - Add support for known failures and warning +count/comparisons to hpx_run_tests.py

  • +
+
+
+
+
HPX V1.0.0 (Apr 24, 2017)#
+
+
General changes#
+

Here are some of the main highlights and changes for this release (in no +particular order):

+
    +
  • Added the facility hpx::split_future which allows one to convert a +future<tuple<Ts...>> into a tuple<future<Ts>...>. This functionality +is not available when compiling HPX with VS2012.

  • +
  • Added a new type of performance counter which allows one to return a list of +values for each invocation. We also added a first counter of this type which +collects a histogram of the times between parcels being created.

  • +
  • Added new LCOs: hpx::lcos::channel and hpx::lcos::local::channel which +are very similar to the well known channel constructs used in the Go language.

  • +
  • Added new performance counters reporting the amount of data handled by the +networking layer on a action-by-action basis (please see PR #2289 for +more details).

  • +
  • Added a new facility hpx::lcos::barrier, replacing the equally named older +one. The new facility has a slightly changed API and is much more efficient. +Most notable, the new facility exposes a (global) function +hpx::lcos::barrier::synchronize() which represents a global barrier across +all localities.

  • +
  • We have started to add support for vectorization to our parallel algorithm +implementations. This support depends on using an external library, currently +either Vc Library or |boost_simd|_. Please see Issue #2333 for a list of +currently supported algorithms. This is an experimental feature and its +implementation and/or API might change in the future. Please see this +blog-post +for more information.

  • +
  • The parameter sequence for the hpx::parallel::transform_reduce overload +taking one iterator range has changed to match the changes this algorithm has +undergone while being moved to C++17. The old overload can be still enabled at +configure time by specifying -DHPX_WITH_TRANSFORM_REDUCE_COMPATIBILITY=On +to CMake.

  • +
  • The algorithm hpx::parallel::inner_product has been renamed to +hpx::parallel::transform_reduce to match the changes this algorithm has +undergone while being moved to C++17. The old inner_product names can be still +enabled at configure time by specifying +-DHPX_WITH_TRANSFORM_REDUCE_COMPATIBILITY=On to CMake.

  • +
  • Added versions of hpx::get_ptr taking client side representations for +component instances as their parameter (instead of a global id).

  • +
  • Added the helper utility +hpx::performance_counters::performance_counter_set helping to encapsulate +a set of performance counters to be managed concurrently.

  • +
  • All execution policies and related classes have been renamed to be consistent +with the naming changes applied for C++17. All policies now live in the +namespace hpx::parallel::execution. The ols names can be still enabled at +configure time by specifying -DHPX_WITH_EXECUTION_POLICY_COMPATIBILITY=On +to CMake.

  • +
  • The thread scheduling subsystem has undergone a major refactoring which +results in significant performance improvements. We have also imroved the +performance of creating hpx::future and of various facilities handling +those.

  • +
  • We have consolidated all of the code in HPX.Compute related to the integration +of CUDA. hpx::partitioned_vector has been enabled to be usable with +hpx::compute::vector which allows one to place the partitions on one or +more GPU devices.

  • +
  • Added new performance counters exposing various internals of the thread +scheduling subsystem, such as the current idle- and busy-loop counters and +instantaneous scheduler utilization.

  • +
  • Extended and improved the use of the ITTNotify hooks allowing to collect +performance counter data and function annotation information from within the +Intel Amplifier tool.

  • +
+
+
+
Breaking changes#
+
    +
  • We have dropped support for the gcc compiler versions V4.6 and 4.7. The +minimal gcc version we now test on is gcc V4.8.

  • +
  • We have removed (default) support for boost::chrono in interfaces, uses of +it have been replaced with std::chrono. This facility can be still enabled +at configure time by specifying -DHPX_WITH_BOOST_CHRONO_COMPATIBILITY=On +to CMake.

  • +
  • The parameter sequence for the hpx::parallel::transform_reduce overload +taking one iterator range has changed to match the changes this algorithm has +undergone while being moved to C++17.

  • +
  • The algorithm hpx::parallel::inner_product has been renamed to +hpx::parallel::transform_reduce to match the changes this algorithm has +undergone while being moved to C++17.

  • +
  • the build options HPX_WITH_COLOCATED_BACKWARDS_COMPATIBILITY and +HPX_WITH_COMPONENT_GET_GID_COMPATIBILITY are now disabled by default. Please +change your code still depending on the deprecated interfaces.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release.

+
    +
  • PR #2596 - Adding apex data

  • +
  • PR #2595 - Remove obsolete file

  • +
  • Issue #2594 - FindOpenCL.cmake mismatch with the official cmake module

  • +
  • PR #2592 - First attempt to introduce spmd_block in hpx

  • +
  • Issue #2591 - Feature request: continuation (then) which does not +require the callable object to take a future<R> as parameter

  • +
  • PR #2588 - Daint fixes

  • +
  • PR #2587 - Fixing transfer_(continuation)_action::schedule

  • +
  • PR #2585 - Work around MSVC having an ICE when compiling with -Ob2

  • +
  • PR #2583 - changing 7zip command to 7za in roll_release.sh

  • +
  • PR #2582 - First attempt to introduce spmd_block in hpx

  • +
  • PR #2581 - Enable annotated function for parallel algorithms

  • +
  • PR #2580 - First attempt to introduce spmd_block in hpx

  • +
  • PR #2579 - Make thread NICE level setting an option

  • +
  • PR #2578 - Implementing enqueue instead of busy wait when no sender is +available

  • +
  • PR #2577 - Retrieve -std=c++11 consistent nvcc flag

  • +
  • PR #2576 - Add missing dependencies of cuda based tests

  • +
  • PR #2575 - Remove warnings due to some captured variables

  • +
  • PR #2573 - Attempt to resolve resolve_locality

  • +
  • PR #2572 - Adding APEX hooks to background thread

  • +
  • PR #2571 - Pick up hpx.ignore_batch_env from config map

  • +
  • PR #2570 - Add commandline options –hpx:print-counters-locally

  • +
  • PR #2569 - Fix computeapi unit tests

  • +
  • PR #2567 - This adds another barrier::synchronize before registering +performance counters

  • +
  • PR #2564 - Cray static toolchain support

  • +
  • PR #2563 - Fixed unhandled exception during startup

  • +
  • PR #2562 - Remove partitioned_vector.cu from build tree when nvcc is +used

  • +
  • Issue #2561 - octo-tiger crash with commit +6e921495ff6c26f125d62629cbaad0525f14f7ab

  • +
  • PR #2560 - Prevent -Wundef warnings on Vc version checks

  • +
  • PR #2559 - Allowing CUDA callback to set the future directly from an OS +thread

  • +
  • PR #2558 - Remove warnings due to float precisions

  • +
  • PR #2557 - Removing bogus handling of compile flags for CUDA

  • +
  • PR #2556 - Fixing scan partitioner

  • +
  • PR #2554 - Add more diagnostics to error thrown from +find_appropriate_destination

  • +
  • Issue #2555 - No valid parcelport configured

  • +
  • PR #2553 - Add cmake cuda_arch option

  • +
  • PR #2552 - Remove incomplete datapar bindings to libflatarray

  • +
  • PR #2551 - Rename hwloc_topology to hwloc_topology_info

  • +
  • PR #2550 - Apex api updates

  • +
  • PR #2549 - Pre-include defines.hpp to get the macro HPX_HAVE_CUDA value

  • +
  • PR #2548 - Fixing issue with disconnect

  • +
  • PR #2546 - Some fixes around cuda clang partitioned_vector example

  • +
  • PR #2545 - Fix uses of the Vc2 datapar flags; the value, not the type, +should be passed to functions

  • +
  • PR #2542 - Make HPX_WITH_MALLOC easier to use

  • +
  • PR #2541 - avoid recompiles when enabling/disabling examples

  • +
  • PR #2540 - Fixing usage of target_link_libraries()

  • +
  • PR #2539 - fix RPATH behaviour

  • +
  • Issue #2538 - HPX_WITH_CUDA corrupts compilation flags

  • +
  • PR #2537 - Add output of a Bazel Skylark extension for paths and compile +options

  • +
  • PR #2536 - Add counter exposing total available memory to Windows as +well

  • +
  • PR #2535 - Remove obsolete support for security

  • +
  • Issue #2534 - Remove command line option --hpx:run-agas-server

  • +
  • PR #2533 - Pre-cache locality endpoints during bootstrap

  • +
  • PR #2532 - Fixing handling of GIDs during serialization preprocessing

  • +
  • PR #2531 - Amend uses of the term “functor”

  • +
  • PR #2529 - added counter for reading available memory

  • +
  • PR #2527 - Facilities to create actions from lambdas

  • +
  • PR #2526 - Updated docs: HPX_WITH_EXAMPLES

  • +
  • PR #2525 - Remove warnings related to unused captured variables

  • +
  • Issue #2524 - CMAKE failed because it is missing: TCMALLOC_LIBRARY +TCMALLOC_INCLUDE_DIR

  • +
  • PR #2523 - Fixing compose_cb stack overflow

  • +
  • PR #2522 - Instead of unlocking, ignore the lock while creating the +message handler

  • +
  • PR #2521 - Create LPROGRESS_ logging macro to simplify progress +tracking and timings

  • +
  • PR #2520 - Intel 17 support

  • +
  • PR #2519 - Fix components example

  • +
  • PR #2518 - Fixing parcel scheduling

  • +
  • Issue #2517 - Race condition during Parcel Coalescing Handler creation

  • +
  • Issue #2516 - HPX locks up when using at least 256 localities

  • +
  • Issue #2515 - error: Install cannot find +“/lib/hpx/libparcel_coalescing.so.0.9.99” but I can see that file

  • +
  • PR #2514 - Making sure that all continuations of a shared_future are +invoked in order

  • +
  • PR #2513 - Fixing locks held during suspension

  • +
  • PR #2512 - MPI Parcelport improvements and fixes related to the +background work changes

  • +
  • PR #2511 - Fixing bit-wise (zero-copy) serialization

  • +
  • Issue #2509 - Linking errors in hwloc_topology

  • +
  • PR #2508 - Added documentation for debugging with core files

  • +
  • PR #2506 - Fixing background work invocations

  • +
  • PR #2505 - Fix tuple serialization

  • +
  • Issue #2504 - Ensure continuations are called in the order they have +been attached

  • +
  • PR #2503 - Adding serialization support for Vc v2 (datapar)

  • +
  • PR #2502 - Resolve various, minor compiler warnings

  • +
  • PR #2501 - Some other fixes around cuda examples

  • +
  • Issue #2500 - nvcc / cuda clang issue due to a missing -DHPX_WITH_CUDA +flag

  • +
  • PR #2499 - Adding support for std::array to wait_all and friends

  • +
  • PR #2498 - Execute background work as HPX thread

  • +
  • PR #2497 - Fixing configuration options for spinlock-deadlock detection

  • +
  • PR #2496 - Accounting for different compilers in CrayKNL toolchain file

  • +
  • PR #2494 - Adding component base class which ties a component instance +to a given executor

  • +
  • PR #2493 - Enable controlling amount of pending threads which must be +available to allow thread stealing

  • +
  • PR #2492 - Adding new command line option –hpx:print-counter-reset

  • +
  • PR #2491 - Resolve ambiguities when compiling with APEX

  • +
  • PR #2490 - Resuming threads waiting on future with higher priority

  • +
  • Issue #2489 - nvcc issue because -std=c++11 appears twice

  • +
  • PR #2488 - Adding performance counters exposing the internal idle and +busy-loop counters

  • +
  • PR #2487 - Allowing for plain suspend to reschedule thread right away

  • +
  • PR #2486 - Only flag HPX code for CUDA if HPX_WITH_CUDA is set

  • +
  • PR #2485 - Making thread-queue parameters runtime-configurable

  • +
  • PR #2484 - Added atomic counter for parcel-destinations

  • +
  • PR #2483 - Added priority-queue lifo scheduler

  • +
  • PR #2482 - Changing scheduler to steal only if more than a minimal +number of tasks are available

  • +
  • PR #2481 - Extending command line option –hpx:print-counter-destination +to support value ‘none’

  • +
  • PR #2479 - Added option to disable signal handler

  • +
  • PR #2478 - Making sure the sine performance counter module gets loaded +only for the corresponding example

  • +
  • Issue #2477 - Breaking at a throw statement

  • +
  • PR #2476 - Annotated function

  • +
  • PR #2475 - Ensure that using %osthread% during logging will not throw +for non-hpx threads

  • +
  • PR #2474 - Remove now superficial non_direct actions from base_lco and +friends

  • +
  • PR #2473 - Refining support for ITTNotify

  • +
  • PR #2472 - Some fixes around hpx compute

  • +
  • Issue #2470 - redefinition of boost::detail::spinlock

  • +
  • Issue #2469 - Dataflow performance issue

  • +
  • PR #2468 - Perf docs update

  • +
  • PR #2466 - Guarantee to execute remote direct actions on HPX-thread

  • +
  • PR #2465 - Improve demo : Async copy and fixed device handling

  • +
  • PR #2464 - Adding performance counter exposing instantaneous scheduler +utilization

  • +
  • PR #2463 - Downcast to future<void>

  • +
  • PR #2462 - Fixed usage of ITT-Notify API with Intel Amplifier

  • +
  • PR #2461 - Cublas demo

  • +
  • PR #2460 - Fixing thread bindings

  • +
  • PR #2459 - Make -std=c++11 nvcc flag consistent for in-build and +installed versions

  • +
  • Issue #2457 - Segmentation fault when registering a partitioned vector

  • +
  • PR #2452 - Properly releasing global barrier for unhandled exceptions

  • +
  • PR #2451 - Fixing long shutdown times

  • +
  • PR #2450 - Attempting to fix initialization errors on newer platforms +(Boost V1.63)

  • +
  • PR #2449 - Replace BOOST_COMPILER_FENCE with an HPX version

  • +
  • PR #2448 - This fixes a possible race in the migration code

  • +
  • +
    PR #2445 - Fixing dataflow et.al. for futures or future-ranges wrapped

    into ref()

    +
    +
    +
  • +
  • PR #2444 - Fix segfaults

  • +
  • PR #2443 - Issue 2442

  • +
  • Issue #2442 - Mismatch between #if/#endif and namespace scope brackets +in this_thread_executers.hpp

  • +
  • Issue #2441 - undeclared identifier BOOST_COMPILER_FENCE

  • +
  • PR #2440 - Knl build

  • +
  • PR #2438 - Datapar backend

  • +
  • PR #2437 - Adapt algorithm parameter sequence changes from C++17

  • +
  • PR #2436 - Adapt execution policy name changes from C++17

  • +
  • Issue #2435 - Trunk broken, undefined reference to +hpx::thread::interrupt(hpx::thread::id, bool)

  • +
  • PR #2434 - More fixes to resource manager

  • +
  • PR #2433 - Added versions of hpx::get_ptr taking client side +representations

  • +
  • PR #2432 - Warning fixes

  • +
  • PR #2431 - Adding facility representing set of performance counters

  • +
  • PR #2430 - Fix parallel_executor thread spawning

  • +
  • PR #2429 - Fix attribute warning for gcc

  • +
  • Issue #2427 - Seg fault running octo-tiger with latest HPX commit

  • +
  • Issue #2426 - Bug in 9592f5c0bc29806fce0dbe73f35b6ca7e027edcb causes +immediate crash in Octo-tiger

  • +
  • PR #2425 - Fix nvcc errors due to constexpr specifier

  • +
  • Issue #2424 - Async action on component present on hpx::find_here is +executing synchronously

  • +
  • PR #2423 - Fix nvcc errors due to constexpr specifier

  • +
  • PR #2422 - Implementing hpx::this_thread thread data functions

  • +
  • PR #2421 - Adding benchmark for wait_all

  • +
  • Issue #2420 - Returning object of a component client from another +component action fails

  • +
  • PR #2419 - Infiniband parcelport

  • +
  • Issue #2418 - gcc + nvcc fails to compile code that uses +partitioned_vector

  • +
  • PR #2417 - Fixing context switching

  • +
  • PR #2416 - Adding fixes and workarounds to allow compilation with +nvcc/msvc (VS2015up3)

  • +
  • PR #2415 - Fix errors coming from hpx compute examples

  • +
  • PR #2414 - Fixing msvc12

  • +
  • PR #2413 - Enable cuda/nvcc or cuda/clang when using +add_hpx_executable()

  • +
  • PR #2412 - Fix issue in HPX_SetupTarget.cmake when cuda is used

  • +
  • PR #2411 - This fixes the core compilation issues with MSVC12

  • +
  • Issue #2410 - undefined reference to opal_hwloc191_hwloc_.....

  • +
  • PR #2409 - Fixing locking for channel and receive_buffer

  • +
  • PR #2407 - Solving #2402 and #2403

  • +
  • PR #2406 - Improve guards

  • +
  • PR #2405 - Enable parallel::for_each for iterators returning proxy types

  • +
  • PR #2404 - Forward the explicitly given result_type in the hpx invoke

  • +
  • Issue #2403 - datapar_execution + zip iterator: lambda arguments aren’t +references

  • +
  • Issue #2402 - datapar algorithm instantiated with wrong type #2402

  • +
  • PR #2401 - Added support for imported libraries to HPX_Libraries.cmake

  • +
  • PR #2400 - Use CMake policy CMP0060

  • +
  • Issue #2399 - Error trying to push back vector of futures to vector

  • +
  • PR #2398 - Allow config #defines to be written out to custom +config/defines.hpp

  • +
  • Issue #2397 - CMake generated config defines can cause tedious rebuilds +category

  • +
  • Issue #2396 - BOOST_ROOT paths are not used at link time

  • +
  • PR #2395 - Fix target_link_libraries() issue when HPX Cuda is enabled

  • +
  • Issue #2394 - Template compilation error using +HPX_WITH_DATAPAR_LIBFLATARRAY

  • +
  • PR #2393 - Fixing lock registration for recursive mutex

  • +
  • PR #2392 - Add keywords in target_link_libraries in hpx_setup_target

  • +
  • PR #2391 - Clang goroutines

  • +
  • Issue #2390 - Adapt execution policy name changes from C++17

  • +
  • PR #2389 - Chunk allocator and pool are not used and are obsolete

  • +
  • PR #2388 - Adding functionalities to datapar needed by octotiger

  • +
  • PR #2387 - Fixing race condition for early parcels

  • +
  • Issue #2386 - Lock registration broken for recursive_mutex

  • +
  • PR #2385 - Datapar zip iterator

  • +
  • PR #2384 - Fixing race condition in for_loop_reduction

  • +
  • PR #2383 - Continuations

  • +
  • PR #2382 - add LibFlatArray-based backend for datapar

  • +
  • PR #2381 - remove unused typedef to get rid of compiler warnings

  • +
  • PR #2380 - Tau cleanup

  • +
  • PR #2379 - Can send immediate

  • +
  • PR #2378 - Renaming copy_helper/copy_n_helper/move_helper/move_n_helper

  • +
  • Issue #2376 - Boost trunk’s spinlock initializer fails to compile

  • +
  • PR #2375 - Add support for minimal thread local data

  • +
  • PR #2374 - Adding API functions set_config_entry_callback

  • +
  • PR #2373 - Add a simple utility for debugging that gives suspended task +backtraces

  • +
  • PR #2372 - Barrier Fixes

  • +
  • Issue #2370 - Can’t wait on a wrapped future

  • +
  • PR #2369 - Fixing stable_partition

  • +
  • PR #2367 - Fixing find_prefixes for Windows platforms

  • +
  • PR #2366 - Testing for experimental/optional only in C++14 mode

  • +
  • PR #2364 - Adding set_config_entry

  • +
  • PR #2363 - Fix papi

  • +
  • PR #2362 - Adding missing macros for new non-direct actions

  • +
  • PR #2361 - Improve cmake output to help debug compiler incompatibility +check

  • +
  • PR #2360 - Fixing race condition in condition_variable

  • +
  • PR #2359 - Fixing shutdown when parcels are still in flight

  • +
  • Issue #2357 - failed to insert console_print_action into +typename_to_id_t registry

  • +
  • PR #2356 - Fixing return type of get_iterator_tuple

  • +
  • PR #2355 - Fixing compilation against Boost 1 62

  • +
  • PR #2354 - Adding serialization for mask_type if CPU_COUNT > 64

  • +
  • PR #2353 - Adding hooks to tie in APEX into the parcel layer

  • +
  • Issue #2352 - Compile errors when using intel 17 beta (for KNL) on +edison

  • +
  • PR #2351 - Fix function vtable get_function_address implementation

  • +
  • Issue #2350 - Build failure - master branch (4de09f5) with Intel +Compiler v17

  • +
  • PR #2349 - Enabling zero-copy serialization support for std::vector<>

  • +
  • PR #2348 - Adding test to verify #2334 is fixed

  • +
  • PR #2347 - Bug fixes for hpx.compute and hpx::lcos::channel

  • +
  • PR #2346 - Removing cmake “find” files that are in the APEX cmake +Modules

  • +
  • PR #2345 - Implemented parallel::stable_partition

  • +
  • PR #2344 - Making hpx::lcos::channel usable with basename registration

  • +
  • PR #2343 - Fix a couple of examples that failed to compile after recent +api changes

  • +
  • Issue #2342 - Enabling APEX causes link errors

  • +
  • PR #2341 - Removing cmake “find” files that are in the APEX cmake +Modules

  • +
  • PR #2340 - Implemented all existing datapar algorithms using Boost.SIMD

  • +
  • PR #2339 - Fixing 2338

  • +
  • PR #2338 - Possible race in sliding semaphore

  • +
  • PR #2337 - Adjust osu_latency test to measure window_size parcels in +flight at once

  • +
  • PR #2336 - Allowing remote direct actions to be executed without +spawning a task

  • +
  • PR #2335 - Making sure multiple components are properly initialized from +arguments

  • +
  • Issue #2334 - Cannot construct component with large vector on a remote +locality

  • +
  • PR #2332 - Fixing hpx::lcos::local::barrier

  • +
  • PR #2331 - Updating APEX support to include OTF2

  • +
  • PR #2330 - Support for data-parallelism for parallel algorithms

  • +
  • Issue #2329 - Coordinate settings in cmake

  • +
  • PR #2328 - fix LibGeoDecomp builds with HPX + GCC 5.3.0 + CUDA 8RC

  • +
  • PR #2326 - Making scan_partitioner work (for now)

  • +
  • Issue #2323 - Constructing a vector of components only correctly +initializes the first component

  • +
  • PR #2322 - Fix problems that bubbled up after merging #2278

  • +
  • PR #2321 - Scalable barrier

  • +
  • PR #2320 - Std flag fixes

  • +
  • Issue #2319 - -std=c++14 and -std=c++1y with Intel can’t build recent +Boost builds due to insufficient C++14 support; don’t enable these flags by +default for Intel

  • +
  • PR #2318 - Improve handling of –hpx:bind=<bind-spec>

  • +
  • PR #2317 - Making sure command line warnings are printed once only

  • +
  • PR #2316 - Fixing command line handling for default bind mode

  • +
  • PR #2315 - Set id_retrieved if set_id is present

  • +
  • Issue #2314 - Warning for requested/allocated thread discrepancy is +printed twice

  • +
  • Issue #2313 - –hpx:print-bind doesn’t work with –hpx:pu-step

  • +
  • Issue #2312 - –hpx:bind range specifier restrictions are overly +restrictive

  • +
  • Issue #2311 - hpx_0.9.99 out of project build fails

  • +
  • PR #2310 - Simplify function registration

  • +
  • PR #2309 - Spelling and grammar revisions in documentation (and some +code)

  • +
  • PR #2306 - Correct minor typo in the documentation

  • +
  • PR #2305 - Cleaning up and fixing parcel coalescing

  • +
  • PR #2304 - Inspect checks for stream related includes

  • +
  • PR #2303 - Add functionality allowing to enumerate threads of given +state

  • +
  • PR #2301 - Algorithm overloads fix for VS2013

  • +
  • PR #2300 - Use <cstdint>, add inspect checks

  • +
  • PR #2299 - Replace boost::[c]ref with std::[c]ref, add inspect checks

  • +
  • PR #2297 - Fixing compilation with no hw_loc

  • +
  • PR #2296 - Hpx compute

  • +
  • PR #2295 - Making sure for_loop(execution::par, 0, N, …) is actually +executed in parallel

  • +
  • PR #2294 - Throwing exceptions if the runtime is not up and running

  • +
  • PR #2293 - Removing unused parcel port code

  • +
  • PR #2292 - Refactor function vtables

  • +
  • PR #2291 - Fixing 2286

  • +
  • PR #2290 - Simplify algorithm overloads

  • +
  • PR #2289 - Adding performance counters reporting parcel related data on +a per-action basis

  • +
  • Issue #2288 - Remove dormant parcelports

  • +
  • Issue #2286 - adjustments to parcel handling to support parcelports that +do not need a connection cache

  • +
  • PR #2285 - add CMake option to disable package export

  • +
  • PR #2283 - Add more inspect checks for use of deprecated components

  • +
  • Issue #2282 - Arithmetic exception in executor static chunker

  • +
  • Issue #2281 - For loop doesn’t parallelize

  • +
  • PR #2280 - Fixing 2277: build failure with PAPI

  • +
  • PR #2279 - Child vs parent stealing

  • +
  • Issue #2277 - master branch build failure (53c5b4f) with papi

  • +
  • PR #2276 - Compile time launch policies

  • +
  • PR #2275 - Replace boost::chrono with std::chrono in interfaces

  • +
  • PR #2274 - Replace most uses of Boost.Assign with initializer list

  • +
  • PR #2273 - Fixed typos

  • +
  • PR #2272 - Inspect checks

  • +
  • PR #2270 - Adding test verifying -Ihpx.os_threads=all

  • +
  • PR #2269 - Added inspect check for now obsolete boost type traits

  • +
  • PR #2268 - Moving more code into source files

  • +
  • Issue #2267 - Add inspect support to deprecate Boost.TypeTraits

  • +
  • PR #2265 - Adding channel LCO

  • +
  • PR #2264 - Make support for std::ref mandatory

  • +
  • PR #2263 - Constrain tuple_member forwarding constructor

  • +
  • Issue #2262 - Test hpx.os_threads=all

  • +
  • Issue #2261 - OS X: Error: no matching constructor for initialization of +‘hpx::lcos::local::condition_variable_any’

  • +
  • Issue #2260 - Make support for std::ref mandatory

  • +
  • PR #2259 - Remove most of Boost.MPL, Boost.EnableIf and Boost.TypeTraits

  • +
  • PR #2258 - Fixing #2256

  • +
  • PR #2257 - Fixing launch process

  • +
  • Issue #2256 - Actions are not registered if not invoked

  • +
  • PR #2255 - Coalescing histogram

  • +
  • PR #2254 - Silence explicit initialization in copy-constructor warnings

  • +
  • PR #2253 - Drop support for GCC 4.6 and 4.7

  • +
  • PR #2252 - Prepare V1.0

  • +
  • PR #2251 - Convert to 0.9.99

  • +
  • PR #2249 - Adding iterator_facade and iterator_adaptor

  • +
  • Issue #2248 - Need a feature to yield to a new task immediately

  • +
  • PR #2246 - Adding split_future

  • +
  • PR #2245 - Add an example for handing over a component instance to a +dynamically launched locality

  • +
  • Issue #2243 - Add example demonstrating AGAS symbolic name registration

  • +
  • Issue #2242 - pkgconfig test broken on CentOS 7 / Boost 1.61

  • +
  • Issue #2241 - Compilation error for partitioned vector in hpx_compute +branch

  • +
  • PR #2240 - Fixing termination detection on one locality

  • +
  • Issue #2239 - Create a new facility lcos::split_all

  • +
  • Issue #2236 - hpx::cout vs. std::cout

  • +
  • PR #2232 - Implement local-only primary namespace service

  • +
  • Issue #2147 - would like to know how much data is being routed by +particular actions

  • +
  • Issue #2109 - Warning while compiling hpx

  • +
  • Issue #1973 - Setting INTERFACE_COMPILE_OPTIONS for hpx_init in CMake +taints Fortran_FLAGS

  • +
  • Issue #1864 - run_guarded using bound function ignores reference

  • +
  • Issue #1754 - Running with TCP parcelport causes immediate crash or +freeze

  • +
  • Issue #1655 - Enable zip_iterator to be used with Boost traversal +iterator categories

  • +
  • Issue #1591 - Optimize AGAS for shared memory only operation

  • +
  • Issue #1401 - Need an efficient infiniband parcelport

  • +
  • Issue #1125 - Fix the IPC parcelport

  • +
  • Issue #839 - Refactor ibverbs and shmem parcelport

  • +
  • Issue #702 - Add instrumentation of parcel layer

  • +
  • Issue #668 - Implement ispc task interface

  • +
  • Issue #533 - Thread queue/deque internal parameters should be runtime +configurable

  • +
  • Issue #475 - Create a means of combining performance counters into +querysets

  • +
+
+
+
+
HPX V0.9.99 (Jul 15, 2016)#
+
+
General changes#
+

As the version number of this release hints, we consider this release to be a +preview for the upcoming HPX V1.0. All of the functionalities we set out to +implement for V1.0 are in place; all of the features we wanted to have exposed +are ready. We are very happy with the stability and performance of HPX and we +would like to present this release to the community in order for us to gather +broad feedback before releasing V1.0. We still expect for some minor details to +change, but on the whole this release represents what we would like to have in a +V1.0.

+

Overall, since the last release we have had almost 1600 commits while closing +almost 400 tickets. These numbers reflect the incredible development activity we +have seen over the last couple of months. We would like to express a big ‘Thank +you!’ to all contributors and those who helped to make this release happen.

+

The most notable addition in terms of new functionality available with this +release is the full implementation of object migration (i.e. the ability to +transparently move HPX components to a different compute node). Additionally, +this release of HPX cleans up many minor issues and some API inconsistencies.

+

Here are some of the main highlights and changes for this release (in no +particular order):

+
    +
  • We have fixed a couple of issues in AGAS and the parcel layer which have +caused hangs, segmentation faults at exit, and a slowdown of applications over +time. Fixing those has significantly increased the overall stability and +performance of distributed runs.

  • +
  • We have started to add parallel algorithm overloads based on the C++ +Extensions for Ranges (N4560) proposal. This also includes the +addition of projections to the existing algorithms. Please see +Issue #1668 for a list of algorithms which have been adapted to +N4560.

  • +
  • We have implemented index-based parallel for-loops based on a corresponding +standardization proposal (P0075R1). Please see Issue #2016 for +a list of available algorithms.

  • +
  • We have added implementations for more parallel algorithms as proposed for the +upcoming C++ 17 Standard. See Issue #1141 for an overview of which +algorithms are available by now.

  • +
  • We have started to implement a new prototypical functionality with +HPX.Compute which uniformly exposes some of the higher level APIs to +heterogeneous architectures (currently CUDA). This functionality is an early +preview and should not be considered stable. It may change considerably in the +future.

  • +
  • We have pervasively added (optional) executor arguments to all API functions +which schedule new work. Executors are now used throughout the code base as +the main means of executing tasks.

  • +
  • Added hpx::make_future<R>(future<T> &&) allowing to convert a future of +any type T into a future of any other type R, either based on default +conversion rules of the embedded types or using a given explicit conversion +function.

  • +
  • We finally finished the implementation of transparent migration of components +to another locality. It is now possible to trigger a migration operation +without ‘stopping the world’ for the object to migrate. HPX will make sure +that no work is being performed on an object before it is migrated and that +all subsequently scheduled work for the migrated object will be transparently +forwarded to the new locality. Please note that the global id of the migrated +object does not change, thus the application will not have to be changed in +any way to support this new functionality. Please note that this feature is +currently considered experimental. See Issue #559 and PR #1966 for +more details.

  • +
  • The hpx::dataflow facility is now usable with actions. Similarly to +hpx::async, actions can be specified as an explicit template argument +(hpx::dataflow<Action>(target, ...)) or as the first argument +(hpx::dataflow(Action(), target, ...)). We have also enabled the use of +distribution policies as the target for dataflow invocations. Please see +Issue #1265 and PR #1912 for more information.

  • +
  • Adding overloads of gather_here and gather_there to accept the plain +values of the data to gather (in addition to the existing overloads expecting +futures).

  • +
  • We have cleaned up and refactored large parts of the code base. This helped +reducing compile and link times of HPX itself and also of applications +depending on it. We have further decreased the dependency of HPX on the +Boost libraries by replacing part of those with facilities available from the +standard libraries.

  • +
  • Wherever possible we have removed dependencies of our API on Boost by +replacing those with the equivalent facility from the C++11 standard library.

  • +
  • We have added new performance counters for parcel coalescing, file-IO, the +AGAS cache, and overall scheduler time. Resetting performance counters has +been overhauled and fixed.

  • +
  • We have introduced a generic client type hpx::components::client<> and +added support for using it with hpx::async. This removes the necessity to +implement specific client types for every component type without losing type +safety. This deemphasizes the need for using the low level hpx::id_type +for referencing (possibly remote) component instances. The plan is to +deprecate the direct use of hpx::id_type in user code in the future.

  • +
  • We have added a special iterator which supports automatic prefetching of one +or more arrays for speeding up loop-like code (see +hpx::parallel::util::make_prefetcher_context()).

  • +
  • We have extended the interfaces exposed from executors (as proposed by +N4406) to accept an arbitrary number of arguments.

  • +
+
+
+
Breaking changes#
+
    +
  • In order to move the dataflow facility to namespace hpx we added a +definition of hpx::dataflow which might create ambiguities in existing +codes. The previous definition of this facility (hpx::lcos::local::dataflow) +has been deprecated and is available only if the constant +-DHPX_WITH_LOCAL_DATAFLOW_COMPATIBILITY=On to CMake is defined at +configuration time. +Please explicitly qualify all uses of the dataflow facility if you enable +this compatibility setting and encounter ambiguities.

  • +
  • The adaptation of the C++ Extensions for Ranges (N4560) proposal +imposes some breaking changes related to the return types of some of the +parallel algorithms. Please see Issue #1668 for a list of algorithms which +have already been adapted.

  • +
  • The facility hpx::lcos::make_future_void() has been replaced by +hpx::make_future<void>().

  • +
  • We have removed support for Intel V13 and gcc 4.4.x.

  • +
  • We have removed (default) support for the generic +hpx::parallel::execution_poliy because it was removed from the Parallelism +TS (__cpp11_n4104__) while it was being added to the upcoming C++17 Standard. +This facility can be still enabled at configure time by specifying +-DHPX_WITH_GENERIC_EXECUTION_POLICY=On to CMake.

  • +
  • Uses of boost::shared_ptr and related facilities have been replaced with +std::shared_ptr and friends. Uses of boost::unique_lock, +boost::lock_guard etc. have also been replaced by the equivalent (and +equally named) tools available from the C++11 standard library.

  • +
  • Facilities that used to expect an explicit boost::unique_lock now take an +std::unique_lock. Additionally, condition_variable no longer aliases +condition_variable_any; its interface now only works with +std::unique_lock<local::mutex>.

  • +
  • Uses of boost::function, boost::bind, boost::tuple have been replaced +by the corresponding facilities in HPX (hpx::util::function, +hpx::util::bind, and hpx::util::tuple, respectively).

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release.

+
    +
  • PR #2250 - change default chunker of parallel executor to static one

  • +
  • PR #2247 - HPX on ppc64le

  • +
  • PR #2244 - Fixing MSVC problems

  • +
  • PR #2238 - Fixing small typos

  • +
  • PR #2237 - Fixing small typos

  • +
  • PR #2234 - Fix broken add test macro when extra args are passed in

  • +
  • PR #2231 - Fixing possible race during future awaiting in serialization

  • +
  • PR #2230 - Fix stream nvcc

  • +
  • PR #2229 - Fixed run_as_hpx_thread

  • +
  • PR #2228 - On prefetching_test branch : adding prefetching_iterator and +related tests used for prefetching containers within lambda functions

  • +
  • PR #2227 - Support for HPXCL’s opencl::event

  • +
  • PR #2226 - Preparing for release of V0.9.99

  • +
  • PR #2225 - fix issue when compiling components with hpxcxx

  • +
  • PR #2224 - Compute alloc fix

  • +
  • PR #2223 - Simplify promise

  • +
  • PR #2222 - Replace last uses of boost::function by util::function_nonser

  • +
  • PR #2221 - Fix config tests

  • +
  • PR #2220 - Fixing gcc 4.6 compilation issues

  • +
  • PR #2219 - nullptr support for [unique_]function

  • +
  • PR #2218 - Introducing clang tidy

  • +
  • PR #2216 - Replace NULL with nullptr

  • +
  • Issue #2214 - Let inspect flag use of NULL, suggest nullptr instead

  • +
  • PR #2213 - Require support for nullptr

  • +
  • PR #2212 - Properly find jemalloc through pkg-config

  • +
  • PR #2211 - Disable a couple of warnings reported by Intel on Windows

  • +
  • PR #2210 - Fixed host::block_allocator::bulk_construct

  • +
  • PR #2209 - Started to clean up new sort algorithms, made things compile +for sort_by_key

  • +
  • PR #2208 - A couple of fixes that were exposed by a new sort algorithm

  • +
  • PR #2207 - Adding missing includes in /hpx/include/serialization.hpp

  • +
  • PR #2206 - Call package_action::get_future before package_action::apply

  • +
  • PR #2205 - The indirect_packaged_task::operator() needs to be run on a +HPX thread

  • +
  • PR #2204 - Variadic executor parameters

  • +
  • PR #2203 - Delay-initialize members of partitioned iterator

  • +
  • PR #2202 - Added segmented fill for hpx::vector

  • +
  • Issue #2201 - Null Thread id encountered on partitioned_vector

  • +
  • PR #2200 - Fix hangs

  • +
  • PR #2199 - Deprecating hpx/traits.hpp

  • +
  • PR #2198 - Making explicit inclusion of external libraries into build

  • +
  • PR #2197 - Fix typo in QT CMakeLists

  • +
  • PR #2196 - Fixing a gcc warning about attributes being ignored

  • +
  • PR #2194 - Fixing partitioned_vector_spmd_foreach example

  • +
  • Issue #2193 - partitioned_vector_spmd_foreach seg faults

  • +
  • PR #2192 - Support Boost.Thread v4

  • +
  • PR #2191 - HPX.Compute prototype

  • +
  • PR #2190 - Spawning operation on new thread if remaining stack space +becomes too small

  • +
  • PR #2189 - Adding callback taking index and future to when_each

  • +
  • PR #2188 - Adding new example demonstrating receive_buffer

  • +
  • PR #2187 - Mask 128-bit ints if CUDA is being used

  • +
  • PR #2186 - Make startup & shutdown functions unique_function

  • +
  • PR #2185 - Fixing logging output not to cause hang on shutdown

  • +
  • PR #2184 - Allowing component clients as action return types

  • +
  • Issue #2183 - Enabling logging output causes hang on shutdown

  • +
  • Issue #2182 - 1d_stencil seg fault

  • +
  • Issue #2181 - Setting small stack size does not change default

  • +
  • PR #2180 - Changing default bind mode to balanced

  • +
  • PR #2179 - adding prefetching_iterator and related tests used for +prefetching containers within lambda functions

  • +
  • PR #2177 - Fixing 2176

  • +
  • Issue #2176 - Launch process test fails on OSX

  • +
  • PR #2175 - Fix unbalanced config/warnings includes, add some new ones

  • +
  • PR #2174 - Fix test categorization : regression not unit

  • +
  • Issue #2172 - Different performance results

  • +
  • Issue #2171 - “negative entry in reference count table” running +octotiger on 32 nodes on queenbee

  • +
  • Issue #2170 - Error while compiling on Mac + boost 1.60

  • +
  • PR #2168 - Fixing problems with is_bitwise_serializable

  • +
  • Issue #2167 - startup & shutdown function should accept unique_function

  • +
  • Issue #2166 - Simple receive_buffer example

  • +
  • PR #2165 - Fix wait all

  • +
  • PR #2164 - Fix wait all

  • +
  • PR #2163 - Fix some typos in config tests

  • +
  • PR #2162 - Improve #includes

  • +
  • PR #2160 - Add inspect check for missing #include <list>

  • +
  • PR #2159 - Add missing finalize call to stop test hanging

  • +
  • PR #2158 - Algo fixes

  • +
  • PR #2157 - Stack check

  • +
  • Issue #2156 - OSX reports stack space incorrectly (generic context +coroutines)

  • +
  • Issue #2155 - Race condition suspected in runtime

  • +
  • PR #2154 - Replace boost::detail::atomic_count with the new +util::atomic_count

  • +
  • PR #2153 - Fix stack overflow on OSX

  • +
  • PR #2152 - Define is_bitwise_serializable as is_trivially_copyable when +available

  • +
  • PR #2151 - Adding missing <cstring> for std::mem* functions

  • +
  • Issue #2150 - Unable to use component clients as action return types

  • +
  • PR #2149 - std::memmove copies bytes, use bytes*sizeof(type) when +copying larger types

  • +
  • PR #2146 - Adding customization point for parallel copy/move

  • +
  • PR #2145 - Applying changes to address warnings issued by latest version +of PVS Studio

  • +
  • Issue #2148 - hpx::parallel::copy is broken after trivially copyable +changes

  • +
  • PR #2144 - Some minor tweaks to compute prototype

  • +
  • PR #2143 - Added Boost version support information over OSX platform

  • +
  • PR #2142 - Fixing memory leak in example

  • +
  • PR #2141 - Add missing specializations in execution policies

  • +
  • PR #2139 - This PR fixes a few problems reported by Clang’s Undefined +Behavior sanitizer

  • +
  • PR #2138 - Revert “Adding fedora docs”

  • +
  • PR #2136 - Removed double semicolon

  • +
  • PR #2135 - Add deprecated #include check for hpx_fwd.hpp

  • +
  • PR #2134 - Resolved memory leak in stencil_8

  • +
  • PR #2133 - Replace uses of boost pointer containers

  • +
  • PR #2132 - Removing unused typedef

  • +
  • PR #2131 - Add several include checks for std facilities

  • +
  • PR #2130 - Fixing parcel compression, adding test

  • +
  • PR #2129 - Fix invalid attribute warnings

  • +
  • Issue #2128 - hpx::init seems to segfault

  • +
  • PR #2127 - Making executor_traits N-nary

  • +
  • PR #2126 - GCC 4.6 fails to deduce the correct type in lambda

  • +
  • PR #2125 - Making parcel coalescing test actually test something

  • +
  • Issue #2124 - Make a testcase for parcel compression

  • +
  • Issue #2123 - hpx/hpx/runtime/applier_fwd.hpp - Multiple defined types

  • +
  • Issue #2122 - Exception in primary_namespace::resolve_free_list

  • +
  • Issue #2121 - Possible memory leak in 1d_stencil_8

  • +
  • PR #2120 - Fixing 2119

  • +
  • Issue #2119 - reduce_by_key compilation problems

  • +
  • Issue #2118 - Premature unwrapping of boost::ref’ed arguments

  • +
  • PR #2117 - Added missing initializer on last constructor for +thread_description

  • +
  • PR #2116 - Use a lightweight bind implementation when no placeholders +are given

  • +
  • PR #2115 - Replace boost::shared_ptr with std::shared_ptr

  • +
  • PR #2114 - Adding hook functions for executor_parameter_traits +supporting timers

  • +
  • Issue #2113 - Compilation error with gcc version 4.9.3 (MacPorts gcc49 +4.9.3_0)

  • +
  • PR #2112 - Replace uses of safe_bool with explicit operator bool

  • +
  • Issue #2111 - Compilation error on QT example

  • +
  • Issue #2110 - Compilation error when passing non-future argument to +unwrapped continuation in dataflow

  • +
  • Issue #2109 - Warning while compiling hpx

  • +
  • Issue #2109 - Stack trace of last bug causing issues with octotiger

  • +
  • Issue #2108 - Stack trace of last bug causing issues with octotiger

  • +
  • PR #2107 - Making sure that a missing parcel_coalescing module does not +cause startup exceptions

  • +
  • PR #2106 - Stop using hpx_fwd.hpp

  • +
  • Issue #2105 - coalescing plugin handler is not optional any more

  • +
  • Issue #2104 - Make executor_traits N-nary

  • +
  • Issue #2103 - Build error with octotiger and hpx commit e657426d

  • +
  • PR #2102 - Combining thread data storage

  • +
  • PR #2101 - Added repartition version of 1d stencil that uses any +performance counter

  • +
  • PR #2100 - Drop obsolete TR1 result_of protocol

  • +
  • PR #2099 - Replace uses of boost::bind with util::bind

  • +
  • PR #2098 - Deprecated inspect checks

  • +
  • PR #2097 - Reduce by key, extends #1141

  • +
  • PR #2096 - Moving local cache from external to hpx/util

  • +
  • PR #2095 - Bump minimum required Boost to 1.50.0

  • +
  • PR #2094 - Add include checks for several Boost utilities

  • +
  • Issue #2093 - /…/local_cache.hpp(89): error #303: explicit type is +missing (“int” assumed)

  • +
  • PR #2091 - Fix for Raspberry pi build

  • +
  • PR #2090 - Fix storage size for util::function<>

  • +
  • PR #2089 - Fix #2088

  • +
  • Issue #2088 - More verbose output from cmake configuration

  • +
  • PR #2087 - Making sure init_globally always executes hpx_main

  • +
  • Issue #2086 - Race condition with recent HPX

  • +
  • PR #2085 - Adding #include checker

  • +
  • PR #2084 - Replace boost lock types with standard library ones

  • +
  • PR #2083 - Simplify packaged task

  • +
  • PR #2082 - Updating APEX version for testing

  • +
  • PR #2081 - Cleanup exception headers

  • +
  • PR #2080 - Make call_once variadic

  • +
  • Issue #2079 - With GNU C++, line 85 of hpx/config/version.hpp causes +link failure when linking application

  • +
  • Issue #2078 - Simple test fails with _GLIBCXX_DEBUG defined

  • +
  • PR #2077 - Instantiate board in nqueen client

  • +
  • PR #2076 - Moving coalescing registration to TUs

  • +
  • PR #2075 - Fixed some documentation typos

  • +
  • PR #2074 - Adding flush-mode to message handler flush

  • +
  • PR #2073 - Fixing performance regression introduced lately

  • +
  • PR #2072 - Refactor local::condition_variable

  • +
  • PR #2071 - Timer based on boost::asio::deadline_timer

  • +
  • PR #2070 - Refactor tuple based functionality

  • +
  • PR #2069 - Fixed typos

  • +
  • Issue #2068 - Seg fault with octotiger

  • +
  • PR #2067 - Algorithm cleanup

  • +
  • PR #2066 - Split credit fixes

  • +
  • PR #2065 - Rename HPX_MOVABLE_BUT_NOT_COPYABLE to HPX_MOVABLE_ONLY

  • +
  • PR #2064 - Fixed some typos in docs

  • +
  • PR #2063 - Adding example demonstrating template components

  • +
  • Issue #2062 - Support component templates

  • +
  • PR #2061 - Replace some uses of lexical_cast<string> with C++11 +std::to_string

  • +
  • PR #2060 - Replace uses of boost::noncopyable with HPX_NON_COPYABLE

  • +
  • PR #2059 - Adding missing for_loop algorithms

  • +
  • PR #2058 - Move several definitions to more appropriate headers

  • +
  • PR #2057 - Simplify assert_owns_lock and ignore_while_checking

  • +
  • PR #2056 - Replacing std::result_of with util::result_of

  • +
  • PR #2055 - Fix process launching/connecting back

  • +
  • PR #2054 - Add a forwarding coroutine header

  • +
  • PR #2053 - Replace uses of boost::unordered_map with std::unordered_map

  • +
  • PR #2052 - Rewrite tuple unwrap

  • +
  • PR #2050 - Replace uses of BOOST_SCOPED_ENUM with C++11 scoped enums

  • +
  • PR #2049 - Attempt to narrow down split_credit problem

  • +
  • PR #2048 - Fixing gcc startup hangs

  • +
  • PR #2047 - Fixing when_xxx and wait_xxx for MSVC12

  • +
  • PR #2046 - adding persistent_auto_chunk_size and related tests for +for_each

  • +
  • PR #2045 - Fixing HPX_HAVE_THREAD_BACKTRACE_DEPTH build time +configuration

  • +
  • PR #2044 - Adding missing service executor types

  • +
  • PR #2043 - Removing ambiguous definitions for is_future_range and +future_range_traits

  • +
  • PR #2042 - Clarify that HPX builds can use (much) more than 2GB per +process

  • +
  • PR #2041 - Changing future_iterator_traits to support pointers

  • +
  • Issue #2040 - Improve documentation memory usage warning?

  • +
  • PR #2039 - Coroutine cleanup

  • +
  • PR #2038 - Fix cmake policy CMP0042 warning MACOSX_RPATH

  • +
  • PR #2037 - Avoid redundant specialization of [unique_]function_nonser

  • +
  • PR #2036 - nvcc dies with an internal error upon pushing/popping +warnings inside templates

  • +
  • Issue #2035 - Use a less restrictive iterator definition in +hpx::lcos::detail::future_iterator_traits

  • +
  • PR #2034 - Fixing compilation error with thread queue wait time +performance counter

  • +
  • Issue #2033 - Compilation error when compiling with thread queue +waittime performance counter

  • +
  • Issue #2032 - Ambiguous template instantiation for is_future_range and +future_range_traits.

  • +
  • PR #2031 - Don’t restart timer on every incoming parcel

  • +
  • PR #2030 - Unify handling of execution policies in parallel algorithms

  • +
  • PR #2029 - Make pkg-config .pc files use .dylib on OSX

  • +
  • PR #2028 - Adding process component

  • +
  • PR #2027 - Making check for compiler compatibility independent on +compiler path

  • +
  • PR #2025 - Fixing inspect tool

  • +
  • PR #2024 - Intel13 removal

  • +
  • PR #2023 - Fix errors related to older boost versions and parameter pack +expansions in lambdas

  • +
  • Issue #2022 - gmake fail: “No rule to make target +/usr/lib46/libboost_context-mt.so”

  • +
  • PR #2021 - Added Sudoku example

  • +
  • Issue #2020 - Make errors related to init_globally.cpp example while +building HPX out of the box

  • +
  • PR #2019 - Fixed some compilation and cmake errors encountered in nqueen +example

  • +
  • PR #2018 - For loop algorithms

  • +
  • PR #2017 - Non-recursive at_index implementation

  • +
  • Issue #2016 - Add index-based for-loops

  • +
  • Issue #2015 - Change default bind-mode to balanced

  • +
  • PR #2014 - Fixed dataflow if invoked action returns a future

  • +
  • PR #2013 - Fixing compilation issues with external example

  • +
  • PR #2012 - Added Sierpinski Triangle example

  • +
  • Issue #2011 - Compilation error while running sample +hello_world_component code

  • +
  • PR #2010 - Segmented move implemented for hpx::vector

  • +
  • Issue #2009 - pkg-config order incorrect on 14.04 / GCC 4.8

  • +
  • Issue #2008 - Compilation error in dataflow of action returning a future

  • +
  • PR #2007 - Adding new performance counter exposing overall scheduler +time

  • +
  • PR #2006 - Function includes

  • +
  • PR #2005 - Adding an example demonstrating how to initialize HPX from a +global object

  • +
  • PR #2004 - Fixing 2000

  • +
  • PR #2003 - Adding generation parameter to gather to enable using it more +than once

  • +
  • PR #2002 - Turn on position independent code to solve link problem with +hpx_init

  • +
  • Issue #2001 - Gathering more than once segfaults

  • +
  • Issue #2000 - Undefined reference to hpx::assertion_failed

  • +
  • Issue #1999 - Seg fault in +hpx::lcos::base_lco_with_value<*>::set_value_nonvirt() when running octo-tiger

  • +
  • PR #1998 - Detect unknown command line options

  • +
  • PR #1997 - Extending thread description

  • +
  • PR #1996 - Adding natvis files to solution (MSVC only)

  • +
  • Issue #1995 - Command line handling does not produce error

  • +
  • PR #1994 - Possible missing include in test_utils.hpp

  • +
  • PR #1993 - Add missing LANGUAGES tag to a +hpx_add_compile_flag_if_available() call in CMakeLists.txt

  • +
  • PR #1992 - Fixing shared_executor_test

  • +
  • PR #1991 - Making sure the winsock library is properly initialized

  • +
  • PR #1990 - Fixing bind_test placeholder ambiguity coming from boost-1.60

  • +
  • PR #1989 - Performance tuning

  • +
  • PR #1987 - Make configurable size of internal storage in util::function

  • +
  • PR #1986 - AGAS Refactoring+1753 Cache mods

  • +
  • PR #1985 - Adding missing task_block::run() overload taking an executor

  • +
  • PR #1984 - Adding an optimized LRU Cache implementation (for AGAS)

  • +
  • PR #1983 - Avoid invoking migration table look up for all objects

  • +
  • PR #1981 - Replacing uintptr_t (which is not defined everywhere) with +std::size_t

  • +
  • PR #1980 - Optimizing LCO continuations

  • +
  • PR #1979 - Fixing Cori

  • +
  • PR #1978 - Fix test check that got broken in hasty fix to memory +overflow

  • +
  • PR #1977 - Refactor action traits

  • +
  • PR #1976 - Fixes typo in README.rst

  • +
  • PR #1975 - Reduce size of benchmark timing arrays to fix test failures

  • +
  • PR #1974 - Add action to update data owned by the partitioned_vector +component

  • +
  • PR #1972 - Adding partitioned_vector SPMD example

  • +
  • PR #1971 - Fixing 1965

  • +
  • PR #1970 - Papi fixes

  • +
  • PR #1969 - Fixing continuation recursions to not depend on fixed amount +of recursions

  • +
  • PR #1968 - More segmented algorithms

  • +
  • Issue #1967 - Simplify component implementations

  • +
  • PR #1966 - Migrate components

  • +
  • Issue #1964 - fatal error: ‘boost/lockfree/detail/branch_hints.hpp’ file +not found

  • +
  • Issue #1962 - parallel:copy_if has race condition when used on in place +arrays

  • +
  • PR #1963 - Fixing Static Parcelport initialization

  • +
  • PR #1961 - Fix function target

  • +
  • Issue #1960 - Papi counters don’t reset

  • +
  • PR #1959 - Fixing 1958

  • +
  • Issue #1958 - inclusive_scan gives incorrect results with +non-commutative operator

  • +
  • PR #1957 - Fixing #1950

  • +
  • PR #1956 - Sort by key example

  • +
  • PR #1955 - Adding regression test for #1946: Hang in wait_all() in +distributed run

  • +
  • Issue #1954 - HPX releases should not use -Werror

  • +
  • PR #1953 - Adding performance analysis for AGAS cache

  • +
  • PR #1952 - Adapting test for explicit variadics to fail for gcc 4.6

  • +
  • PR #1951 - Fixing memory leak

  • +
  • Issue #1950 - Simplify external builds

  • +
  • PR #1949 - Fixing yet another lock that is being held during suspension

  • +
  • PR #1948 - Fixed container algorithms for Intel

  • +
  • PR #1947 - Adding workaround for tagged_tuple

  • +
  • Issue #1946 - Hang in wait_all() in distributed run

  • +
  • PR #1945 - Fixed container algorithm tests

  • +
  • Issue #1944 - assertion ‘p.destination_locality() == +hpx::get_locality()’ failed

  • +
  • PR #1943 - Fix a couple of compile errors with clang

  • +
  • PR #1942 - Making parcel coalescing functional

  • +
  • Issue #1941 - Re-enable parcel coalescing

  • +
  • PR #1940 - Touching up make_future

  • +
  • PR #1939 - Fixing problems in over-subscription management in the +resource manager

  • +
  • PR #1938 - Removing use of unified Boost.Thread header

  • +
  • PR #1937 - Cleaning up the use of Boost.Accumulator headers

  • +
  • PR #1936 - Making sure interval timer is started for aggregating +performance counters

  • +
  • PR #1935 - Tagged results

  • +
  • PR #1934 - Fix remote async with deferred launch policy

  • +
  • Issue #1933 - Floating point exception in +statistics_counter<boost::accumulators::tag::mean>::get_counter_value

  • +
  • PR #1932 - Removing superfluous includes of +boost/lockfree/detail/branch_hints.hpp

  • +
  • PR #1931 - fix compilation with clang 3.8.0

  • +
  • Issue #1930 - Missing online documentation for HPX 0.9.11

  • +
  • PR #1929 - LWG2485: get() should be overloaded for const tuple&&

  • +
  • PR #1928 - Revert “Using ninja for circle-ci builds”

  • +
  • PR #1927 - Using ninja for circle-ci builds

  • +
  • PR #1926 - Fixing serialization of std::array

  • +
  • Issue #1925 - Issues with static HPX libraries

  • +
  • Issue #1924 - Performance degrading over time

  • +
  • Issue #1923 - serialization of std::array appears broken in latest +commit

  • +
  • PR #1922 - Container algorithms

  • +
  • PR #1921 - Tons of smaller quality improvements

  • +
  • Issue #1920 - Seg fault in hpx::serialization::output_archive::add_gid +when running octotiger

  • +
  • Issue #1919 - Intel 15 compiler bug preventing HPX build

  • +
  • PR #1918 - Address sanitizer fixes

  • +
  • PR #1917 - Fixing compilation problems of parallel::sort with Intel +compilers

  • +
  • PR #1916 - Making sure code compiles if HPX_WITH_HWLOC=Off

  • +
  • Issue #1915 - max_cores undefined if HPX_WITH_HWLOC=Off

  • +
  • PR #1913 - Add utility member functions for partitioned_vector

  • +
  • PR #1912 - Adding support for invoking actions to dataflow

  • +
  • PR #1911 - Adding first batch of container algorithms

  • +
  • PR #1910 - Keep cmake_module_path

  • +
  • PR #1909 - Fix mpirun with pbs

  • +
  • PR #1908 - Changing parallel::sort to return the last iterator as +proposed by N4560

  • +
  • PR #1907 - Adding a minimum version for Open MPI

  • +
  • PR #1906 - Updates to the Release Procedure

  • +
  • PR #1905 - Fixing #1903

  • +
  • PR #1904 - Making sure std containers are cleared before serialization +loads data

  • +
  • Issue #1903 - When running octotiger, I get: assertion +'(*new_gids_)[gid].size() == 1' failed: HPX(assertion_failure)

  • +
  • Issue #1902 - Immediate crash when running hpx/octotiger with +_GLIBCXX_DEBUG defined.

  • +
  • PR #1901 - Making non-serializable classes non-serializable

  • +
  • Issue #1900 - Two possible issues with std::list serialization

  • +
  • PR #1899 - Fixing a problem with credit splitting as revealed by #1898

  • +
  • Issue #1898 - Accessing component from locality where it was not created +segfaults

  • +
  • PR #1897 - Changing parallel::sort to return the last iterator as +proposed by N4560

  • +
  • Issue #1896 - version 1.0?

  • +
  • Issue #1895 - Warning comment on numa_allocator is not very clear

  • +
  • PR #1894 - Add support for compilers that have thread_local

  • +
  • PR #1893 - Fixing 1890

  • +
  • PR #1892 - Adds typed future_type for executor_traits

  • +
  • PR #1891 - Fix wording in certain parallel algorithm docs

  • +
  • Issue #1890 - Invoking papi counters give segfault

  • +
  • PR #1889 - Fixing problems as reported by clang-check

  • +
  • PR #1888 - WIP parallel is_heap

  • +
  • PR #1887 - Fixed resetting performance counters related to idle-rate, +etc

  • +
  • Issue #1886 - Run hpx with qsub does not work

  • +
  • PR #1885 - Warning cleaning pass

  • +
  • PR #1884 - Add missing parallel algorithm header

  • +
  • PR #1883 - Add feature test for thread_local on Clang for TLS

  • +
  • PR #1882 - Fix some redundant qualifiers

  • +
  • Issue #1881 - Unable to compile Octotiger using HPX and Intel MPI on +SuperMIC

  • +
  • Issue #1880 - clang with libc++ on Linux needs TLS case

  • +
  • PR #1879 - Doc fixes for #1868

  • +
  • PR #1878 - Simplify functions

  • +
  • PR #1877 - Removing most usage of Boost.Config

  • +
  • PR #1876 - Add missing parallel algorithms to algorithm.hpp

  • +
  • PR #1875 - Simplify callables

  • +
  • PR #1874 - Address long standing FIXME on using std::unique_ptr with +incomplete types

  • +
  • PR #1873 - Fixing 1871

  • +
  • PR #1872 - Making sure PBS environment uses specified node list even if +no PBS_NODEFILE env is available

  • +
  • Issue #1871 - Fortran checks should be optional

  • +
  • PR #1870 - Touch local::mutex

  • +
  • PR #1869 - Documentation refactoring based off #1868

  • +
  • PR #1867 - Embrace static_assert

  • +
  • PR #1866 - Fix #1803 with documentation refactoring

  • +
  • PR #1865 - Setting OUTPUT_NAME as target properties

  • +
  • PR #1863 - Use SYSTEM for boost includes

  • +
  • PR #1862 - Minor cleanups

  • +
  • PR #1861 - Minor Corrections for Release

  • +
  • PR #1860 - Fixing hpx gdb script

  • +
  • Issue #1859 - reset_active_counters resets times and thread counts +before some of the counters are evaluated

  • +
  • PR #1858 - Release V0.9.11

  • +
  • PR #1857 - removing diskperf example from 9.11 release

  • +
  • PR #1856 - fix return in packaged_task_base::reset()

  • +
  • Issue #1842 - Install error: file INSTALL cannot find +libhpx_parcel_coalescing.so.0.9.11

  • +
  • PR #1839 - Adding fedora docs

  • +
  • PR #1824 - Changing version on master to V0.9.12

  • +
  • PR #1818 - Fixing #1748

  • +
  • Issue #1815 - seg fault in AGAS

  • +
  • Issue #1803 - wait_all documentation

  • +
  • Issue #1796 - Outdated documentation to be revised

  • +
  • Issue #1759 - glibc munmap_chunk or free(): invalid pointer on SuperMIC

  • +
  • Issue #1753 - HPX performance degrades with time since execution begins

  • +
  • Issue #1748 - All public HPX headers need to be self contained

  • +
  • PR #1719 - How to build HPX with Visual Studio

  • +
  • Issue #1684 - Race condition when using –hpx:connect?

  • +
  • PR #1658 - Add serialization for std::set (as there is for std::vector +and std::map)

  • +
  • PR #1641 - Generic client

  • +
  • Issue #1632 - heartbeat example fails on separate nodes

  • +
  • PR #1603 - Adds preferred namespace check to inspect tool

  • +
  • Issue #1559 - Extend inspect tool

  • +
  • Issue #1523 - Remote async with deferred launch policy never executes

  • +
  • Issue #1472 - Serialization issues

  • +
  • Issue #1457 - Implement N4392: C++ Latches and Barriers

  • +
  • PR #1444 - Enabling usage of moveonly types for component construction

  • +
  • Issue #1407 - The Intel 13 compiler has failing unit tests

  • +
  • Issue #1405 - Allow component constructors to take movable only types

  • +
  • Issue #1265 - Enable dataflow() to be usable with actions

  • +
  • Issue #1236 - NUMA aware allocators

  • +
  • Issue #802 - Fix Broken Examples

  • +
  • Issue #559 - Add hpx::migrate facility

  • +
  • Issue #449 - Make actions with template arguments usable and add +documentation

  • +
  • Issue #279 - Refactor addressing_service into a base class and two +derived classes

  • +
  • Issue #224 - Changing thread state metadata is not thread safe

  • +
  • Issue #55 - Uniform syntax for enums should be implemented

  • +
+
+
+
+
HPX V0.9.11 (Nov 11, 2015)#
+

Our main focus for this release was the design and development of a coherent set +of higher-level APIs exposing various types of parallelism to the application +programmer. We introduced the concepts of an executor, which can be used to +customize the where and when of execution of tasks in the context of +parallelizing codes. We extended all APIs related to managing parallel tasks to +support executors which gives the user the choce of either using one of the +predefined executor types or to provide its own, possibly application specific, +executor. We paid very close attention to align all of these changes with the +existing C++ Standards documents or with the ongoing proposals for +standardization.

+

This release is the first after our change to a new development policy. We +switched all development to be strictly performed on branches only, all direct +commits to our main branch (master) are prohibited. Any change has to go +through a peer review before it will be merged to master. As a result the +overall stability of our code base has significantly increased, the development +process itself has been simplified. This change manifests itself in a large +number of pull-requests which have been merged (please see below for a full list +of closed issues and pull-requests). All in all for this release, we closed +almost 100 issues and merged over 290 pull-requests. There have been over 1600 +commits to the master branch since the last release.

+
+
General changes#
+
    +
  • We are moving into the direction of unifying managed and simple components. As +such, the classes hpx::components::component and +hpx::components::component_base have been added which currently +just forward to the currently existing simple component facilities. The +examples have been converted to only use those two classes.

  • +
  • Added integration with the CircleCI hosted continuous integration +service. This gives us constant and immediate feedback on the health of our +master branch.

  • +
  • The compiler configuration subsystem in the build system has been +reimplemented. Instead of using Boost.Config we now use our own lightweight +set of cmake scripts to determine the available language and library features +supported by the used compiler.

  • +
  • The API for creating instances of components has been consolidated. All +component instances should be created using the hpx::new_ only. It +allows one to instantiate both, single component instances and multiple +component instances. The placement of the created components can be controlled +by special distribution policies. Please see the corresponding documentation +outlining the use of hpx::new_.

  • +
  • Introduced four new distribution policies which can be used with many API +functions which traditionally expected to be used with a locality id. The new +distribution policies are:

    + +
  • +
  • The new distribution policies can now be also used with hpx::async. This +change also deprecates hpx::async_colocated(id, ...) which now is replaced +by a distribution policy: hpx::async(hpx::colocated(id), ...).

  • +
  • The hpx::vector and hpx::unordered_map data structures can now be used +with the new distribution policies as well.

  • +
  • The parallel facility hpx::parallel::task_region has been renamed to +hpx::parallel::task_block based on the changes in the +corresponding standardization proposal N4411.

  • +
  • Added extensions to the parallel facility +hpx::parallel::task_block allowing to combine a task_block with +an execution policy. This implies a minor breaking change as the +hpx::parallel::task_block is now a template.

  • +
  • Added new LCOs: hpx::lcos::latch and hpx::lcos::local::latch which +semantically conform to the proposed std::latch (see N4399).

  • +
  • Added performance counters exposing data related to data transferred by +input/output (filesystem) operations (thanks to Maciej Brodowicz).

  • +
  • Added performance counters allowing to track the number of action invocations +(local and remote invocations).

  • +
  • Added new command line options –hpx:print-counter-at and +–hpx:reset-counters.

  • +
  • The hpx::vector component has been renamed to hpx::partitioned_vector +to make it explicit that the underlying memory is not contiguous.

  • +
  • Introduced a completely new and uniform higher-level parallelism API which is +based on executors. All existing parallelism APIs have been adapted to this. +We have added a large number of different executor types, such as a numa-aware +executor, a this-thread executor, etc.

  • +
  • Added support for the MingW toolchain on Windows (thanks to Eric Lemanissier).

  • +
  • HPX now includes support for APEX, (Autonomic Performance Environment for +eXascale). APEX is an instrumentation and software adaptation library that +provides an interface to TAU profiling / tracing as well as runtime adaptation +of HPX applications through policy definitions. For more information and +documentation, please see https://github.com/UO-OACISS/xpress-apex. To +enable APEX at configuration time, specify -DHPX_WITH_APEX=On. To also +include support for TAU profiling, specify -DHPX_WITH_TAU=On and specify +the -DTAU_ROOT, -DTAU_ARCH and -DTAU_OPTIONS cmake parameters.

  • +
  • We have implemented many more of the Using parallel algorithms. Please see +Issue #1141 for the list of all available parallel algorithms (thanks to +Daniel Bourgeois and John Biddiscombe for contributing their work).

  • +
+
+
+
Breaking changes#
+
    +
  • We are moving into the direction of unifying managed and simple components. In +order to stop exposing the old facilities, all examples have been converted to +use the new classes. The breaking change in this release is that performance +counters are now a hpx::components::component_base instead of +hpx::components::managed_component_base.

  • +
  • We removed the support for stackless threads. It turned out that there was no +performance benefit when using stackless threads. As such, we decided to clean +up our codebase. This feature was not documented.

  • +
  • The CMake project name has changed from ‘hpx’ to ‘HPX’ for consistency and +compatibility with naming conventions and other CMake projects. Generated +config files go into <prefix>/lib/cmake/HPX and not <prefix>/lib/cmake/hpx.

  • +
  • The macro HPX_REGISTER_MINIMAL_COMPONENT_FACTORY has been deprecated. +Please use HPX_REGISTER_COMPONENT. +instead. The old macro will be removed in the next release.

  • +
  • The obsolete distributing_factory and binpacking_factory components have been +removed. The corresponding functionality is now provided by the +hpx::new_ API function in conjunction with the +hpx::default_layout and hpx::binpacking distribution policies +(hpx::components::default_distribution_policy and +hpx::components::binpacking_distribution_policy)

  • +
  • The API function hpx::new_colocated has been deprecated. Please use the +consolidated API hpx::new_ in conjunction with the new +hpx::colocated distribution policy +(hpx::components::colocating_distribution_policy) instead. The +old API function will still be available for at least one release of HPX if +the configuration variable HPX_WITH_COLOCATED_BACKWARDS_COMPATIBILITY is +enabled.

  • +
  • The API function hpx::async_colocated has been deprecated. Please use the +consolidated API hpx::async in conjunction with the new hpx::colocated +distribution policy +(hpx::components::colocating_distribution_policy) instead. The +old API function will still be available for at least one release of HPX if +the configuration variable HPX_WITH_COLOCATED_BACKWARDS_COMPATIBILITY is +enabled.

  • +
  • The obsolete remote_object component has been removed.

  • +
  • Replaced the use of Boost.Serialization with our own solution. While the new +version is mostly compatible with Boost.Serialization, this change requires +some minor code modifications in user code. For more information, please see +the corresponding announcement on the +hpx-users@stellar.cct.lsu.edu mailing list.

  • +
  • The names used by cmake to influence various configuration options have been +unified. The new naming scheme relies on all configuration constants to start +with HPX_WITH_..., while the preprocessor constant which is used at build +time starts with HPX_HAVE_.... For instance, the former cmake command line +-DHPX_MALLOC=... now has to be specified a -DHPX_WITH_MALLOC=... and +will cause the preprocessor constant HPX_HAVE_MALLOC to be defined. The +actual name of the constant (i.e. MALLOC) has not changed. Please see the +corresponding documentation for more details (CMake options).

  • +
  • The get_gid() functions exposed by the component base classes +hpx::components::server::simple_component_base, +hpx::components::server::managed_component_base, and +hpx::components::server::fixed_component_base have been replaced by two +new functions: get_unmanaged_id() and get_id(). To enable the old +function name for backwards compatibility, use the cmake configuration option +HPX_WITH_COMPONENT_GET_GID_COMPATIBILITY=On.

  • +
  • All functions which were named get_gid() but were returning +hpx::id_type have been renamed to get_id(). To enable the old function +names for backwards compatibility, use the cmake configuration option +HPX_WITH_COMPONENT_GET_GID_COMPATIBILITY=On.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release.

+
    +
  • PR #1855 - Completely removing external/endian

  • +
  • PR #1854 - Don’t pollute CMAKE_CXX_FLAGS through find_package()

  • +
  • PR #1853 - Updating CMake configuration to get correct version of TAU +library

  • +
  • PR #1852 - Fixing Performance Problems with MPI Parcelport

  • +
  • PR #1851 - Fixing hpx_add_link_flag() and hpx_remove_link_flag()

  • +
  • PR #1850 - Fixing 1836, adding parallel::sort

  • +
  • PR #1849 - Fixing configuration for use of more than 64 cores

  • +
  • PR #1848 - Change default APEX version for release

  • +
  • PR #1847 - Fix client_base::then on release

  • +
  • PR #1846 - Removing broken lcos::local::channel from release

  • +
  • PR #1845 - Adding example demonstrating a possible safe-object +implementation to release

  • +
  • PR #1844 - Removing stubs from accumulator examples

  • +
  • PR #1843 - Don’t pollute CMAKE_CXX_FLAGS through find_package()

  • +
  • PR #1841 - Fixing client_base<>::then

  • +
  • PR #1840 - Adding example demonstrating a possible safe-object +implementation

  • +
  • PR #1838 - Update version rc1

  • +
  • PR #1837 - Removing broken lcos::local::channel

  • +
  • PR #1835 - Adding explicit move constructor and assignment operator to +hpx::lcos::promise

  • +
  • PR #1834 - Making hpx::lcos::promise move-only

  • +
  • PR #1833 - Adding fedora docs

  • +
  • Issue #1832 - hpx::lcos::promise<> must be move-only

  • +
  • PR #1831 - Fixing resource manager gcc5.2

  • +
  • PR #1830 - Fix intel13

  • +
  • PR #1829 - Unbreaking thread test

  • +
  • PR #1828 - Fixing #1620

  • +
  • PR #1827 - Fixing a memory management issue for the Parquet application

  • +
  • Issue #1826 - Memory management issue in hpx::lcos::promise

  • +
  • PR #1825 - Adding hpx::components::component and +hpx::components::component_base

  • +
  • PR #1823 - Adding git commit id to circleci build

  • +
  • PR #1822 - applying fixes suggested by clang 3.7

  • +
  • PR #1821 - Hyperlink fixes

  • +
  • PR #1820 - added parallel multi-locality sanity test

  • +
  • PR #1819 - Fixing #1667

  • +
  • Issue #1817 - Hyperlinks generated by inspect tool are wrong

  • +
  • PR #1816 - Support hpxrx

  • +
  • PR #1814 - Fix async to dispatch to the correct locality in all cases

  • +
  • Issue #1813 - async(launch::…, action(), …) always invokes locally

  • +
  • PR #1812 - fixed syntax error in CMakeLists.txt

  • +
  • PR #1811 - Agas optimizations

  • +
  • PR #1810 - drop superfluous typedefs

  • +
  • PR #1809 - Allow HPX to be used as an optional package in 3rd party code

  • +
  • PR #1808 - Fixing #1723

  • +
  • PR #1807 - Making sure resolve_localities does not hang during normal +operation

  • +
  • Issue #1806 - Spinlock no longer movable and deletes operator ‘=’, +breaks MiniGhost

  • +
  • Issue #1804 - register_with_basename causes hangs

  • +
  • PR #1801 - Enhanced the inspect tool to take user directly to the +problem with hyperlinks

  • +
  • Issue #1800 - Problems compiling application on smic

  • +
  • PR #1799 - Fixing cv exceptions

  • +
  • PR #1798 - Documentation refactoring & updating

  • +
  • PR #1797 - Updating the activeharmony CMake module

  • +
  • PR #1795 - Fixing cv

  • +
  • PR #1794 - Fix connect with hpx::runtime_mode_connect

  • +
  • PR #1793 - fix a wrong use of HPX_MAX_CPU_COUNT instead of +HPX_HAVE_MAX_CPU_COUNT

  • +
  • PR #1792 - Allow for default constructed parcel instances to be moved

  • +
  • PR #1791 - Fix connect with hpx::runtime_mode_connect

  • +
  • Issue #1790 - assertion action_.get() failed: HPX(assertion_failure) +when running Octotiger with pull request 1786

  • +
  • PR #1789 - Fixing discover_counter_types API function

  • +
  • Issue #1788 - connect with hpx::runtime_mode_connect

  • +
  • Issue #1787 - discover_counter_types not working

  • +
  • PR #1786 - Changing addressing_service to use std::unordered_map instead +of std::map

  • +
  • PR #1785 - Fix is_iterator for container algorithms

  • +
  • PR #1784 - Adding new command line options:

  • +
  • PR #1783 - Minor changes for APEX support

  • +
  • PR #1782 - Drop legacy forwarding action traits

  • +
  • PR #1781 - Attempt to resolve the race between cv::wait_xxx and +cv::notify_all

  • +
  • PR #1780 - Removing serialize_sequence

  • +
  • PR #1779 - Fixed #1501: hwloc configuration options are wrong for MIC

  • +
  • PR #1778 - Removing ability to enable/disable parcel handling

  • +
  • PR #1777 - Completely removing stackless threads

  • +
  • PR #1776 - Cleaning up util/plugin

  • +
  • PR #1775 - Agas fixes

  • +
  • PR #1774 - Action invocation count

  • +
  • PR #1773 - replaced MSVC variable with WIN32

  • +
  • PR #1772 - Fixing Problems in MPI parcelport and future serialization.

  • +
  • PR #1771 - Fixing intel 13 compiler errors related to variadic template +template parameters for lcos::when_ tests

  • +
  • PR #1770 - Forwarding decay to std::

  • +
  • PR #1769 - Add more characters with special regex meaning to the +existing patch

  • +
  • PR #1768 - Adding test for receive_buffer

  • +
  • PR #1767 - Making sure that uptime counter throws exception on any +attempt to be reset

  • +
  • PR #1766 - Cleaning up code related to throttling scheduler

  • +
  • PR #1765 - Restricting thread_data to creating only with +intrusive_pointers

  • +
  • PR #1764 - Fixing 1763

  • +
  • Issue #1763 - UB in thread_data::operator delete

  • +
  • PR #1762 - Making sure all serialization registries/factories are unique

  • +
  • PR #1761 - Fixed #1751: hpx::future::wait_for fails a simple test

  • +
  • PR #1758 - Fixing #1757

  • +
  • Issue #1757 - pinning not correct using –hpx:bind

  • +
  • Issue #1756 - compilation error with MinGW

  • +
  • PR #1755 - Making output serialization const-correct

  • +
  • Issue #1753 - HPX performance degrades with time since execution begins

  • +
  • Issue #1752 - Error in AGAS

  • +
  • Issue #1751 - hpx::future::wait_for fails a simple test

  • +
  • PR #1750 - Removing hpx_fwd.hpp includes

  • +
  • PR #1749 - Simplify result_of and friends

  • +
  • PR #1747 - Removed superfluous code from message_buffer.hpp

  • +
  • PR #1746 - Tuple dependencies

  • +
  • Issue #1745 - Broken when_some which takes iterators

  • +
  • PR #1744 - Refining archive interface

  • +
  • PR #1743 - Fixing when_all when only a single future is passed

  • +
  • PR #1742 - Config includes

  • +
  • PR #1741 - Os executors

  • +
  • Issue #1740 - hpx::promise has some problems

  • +
  • PR #1739 - Parallel composition with generic containers

  • +
  • Issue #1738 - After building program and successfully linking to a +version of hpx DHPX_DIR seems to be ignored

  • +
  • Issue #1737 - Uptime problems

  • +
  • PR #1736 - added convenience c-tor and begin()/end() to serialize_buffer

  • +
  • PR #1735 - Config includes

  • +
  • PR #1734 - Fixed #1688: Add timer counters for tfunc_total and +exec_total

  • +
  • Issue #1733 - Add unit test for hpx/lcos/local/receive_buffer.hpp

  • +
  • PR #1732 - Renaming get_os_thread_count

  • +
  • PR #1731 - Basename registration

  • +
  • Issue #1730 - Use after move of thread_init_data

  • +
  • PR #1729 - Rewriting channel based on new gate component

  • +
  • PR #1728 - Fixing #1722

  • +
  • PR #1727 - Fixing compile problems with apply_colocated

  • +
  • PR #1726 - Apex integration

  • +
  • PR #1725 - fixed test timeouts

  • +
  • PR #1724 - Renaming vector

  • +
  • Issue #1723 - Drop support for intel compilers and gcc 4.4. based +standard libs

  • +
  • Issue #1722 - Add support for detecting non-ready futures before +serialization

  • +
  • PR #1721 - Unifying parallel executors, initializing from launch policy

  • +
  • PR #1720 - dropped superfluous typedef

  • +
  • Issue #1718 - Windows 10 x64, VS 2015 - Unknown CMake command +“add_hpx_pseudo_target”.

  • +
  • PR #1717 - Timed executor traits for thread-executors

  • +
  • PR #1716 - serialization of arrays didn’t work with non-pod types. fixed

  • +
  • PR #1715 - List serialization

  • +
  • PR #1714 - changing misspellings

  • +
  • PR #1713 - Fixed distribution policy executors

  • +
  • PR #1712 - Moving library detection to be executed after feature tests

  • +
  • PR #1711 - Simplify parcel

  • +
  • PR #1710 - Compile only tests

  • +
  • PR #1709 - Implemented timed executors

  • +
  • PR #1708 - Implement parallel::executor_traits for thread-executors

  • +
  • PR #1707 - Various fixes to threads::executors to make custom schedulers +work

  • +
  • PR #1706 - Command line option –hpx:cores does not work as expected

  • +
  • Issue #1705 - command line option –hpx:cores does not work as expected

  • +
  • PR #1704 - vector deserialization is speeded up a little

  • +
  • PR #1703 - Fixing shared_mutes

  • +
  • Issue #1702 - Shared_mutex does not compile with no_mutex cond_var

  • +
  • PR #1701 - Add distribution_policy_executor

  • +
  • PR #1700 - Executor parameters

  • +
  • PR #1699 - Readers writer lock

  • +
  • PR #1698 - Remove leftovers

  • +
  • PR #1697 - Fixing held locks

  • +
  • PR #1696 - Modified Scan Partitioner for Algorithms

  • +
  • PR #1695 - This thread executors

  • +
  • PR #1694 - Fixed #1688: Add timer counters for tfunc_total and +exec_total

  • +
  • PR #1693 - Fix #1691: is_executor template specification fails for +inherited executors

  • +
  • PR #1692 - Fixed #1662: Possible exception source in +coalescing_message_handler

  • +
  • Issue #1691 - is_executor template specification fails for inherited +executors

  • +
  • PR #1690 - added macro for non-intrusive serialization of classes +without a default c-tor

  • +
  • PR #1689 - Replace value_or_error with custom storage, unify future_data +state

  • +
  • Issue #1688 - Add timer counters for tfunc_total and exec_total

  • +
  • PR #1687 - Fixed interval timer

  • +
  • PR #1686 - Fixing cmake warnings about not existing pseudo target +dependencies

  • +
  • PR #1685 - Converting partitioners to use bulk async execute

  • +
  • PR #1683 - Adds a tool for inspect that checks for character limits

  • +
  • PR #1682 - Change project name to (uppercase) HPX

  • +
  • PR #1681 - Counter shortnames

  • +
  • PR #1680 - Extended Non-intrusive Serialization to Ease Usage for +Library Developers

  • +
  • PR #1679 - Working on 1544: More executor changes

  • +
  • PR #1678 - Transpose fixes

  • +
  • PR #1677 - Improve Boost compatibility check

  • +
  • PR #1676 - 1d stencil fix

  • +
  • Issue #1675 - hpx project name is not HPX

  • +
  • PR #1674 - Fixing the MPI parcelport

  • +
  • PR #1673 - added move semantics to map/vector deserialization

  • +
  • PR #1672 - Vs2015 await

  • +
  • PR #1671 - Adapt transform for #1668

  • +
  • PR #1670 - Started to work on #1668

  • +
  • PR #1669 - Add this_thread_executors

  • +
  • Issue #1667 - Apple build instructions in docs are out of date

  • +
  • PR #1666 - Apex integration

  • +
  • PR #1665 - Fixes an error with the whitespace check that showed the +incorrect location of the error

  • +
  • Issue #1664 - Inspect tool found incorrect endline whitespace

  • +
  • PR #1663 - Improve use of locks

  • +
  • Issue #1662 - Possible exception source in coalescing_message_handler

  • +
  • PR #1661 - Added support for 128bit number serialization

  • +
  • PR #1660 - Serialization 128bits

  • +
  • PR #1659 - Implemented inner_product and adjacent_diff algos

  • +
  • PR #1658 - Add serialization for std::set (as there is for std::vector +and std::map)

  • +
  • PR #1657 - Use of shared_ptr in io_service_pool changed to unique_ptr

  • +
  • Issue #1656 - 1d_stencil codes all have wrong factor

  • +
  • PR #1654 - When using runtime_mode_connect, find the correct localhost +public ip address

  • +
  • PR #1653 - Fixing 1617

  • +
  • PR #1652 - Remove traits::action_may_require_id_splitting

  • +
  • PR #1651 - Fixed performance counters related to AGAS cache timings

  • +
  • PR #1650 - Remove leftovers of traits::type_size

  • +
  • PR #1649 - Shorten target names on Windows to shorten used path names

  • +
  • PR #1648 - Fixing problems introduced by merging #1623 for older +compilers

  • +
  • PR #1647 - Simplify running automatic builds on Windows

  • +
  • Issue #1646 - Cache insert and update performance counters are broken

  • +
  • Issue #1644 - Remove leftovers of traits::type_size

  • +
  • Issue #1643 - Remove traits::action_may_require_id_splitting

  • +
  • PR #1642 - Adds spell checker to the inspect tool for qbk and doxygen +comments

  • +
  • PR #1640 - First step towards fixing 688

  • +
  • PR #1639 - Re-apply remaining changes from limit_dataflow_recursion +branch

  • +
  • PR #1638 - This fixes possible deadlock in the test +ignore_while_locked_1485

  • +
  • PR #1637 - Fixing hpx::wait_all() invoked with two vector<future<T>>

  • +
  • PR #1636 - Partially re-apply changes from limit_dataflow_recursion +branch

  • +
  • PR #1635 - Adding missing test for #1572

  • +
  • PR #1634 - Revert “Limit recursion-depth in dataflow to a configurable +constant”

  • +
  • PR #1633 - Add command line option to ignore batch environment

  • +
  • PR #1631 - hpx::lcos::queue exhibits strange behavior

  • +
  • PR #1630 - Fixed endline_whitespace_check.cpp to detect lines with only +whitespace

  • +
  • Issue #1629 - Inspect trailing whitespace checker problem

  • +
  • PR #1628 - Removed meaningless const qualifiers. Minor icpc fix.

  • +
  • PR #1627 - Fixing the queue LCO and add example demonstrating its use

  • +
  • PR #1626 - Deprecating get_gid(), add get_id() and get_unmanaged_id()

  • +
  • PR #1625 - Allowing to specify whether to send credits along with +message

  • +
  • Issue #1624 - Lifetime issue

  • +
  • Issue #1623 - hpx::wait_all() invoked with two vector<future<T>> fails

  • +
  • PR #1622 - Executor partitioners

  • +
  • PR #1621 - Clean up coroutines implementation

  • +
  • Issue #1620 - Revert #1535

  • +
  • PR #1619 - Fix result type calculation for hpx::make_continuation

  • +
  • PR #1618 - Fixing RDTSC on Xeon/Phi

  • +
  • Issue #1617 - hpx cmake not working when run as a subproject

  • +
  • Issue #1616 - cmake problem resulting in RDTSC not working correctly for +Xeon Phi creates very strange results for duration counters

  • +
  • Issue #1615 - hpx::make_continuation requires input and output to be the +same

  • +
  • PR #1614 - Fixed remove copy test

  • +
  • Issue #1613 - Dataflow causes stack overflow

  • +
  • PR #1612 - Modified foreach partitioner to use bulk execute

  • +
  • PR #1611 - Limit recursion-depth in dataflow to a configurable constant

  • +
  • PR #1610 - Increase timeout for CircleCI

  • +
  • PR #1609 - Refactoring thread manager, mainly extracting thread pool

  • +
  • PR #1608 - Fixed running multiple localities without localities +parameter

  • +
  • PR #1607 - More algorithm fixes to adjacentfind

  • +
  • Issue #1606 - Running without localities parameter binds to bogus port +range

  • +
  • Issue #1605 - Too many serializations

  • +
  • PR #1604 - Changes the HPX image into a hyperlink

  • +
  • PR #1601 - Fixing problems with remove_copy algorithm tests

  • +
  • PR #1600 - Actions with ids cleanup

  • +
  • PR #1599 - Duplicate binding of global ids should fail

  • +
  • PR #1598 - Fixing array access

  • +
  • PR #1597 - Improved the reliability of connecting/disconnecting +localities

  • +
  • Issue #1596 - Duplicate id binding should fail

  • +
  • PR #1595 - Fixing more cmake config constants

  • +
  • PR #1594 - Fixing preprocessor constant used to enable C++11 chrono

  • +
  • PR #1593 - Adding operator|() for hpx::launch

  • +
  • Issue #1592 - Error (typo) in the docs

  • +
  • Issue #1590 - CMake fails when CMAKE_BINARY_DIR contains ‘+’.

  • +
  • Issue #1589 - Disconnecting a locality results in segfault using +heartbeat example

  • +
  • PR #1588 - Fix doc string for config option HPX_WITH_EXAMPLES

  • +
  • PR #1586 - Fixing 1493

  • +
  • PR #1585 - Additional Check for Inspect Tool to detect Endline +Whitespace

  • +
  • Issue #1584 - Clean up coroutines implementation

  • +
  • PR #1583 - Adding a check for end line whitespace

  • +
  • PR #1582 - Attempt to fix assert firing after scheduling loop was exited

  • +
  • PR #1581 - Fixed adjacentfind_binary test

  • +
  • PR #1580 - Prevent some of the internal cmake lists from growing +indefinitely

  • +
  • PR #1579 - Removing type_size trait, replacing it with special archive +type

  • +
  • Issue #1578 - Remove demangle_helper

  • +
  • PR #1577 - Get ptr problems

  • +
  • Issue #1576 - Refactor async, dataflow, and future::then

  • +
  • PR #1575 - Fixing tests for parallel rotate

  • +
  • PR #1574 - Cleaning up schedulers

  • +
  • PR #1573 - Fixing thread pool executor

  • +
  • PR #1572 - Fixing number of configured localities

  • +
  • PR #1571 - Reimplement decay

  • +
  • PR #1570 - Refactoring async, apply, and dataflow APIs

  • +
  • PR #1569 - Changed range for mach-o library lookup

  • +
  • PR #1568 - Mark decltype support as required

  • +
  • PR #1567 - Removed const from algorithms

  • +
  • Issue #1566 - CMAKE Configuration Test Failures for clang 3.5 on debian

  • +
  • PR #1565 - Dylib support

  • +
  • PR #1564 - Converted partitioners and some algorithms to use executors

  • +
  • PR #1563 - Fix several #includes for Boost.Preprocessor

  • +
  • PR #1562 - Adding configuration option disabling/enabling all message +handlers

  • +
  • PR #1561 - Removed all occurrences of boost::move replacing it with +std::move

  • +
  • Issue #1560 - Leftover HPX_REGISTER_ACTION_DECLARATION_2

  • +
  • PR #1558 - Revisit async/apply SFINAE conditions

  • +
  • PR #1557 - Removing type_size trait, replacing it with special archive +type

  • +
  • PR #1556 - Executor algorithms

  • +
  • PR #1555 - Remove the necessity to specify archive flags on the +receiving end

  • +
  • PR #1554 - Removing obsolete Boost.Serialization macros

  • +
  • PR #1553 - Properly fix HPX_DEFINE_*_ACTION macros

  • +
  • PR #1552 - Fixed algorithms relying on copy_if implementation

  • +
  • PR #1551 - Pxfs - Modifying FindOrangeFS.cmake based on OrangeFS 2.9.X

  • +
  • Issue #1550 - Passing plain identifier inside HPX_DEFINE_PLAIN_ACTION_1

  • +
  • PR #1549 - Fixing intel14/libstdc++4.4

  • +
  • PR #1548 - Moving raw_ptr to detail namespace

  • +
  • PR #1547 - Adding support for executors to future.then

  • +
  • PR #1546 - Executor traits result types

  • +
  • PR #1545 - Integrate executors with dataflow

  • +
  • PR #1543 - Fix potential zero-copy for +primarynamespace::bulk_service_async et.al.

  • +
  • PR #1542 - Merging HPX0.9.10 into pxfs branch

  • +
  • PR #1541 - Removed stale cmake tests, unused since the great cmake +refactoring

  • +
  • PR #1540 - Fix idle-rate on platforms without TSC

  • +
  • PR #1539 - Reporting situation if zero-copy-serialization was performed +by a parcel generated from a plain apply/async

  • +
  • PR #1538 - Changed return type of bulk executors and added test

  • +
  • Issue #1537 - Incorrect cpuid config tests

  • +
  • PR #1536 - Changed return type of bulk executors and added test

  • +
  • PR #1535 - Make sure promise::get_gid() can be called more than once

  • +
  • PR #1534 - Fixed async_callback with bound callback

  • +
  • PR #1533 - Updated the link in the documentation to a publically- +accessible URL

  • +
  • PR #1532 - Make sure sync primitives are not copyable nor movable

  • +
  • PR #1531 - Fix unwrapped issue with future ranges of void type

  • +
  • PR #1530 - Serialization complex

  • +
  • Issue #1528 - Unwrapped issue with future<void>

  • +
  • Issue #1527 - HPX does not build with Boost 1.58.0

  • +
  • PR #1526 - Added support for boost.multi_array serialization

  • +
  • PR #1525 - Properly handle deferred futures, fixes #1506

  • +
  • PR #1524 - Making sure invalid action argument types generate clear +error message

  • +
  • Issue #1522 - Need serialization support for boost multi array

  • +
  • Issue #1521 - Remote async and zero-copy serialization optimizations +don’t play well together

  • +
  • PR #1520 - Fixing UB whil registering polymorphic classes for +serialization

  • +
  • PR #1519 - Making detail::condition_variable safe to use

  • +
  • PR #1518 - Fix when_some bug missing indices in its result

  • +
  • Issue #1517 - Typo may affect CMake build system tests

  • +
  • PR #1516 - Fixing Posix context

  • +
  • PR #1515 - Fixing Posix context

  • +
  • PR #1514 - Correct problems with loading dynamic components

  • +
  • PR #1513 - Fixing intel glibc4 4

  • +
  • Issue #1508 - memory and papi counters do not work

  • +
  • Issue #1507 - Unrecognized Command Line Option Error causing exit status +0

  • +
  • Issue #1506 - Properly handle deferred futures

  • +
  • PR #1505 - Adding #include - would not compile without this

  • +
  • Issue #1502 - boost::filesystem::exists throws unexpected exception

  • +
  • Issue #1501 - hwloc configuration options are wrong for MIC

  • +
  • PR #1504 - Making sure boost::filesystem::exists() does not throw

  • +
  • PR #1500 - Exit application on --hpx:version/-v and +--hpx:info

  • +
  • PR #1498 - Extended task block

  • +
  • PR #1497 - Unique ptr serialization

  • +
  • PR #1496 - Unique ptr serialization (closed)

  • +
  • PR #1495 - Switching circleci build type to debug

  • +
  • Issue #1494 - --hpx:version/-v does not exit after printing +version information

  • +
  • Issue #1493 - add an hpx_ prefix to libraries and components to +avoid name conflicts

  • +
  • Issue #1492 - Define and ensure limitations for arguments to async/apply

  • +
  • PR #1489 - Enable idle rate counter on demand

  • +
  • PR #1488 - Made sure detail::condition_variable can be safely +destroyed

  • +
  • PR #1487 - Introduced default (main) template implementation for +ignore_while_checking

  • +
  • PR #1486 - Add HPX inspect tool

  • +
  • Issue #1485 - ignore_while_locked doesn’t support all Lockable types

  • +
  • PR #1484 - Docker image generation

  • +
  • PR #1483 - Move external endian library into HPX

  • +
  • PR #1482 - Actions with integer type ids

  • +
  • Issue #1481 - Sync primitives safe destruction

  • +
  • Issue #1480 - Move external/boost/endian into hpx/util

  • +
  • Issue #1478 - Boost inspect violations

  • +
  • PR #1479 - Adds serialization for arrays; some further/minor fixes

  • +
  • PR #1477 - Fixing problems with the Intel compiler using a GCC 4.4 std +library

  • +
  • PR #1476 - Adding hpx::lcos::latch and hpx::lcos::local::latch

  • +
  • Issue #1475 - Boost inspect violations

  • +
  • PR #1473 - Fixing action move tests

  • +
  • Issue #1471 - Sync primitives should not be movable

  • +
  • PR #1470 - Removing hpx::util::polymorphic_factory

  • +
  • PR #1468 - Fixed container creation

  • +
  • Issue #1467 - HPX application fail during finalization

  • +
  • Issue #1466 - HPX doesn’t pick up Torque’s nodefile on SuperMIC

  • +
  • Issue #1464 - HPX option for pre and post bootstrap performance counters

  • +
  • PR #1463 - Replacing async_colocated(id, ...) with +async(colocated(id), ...)

  • +
  • PR #1462 - Consolidated task_region with N4411

  • +
  • PR #1461 - Consolidate inconsistent CMake option names

  • +
  • Issue #1460 - Which malloc is actually used? or at least which one is +HPX built with

  • +
  • Issue #1459 - Make cmake configure step fail explicitly if compiler +version is not supported

  • +
  • Issue #1458 - Update parallel::task_region with N4411

  • +
  • PR #1456 - Consolidating new_<>()

  • +
  • Issue #1455 - Replace async_colocated(id, ...) with +async(colocated(id), ...)

  • +
  • PR #1454 - Removed harmful std::moves from return statements

  • +
  • PR #1453 - Use range-based for-loop instead of Boost.Foreach

  • +
  • PR #1452 - C++ feature tests

  • +
  • PR #1451 - When serializing, pass archive flags to traits::get_type_size

  • +
  • Issue #1450 - traits:get_type_size needs archive flags to enable +zero_copy optimizations

  • +
  • Issue #1449 - “couldn’t create performance counter” - AGAS

  • +
  • Issue #1448 - Replace distributing factories with new_<T[]>(...)

  • +
  • PR #1447 - Removing obsolete remote_object component

  • +
  • PR #1446 - Hpx serialization

  • +
  • PR #1445 - Replacing travis with circleci

  • +
  • PR #1443 - Always stripping HPX command line arguments before executing +start function

  • +
  • PR #1442 - Adding –hpx:bind=none to disable thread affinities

  • +
  • Issue #1439 - Libraries get linked in multiple times, RPATH is not +properly set

  • +
  • PR #1438 - Removed superfluous typedefs

  • +
  • Issue #1437 - hpx::init() should strip HPX-related flags from argv

  • +
  • Issue #1436 - Add strong scaling option to htts

  • +
  • PR #1435 - Adding async_cb, async_continue_cb, and +async_colocated_cb

  • +
  • PR #1434 - Added missing install rule, removed some dead CMake code

  • +
  • PR #1433 - Add GitExternal and SubProject cmake scripts from +eyescale/cmake repo

  • +
  • Issue #1432 - Add command line flag to disable thread pinning

  • +
  • PR #1431 - Fix #1423

  • +
  • Issue #1430 - Inconsistent CMake option names

  • +
  • Issue #1429 - Configure setting HPX_HAVE_PARCELPORT_MPI is ignored

  • +
  • PR #1428 - Fixes #1419 (closed)

  • +
  • PR #1427 - Adding stencil_iterator and transform_iterator

  • +
  • PR #1426 - Fixes #1419

  • +
  • PR #1425 - During serialization memory allocation should honour +allocator chunk size

  • +
  • Issue #1424 - chunk allocation during serialization does not use memory +pool/allocator chunk size

  • +
  • Issue #1423 - Remove HPX_STD_UNIQUE_PTR

  • +
  • Issue #1422 - hpx:threads=all allocates too many os threads

  • +
  • PR #1420 - added .travis.yml

  • +
  • Issue #1419 - Unify enums: hpx::runtime::state and hpx::state

  • +
  • PR #1416 - Adding travis builder

  • +
  • Issue #1414 - Correct directory for dispatch_gcc46.hpp iteration

  • +
  • Issue #1410 - Set operation algorithms

  • +
  • Issue #1389 - Parallel algorithms relying on scan partitioner break for +small number of elements

  • +
  • Issue #1325 - Exceptions thrown during parcel handling are not handled +correctly

  • +
  • Issue #1315 - Errors while running performance tests

  • +
  • Issue #1309 - hpx::vector partitions are not easily extendable by +applications

  • +
  • PR #1300 - Added serialization/de-serialization to examples.tuplespace

  • +
  • Issue #1251 - hpx::threads::get_thread_count doesn’t consider pending +threads

  • +
  • Issue #1008 - Decrease in application performance overtime; occasional +spikes of major slowdown

  • +
  • Issue #1001 - Zero copy serialization raises assert

  • +
  • Issue #721 - Make HPX usable for Xeon Phi

  • +
  • Issue #524 - Extend scheduler to support threads which can’t be stolen

  • +
+
+
+
+
HPX V0.9.10 (Mar 24, 2015)#
+
+
General changes#
+

This is the 12th official release of HPX. It coincides with the 7th +anniversary of the first commit to our source code repository. Since then, we +have seen over 12300 commits amounting to more than 220000 lines of C++ code.

+

The major focus of this release was to improve the reliability of large scale +runs. We believe to have achieved this goal as we now can reliably run HPX +applications on up to ~24k cores. We have also shown that HPX can be used with +success for symmetric runs (applications using both, host cores and Intel +Xeon/Phi coprocessors). This is a huge step forward in terms of the usability of +HPX. The main focus of this work involved isolating the causes of the +segmentation faults at start up and shut down. Many of these issues were +discovered to be the result of the suspension of threads which hold locks.

+

A very important improvement introduced with this release is the refactoring of +the code representing our parcel-port implementation. Parcel- ports can now be +implemented by 3rd parties as independent plugins which are dynamically loaded +at runtime (static linking of parcel-ports is also supported). This refactoring +also includes a massive improvement of the performance of our existing +parcel-ports. We were able to significantly reduce the networking latencies and +to improve the available networking bandwidth. Please note that in this release +we disabled the ibverbs and ipc parcel ports as those have not been ported to +the new plugin system yet (see Issue #839).

+

Another corner stone of this release is our work towards a complete +implementation of __cpp11_n4104__ (Working Draft, Technical Specification for +C++ Extensions for Parallelism). This document defines a set of parallel +algorithms to be added to the C++ standard library. We now have implemented +about 75% of all specified parallel algorithms (see [link +hpx.manual.parallel.parallel_algorithms Parallel Algorithms] for more details). +We also implemented some extensions to __cpp11_n4104__ allowing to invoke all of +the algorithms asynchronously.

+

This release adds a first implementation of hpx::vector which is a +distributed data structure closely aligned to the functionality of +std::vector. The difference is that hpx::vector stores the data in +partitions where the partitions can be distributed over different localities. We +started to work on allowing to use the parallel algorithms with hpx::vector. +At this point we have implemented only a few of the parallel algorithms to +support distributed data structures (like hpx::vector) for testing purposes +(see Issue #1338 for a documentation of our progress).

+
+
+
Breaking changes#
+

With this release we put a lot of effort into changing the code base to be more +compatible to C++11. These changes have caused the following issues for backward +compatibility:

+
    +
  • Move to Variadics- All of the API now uses variadic templates. However, this +change required to modify the argument sequence for some of the exiting API +functions (hpx::async_continue, hpx::apply_continue, +hpx::when_each, hpx::wait_each, synchronous invocation +of actions).

  • +
  • Changes to Macros- We also removed the macros HPX_STD_FUNCTION and +HPX_STD_TUPLE. This shouldn’t affect any user code as we replaced +HPX_STD_FUNCTION with hpx::util::function_nonser which was the default +expansion used for this macro. All HPX API functions which expect a +hpx::util::function_nonser (or a hpx::util::unique_function_nonser) +can now be transparently called with a compatible std::function instead. +Similarly, HPX_STD_TUPLE was replaced by its default expansion as well: +hpx::util::tuple.

  • +
  • Changes to hpx::unique_future- hpx::unique_future, which was +deprecated in the previous release for hpx::future is now +completely removed from HPX. This completes the transition to a completely +standards conforming implementation of hpx::future.

  • +
  • Changes to Supported Compilers. Finally, in order to utilize more C++11 +semantics, we have officially dropped support for GCC 4.4 and MSVC 2012. +Please see our Prerequisites page for more details.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release.

+
    +
  • Issue #1402 - Internal shared_future serialization copies

  • +
  • Issue #1399 - Build takes unusually long time…

  • +
  • Issue #1398 - Tests using the scan partitioner are broken on at least +gcc 4.7 and intel compiler

  • +
  • Issue #1397 - Completely remove hpx::unique_future

  • +
  • Issue #1396 - Parallel scan algorithms with different initial values

  • +
  • Issue #1395 - Race Condition - 1d_stencil_8 - SuperMIC

  • +
  • Issue #1394 - “suspending thread while at least one lock is being +held” - 1d_stencil_8 - SuperMIC

  • +
  • Issue #1393 - SEGFAULT in 1d_stencil_8 on SuperMIC

  • +
  • Issue #1392 - Fixing #1168

  • +
  • Issue #1391 - Parallel Algorithms for scan partitioner for small number +of elements

  • +
  • Issue #1387 - Failure with more than 4 localities

  • +
  • Issue #1386 - Dispatching unhandled exceptions to outer user code

  • +
  • Issue #1385 - Adding Copy algorithms, fixing parallel::copy_if

  • +
  • Issue #1384 - Fixing 1325

  • +
  • Issue #1383 - Fixed #504: Refactor Dataflow LCO to work with futures, +this removes the dataflow component as it is obsolete

  • +
  • Issue #1382 - is_sorted, is_sorted_until and is_partitioned +algorithms

  • +
  • Issue #1381 - fix for CMake versions prior to 3.1

  • +
  • Issue #1380 - resolved warning in CMake 3.1 and newer

  • +
  • Issue #1379 - Compilation error with papi

  • +
  • Issue #1378 - Towards safer migration

  • +
  • Issue #1377 - HPXConfig.cmake should include TCMALLOC_LIBRARY and +TCMALLOC_INCLUDE_DIR

  • +
  • Issue #1376 - Warning on uninitialized member

  • +
  • Issue #1375 - Fixing 1163

  • +
  • Issue #1374 - Fixing the MSVC 12 release builder

  • +
  • Issue #1373 - Modifying parallel search algorithm for zero length +searches

  • +
  • Issue #1372 - Modifying parallel search algorithm for zero length +searches

  • +
  • Issue #1371 - Avoid holding a lock during agas::incref while doing a +credit split

  • +
  • Issue #1370 - --hpx:bind throws unexpected error

  • +
  • Issue #1369 - Getting rid of (void) in loops

  • +
  • Issue #1368 - Variadic templates support for tuple

  • +
  • Issue #1367 - One last batch of variadic templates support

  • +
  • Issue #1366 - Fixing symbolic namespace hang

  • +
  • Issue #1365 - More held locks

  • +
  • Issue #1364 - Add counters 1363

  • +
  • Issue #1363 - Add thread overhead counters

  • +
  • Issue #1362 - Std config removal

  • +
  • Issue #1361 - Parcelport plugins

  • +
  • Issue #1360 - Detuplify transfer_action

  • +
  • Issue #1359 - Removed obsolete checks

  • +
  • Issue #1358 - Fixing 1352

  • +
  • Issue #1357 - Variadic templates support for runtime_support and +components

  • +
  • Issue #1356 - fixed coordinate test for intel13

  • +
  • Issue #1355 - fixed coordinate.hpp

  • +
  • Issue #1354 - Lexicographical Compare completed

  • +
  • Issue #1353 - HPX should set Boost_ADDITIONAL_VERSIONS flags

  • +
  • Issue #1352 - Error: Cannot find action ‘’ in type registry: +HPX(bad_action_code)

  • +
  • Issue #1351 - Variadic templates support for appliers

  • +
  • Issue #1350 - Actions simplification

  • +
  • Issue #1349 - Variadic when and wait functions

  • +
  • Issue #1348 - Added hpx_init header to test files

  • +
  • Issue #1347 - Another batch of variadic templates support

  • +
  • Issue #1346 - Segmented copy

  • +
  • Issue #1345 - Attempting to fix hangs during shutdown

  • +
  • Issue #1344 - Std config removal

  • +
  • Issue #1343 - Removing various distribution policies for hpx::vector

  • +
  • Issue #1342 - Inclusive scan

  • +
  • Issue #1341 - Exclusive scan

  • +
  • Issue #1340 - Adding parallel::count for distributed data +structures, adding tests

  • +
  • Issue #1339 - Update argument order for transform_reduce

  • +
  • Issue #1337 - Fix dataflow to handle properly ranges of futures

  • +
  • Issue #1336 - dataflow needs to hold onto futures passed to it

  • +
  • Issue #1335 - Fails to compile with msvc14

  • +
  • Issue #1334 - Examples build problem

  • +
  • Issue #1333 - Distributed transform reduce

  • +
  • Issue #1332 - Variadic templates support for actions

  • +
  • Issue #1331 - Some ambiguous calls of map::erase have been prevented by +adding additional check in locality constructor.

  • +
  • Issue #1330 - Defining Plain Actions does not work as described in the +documentation

  • +
  • Issue #1329 - Distributed vector cleanup

  • +
  • Issue #1328 - Sync docs and comments with code in hello_world example

  • +
  • Issue #1327 - Typos in docs

  • +
  • Issue #1326 - Documentation and code diverged in Fibonacci tutorial

  • +
  • Issue #1325 - Exceptions thrown during parcel handling are not handled +correctly

  • +
  • Issue #1324 - fixed bandwidth calculation

  • +
  • Issue #1323 - mmap() failed to allocate thread stack due to insufficient +resources

  • +
  • Issue #1322 - HPX fails to build aa182cf

  • +
  • Issue #1321 - Limiting size of outgoing messages while coalescing +parcels

  • +
  • Issue #1320 - passing a future with launch::deferred in remote function +call causes hang

  • +
  • Issue #1319 - An exception when tries to specify number high priority +threads with abp-priority

  • +
  • Issue #1318 - Unable to run program with abp-priority and +numa-sensitivity enabled

  • +
  • Issue #1317 - N4071 Search/Search_n finished, minor changes

  • +
  • Issue #1316 - Add config option to make -Ihpx.run_hpx_main!=1 the +default

  • +
  • Issue #1314 - Variadic support for async and apply

  • +
  • Issue #1313 - Adjust when_any/some to the latest proposed interfaces

  • +
  • Issue #1312 - Fixing #857: hpx::naming::locality leaks parcelport +specific information into the public interface

  • +
  • Issue #1311 - Distributed get’er/set’er_values for distributed vector

  • +
  • Issue #1310 - Crashing in +hpx::parcelset::policies::mpi::connection_handler::handle_messages() on +SuperMIC

  • +
  • Issue #1308 - Unable to execute an application with –hpx:threads

  • +
  • Issue #1307 - merge_graph linking issue

  • +
  • Issue #1306 - First batch of variadic templates support

  • +
  • Issue #1305 - Create a compiler wrapper

  • +
  • Issue #1304 - Provide a compiler wrapper for hpx

  • +
  • Issue #1303 - Drop support for GCC44

  • +
  • Issue #1302 - Fixing #1297

  • +
  • Issue #1301 - Compilation error when tried to use boost range iterators +with wait_all

  • +
  • Issue #1298 - Distributed vector

  • +
  • Issue #1297 - Unable to invoke component actions recursively

  • +
  • Issue #1294 - HDF5 build error

  • +
  • Issue #1275 - The parcelport implementation is non-optimal

  • +
  • Issue #1267 - Added classes and unit tests for local_file, orangefs_file +and pxfs_file

  • +
  • Issue #1264 - Error “assertion ‘!m_fun’ failed” randomly occurs when +using TCP

  • +
  • Issue #1254 - thread binding seems to not work properly

  • +
  • Issue #1220 - parallel::copy_if is broken

  • +
  • Issue #1217 - Find a better way of fixing the issue patched by #1216

  • +
  • Issue #1168 - Starting HPX on Cray machines using aprun isn’t working +correctly

  • +
  • Issue #1085 - Replace startup and shutdown barriers with broadcasts

  • +
  • Issue #981 - With SLURM, –hpx:threads=8 should not be necessary

  • +
  • Issue #857 - hpx::naming::locality leaks parcelport specific information +into the public interface

  • +
  • Issue #850 - “flush” not documented

  • +
  • Issue #763 - Create buildbot instance that uses std::bind as +HPX_STD_BIND

  • +
  • Issue #680 - Convert parcel ports into a plugin system

  • +
  • Issue #582 - Make exception thrown from HPX threads available from +hpx::init

  • +
  • Issue #504 - Refactor Dataflow LCO to work with futures

  • +
  • Issue #196 - Don’t store copies of the locality network metadata in the +gva table

  • +
+
+
+
+
HPX V0.9.9 (Oct 31, 2014, codename Spooky)#
+
+
General changes#
+

We have had over 1500 commits since the last release and we have closed over 200 +tickets (bugs, feature requests, pull requests, etc.). These are by far the +largest numbers of commits and resolved issues for any of the HPX releases so +far. We are especially happy about the large number of people who contributed +for the first time to HPX.

+
    +
  • We completed the transition from the older (non-conforming) implementation of +hpx::future to the new and fully conforming version by removing the old +code and by renaming the type hpx::unique_future to hpx::future. In +order to maintain backwards compatibility with existing code which uses the +type hpx::unique_future we support the configuration variable +HPX_UNIQUE_FUTURE_ALIAS. If this variable is set to ON while running +cmake it will additionally define a template alias for this type.

  • +
  • We rewrote and significantly changed our build system. Please have a look at +the new (now generated) documentation here: Building HPX. Please +revisit your build scripts to adapt to the changes. The most notable changes +are:

    +
    +
      +
    • HPX_NO_INSTALL is no longer necessary.

    • +
    • For external builds, you need to set HPX_DIR instead of HPX_ROOT as +described here: Using HPX with CMake-based projects.

    • +
    • IDEs that support multiple configurations (Visual Studio and XCode) can now +be used as intended. that means no build dir.

    • +
    • Building HPX statically (without dynamic libraries) is now supported +(-DHPX_STATIC_LINKING=On).

    • +
    • Please note that many variables used to configure the build process have +been renamed to unify the naming conventions (see the section +CMake options for more information).

    • +
    • This also fixes a long list of issues, for more information see +Issue #1204.

    • +
    +
    +
  • +
  • We started to implement various proposals to the C++ Standardization committee +related to parallelism and concurrency, most notably N4409 (Working +Draft, Technical Specification for C++ Extensions for Parallelism), +N4411 (Task Region Rev. 3), and N4313 (Working Draft, +Technical Specification for C++ Extensions for Concurrency).

  • +
  • We completely remodeled our automatic build system to run builds and unit +tests on various systems and compilers. This allows us to find most bugs right +as they were introduced and helps to maintain a high level of quality and +compatibility. The newest build logs can be found at HPX Buildbot Website.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release.

+
    +
  • Issue #1296 - Rename make_error_future to make_exceptional_future, +adjust to N4123

  • +
  • Issue #1295 - building issue

  • +
  • Issue #1293 - Transpose example

  • +
  • Issue #1292 - Wrong abs() function used in example

  • +
  • Issue #1291 - non-synchronized shift operators have been removed

  • +
  • Issue #1290 - RDTSCP is defined as true for Xeon Phi build

  • +
  • Issue #1289 - Fixing 1288

  • +
  • Issue #1288 - Add new performance counters

  • +
  • Issue #1287 - Hierarchy scheduler broken performance counters

  • +
  • Issue #1286 - Algorithm cleanup

  • +
  • Issue #1285 - Broken Links in Documentation

  • +
  • Issue #1284 - Uninitialized copy

  • +
  • Issue #1283 - missing boost::scoped_ptr includes

  • +
  • Issue #1282 - Update documentation of build options for schedulers

  • +
  • Issue #1281 - reset idle rate counter

  • +
  • Issue #1280 - Bug when executing on Intel MIC

  • +
  • Issue #1279 - Add improved when_all/wait_all

  • +
  • Issue #1278 - Implement improved when_all/wait_all

  • +
  • Issue #1277 - feature request: get access to argc argv and variables_map

  • +
  • Issue #1276 - Remove merging map

  • +
  • Issue #1274 - Weird (wrong) string code in papi.cpp

  • +
  • Issue #1273 - Sequential task execution policy

  • +
  • Issue #1272 - Avoid CMake name clash for Boost.Thread library

  • +
  • Issue #1271 - Updates on HPX Test Units

  • +
  • Issue #1270 - hpx/util/safe_lexical_cast.hpp is added

  • +
  • Issue #1269 - Added default value for “LIB” cmake variable

  • +
  • Issue #1268 - Memory Counters not working

  • +
  • Issue #1266 - FindHPX.cmake is not installed

  • +
  • Issue #1263 - apply_remote test takes too long

  • +
  • Issue #1262 - Chrono cleanup

  • +
  • Issue #1261 - Need make install for papi counters and this builds all +the examples

  • +
  • Issue #1260 - Documentation of Stencil example claims

  • +
  • Issue #1259 - Avoid double-linking Boost on Windows

  • +
  • Issue #1257 - Adding additional parameter to create_thread

  • +
  • Issue #1256 - added buildbot changes to release notes

  • +
  • Issue #1255 - Cannot build MiniGhost

  • +
  • Issue #1253 - hpx::thread defects

  • +
  • Issue #1252 - HPX_PREFIX is too fragile

  • +
  • Issue #1250 - switch_to_fiber_emulation does not work properly

  • +
  • Issue #1249 - Documentation is generated under Release folder

  • +
  • Issue #1248 - Fix usage of hpx_generic_coroutine_context and get tests +passing on powerpc

  • +
  • Issue #1247 - Dynamic linking error

  • +
  • Issue #1246 - Make cpuid.cpp C++11 compliant

  • +
  • Issue #1245 - HPX fails on startup (setting thread affinity mask)

  • +
  • Issue #1244 - HPX_WITH_RDTSC configure test fails, but should succeed

  • +
  • Issue #1243 - CTest dashboard info for CSCS CDash drop location

  • +
  • Issue #1242 - Mac fixes

  • +
  • Issue #1241 - Failure in Distributed with Boost 1.56

  • +
  • Issue #1240 - fix a race condition in examples.diskperf

  • +
  • Issue #1239 - fix wait_each in examples.diskperf

  • +
  • Issue #1238 - Fixed #1237: hpx::util::portable_binary_iarchive failed

  • +
  • Issue #1237 - hpx::util::portable_binary_iarchive faileds

  • +
  • Issue #1235 - Fixing clang warnings and errors

  • +
  • Issue #1234 - TCP runs fail: Transport endpoint is not connected

  • +
  • Issue #1233 - Making sure the correct number of threads is registered +with AGAS

  • +
  • Issue #1232 - Fixing race in wait_xxx

  • +
  • Issue #1231 - Parallel minmax

  • +
  • Issue #1230 - Distributed run of 1d_stencil_8 uses less threads than +spec. & sometimes gives errors

  • +
  • Issue #1229 - Unstable number of threads

  • +
  • Issue #1228 - HPX link error (cmake / MPI)

  • +
  • Issue #1226 - Warning about struct/class thread_counters

  • +
  • Issue #1225 - Adding parallel::replace etc

  • +
  • Issue #1224 - Extending dataflow to pass through non-future arguments

  • +
  • Issue #1223 - Remaining find algorithms implemented, N4071

  • +
  • Issue #1222 - Merging all the changes

  • +
  • Issue #1221 - No error output when using mpirun with hpx

  • +
  • Issue #1219 - Adding new AGAS cache performance counters

  • +
  • Issue #1216 - Fixing using futures (clients) as arguments to actions

  • +
  • Issue #1215 - Error compiling simple component

  • +
  • Issue #1214 - Stencil docs

  • +
  • Issue #1213 - Using more than a few dozen MPI processes on SuperMike +results in a seg fault before getting to hpx_main

  • +
  • Issue #1212 - Parallel rotate

  • +
  • Issue #1211 - Direct actions cause the future’s shared_state to be +leaked

  • +
  • Issue #1210 - Refactored local::promise to be standard conformant

  • +
  • Issue #1209 - Improve command line handling

  • +
  • Issue #1208 - Adding parallel::reverse and parallel::reverse_copy

  • +
  • Issue #1207 - Add copy_backward and move_backward

  • +
  • Issue #1206 - N4071 additional algorithms implemented

  • +
  • Issue #1204 - Cmake simplification and various other minor changes

  • +
  • Issue #1203 - Implementing new launch policy for (local) async: +hpx::launch::fork.

  • +
  • Issue #1202 - Failed assertion in connection_cache.hpp

  • +
  • Issue #1201 - pkg-config doesn’t add mpi link directories

  • +
  • Issue #1200 - Error when querying time performance counters

  • +
  • Issue #1199 - library path is now configurable (again)

  • +
  • Issue #1198 - Error when querying performance counters

  • +
  • Issue #1197 - tests fail with intel compiler

  • +
  • Issue #1196 - Silence several warnings

  • +
  • Issue #1195 - Rephrase initializers to work with VC++ 2012

  • +
  • Issue #1194 - Simplify parallel algorithms

  • +
  • Issue #1193 - Adding parallel::equal

  • +
  • Issue #1192 - HPX(out_of_memory) on including <hpx/hpx.hpp>

  • +
  • Issue #1191 - Fixing #1189

  • +
  • Issue #1190 - Chrono cleanup

  • +
  • Issue #1189 - Deadlock .. somewhere? (probably serialization)

  • +
  • Issue #1188 - Removed future::get_status()

  • +
  • Issue #1186 - Fixed FindOpenCL to find current AMD APP SDK

  • +
  • Issue #1184 - Tweaking future unwrapping

  • +
  • Issue #1183 - Extended parallel::reduce

  • +
  • Issue #1182 - future::unwrap hangs for launch::deferred

  • +
  • Issue #1181 - Adding all_of, any_of, and none_of and +corresponding documentation

  • +
  • Issue #1180 - hpx::cout defect

  • +
  • Issue #1179 - hpx::async does not work for member function pointers +when called on types with self-defined unary operator*

  • +
  • Issue #1178 - Implemented variadic hpx::util::zip_iterator

  • +
  • Issue #1177 - MPI parcelport defect

  • +
  • Issue #1176 - HPX_DEFINE_COMPONENT_CONST_ACTION_TPL does not have a +2-argument version

  • +
  • Issue #1175 - Create util::zip_iterator working with util::tuple<>

  • +
  • Issue #1174 - Error Building HPX on linux, +root_certificate_authority.cpp

  • +
  • Issue #1173 - hpx::cout output lost

  • +
  • Issue #1172 - HPX build error with Clang 3.4.2

  • +
  • Issue #1171 - CMAKE_INSTALL_PREFIX ignored

  • +
  • Issue #1170 - Close hpx_benchmarks repository on Github

  • +
  • Issue #1169 - Buildbot emails have syntax error in url

  • +
  • Issue #1167 - Merge partial implementation of standards proposal N3960

  • +
  • Issue #1166 - Fixed several compiler warnings

  • +
  • Issue #1165 - cmake warns: “tests.regressions.actions” does not exist

  • +
  • Issue #1164 - Want my own serialization of hpx::future

  • +
  • Issue #1162 - Segfault in hello_world example

  • +
  • Issue #1161 - Use HPX_ASSERT to aid the compiler

  • +
  • Issue #1160 - Do not put -DNDEBUG into hpx_application.pc

  • +
  • Issue #1159 - Support Clang 3.4.2

  • +
  • Issue #1158 - Fixed #1157: Rename when_n/wait_n, add +when_xxx_n/wait_xxx_n

  • +
  • Issue #1157 - Rename when_n/wait_n, add when_xxx_n/wait_xxx_n

  • +
  • Issue #1156 - Force inlining fails

  • +
  • Issue #1155 - changed header of printout to be compatible with python +csv module

  • +
  • Issue #1154 - Fixing iostreams

  • +
  • Issue #1153 - Standard manipulators (like std::endl) do not work with +hpx::ostream

  • +
  • Issue #1152 - Functions revamp

  • +
  • Issue #1151 - Suppressing cmake 3.0 policy warning for CMP0026

  • +
  • Issue #1150 - Client Serialization error

  • +
  • Issue #1149 - Segfault on Stampede

  • +
  • Issue #1148 - Refactoring mini-ghost

  • +
  • Issue #1147 - N3960 copy_if and copy_n implemented and tested

  • +
  • Issue #1146 - Stencil print

  • +
  • Issue #1145 - N3960 hpx::parallel::copy implemented and tested

  • +
  • Issue #1144 - OpenMP examples 1d_stencil do not build

  • +
  • Issue #1143 - 1d_stencil OpenMP examples do not build

  • +
  • Issue #1142 - Cannot build HPX with gcc 4.6 on OS X

  • +
  • Issue #1140 - Fix OpenMP lookup, enable usage of config tests in +external CMake projects.

  • +
  • Issue #1139 - hpx/hpx/config/compiler_specific.hpp

  • +
  • Issue #1138 - clean up pkg-config files

  • +
  • Issue #1137 - Improvements to create binary packages

  • +
  • Issue #1136 - HPX_GCC_VERSION not defined on all compilers

  • +
  • Issue #1135 - Avoiding collision between winsock2.h and windows.h

  • +
  • Issue #1134 - Making sure, that hpx::finalize can be called from any +locality

  • +
  • Issue #1133 - 1d stencil examples

  • +
  • Issue #1131 - Refactor unique_function implementation

  • +
  • Issue #1130 - Unique function

  • +
  • Issue #1129 - Some fixes to the Build system on OS X

  • +
  • Issue #1128 - Action future args

  • +
  • Issue #1127 - Executor causes segmentation fault

  • +
  • Issue #1124 - Adding new API functions: register_id_with_basename, +unregister_id_with_basename, find_ids_from_basename; adding test

  • +
  • Issue #1123 - Reduce nesting of try-catch construct in +encode_parcels?

  • +
  • Issue #1122 - Client base fixes

  • +
  • Issue #1121 - Update hpxrun.py.in

  • +
  • Issue #1120 - HTTS2 tests compile errors on v110 (VS2012)

  • +
  • Issue #1119 - Remove references to boost::atomic in accumulator example

  • +
  • Issue #1118 - Only build test thread_pool_executor_1114_test if +HPX_SCHEDULER is set

  • +
  • Issue #1117 - local_queue_executor linker error on vc110

  • +
  • Issue #1116 - Disabled performance counter should give runtime errors, +not invalid data

  • +
  • Issue #1115 - Compile error with Intel C++ 13.1

  • +
  • Issue #1114 - Default constructed executor is not usable

  • +
  • Issue #1113 - Fast compilation of logging causes ABI incompatibilities +between different NDEBUG values

  • +
  • Issue #1112 - Using thread_pool_executors causes segfault

  • +
  • Issue #1111 - hpx::threads::get_thread_data always returns zero

  • +
  • Issue #1110 - Remove unnecessary null pointer checks

  • +
  • Issue #1109 - More tests adjustments

  • +
  • Issue #1108 - Clarify build rules for “libboost_atomic-mt.so”?

  • +
  • Issue #1107 - Remove unnecessary null pointer checks

  • +
  • Issue #1106 - network_storage benchmark improvements, adding legends to +plots and tidying layout

  • +
  • Issue #1105 - Add more plot outputs and improve instructions doc

  • +
  • Issue #1104 - Complete quoting for parameters of some CMake commands

  • +
  • Issue #1103 - Work on test/scripts

  • +
  • Issue #1102 - Changed minimum requirement of window install to 2012

  • +
  • Issue #1101 - Changed minimum requirement of window install to 2012

  • +
  • Issue #1100 - Changed readme to no longer specify using MSVC 2010 +compiler

  • +
  • Issue #1099 - Error returning futures from component actions

  • +
  • Issue #1098 - Improve storage test

  • +
  • Issue #1097 - data_actions quickstart example calls missing function +decorate_action of data_get_action

  • +
  • Issue #1096 - MPI parcelport broken with new zero copy optimization

  • +
  • Issue #1095 - Warning C4005: _WIN32_WINNT: Macro redefinition

  • +
  • Issue #1094 - Syntax error for -DHPX_UNIQUE_FUTURE_ALIAS in master

  • +
  • Issue #1093 - Syntax error for -DHPX_UNIQUE_FUTURE_ALIAS

  • +
  • Issue #1092 - Rename unique_future<> back to future<>

  • +
  • Issue #1091 - Inconsistent error message

  • +
  • Issue #1090 - On windows 8.1 the examples crashed if using more than one +os thread

  • +
  • Issue #1089 - Components should be allowed to have their own executor

  • +
  • Issue #1088 - Add possibility to select a network interface for the +ibverbs parcelport

  • +
  • Issue #1087 - ibverbs and ipc parcelport uses zero copy optimization

  • +
  • Issue #1083 - Make shell examples copyable in docs

  • +
  • Issue #1082 - Implement proper termination detection during shutdown

  • +
  • Issue #1081 - Implement thread_specific_ptr for hpx::threads

  • +
  • Issue #1072 - make install not working properly

  • +
  • Issue #1070 - Complete quoting for parameters of some CMake commands

  • +
  • Issue #1059 - Fix more unused variable warnings

  • +
  • Issue #1051 - Implement when_each

  • +
  • Issue #973 - Would like option to report hwloc bindings

  • +
  • Issue #970 - Bad flags for Fortran compiler

  • +
  • Issue #941 - Create a proper user level context switching class for BG/Q

  • +
  • Issue #935 - Build error with gcc 4.6 and Boost 1.54.0 on hpx trunk and +0.9.6

  • +
  • Issue #934 - Want to build HPX without dynamic libraries

  • +
  • Issue #927 - Make hpx/lcos/reduce.hpp accept futures of id_type

  • +
  • Issue #926 - All unit tests that are run with more than one thread with +CTest/hpx_run_test should configure hpx.os_threads

  • +
  • Issue #925 - regression_dataflow_791 needs to be brought in line with +HPX standards

  • +
  • Issue #899 - Fix race conditions in regression tests

  • +
  • Issue #879 - Hung test leads to cascading test failure; make tests +should support the MPI parcelport

  • +
  • Issue #865 - future<T> and friends shall work for movable only Ts

  • +
  • Issue #847 - Dynamic libraries are not installed on OS X

  • +
  • Issue #816 - First Program tutorial pull request

  • +
  • Issue #799 - Wrap lexical_cast to avoid exceptions

  • +
  • Issue #720 - broken configuration when using ccmake on Ubuntu

  • +
  • Issue #622 - --hpx:hpx and --hpx:debug-hpx-log is nonsensical

  • +
  • Issue #525 - Extend barrier LCO test to run in distributed

  • +
  • Issue #515 - Multi-destination version of hpx::apply is broken

  • +
  • Issue #509 - Push Boost.Atomic changes upstream

  • +
  • Issue #503 - Running HPX applications on Windows should not require +setting %PATH%

  • +
  • Issue #461 - Add a compilation sanity test

  • +
  • Issue #456 - hpx_run_tests.py should log output from tests that timeout

  • +
  • Issue #454 - Investigate threadmanager performance

  • +
  • Issue #345 - Add more versatile environmental/cmake variable support to +hpx_find_* CMake macros

  • +
  • Issue #209 - Support multiple configurations in generated build files

  • +
  • Issue #190 - hpx::cout should be a std::ostream

  • +
  • Issue #189 - iostreams component should use startup/shutdown functions

  • +
  • Issue #183 - Use Boost.ICL for correctness in AGAS

  • +
  • Issue #44 - Implement real futures

  • +
+
+
+
+
HPX V0.9.8 (Mar 24, 2014)#
+

We have had over 800 commits since the last release and we have closed over 65 +tickets (bugs, feature requests, etc.).

+

With the changes below, HPX is once again leading the charge of a whole new +era of computation. By intrinsically breaking down and synchronizing the work to +be done, HPX insures that application developers will no longer have to fret +about where a segment of code executes. That allows coders to focus their time +and energy to understanding the data dependencies of their algorithms and +thereby the core obstacles to an efficient code. Here are some of the advantages +of using HPX:

+
    +
  • HPX is solidly rooted in a sophisticated theoretical execution model – +ParalleX

  • +
  • HPX exposes an API fully conforming to the C++11 and the draft C++14 +standards, extended and applied to distributed computing. Everything +programmers know about the concurrency primitives of the standard C++ library +is still valid in the context of HPX.

  • +
  • It provides a competitive, high performance implementation of modern, +future-proof ideas which gives an smooth migration path from today’s +mainstream techniques

  • +
  • There is no need for the programmer to worry about lower level parallelization +paradigms like threads or message passing; no need to understand pthreads, +MPI, OpenMP, or Windows threads, etc.

  • +
  • There is no need to think about different types of parallelism such as tasks, +pipelines, or fork-join, task or data parallelism.

  • +
  • The same source of your program compiles and runs on Linux, BlueGene/Q, Mac OS +X, Windows, and Android.

  • +
  • The same code runs on shared memory multi-core systems and supercomputers, on +handheld devices and Intel® Xeon Phi™ accelerators, or a +heterogeneous mix of those.

  • +
+
+
General changes#
+
    +
  • A major API breaking change for this release was introduced by implementing +hpx::future and hpx::shared_future fully in conformance with the +C++11 Standard. While hpx::shared_future is new and will not create any +compatibility problems, we revised the interface and implementation of the +existing hpx::future. For more details please see the mailing list +archive. To +avoid any incompatibilities for existing code we named the type which +implements the std::future interface as hpx::unique_future. For the +next release this will be renamed to hpx::future, making it full +conforming to C++11 Standard.

  • +
  • A large part of the code base of HPX has been refactored and partially +re-implemented. The main changes were related to

    +
      +
    • The threading subsystem: these changes significantly reduce the amount of +overheads caused by the schedulers, improve the modularity of the code +base, and extend the variety of available scheduling algorithms.

    • +
    • The parcel subsystem: these changes improve the performance of the HPX +networking layer, modularize the structure of the parcelports, and +simplify the creation of new parcelports for other underlying networking +libraries.

    • +
    • The API subsystem: these changes improved the conformance of the API to +C++11 Standard, extend and unify the available API functionality, and decrease +the overheads created by various elements of the API.

    • +
    • The robustness of the component loading subsystem has been improved +significantly, allowing to more portably and more reliably register the +components needed by an application as startup. This additionally speeds up +general application initialization.

    • +
    +
  • +
  • We added new API functionality like hpx::migrate and hpx::copy_component +which are the basic building blocks necessary for implementing higher level +abstractions for system-wide load balancing, runtime-adaptive resource +management, and object-oriented checkpointing and state-management.

  • +
  • We removed the use of C++11 move emulation (using Boost.Move), replacing it +with C++11 rvalue references. This is the first step towards using more and +more native C++11 facilities which we plan to introduce in the future.

  • +
  • We improved the reference counting scheme used by HPX which helps +managing distributed objects and memory. This improves the overall stability +of HPX and further simplifies writing real world applications.

  • +
  • The minimal Boost version required to use HPX is now V1.49.0.

  • +
  • This release coincides with the first release of HPXPI (V0.1.0), the +first implementation of the XPI specification.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release.

+
    +
  • Issue #1086 - Expose internal boost::shared_array to allow user +management of array lifetime

  • +
  • Issue #1083 - Make shell examples copyable in docs

  • +
  • Issue #1080 - /threads{locality#*/total}/count/cumulative broken

  • +
  • Issue #1079 - Build problems on OS X

  • +
  • Issue #1078 - Improve robustness of component loading

  • +
  • Issue #1077 - Fix a missing enum definition for ‘take’ mode

  • +
  • Issue #1076 - Merge Jb master

  • +
  • Issue #1075 - Unknown CMake command “add_hpx_pseudo_target”

  • +
  • Issue #1074 - Implement apply_continue_callback and +apply_colocated_callback

  • +
  • Issue #1073 - The new apply_colocated and async_colocated +functions lead to automatic registered functions

  • +
  • Issue #1071 - Remove deferred_packaged_task

  • +
  • Issue #1069 - serialize_buffer with allocator fails at destruction

  • +
  • Issue #1068 - Coroutine include and forward declarations missing

  • +
  • Issue #1067 - Add allocator support to util::serialize_buffer

  • +
  • Issue #1066 - Allow for MPI_Init being called before HPX launches

  • +
  • Issue #1065 - AGAS cache isn’t used/populated on worker localities

  • +
  • Issue #1064 - Reorder includes to ensure ws2 includes early

  • +
  • Issue #1063 - Add hpx::runtime::suspend and hpx::runtime::resume

  • +
  • Issue #1062 - Fix async_continue to properly handle return types

  • +
  • Issue #1061 - Implement async_colocated and apply_colocated

  • +
  • Issue #1060 - Implement minimal component migration

  • +
  • Issue #1058 - Remove HPX_UTIL_TUPLE from code base

  • +
  • Issue #1057 - Add performance counters for threading subsystem

  • +
  • Issue #1055 - Thread allocation uses two memory pools

  • +
  • Issue #1053 - Work stealing flawed

  • +
  • Issue #1052 - Fix a number of warnings

  • +
  • Issue #1049 - Fixes for TLS on OSX and more reliable test running

  • +
  • Issue #1048 - Fixing after 588 hang

  • +
  • Issue #1047 - Use port ‘0’ for networking when using one locality

  • +
  • Issue #1046 - composable_guard test is broken when having more than +one thread

  • +
  • Issue #1045 - Security missing headers

  • +
  • Issue #1044 - Native TLS on FreeBSD via __thread

  • +
  • Issue #1043 - async et.al. compute the wrong result type

  • +
  • Issue #1042 - async et.al. implicitly unwrap reference_wrappers

  • +
  • Issue #1041 - Remove redundant costly Kleene stars from regex searches

  • +
  • Issue #1040 - CMake script regex match patterns has unnecessary kleenes

  • +
  • Issue #1039 - Remove use of Boost.Move and replace with std::move and +real rvalue refs

  • +
  • Issue #1038 - Bump minimal required Boost to 1.49.0

  • +
  • Issue #1037 - Implicit unwrapping of futures in async broken

  • +
  • Issue #1036 - Scheduler hangs when user code attempts to “block” +OS-threads

  • +
  • Issue #1035 - Idle-rate counter always reports 100% idle rate

  • +
  • Issue #1034 - Symbolic name registration causes application hangs

  • +
  • Issue #1033 - Application options read in from an options file generate +an error message

  • +
  • Issue #1032 - hpx::id_type local reference counting is wrong

  • +
  • Issue #1031 - Negative entry in reference count table

  • +
  • Issue #1030 - Implement condition_variable

  • +
  • Issue #1029 - Deadlock in thread scheduling subsystem

  • +
  • Issue #1028 - HPX-thread cumulative count performance counters report +incorrect value

  • +
  • Issue #1027 - Expose hpx::thread_interrupted error code as a +separate exception type

  • +
  • Issue #1026 - Exceptions thrown in asynchronous calls can be lost if the +value of the future is never queried

  • +
  • Issue #1025 - future::wait_for/wait_until do not remove callback

  • +
  • Issue #1024 - Remove dependence to boost assert and create hpx assert

  • +
  • Issue #1023 - Segfaults with tcmalloc

  • +
  • Issue #1022 - prerequisites link in readme is broken

  • +
  • Issue #1020 - HPX Deadlock on external synchronization

  • +
  • Issue #1019 - Convert using BOOST_ASSERT to HPX_ASSERT

  • +
  • Issue #1018 - compiling bug with gcc 4.8.1

  • +
  • Issue #1017 - Possible crash in io_pool executor

  • +
  • Issue #1016 - Crash at startup

  • +
  • Issue #1014 - Implement Increment/Decrement Merging

  • +
  • Issue #1013 - Add more logging channels to enable greater control over +logging granularity

  • +
  • Issue #1012 - --hpx:debug-hpx-log and --hpx:debug-agas-log lead +to non-thread safe writes

  • +
  • Issue #1011 - After installation, running applications from the +build/staging directory no longer works

  • +
  • Issue #1010 - Mergeable decrement requests are not being merged

  • +
  • Issue #1009 - --hpx:list-symbolic-names crashes

  • +
  • Issue #1007 - Components are not properly destroyed

  • +
  • Issue #1006 - Segfault/hang in set_data

  • +
  • Issue #1003 - Performance counter naming issue

  • +
  • Issue #982 - Race condition during startup

  • +
  • Issue #912 - OS X: component type not found in map

  • +
  • Issue #663 - Create a buildbot slave based on Clang 3.2/OSX

  • +
  • Issue #636 - Expose this_locality::apply<act>(p1, p2); for local +execution

  • +
  • Issue #197 - Add --console=address option for PBS runs

  • +
  • Issue #175 - Asynchronous AGAS API

  • +
+
+
+
+
HPX V0.9.7 (Nov 13, 2013)#
+

We have had over 1000 commits since the last release and we have closed over 180 +tickets (bugs, feature requests, etc.).

+
+
General changes#
+
    +
  • Ported HPX to BlueGene/Q

  • +
  • Improved HPX support for Xeon/Phi accelerators

  • +
  • Reimplemented hpx::bind, hpx::tuple, and hpx::function for better +performance and better compliance with the C++11 Standard. Added hpx::mem_fn.

  • +
  • Reworked hpx::when_all and hpx::when_any for better compliance with +the ongoing C++ standardization effort, added heterogeneous version for those +functions. Added hpx::when_any_swapped.

  • +
  • Added hpx::copy as a precursor for a migrate functionality

  • +
  • Added hpx::get_ptr allowing to directly access the memory underlying a +given component

  • +
  • Added the hpx::lcos::broadcast, hpx::lcos::reduce, and +hpx::lcos::fold collective operations

  • +
  • Added hpx::get_locality_name allowing to retrieve the name of any of the +localities for the application.

  • +
  • Added support for more flexible thread affinity control from the HPX command +line, such as new modes for --hpx:bind (balanced, scattered, +compact), improved default settings when running multiple localities on +the same node.

  • +
  • Added experimental executors for simpler thread pooling and scheduling. This +API may change in the future as it will stay aligned with the ongoing C++ +standardization efforts.

  • +
  • Massively improved the performance of the HPX serialization code. Added +partial support for zero copy serialization of array and bitwise-copyable +types.

  • +
  • General performance improvements of the code related to threads and futures.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release.

+
    +
  • Issue #1005 - Allow one to disable array optimizations and zero copy +optimizations for each parcelport

  • +
  • Issue #1004 - Generate new HPX logo image for the docs

  • +
  • Issue #1002 - If MPI parcelport is not available, running HPX under +mpirun should fail

  • +
  • Issue #1001 - Zero copy serialization raises assert

  • +
  • Issue #1000 - Can’t connect to a HPX application running with the MPI +parcelport from a non MPI parcelport locality

  • +
  • Issue #999 - Optimize hpx::when_n

  • +
  • Issue #998 - Fixed const-correctness

  • +
  • Issue #997 - Making serialize_buffer::data() type save

  • +
  • Issue #996 - Memory leak in hpx::lcos::promise

  • +
  • Issue #995 - Race while registering pre-shutdown functions

  • +
  • Issue #994 - thread_rescheduling regression test does not compile

  • +
  • Issue #992 - Correct comments and messages

  • +
  • Issue #991 - setcap cap_sys_rawio=ep for power profiling causes an HPX +application to abort

  • +
  • Issue #989 - Jacobi hangs during execution

  • +
  • Issue #988 - multiple_init test is failing

  • +
  • Issue #986 - Can’t call a function called “init” from “main” when using +<hpx/hpx_main.hpp>

  • +
  • Issue #984 - Reference counting tests are failing

  • +
  • Issue #983 - thread_suspension_executor test fails

  • +
  • Issue #980 - Terminating HPX threads don’t leave stack in virgin state

  • +
  • Issue #979 - Static scheduler not in documents

  • +
  • Issue #978 - Preprocessing limits are broken

  • +
  • Issue #977 - Make tests.regressions.lcos.future_hang_on_get shorter

  • +
  • Issue #976 - Wrong library order in pkgconfig

  • +
  • Issue #975 - Please reopen #963

  • +
  • Issue #974 - Option pu-offset ignored in fixing_588 branch

  • +
  • Issue #972 - Cannot use MKL with HPX

  • +
  • Issue #969 - Non-existent INI files requested on the command line via +--hpx:config do not cause warnings or errors.

  • +
  • Issue #968 - Cannot build examples in fixing_588 branch

  • +
  • Issue #967 - Command line description of --hpx:queuing seems wrong

  • +
  • Issue #966 - --hpx:print-bind physical core numbers are wrong

  • +
  • Issue #965 - Deadlock when building in Release mode

  • +
  • Issue #963 - Not all worker threads are working

  • +
  • Issue #962 - Problem with SLURM integration

  • +
  • Issue #961 - --hpx:print-bind outputs incorrect information

  • +
  • Issue #960 - Fix cut and paste error in documentation of +get_thread_priority

  • +
  • Issue #959 - Change link to boost.atomic in documentation to point to +boost.org

  • +
  • Issue #958 - Undefined reference to intrusive_ptr_release

  • +
  • Issue #957 - Make tuple standard compliant

  • +
  • Issue #956 - Segfault with a3382fb

  • +
  • Issue #955 - --hpx:nodes and --hpx:nodefiles do not work with +foreign nodes

  • +
  • Issue #954 - Make order of arguments for hpx::async and hpx::broadcast +consistent

  • +
  • Issue #953 - Cannot use MKL with HPX

  • +
  • Issue #952 - register_[pre_]shutdown_function never throw

  • +
  • Issue #951 - Assert when number of threads is greater than hardware +concurrency

  • +
  • Issue #948 - HPX_HAVE_GENERIC_CONTEXT_COROUTINES conflicts with +HPX_HAVE_FIBER_BASED_COROUTINES

  • +
  • Issue #947 - Need MPI_THREAD_MULTIPLE for backward compatibility

  • +
  • Issue #946 - HPX does not call MPI_Finalize

  • +
  • Issue #945 - Segfault with hpx::lcos::broadcast

  • +
  • Issue #944 - OS X: assertion pu_offset_ < hardware_concurrency +failed

  • +
  • Issue #943 - #include <hpx/hpx_main.hpp> does not work

  • +
  • Issue #942 - Make the BG/Q work with -O3

  • +
  • Issue #940 - Use separator when concatenating locality name

  • +
  • Issue #939 - Refactor MPI parcelport to use MPI_Wait instead of +multiple MPI_Test calls

  • +
  • Issue #938 - Want to officially access client_base::gid_

  • +
  • Issue #937 - client_base::gid_ should be private``

  • +
  • Issue #936 - Want doxygen-like source code index

  • +
  • Issue #935 - Build error with gcc 4.6 and Boost 1.54.0 on hpx trunk and +0.9.6

  • +
  • Issue #933 - Cannot build HPX with Boost 1.54.0

  • +
  • Issue #932 - Components are destructed too early

  • +
  • Issue #931 - Make HPX work on BG/Q

  • +
  • Issue #930 - make git-docs is broken

  • +
  • Issue #929 - Generating index in docs broken

  • +
  • Issue #928 - Optimize hpx::util::static_ for C++11 compilers +supporting magic statics

  • +
  • Issue #924 - Make kill_process_tree (in process.py) more robust on Mac +OSX

  • +
  • Issue #923 - Correct BLAS and RNPL cmake tests

  • +
  • Issue #922 - Cannot link against BLAS

  • +
  • Issue #921 - Implement hpx::mem_fn

  • +
  • Issue #920 - Output locality with --hpx:print-bind

  • +
  • Issue #919 - Correct grammar; simplify boolean expressions

  • +
  • Issue #918 - Link to hello_world.cpp is broken

  • +
  • Issue #917 - adapt cmake file to new boostbook version

  • +
  • Issue #916 - fix problem building documentation with xsltproc >= 1.1.27

  • +
  • Issue #915 - Add another TBBMalloc library search path

  • +
  • Issue #914 - Build problem with Intel compiler on Stampede (TACC)

  • +
  • Issue #913 - fix error messages in fibonacci examples

  • +
  • Issue #911 - Update OS X build instructions

  • +
  • Issue #910 - Want like to specify MPI_ROOT instead of compiler wrapper +script

  • +
  • Issue #909 - Warning about void* arithmetic

  • +
  • Issue #908 - Buildbot for MIC is broken

  • +
  • Issue #906 - Can’t use --hpx:bind=balanced with multiple MPI +processes

  • +
  • Issue #905 - --hpx:bind documentation should describe full grammar

  • +
  • Issue #904 - Add hpx::lcos::fold and hpx::lcos::inverse_fold collective +operation

  • +
  • Issue #903 - Add hpx::when_any_swapped()

  • +
  • Issue #902 - Add hpx::lcos::reduce collective operation

  • +
  • Issue #901 - Web documentation is not searchable

  • +
  • Issue #900 - Web documentation for trunk has no index

  • +
  • Issue #898 - Some tests fail with GCC 4.8.1 and MPI parcel port

  • +
  • Issue #897 - HWLOC causes failures on Mac

  • +
  • Issue #896 - pu-offset leads to startup error

  • +
  • Issue #895 - hpx::get_locality_name not defined

  • +
  • Issue #894 - Race condition at shutdown

  • +
  • Issue #893 - --hpx:print-bind switches std::cout to hexadecimal mode

  • +
  • Issue #892 - hwloc_topology_load can be expensive – don’t call +multiple times

  • +
  • Issue #891 - The documentation for get_locality_name is wrong

  • +
  • Issue #890 - --hpx:print-bind should not exit

  • +
  • Issue #889 - --hpx:debug-hpx-log=FILE does not work

  • +
  • Issue #888 - MPI parcelport does not exit cleanly for –hpx:print-bind

  • +
  • Issue #887 - Choose thread affinities more cleverly

  • +
  • Issue #886 - Logging documentation is confusing

  • +
  • Issue #885 - Two threads are slower than one

  • +
  • Issue #884 - is_callable failing with member pointers in C++11

  • +
  • Issue #883 - Need help with is_callable_test

  • +
  • Issue #882 - tests.regressions.lcos.future_hang_on_get does not +terminate

  • +
  • Issue #881 - tests/regressions/block_matrix/matrix.hh won’t compile with +GCC 4.8.1

  • +
  • Issue #880 - HPX does not work on OS X

  • +
  • Issue #878 - future::unwrap triggers assertion

  • +
  • Issue #877 - “make tests” has build errors on Ubuntu 12.10

  • +
  • Issue #876 - tcmalloc is used by default, even if it is not present

  • +
  • Issue #875 - global_fixture is defined in a header file

  • +
  • Issue #874 - Some tests take very long

  • +
  • Issue #873 - Add block-matrix code as regression test

  • +
  • Issue #872 - HPX documentation does not say how to run tests with +detailed output

  • +
  • Issue #871 - All tests fail with “make test”

  • +
  • Issue #870 - Please explicitly disable serialization in classes that +don’t support it

  • +
  • Issue #868 - boost_any test failing

  • +
  • Issue #867 - Reduce the number of copies of hpx::function arguments

  • +
  • Issue #863 - Futures should not require a default constructor

  • +
  • Issue #862 - value_or_error shall not default construct its result

  • +
  • Issue #861 - HPX_UNUSED macro

  • +
  • Issue #860 - Add functionality to copy construct a component

  • +
  • Issue #859 - hpx::endl should flush

  • +
  • Issue #858 - Create hpx::get_ptr<> allowing to access component +implementation

  • +
  • Issue #855 - Implement hpx::INVOKE

  • +
  • Issue #854 - hpx/hpx.hpp does not include +hpx/include/iostreams.hpp

  • +
  • Issue #853 - Feature request: null future

  • +
  • Issue #852 - Feature request: Locality names

  • +
  • Issue #851 - hpx::cout output does not appear on screen

  • +
  • Issue #849 - All tests fail on OS X after installing

  • +
  • Issue #848 - Update OS X build instructions

  • +
  • Issue #846 - Update hpx_external_example

  • +
  • Issue #845 - Issues with having both debug and release modules in the +same directory

  • +
  • Issue #844 - Create configuration header

  • +
  • Issue #843 - Tests should use CTest

  • +
  • Issue #842 - Remove buffer_pool from MPI parcelport

  • +
  • Issue #841 - Add possibility to broadcast an index with +hpx::lcos::broadcast

  • +
  • Issue #838 - Simplify util::tuple

  • +
  • Issue #837 - Adopt boost::tuple tests for util::tuple

  • +
  • Issue #836 - Adopt boost::function tests for util::function

  • +
  • Issue #835 - Tuple interface missing pieces

  • +
  • Issue #833 - Partially preprocessing files not working

  • +
  • Issue #832 - Native papi counters do not work with wild cards

  • +
  • Issue #831 - Arithmetics counter fails if only one parameter is given

  • +
  • Issue #830 - Convert hpx::util::function to use new scheme for +serializing its base pointer

  • +
  • Issue #829 - Consistently use decay<T> instead of remove_const< +remove_reference<T>>

  • +
  • Issue #828 - Update future implementation to N3721 and N3722

  • +
  • Issue #827 - Enable MPI parcelport for bootstrapping whenever +application was started using mpirun

  • +
  • Issue #826 - Support command line option --hpx:print-bind even if +--hpx::bind was not used

  • +
  • Issue #825 - Memory counters give segfault when attempting to use thread +wild cards or numbers only total works

  • +
  • Issue #824 - Enable lambda functions to be used with +hpx::async/hpx::apply

  • +
  • Issue #823 - Using a hashing filter

  • +
  • Issue #822 - Silence unused variable warning

  • +
  • Issue #821 - Detect if a function object is callable with given +arguments

  • +
  • Issue #820 - Allow wildcards to be used for performance counter names

  • +
  • Issue #819 - Make the AGAS symbolic name registry distributed

  • +
  • Issue #818 - Add future::then() overload taking an executor

  • +
  • Issue #817 - Fixed typo

  • +
  • Issue #815 - Create an lco that is performing an efficient broadcast of +actions

  • +
  • Issue #814 - Papi counters cannot specify thread#* to get the counts for +all threads

  • +
  • Issue #813 - Scoped unlock

  • +
  • Issue #811 - simple_central_tuplespace_client run error

  • +
  • Issue #810 - ostream error when << any objects

  • +
  • Issue #809 - Optimize parcel serialization

  • +
  • Issue #808 - HPX applications throw exception when executed from the +build directory

  • +
  • Issue #807 - Create performance counters exposing overall AGAS +statistics

  • +
  • Issue #795 - Create timed make_ready_future

  • +
  • Issue #794 - Create heterogeneous when_all/when_any/etc.

  • +
  • Issue #721 - Make HPX usable for Xeon Phi

  • +
  • Issue #694 - CMake should complain if you attempt to build an example +without its dependencies

  • +
  • Issue #692 - SLURM support broken

  • +
  • Issue #683 - python/hpx/process.py imports epoll on all platforms

  • +
  • Issue #619 - Automate the doc building process

  • +
  • Issue #600 - GTC performance broken

  • +
  • Issue #577 - Allow for zero copy serialization/networking

  • +
  • Issue #551 - Change executable names to have debug postfix in Debug +builds

  • +
  • Issue #544 - Write a custom .lib file on Windows pulling in hpx_init and +hpx.dll, phase out hpx_init

  • +
  • Issue #534 - hpx::init should take functions by std::function +and should accept all forms of hpx_main

  • +
  • Issue #508 - FindPackage fails to set FOO_LIBRARY_DIR

  • +
  • Issue #506 - Add cmake support to generate ini files for external +applications

  • +
  • Issue #470 - Changing build-type after configure does not update boost +library names

  • +
  • Issue #453 - Document hpx_run_tests.py

  • +
  • Issue #445 - Significant performance mismatch between MPI and HPX in SMP +for allgather example

  • +
  • Issue #443 - Make docs viewable from build directory

  • +
  • Issue #421 - Support multiple HPX instances per node in a batch +environment like PBS or SLURM

  • +
  • Issue #316 - Add message size limitation

  • +
  • Issue #249 - Clean up locking code in big boot barrier

  • +
  • Issue #136 - Persistent CMake variables need to be marked as cache +variables

  • +
+
+
+
+
HPX V0.9.6 (Jul 30, 2013)#
+

We have had over 1200 commits since the last release and we have closed +roughly 140 tickets (bugs, feature requests, etc.).

+
+
General changes#
+

The major new features in this release are:

+
    +
  • We further consolidated the API exposed by HPX. We aligned our APIs as much +as possible with the existing C++11 Standard and related proposals to the C++ +standardization committee (such as N3632 and N3857).

  • +
  • We implemented a first version of a distributed AGAS service which essentially +eliminates all explicit AGAS network traffic.

  • +
  • We created a native ibverbs parcelport allowing to take advantage of the +superior latency and bandwidth characteristics of Infiniband networks.

  • +
  • We successfully ported HPX to the Xeon Phi platform.

  • +
  • Support for the SLURM scheduling system was implemented.

  • +
  • Major efforts have been dedicated to improving the performance counter +framework, numerous new counters were implemented and new APIs were added.

  • +
  • We added a modular parcel compression system allowing to improve bandwidth +utilization (by reducing the overall size of the transferred data).

  • +
  • We added a modular parcel coalescing system allowing to combine several +parcels into larger messages. This reduces latencies introduced by the +communication layer.

  • +
  • Added an experimental executors API allowing to use different scheduling +policies for different parts of the code. This API has been modelled after the +Standards proposal N3562. This API is bound to change in the future, +though.

  • +
  • Added minimal security support for localities which is enforced on the +parcelport level. This support is preliminary and experimental and might +change in the future.

  • +
  • We created a parcelport using low level MPI functions. This is in support of +legacy applications which are to be gradually ported and to support platforms +where MPI is the only available portable networking layer.

  • +
  • We added a preliminary and experimental implementation of a tuple-space object +which exposes an interface similar to such systems described in the literature +(see for instance The Linda Coordination Language).

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release. This is +again a very long list of newly implemented features and fixed issues.

+
    +
  • Issue #806 - make (all) in examples folder does nothing

  • +
  • Issue #805 - Adding the introduction and fixing DOCBOOK dependencies for +Windows use

  • +
  • Issue #804 - Add stackless (non-suspendable) thread type

  • +
  • Issue #803 - Create proper serialization support functions for +util::tuple

  • +
  • Issue #800 - Add possibility to disable array optimizations during +serialization

  • +
  • Issue #798 - HPX_LIMIT does not work for local dataflow

  • +
  • Issue #797 - Create a parcelport which uses MPI

  • +
  • Issue #796 - Problem with Large Numbers of Threads

  • +
  • Issue #793 - Changing dataflow test case to hang consistently

  • +
  • Issue #792 - CMake Error

  • +
  • Issue #791 - Problems with local::dataflow

  • +
  • Issue #790 - wait_for() doesn’t compile

  • +
  • Issue #789 - HPX with Intel compiler segfaults

  • +
  • Issue #788 - Intel compiler support

  • +
  • Issue #787 - Fixed SFINAEd specializations

  • +
  • Issue #786 - Memory issues during benchmarking.

  • +
  • Issue #785 - Create an API allowing to register external threads with +HPX

  • +
  • Issue #784 - util::plugin is throwing an error when a symbol is not +found

  • +
  • Issue #783 - How does hpx:bind work?

  • +
  • Issue #782 - Added quotes around STRING REPLACE potentially empty +arguments

  • +
  • Issue #781 - Make sure no exceptions propagate into the thread manager

  • +
  • Issue #780 - Allow arithmetics performance counters to expand its +parameters

  • +
  • Issue #779 - Test case for 778

  • +
  • Issue #778 - Swapping futures segfaults

  • +
  • Issue #777 - hpx::lcos::details::when_xxx don’t restore completion +handlers

  • +
  • Issue #776 - Compiler chokes on dataflow overload with launch policy

  • +
  • Issue #775 - Runtime error with local dataflow (copying futures?)

  • +
  • Issue #774 - Using local dataflow without explicit namespace

  • +
  • Issue #773 - Local dataflow with unwrap: functor operators need to be +const

  • +
  • Issue #772 - Allow (remote) actions to return a future

  • +
  • Issue #771 - Setting HPX_LIMIT gives huge boost MPL errors

  • +
  • Issue #770 - Add launch policy to (local) dataflow

  • +
  • Issue #769 - Make compile time configuration information available

  • +
  • Issue #768 - Const correctness problem in local dataflow

  • +
  • Issue #767 - Add launch policies to async

  • +
  • Issue #766 - Mark data structures for optimized (array based) +serialization

  • +
  • Issue #765 - Align hpx::any with N3508: Any Library Proposal +(Revision 2)

  • +
  • Issue #764 - Align hpx::future with newest N3558: A Standardized +Representation of Asynchronous Operations

  • +
  • Issue #762 - added a human readable output for the ping pong example

  • +
  • Issue #761 - Ambiguous typename when constructing derived component

  • +
  • Issue #760 - Simple components can not be derived

  • +
  • Issue #759 - make install doesn’t give a complete install

  • +
  • Issue #758 - Stack overflow when using locking_hook<>

  • +
  • Issue #757 - copy paste error; unsupported function overloading

  • +
  • Issue #756 - GTCX runtime issue in Gordon

  • +
  • Issue #755 - Papi counters don’t work with reset and evaluate API’s

  • +
  • Issue #753 - cmake bugfix and improved component action docs

  • +
  • Issue #752 - hpx simple component docs

  • +
  • Issue #750 - Add hpx::util::any

  • +
  • Issue #749 - Thread phase counter is not reset

  • +
  • Issue #748 - Memory performance counter are not registered

  • +
  • Issue #747 - Create performance counters exposing arithmetic operations

  • +
  • Issue #745 - apply_callback needs to invoke callback when applied +locally

  • +
  • Issue #744 - CMake fixes

  • +
  • Issue #743 - Problem Building github version of HPX

  • +
  • Issue #742 - Remove HPX_STD_BIND

  • +
  • Issue #741 - assertion ‘px != 0’ failed: HPX(assertion_failure) for low +numbers of OS threads

  • +
  • Issue #739 - Performance counters do not count to the end of the program +or evaluation

  • +
  • Issue #738 - Dedicated AGAS server runs don’t work; console ignores -a +option.

  • +
  • Issue #737 - Missing bind overloads

  • +
  • Issue #736 - Performance counter wildcards do not always work

  • +
  • Issue #735 - Create native ibverbs parcelport based on rdma operations

  • +
  • Issue #734 - Threads stolen performance counter total is incorrect

  • +
  • Issue #733 - Test benchmarks need to be checked and fixed

  • +
  • Issue #732 - Build fails with Mac, using mac ports clang-3.3 on latest +git branch

  • +
  • Issue #731 - Add global start/stop API for performance counters

  • +
  • Issue #730 - Performance counter values are apparently incorrect

  • +
  • Issue #729 - Unhandled switch

  • +
  • Issue #728 - Serialization of hpx::util::function between two localities +causes seg faults

  • +
  • Issue #727 - Memory counters on Mac OS X

  • +
  • Issue #725 - Restore original thread priority on resume

  • +
  • Issue #724 - Performance benchmarks do not depend on main HPX libraries

  • +
  • Issue #723 - [teletype]–hpx:nodes=``cat $PBS_NODEFILE`` works; +–hpx:nodefile=$PBS_NODEFILE does not.[c++]

  • +
  • Issue #722 - Fix binding const member functions as actions

  • +
  • Issue #719 - Create performance counter exposing compression ratio

  • +
  • Issue #718 - Add possibility to compress parcel data

  • +
  • Issue #717 - strip_credit_from_gid has misleading semantics

  • +
  • Issue #716 - Non-option arguments to programs run using pbsdsh must +be before --hpx:nodes, contrary to directions

  • +
  • Issue #715 - Re-thrown exceptions should retain the original call site

  • +
  • Issue #714 - failed assertion in debug mode

  • +
  • Issue #713 - Add performance counters monitoring connection caches

  • +
  • Issue #712 - Adjust parcel related performance counters to be connection +type specific

  • +
  • Issue #711 - configuration failure

  • +
  • Issue #710 - Error “timed out while trying to find room in the +connection cache” when trying to start multiple localities on a single +computer

  • +
  • Issue #709 - Add new thread state ‘staged’ referring to task +descriptions

  • +
  • Issue #708 - Detect/mitigate bad non-system installs of GCC on Redhat +systems

  • +
  • Issue #707 - Many examples do not link with Git HEAD version

  • +
  • Issue #706 - hpx::init removes portions of non-option command line +arguments before last = sign

  • +
  • Issue #705 - Create rolling average and median aggregating performance +counters

  • +
  • Issue #704 - Create performance counter to expose thread queue waiting +time

  • +
  • Issue #703 - Add support to HPX build system to find librcrtool.a and +related headers

  • +
  • Issue #699 - Generalize instrumentation support

  • +
  • Issue #698 - compilation failure with hwloc absent

  • +
  • Issue #697 - Performance counter counts should be zero indexed

  • +
  • Issue #696 - Distributed problem

  • +
  • Issue #695 - Bad perf counter time printed

  • +
  • Issue #693 - --help doesn’t print component specific command line +options

  • +
  • Issue #692 - SLURM support broken

  • +
  • Issue #691 - exception while executing any application linked with hwloc

  • +
  • Issue #690 - thread_id_test and thread_launcher_test failing

  • +
  • Issue #689 - Make the buildbots use hwloc

  • +
  • Issue #687 - compilation error fix (hwloc_topology)

  • +
  • Issue #686 - Linker Error for Applications

  • +
  • Issue #684 - Pinning of service thread fails when number of worker +threads equals the number of cores

  • +
  • Issue #682 - Add performance counters exposing number of stolen threads

  • +
  • Issue #681 - Add apply_continue for asynchronous chaining of actions

  • +
  • Issue #679 - Remove obsolete async_callback API functions

  • +
  • Issue #678 - Add new API for setting/triggering LCOs

  • +
  • Issue #677 - Add async_continue for true continuation style actions

  • +
  • Issue #676 - Buildbot for gcc 4.4 broken

  • +
  • Issue #675 - Partial preprocessing broken

  • +
  • Issue #674 - HPX segfaults when built with gcc 4.7

  • +
  • Issue #673 - use_guard_pages has inconsistent preprocessor guards

  • +
  • Issue #672 - External build breaks if library path has spaces

  • +
  • Issue #671 - release tarballs are tarbombs

  • +
  • Issue #670 - CMake won’t find Boost headers in layout=versioned install

  • +
  • Issue #669 - Links in docs to source files broken if not installed

  • +
  • Issue #667 - Not reading ini file properly

  • +
  • Issue #664 - Adapt new meanings of ‘const’ and ‘mutable’

  • +
  • Issue #661 - Implement BTL Parcel port

  • +
  • Issue #655 - Make HPX work with the “decltype” result_of

  • +
  • Issue #647 - documentation for specifying the number of high priority +threads --hpx:high-priority-threads

  • +
  • Issue #643 - Error parsing host file

  • +
  • Issue #642 - HWLoc issue with TAU

  • +
  • Issue #639 - Logging potentially suspends a running thread

  • +
  • Issue #634 - Improve error reporting from parcel layer

  • +
  • Issue #627 - Add tests for async and apply overloads that accept regular +C++ functions

  • +
  • Issue #626 - hpx/future.hpp header

  • +
  • Issue #601 - Intel support

  • +
  • Issue #557 - Remove action codes

  • +
  • Issue #531 - AGAS request and response classes should use switch +statements

  • +
  • Issue #529 - Investigate the state of hwloc support

  • +
  • Issue #526 - Make HPX aware of hyper-threading

  • +
  • Issue #518 - Create facilities allowing to use plain arrays as action +arguments

  • +
  • Issue #473 - hwloc thread binding is broken on CPUs with hyperthreading

  • +
  • Issue #383 - Change result type detection for hpx::util::bind to use +result_of protocol

  • +
  • Issue #341 - Consolidate route code

  • +
  • Issue #219 - Only copy arguments into actions once

  • +
  • Issue #177 - Implement distributed AGAS

  • +
  • Issue #43 - Support for Darwin (Xcode + Clang)

  • +
+
+
+
+
HPX V0.9.5 (Jan 16, 2013)#
+

We have had over 1000 commits since the last release and we have closed roughly +150 tickets (bugs, feature requests, etc.).

+
+
General changes#
+

This release is continuing along the lines of code and API consolidation, and +overall usability inprovements. We dedicated much attention to performance and +we were able to significantly improve the threading and networking subsystems.

+

We successfully ported HPX to the Android platform. HPX applications now not +only can run on mobile devices, but we support heterogeneous applications +running across architecture boundaries. At the Supercomputing Conference 2012 we +demonstrated connecting Android tablets to simulations running on a Linux +cluster. The Android tablet was used to query performance counters from the +Linux simulation and to steer its parameters.

+

We successfully ported HPX to Mac OSX (using the Clang compiler). Thanks to +Pyry Jahkola for contributing the corresponding patches. Please see the section +macos_installation for more details.

+

We made a special effort to make HPX usable in highly concurrent use cases. Many +of the HPX API functions which possibly take longer than 100 microseconds to +execute now can be invoked asynchronously. We added uniform support for +composing futures which simplifies to write asynchronous code. HPX actions +(function objects encapsulating possibly concurrent remote function invocations) +are now well integrated with all other API facilities such like hpx::bind.

+

All of the API has been aligned as much as possible with established paradigms. +HPX now mirrors many of the facilities as defined in the C++11 Standard, such as +hpx::thread, hpx::function, hpx::future, etc.

+

A lot of work has been put into improving the documentation. Many of the API +functions are documented now, concepts are explained in detail, and examples are +better described than before. The new documentation index enables finding +information with lesser effort.

+

This is the first release of HPX we perform after the move to Github This +step has enabled a wider participation from the community and further encourages +us in our decision to release HPX as a true open source library (HPX is licensed +under the very liberal Boost Software License).

+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release. This is by +far the longest list of newly implemented features and fixed issues for any of +HPX’ releases so far.

+
    +
  • Issue #666 - Segfault on calling hpx::finalize twice

  • +
  • Issue #665 - Adding declaration num_of_cores

  • +
  • Issue #662 - pkgconfig is building wrong

  • +
  • Issue #660 - Need uninterrupt function

  • +
  • Issue #659 - Move our logging library into a different namespace

  • +
  • Issue #658 - Dynamic performance counter types are broken

  • +
  • Issue #657 - HPX v0.9.5 (RC1) hello_world example segfaulting

  • +
  • Issue #656 - Define the affinity of parcel-pool, io-pool, and timer-pool +threads

  • +
  • Issue #654 - Integrate the Boost auto_index tool with documentation

  • +
  • Issue #653 - Make HPX build on OS X + Clang + libc++

  • +
  • Issue #651 - Add fine-grained control for thread pinning

  • +
  • Issue #650 - Command line no error message when using -hpx:(anything)

  • +
  • Issue #645 - Command line aliases don’t work in [teletype]``@file``[c++]

  • +
  • Issue #644 - Terminated threads are not always properly cleaned up

  • +
  • Issue #640 - future_data<T>::set_on_completed_ used without locks

  • +
  • Issue #638 - hpx build with intel compilers fails on linux

  • +
  • Issue #637 - –copy-dt-needed-entries breaks with gold

  • +
  • Issue #635 - Boost V1.53 will add Boost.Lockfree and Boost.Atomic

  • +
  • Issue #633 - Re-add examples to final 0.9.5 release

  • +
  • Issue #632 - Example thread_aware_timer is broken

  • +
  • Issue #631 - FFT application throws error in parcellayer

  • +
  • Issue #630 - Event synchronization example is broken

  • +
  • Issue #629 - Waiting on futures hangs

  • +
  • Issue #628 - Add an HPX_ALWAYS_ASSERT macro

  • +
  • Issue #625 - Port coroutines context switch benchmark

  • +
  • Issue #621 - New INI section for stack sizes

  • +
  • Issue #618 - pkg_config support does not work with a HPX debug build

  • +
  • Issue #617 - +hpx/external/logging/boost/logging/detail/cache_before_init.hpp:139:67: error: +‘get_thread_id’ was not declared in this scope

  • +
  • Issue #616 - Change wait_xxx not to use locking

  • +
  • Issue #615 - Revert visibility ‘fix’ +(fb0b6b8245dad1127b0c25ebafd9386b3945cca9)

  • +
  • Issue #614 - Fix Dataflow linker error

  • +
  • Issue #613 - find_here should throw an exception on failure

  • +
  • Issue #612 - Thread phase doesn’t show up in debug mode

  • +
  • Issue #611 - Make stack guard pages configurable at runtime +(initialization time)

  • +
  • Issue #610 - Co-Locate Components

  • +
  • Issue #609 - future_overhead

  • +
  • Issue #608 - --hpx:list-counter-infos problem

  • +
  • Issue #607 - Update Boost.Context based backend for coroutines

  • +
  • Issue #606 - 1d_wave_equation is not working

  • +
  • Issue #605 - Any C++ function that has serializable arguments and a +serializable return type should be remotable

  • +
  • Issue #604 - Connecting localities isn’t working anymore

  • +
  • Issue #603 - Do not verify any ini entries read from a file

  • +
  • Issue #602 - Rename argument_size to type_size/ added implementation to +get parcel size

  • +
  • Issue #599 - Enable locality specific command line options

  • +
  • Issue #598 - Need an API that accesses the performance counter reporting +the system uptime

  • +
  • Issue #597 - compiling on ranger

  • +
  • Issue #595 - I need a place to store data in a thread self pointer

  • +
  • Issue #594 - 32/64 interoperability

  • +
  • Issue #593 - Warn if logging is disabled at compile time but requested +at runtime

  • +
  • Issue #592 - Add optional argument value to --hpx:list-counters and +--hpx:list-counter-infos

  • +
  • Issue #591 - Allow for wildcards in performance counter names specified +with --hpx:print-counter

  • +
  • Issue #590 - Local promise semantic differences

  • +
  • Issue #589 - Create API to query performance counter names

  • +
  • Issue #587 - Add get_num_localities and get_num_threads to AGAS API

  • +
  • Issue #586 - Adjust local AGAS cache size based on number of localities

  • +
  • Issue #585 - Error while using counters in HPX

  • +
  • Issue #584 - counting argument size of actions, initial pass.

  • +
  • Issue #581 - Remove RemoteResult template parameter for future<>

  • +
  • Issue #580 - Add possibility to hook into actions

  • +
  • Issue #578 - Use angle brackets in HPX error dumps

  • +
  • Issue #576 - Exception incorrectly thrown when --help is used

  • +
  • Issue #575 - HPX(bad_component_type) with gcc 4.7.2 and boost 1.51

  • +
  • Issue #574 - --hpx:connect command line parameter not working +correctly

  • +
  • Issue #571 - hpx::wait() (callback version) should pass the future +to the callback function

  • +
  • Issue #570 - hpx::wait should operate on boost::arrays and +std::lists

  • +
  • Issue #569 - Add a logging sink for Android

  • +
  • Issue #568 - 2-argument version of HPX_DEFINE_COMPONENT_ACTION

  • +
  • Issue #567 - Connecting to a running HPX application works only once

  • +
  • Issue #565 - HPX doesn’t shutdown properly

  • +
  • Issue #564 - Partial preprocessing of new component creation interface

  • +
  • Issue #563 - Add hpx::start/hpx::stop to avoid blocking main +thread

  • +
  • Issue #562 - All command line arguments swallowed by hpx

  • +
  • Issue #561 - Boost.Tuple is not move aware

  • +
  • Issue #558 - boost::shared_ptr<> style semantics/syntax for client +classes

  • +
  • Issue #556 - Creation of partially preprocessed headers should be +enabled for Boost newer than V1.50

  • +
  • Issue #555 - BOOST_FORCEINLINE does not name a type

  • +
  • Issue #554 - Possible race condition in thread get_id()

  • +
  • Issue #552 - Move enable client_base

  • +
  • Issue #550 - Add stack size category ‘huge’

  • +
  • Issue #549 - ShenEOS run seg-faults on single or distributed runs

  • +
  • Issue #545 - AUTOGLOB broken for add_hpx_component

  • +
  • Issue #542 - FindHPX_HDF5 still searches multiple times

  • +
  • Issue #541 - Quotes around application name in hpx::init

  • +
  • Issue #539 - Race conditition occurring with new lightweight threads

  • +
  • Issue #535 - hpx_run_tests.py exits with no error code when tests are +missing

  • +
  • Issue #530 - Thread description(<unknown>) in logs

  • +
  • Issue #523 - Make thread objects more lightweight

  • +
  • Issue #521 - hpx::error_code is not usable for lightweight error +handling

  • +
  • Issue #520 - Add full user environment to HPX logs

  • +
  • Issue #519 - Build succeeds, running fails

  • +
  • Issue #517 - Add a guard page to linux coroutine stacks

  • +
  • Issue #516 - hpx::thread::detach suspends while holding locks, leads to +hang in debug

  • +
  • Issue #514 - Preprocessed headers for <hpx/apply.hpp> don’t compile

  • +
  • Issue #513 - Buildbot configuration problem

  • +
  • Issue #512 - Implement action based stack size customization

  • +
  • Issue #511 - Move action priority into a separate type trait

  • +
  • Issue #510 - trunk broken

  • +
  • Issue #507 - no matching function for call to +boost::scoped_ptr<hpx::threads::topology>::scoped_ptr(hpx::threads::linux_topology*)

  • +
  • Issue #505 - undefined_symbol regression test currently failing

  • +
  • Issue #502 - Adding OpenCL and OCLM support to HPX for Windows and Linux

  • +
  • Issue #501 - find_package(HPX) sets cmake output variables

  • +
  • Issue #500 - wait_any/wait_all are badly named

  • +
  • Issue #499 - Add support for disabling pbs support in pbs runs

  • +
  • Issue #498 - Error during no-cache runs

  • +
  • Issue #496 - Add partial preprocessing support to cmake

  • +
  • Issue #495 - Support HPX modules exporting startup/shutdown functions +only

  • +
  • Issue #494 - Allow modules to specify when to run startup/shutdown +functions

  • +
  • Issue #493 - Avoid constructing a string in make_success_code

  • +
  • Issue #492 - Performance counter creation is no longer synchronized at +startup

  • +
  • Issue #491 - Performance counter creation is no longer synchronized at +startup

  • +
  • Issue #490 - Sheneos on_completed_bulk seg fault in distributed

  • +
  • Issue #489 - compiling issue with g++44

  • +
  • Issue #488 - Adding OpenCL and OCLM support to HPX for the MSVC platform

  • +
  • Issue #487 - FindHPX.cmake problems

  • +
  • Issue #485 - Change distributing_factory and binpacking_factory to use +bulk creation

  • +
  • Issue #484 - Change HPX_DONT_USE_PREPROCESSED_FILES to +HPX_USE_PREPROCESSED_FILES

  • +
  • Issue #483 - Memory counter for Windows

  • +
  • Issue #479 - strange errors appear when requesting performance counters +on multiple nodes

  • +
  • Issue #477 - Create (global) timer for multi-threaded measurements

  • +
  • Issue #472 - Add partial preprocessing using Wave

  • +
  • Issue #471 - Segfault stack traces don’t show up in release

  • +
  • Issue #468 - External projects need to link with internal components

  • +
  • Issue #462 - Startup/shutdown functions are called more than once

  • +
  • Issue #458 - Consolidate hpx::util::high_resolution_timer and +hpx::util::high_resolution_clock

  • +
  • Issue #457 - index out of bounds in allgather_and_gate on 4 cores or +more

  • +
  • Issue #448 - Make HPX compile with clang

  • +
  • Issue #447 - ‘make tests’ should execute tests on local installation

  • +
  • Issue #446 - Remove SVN-related code from the codebase

  • +
  • Issue #444 - race condition in smp

  • +
  • Issue #441 - Patched Boost.Serialization headers should only be +installed if needed

  • +
  • Issue #439 - Components using HPX_REGISTER_STARTUP_MODULE fail to +compile with MSVC

  • +
  • Issue #436 - Verify that no locks are being held while threads are +suspended

  • +
  • Issue #435 - Installing HPX should not clobber existing Boost +installation

  • +
  • Issue #434 - Logging external component failed (Boost 1.50)

  • +
  • Issue #433 - Runtime crash when building all examples

  • +
  • Issue #432 - Dataflow hangs on 512 cores/64 nodes

  • +
  • Issue #430 - Problem with distributing factory

  • +
  • Issue #424 - File paths referring to XSL-files need to be properly +escaped

  • +
  • Issue #417 - Make dataflow LCOs work out of the box by using partial +preprocessing

  • +
  • Issue #413 - hpx_svnversion.py fails on Windows

  • +
  • Issue #412 - Make hpx::error_code equivalent to hpx::exception

  • +
  • Issue #398 - HPX clobbers out-of-tree application specific CMake +variables (specifically CMAKE_BUILD_TYPE)

  • +
  • Issue #394 - Remove code generating random port numbers for network

  • +
  • Issue #378 - ShenEOS scaling issues

  • +
  • Issue #354 - Create a coroutines wrapper for Boost.Context

  • +
  • Issue #349 - Commandline option --localities=N/-lN should be +necessary only on AGAS locality

  • +
  • Issue #334 - Add auto_index support to cmake based documentation +toolchain

  • +
  • Issue #318 - Network benchmarks

  • +
  • Issue #317 - Implement network performance counters

  • +
  • Issue #310 - Duplicate logging entries

  • +
  • Issue #230 - Add compile time option to disable thread debugging info

  • +
  • Issue #171 - Add an INI option to turn off deadlock detection +independently of logging

  • +
  • Issue #170 - OSHL internal counters are incorrect

  • +
  • Issue #103 - Better diagnostics for multiple component/action +registerations under the same name

  • +
  • Issue #48 - Support for Darwin (Xcode + Clang)

  • +
  • Issue #21 - Build fails with GCC 4.6

  • +
+
+
+
+
HPX V0.9.0 (Jul 5, 2012)#
+

We have had roughly 800 commits since the last release and we have closed +approximately 80 tickets (bugs, feature requests, etc.).

+
+
General changes#
+
    +
  • Significant improvements made to the usability of HPX in large-scale, +distributed environments.

  • +
  • Renamed hpx::lcos::packaged_task to +hpx::lcos::packaged_action to reflect the semantic differences to +a packaged_task as defined by the C++11 Standard.

  • +
  • HPX now exposes hpx::thread which is compliant to the C++11 +std::thread type except that it (purely locally) represents an HPX thread. +This new type does not expose any of the remote capabilities of the underlying +HPX-thread implementation.

  • +
  • The type hpx::lcos::future is now compliant to the C++11 +std::future<> type. This type can be used to synchronize both, local and +remote operations. In both cases the control flow will ‘return’ to the future +in order to trigger any continuation.

  • +
  • The types hpx::lcos::local::promise and +hpx::lcos::local::packaged_task are now compliant to the C++11 +std::promise<> and std::packaged_task<> types. These can be used to +create a future representing local work only. Use the types +hpx::lcos::promise and hpx::lcos::packaged_action +to wrap any (possibly remote) action into a future.

  • +
  • hpx::thread and hpx::lcos::future are now +cancelable.

  • +
  • Added support for sequential and logic composition of +hpx::lcos::futures. The member function +hpx::lcos::future::when permits futures to be sequentially +composed. The helper functions hpx::wait_all, +hpx::wait_any, and hpx::wait_n can be used to wait for +more than one future at a time.

  • +
  • HPX now exposes hpx::apply and hpx::async as the +preferred way of creating (or invoking) any deferred work. These functions are +usable with various types of functions, function objects, and actions and +provide a uniform way to spawn deferred tasks.

  • +
  • HPX now utilizes hpx::util::bind to (partially) bind local +functions and function objects, and also actions. Remote bound actions can +have placeholders as well.

  • +
  • HPX continuations are now fully polymorphic. The class +hpx::actions::forwarding_continuation is an example of how the +user can write is own types of continuations. It can be used to execute any +function as an continuation of a particular action.

  • +
  • Reworked the action invocation API to be fully conformant to normal functions. +Actions can now be invoked using hpx::apply, +hpx::async, or using the operator() implemented on actions. +Actions themselves can now be cheaply instantiated as they do not have any +members anymore.

  • +
  • Reworked the lazy action invocation API. Actions can now be directly bound +using hpx::util::bind by passing an action instance as the first +argument.

  • +
  • A minimal HPX program now looks like this:

    +
    #include <hpx/hpx_init.hpp>
    +
    +int hpx_main()
    +{
    +    return hpx::finalize();
    +}
    +
    +int main()
    +{
    +    return hpx::init();
    +}
    +
    +
    +

    This removes the immediate dependency on the Boost.Program_options library.

    +
    +

    Note

    +

    This minimal version of an HPX program does not support any of the +default command line arguments (such as –help, or command line options +related to PBS). It is suggested to always pass argc and argv to +HPX as shown in the example below.

    +
    +
  • +
  • In order to support those, but still not to depend on Boost.Program_options, +the minimal program can be written as:

    +
    #include <hpx/hpx_init.hpp>
    +
    +// The arguments for hpx_main can be left off, which very similar to the
    +// behavior of ``main()`` as defined by C++.
    +int hpx_main(int argc, char* argv[])
    +{
    +    return hpx::finalize();
    +}
    +
    +int main(int argc, char* argv[])
    +{
    +    return hpx::init(argc, argv);
    +}
    +
    +
    +
  • +
  • Added performance counters exposing the number of component instances which +are alive on a given locality.

  • +
  • Added performance counters exposing then number of messages sent and received, +the number of parcels sent and received, the number of bytes sent and +received, the overall time required to send and receive data, and the overall +time required to serialize and deserialize the data.

  • +
  • Added a new component: hpx::components::binpacking_factory which +is equivalent to the existing +hpx::components::distributing_factory component, except that it +equalizes the overall population of the components to create. It exposes two +factory methods, one based on the number of existing instances of the +component type to create, and one based on an arbitrary performance counter +which will be queried for all relevant localities.

  • +
  • Added API functions allowing to access elements of the diagnostic information +embedded in the given exception: hpx::get_locality_id, +hpx::get_host_name, hpx::get_process_id, +hpx::get_function_name, hpx::get_file_name, +hpx::get_line_number, hpx::get_os_thread, +hpx::get_thread_id, and hpx::get_thread_description.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release:

+
    +
  • Issue #71 - GIDs that are not serialized via handle_gid<> should +raise an exception

  • +
  • Issue #105 - Allow for hpx::util::functions to be registered +in the AGAS symbolic namespace

  • +
  • Issue #107 - Nasty threadmanger race condition (reproducible in +sheneos_test)

  • +
  • Issue #108 - Add millisecond resolution to HPX logs on Linux

  • +
  • Issue #110 - Shutdown hang in distributed with release build

  • +
  • Issue #116 - Don’t use TSS for the applier and runtime pointers

  • +
  • Issue #162 - Move local synchronous execution shortcut from +hpx::function to the applier

  • +
  • Issue #172 - Cache sources in CMake and check if they change manually

  • +
  • Issue #178 - Add an INI option to turn off ranged-based AGAS caching

  • +
  • Issue #187 - Support for disabling performance counter deployment

  • +
  • Issue #202 - Support for sending performance counter data to a specific +file

  • +
  • Issue #218 - boost.coroutines allows different stack sizes, but stack +pool is unaware of this

  • +
  • Issue #231 - Implement movable boost::bind

  • +
  • Issue #232 - Implement movable boost::function

  • +
  • Issue #236 - Allow binding hpx::util::function to actions

  • +
  • Issue #239 - Replace hpx::function with +hpx::util::function

  • +
  • Issue #240 - Can’t specify RemoteResult with lcos::async

  • +
  • Issue #242 - REGISTER_TEMPLATE support for plain actions

  • +
  • Issue #243 - handle_gid<> support for +hpx::util::function

  • +
  • Issue #245 - *_c_cache code throws an exception if the queried GID +is not in the local cache

  • +
  • Issue #246 - Undefined references in dataflow/adaptive1d example

  • +
  • Issue #252 - Problems configuring sheneos with CMake

  • +
  • Issue #254 - Lifetime of components doesn’t end when client goes out of +scope

  • +
  • Issue #259 - CMake does not detect that MSVC10 has lambdas

  • +
  • Issue #260 - io_service_pool segfault

  • +
  • Issue #261 - Late parcel executed outside of pxthread

  • +
  • Issue #263 - Cannot select allocator with CMake

  • +
  • Issue #264 - Fix allocator select

  • +
  • Issue #267 - Runtime error for hello_world

  • +
  • Issue #269 - pthread_affinity_np test fails to compile

  • +
  • Issue #270 - Compiler noise due to -Wcast-qual

  • +
  • Issue #275 - Problem with configuration tests/include paths on Gentoo

  • +
  • Issue #325 - Sheneos is 200-400 times slower than the fortran equivalent

  • +
  • Issue #331 - hpx::init and hpx_main() should not depend +on program_options

  • +
  • Issue #333 - Add doxygen support to CMake for doc toolchain

  • +
  • Issue #340 - Performance counters for parcels

  • +
  • Issue #346 - Component loading error when running hello_world in +distributed on MSVC2010

  • +
  • Issue #362 - Missing initializer error

  • +
  • Issue #363 - Parcel port serialization error

  • +
  • Issue #366 - Parcel buffering leads to types incompatible exception

  • +
  • Issue #368 - Scalable alternative to rand() needed for HPX

  • +
  • Issue #369 - IB over IP is substantially slower than just using standard +TCP/IP

  • +
  • Issue #374 - hpx::lcos::wait should work with dataflows and +arbitrary classes meeting the future interface

  • +
  • Issue #375 - Conflicting/ambiguous overloads of +hpx::lcos::wait

  • +
  • Issue #376 - Find_HPX.cmake should set CMake variable HPX_FOUND for out +of tree builds

  • +
  • Issue #377 - ShenEOS interpolate bulk and interpolate_one_bulk are +broken

  • +
  • Issue #379 - Add support for distributed runs under SLURM

  • +
  • Issue #382 - _Unwind_Word not declared in boost.backtrace

  • +
  • Issue #387 - Doxygen should look only at list of specified files

  • +
  • Issue #388 - Running make install on an out-of-tree application is +broken

  • +
  • Issue #391 - Out-of-tree application segfaults when running in qsub

  • +
  • Issue #392 - Remove HPX_NO_INSTALL option from cmake build system

  • +
  • Issue #396 - Pragma related warnings when compiling with older gcc +versions

  • +
  • Issue #399 - Out of tree component build problems

  • +
  • Issue #400 - Out of source builds on Windows: linker should not receive +compiler flags

  • +
  • Issue #401 - Out of source builds on Windows: components need to be +linked with hpx_serialization

  • +
  • Issue #404 - gfortran fails to link automatically when fortran files are +present

  • +
  • Issue #405 - Inability to specify linking order for external libraries

  • +
  • Issue #406 - Adapt action limits such that dataflow applications work +without additional defines

  • +
  • Issue #415 - locality_results is not a member of +hpx::components::server

  • +
  • Issue #425 - Breaking changes to traits::*result wrt +std::vector<id_type>

  • +
  • Issue #426 - AUTOGLOB needs to be updated to support fortran

  • +
+
+
+
+
HPX V0.8.1 (Apr 21, 2012)#
+

This is a point release including important bug fixes for HPX V0.8.0 (Mar 23, 2012).

+
+
General changes#
+
    +
  • HPX does not need to be installed anymore to be functional.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this point release:

+
    +
  • Issue #295 - Don’t require install path to be known at compile time.

  • +
  • Issue #371 - Add hpx iostreams to standard build.

  • +
  • Issue #384 - Fix compilation with GCC 4.7.

  • +
  • Issue #390 - Remove keep_factory_alive startup call from ShenEOS; add +shutdown call to H5close.

  • +
  • Issue #393 - Thread affinity control is broken.

  • +
+
+
+
Bug fixes (commits)#
+

Here is a list of the important commits included in this point release:

+
    +
  • r7642 - External: Fix backtrace memory violation.

  • +
  • +
    r7775 - Components: Fix symbol visibility bug with component startup

    providers. This prevents one components providers from overriding +another components.

    +
    +
    +
  • +
  • r7778 - Components: Fix startup/shutdown provider shadowing issues.

  • +
+
+
+
+
HPX V0.8.0 (Mar 23, 2012)#
+

We have had roughly 1000 commits since the last release and we have closed +approximately 70 tickets (bugs, feature requests, etc.).

+
+
General changes#
+
    +
  • Improved PBS support, allowing for arbitrary naming schemes of node-hostnames.

  • +
  • Finished verification of the reference counting framework.

  • +
  • Implemented decrement merging logic to optimize the distributed reference +counting system.

  • +
  • Restructured the LCO framework. Renamed hpx::lcos::eager_future<> and +hpx::lcos::lazy_future<> into hpx::lcos::packaged_task and +hpx::lcos::deferred_packaged_task. Split +hpx::lcos::promise into hpx::lcos::packaged_task and +hpx::lcos::future. Added ‘local’ futures (in namespace +hpx::lcos::local).

  • +
  • Improved the general performance of local and remote action invocations. This +(under certain circumstances) drastically reduces the number of copies created +for each of the parameters and return values.

  • +
  • Reworked the performance counter framework. Performance counters are now +created only when needed, which reduces the overall resource requirements. The +new framework allows for much more flexible creation and management of +performance counters. The new sine example application demonstrates some of +the capabilities of the new infrastructure.

  • +
  • Added a buildbot-based continuous build system which gives instant, automated +feedback on each commit to SVN.

  • +
  • Added more automated tests to verify proper functioning of HPX.

  • +
  • Started to create documentation for HPX and its API.

  • +
  • Added documentation toolchain to the build system.

  • +
  • Added dataflow LCO.

  • +
  • Changed default HPX command line options to have hpx: prefix. For +instance, the former option --threads is now --hpx:threads. This +has been done to make ambiguities with possible application specific command +line options as unlikely as possible. See the section HPX Command Line Options for a +full list of available options.

  • +
  • Added the possibility to define command line aliases. The former short +(one-letter) command line options have been predefined as aliases for +backwards compatibility. See the section HPX Command Line Options for a detailed +description of command line option aliasing.

  • +
  • Network connections are now cached based on the connected host. The number of +simultaneous connections to a particular host is now limited. Parcels are +buffered and bundled if all connections are in use.

  • +
  • Added more refined thread affinity control. This is based on the external +library Portable Hardware Locality (HWLOC).

  • +
  • Improved support for Windows builds with CMake.

  • +
  • Added support for components to register their own command line options.

  • +
  • Added the possibility to register custom startup/shutdown functions for any +component. These functions are guaranteed to be executed by an HPX thread.

  • +
  • Added two new experimental thread schedulers: hierarchy_scheduler and +periodic_priority_scheduler. These can be activated by using the command line +options --hpx:queuing=hierarchy or --hpx:queuing=periodic.

  • +
+
+
+
Example applications#
+
    +
  • Graph500 performance benchmark (thanks to +Matthew Anderson for contributing this application).

  • +
  • GTC (Gyrokinetic Toroidal Code): +a skeleton for particle in cell type codes.

  • +
  • Random Memory Access: an example demonstrating random memory accesses in a +large array

  • +
  • ShenEOS example, demonstrating +partitioning of large read-only data structures and exposing an interpolation +API.

  • +
  • Sine performance counter demo.

  • +
  • Accumulator examples demonstrating how to write and use HPX components.

  • +
  • Quickstart examples (like hello_world, fibonacci, quicksort, factorial, etc.) +demonstrating simple HPX concepts which introduce some of the concepts in +HPX.

  • +
  • Load balancing and work stealing demos.

  • +
+
+
+
API changes#
+
    +
  • Moved all local LCOs into a separate namespace hpx::lcos::local (for +instance, hpx::lcos::local_mutex is now +hpx::lcos::local::mutex).

  • +
  • Replaced hpx::actions::function with hpx::util::function. +Cleaned up related code.

  • +
  • Removed hpx::traits::handle_gid and moved handling of global reference +counts into the corresponding serialization code.

  • +
  • Changed terminology: prefix is now called locality_id, renamed the +corresponding API functions (such as hpx::get_prefix, which is now called +hpx::get_locality_id).

  • +
  • Adding hpx::find_remote_localities, and +hpx::get_num_localities.

  • +
  • Changed performance counter naming scheme to make it more bash friendly. +The new performance counter naming scheme is now

    +
    /object{parentname#parentindex/instance#index}/counter#parameters
    +
    +
    +
  • +
  • Added hpx::get_worker_thread_num replacing +hpx::threadmanager_base::get_thread_num.

  • +
  • Renamed hpx::get_num_os_threads to hpx::get_os_threads_count.

  • +
  • Added hpx::threads::get_thread_count.

  • +
  • Restructured the Futures sub-system, renaming types in accordance with the +terminology used by the C++11 ISO standard.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release:

+
    +
  • Issue #31 - Specialize handle_gid<> for examples and tests

  • +
  • Issue #72 - Fix AGAS reference counting

  • +
  • Issue #104 - heartbeat throws an exception when decrefing the +performance counter it’s watching

  • +
  • Issue #111 - throttle causes an exception on the target application

  • +
  • Issue #142 - One failed component loading causes an unrelated component +to fail

  • +
  • Issue #165 - Remote exception propagation bug in AGAS reference counting +test

  • +
  • Issue #186 - Test credit exhaustion/splitting (e.g. prepare_gid and +symbol NS)

  • +
  • Issue #188 - Implement remaining AGAS reference counting test cases

  • +
  • Issue #258 - No type checking of GIDs in stubs classes

  • +
  • Issue #271 - Seg fault/shared pointer assertion in distributed code

  • +
  • Issue #281 - CMake options need descriptive text

  • +
  • Issue #283 - AGAS caching broken (gva_cache needs to be rewritten +with ICL)

  • +
  • Issue #285 - HPX_INSTALL root directory not the same as +CMAKE_INSTALL_PREFIX

  • +
  • Issue #286 - New segfault in dataflow applications

  • +
  • Issue #289 - Exceptions should only be logged if not handled

  • +
  • Issue #290 - c++11 tests failure

  • +
  • Issue #293 - Build target for component libraries

  • +
  • Issue #296 - Compilation error with Boost V1.49rc1

  • +
  • Issue #298 - Illegal instructions on termination

  • +
  • Issue #299 - gravity aborts with multiple threads

  • +
  • Issue #301 - Build error with Boost trunk

  • +
  • Issue #303 - Logging assertion failure in distributed runs

  • +
  • Issue #304 - Exception ‘what’ strings are lost when exceptions from +decode_parcel are reported

  • +
  • Issue #306 - Performance counter user interface issues

  • +
  • Issue #307 - Logging exception in distributed runs

  • +
  • Issue #308 - Logging deadlocks in distributed

  • +
  • Issue #309 - Reference counting test failures and exceptions

  • +
  • Issue #311 - Merge AGAS remote_interface with the runtime_support object

  • +
  • Issue #314 - Object tracking for id_types

  • +
  • Issue #315 - Remove handle_gid and handle credit splitting in id_type +serialization

  • +
  • Issue #320 - applier::get_locality_id() should return an error value (or +throw an exception)

  • +
  • Issue #321 - Optimization for id_types which are never split should be +restored

  • +
  • Issue #322 - Command line processing ignored with Boost 1.47.0

  • +
  • Issue #323 - Credit exhaustion causes object to stay alive

  • +
  • Issue #324 - Duplicate exception messages

  • +
  • Issue #326 - Integrate Quickbook with CMake

  • +
  • Issue #329 - –help and –version should still work

  • +
  • Issue #330 - Create pkg-config files

  • +
  • Issue #337 - Improve usability of performance counter timestamps

  • +
  • Issue #338 - Non-std exceptions deriving from std::exceptions in tfunc +may be sliced

  • +
  • Issue #339 - Decrease the number of send_pending_parcels threads

  • +
  • Issue #343 - Dynamically setting the stack size doesn’t work

  • +
  • Issue #351 - ‘make install’ does not update documents

  • +
  • Issue #353 - Disable FIXMEs in the docs by default; add a doc developer +CMake option to enable FIXMEs

  • +
  • Issue #355 - ‘make’ doesn’t do anything after correct configuration

  • +
  • Issue #356 - Don’t use hpx::util::static_ in topology code

  • +
  • Issue #359 - Infinite recursion in hpx::tuple serialization

  • +
  • Issue #361 - Add compile time option to disable logging completely

  • +
  • Issue #364 - Installation seriously broken in r7443

  • +
+
+
+
+
HPX V0.7.0 (Dec 12, 2011)#
+

We have had roughly 1000 commits since the last release and we have closed +approximately 120 tickets (bugs, feature requests, etc.).

+
+
General changes#
+
    +
  • Completely removed code related to deprecated AGAS V1, started to work on AGAS +V2.1.

  • +
  • Started to clean up and streamline the exposed APIs (see ‘API changes’ below +for more details).

  • +
  • Revamped and unified performance counter framework, added a lot of new +performance counter instances for monitoring of a diverse set of internal +HPX parameters (queue lengths, access statistics, etc.).

  • +
  • Improved general error handling and logging support.

  • +
  • Fixed several race conditions, improved overall stability, decreased memory +footprint, improved overall performance (major optimizations include native +TLS support and ranged-based AGAS caching).

  • +
  • Added support for running HPX applications with PBS.

  • +
  • Many updates to the build system, added support for gcc 4.5.x and 4.6.x, added +C++11 support.

  • +
  • Many updates to default command line options.

  • +
  • Added many tests, set up buildbot for continuous integration testing.

  • +
  • Better shutdown handling of distributed applications.

  • +
+
+
+
Example applications#
+
    +
  • quickstart/factorial and quickstart/fibonacci, future-recursive parallel +algorithms.

  • +
  • quickstart/hello_world, distributed hello world example.

  • +
  • quickstart/rma, simple remote memory access example

  • +
  • quickstart/quicksort, parallel quicksort implementation.

  • +
  • gtc, gyrokinetic torodial code.

  • +
  • bfs, breadth-first-search, example code for a graph application.

  • +
  • sheneos, partitioning of large data sets.

  • +
  • accumulator, simple component example.

  • +
  • balancing/os_thread_num, balancing/px_thread_phase, examples demonstrating +load balancing and work stealing.

  • +
+
+
+
API changes#
+
    +
  • Added hpx::find_all_localities.

  • +
  • Added hpx::terminate for non-graceful termination of applications.

  • +
  • Added hpx::lcos::async functions for simpler asynchronous programming.

  • +
  • Added new AGAS interface for handling of symbolic namespace +(hpx::agas::*).

  • +
  • Renamed hpx::components::wait to hpx::lcos::wait.

  • +
  • Renamed hpx::lcos::future_value to hpx::lcos::promise.

  • +
  • Renamed hpx::lcos::recursive_mutex to +hpx::lcos::local_recursive_mutex, hpx::lcos::mutex to +hpx::lcos::local_mutex

  • +
  • Removed support for Boost versions older than V1.38, recommended Boost version +is now V1.47 and newer.

  • +
  • Removed hpx::process (this will be replaced by a real process +implementation in the future).

  • +
  • Removed non-functional LCO code (hpx::lcos::dataflow, +hpx::lcos::thunk, hpx::lcos::dataflow_variable).

  • +
  • Removed deprecated hpx::naming::full_address.

  • +
+
+
+
Bug fixes (closed tickets)#
+

Here is a list of the important tickets we closed for this release:

+
    +
  • Issue #28 - Integrate Windows/Linux CMake code for HPX core

  • +
  • Issue #32 - hpx::cout() should be hpx::cout

  • +
  • Issue #33 - AGAS V2 legacy client does not properly handle error_code

  • +
  • Issue #60 - AGAS: allow for registerid to optionally take ownership of +the gid

  • +
  • Issue #62 - adaptive1d compilation failure in Fusion

  • +
  • Issue #64 - Parcel subsystem doesn’t resolve domain names

  • +
  • Issue #83 - No error handling if no console is available

  • +
  • Issue #84 - No error handling if a hosted locality is treated as the +bootstrap server

  • +
  • Issue #90 - Add general commandline option -N

  • +
  • Issue #91 - Add possibility to read command line arguments from file

  • +
  • Issue #92 - Always log exceptions/errors to the log file

  • +
  • Issue #93 - Log the command line/program name

  • +
  • Issue #95 - Support for distributed launches

  • +
  • Issue #97 - Attempt to create a bad component type in AMR examples

  • +
  • Issue #100 - factorial and factorial_get examples trigger AGAS component +type assertions

  • +
  • Issue #101 - Segfault when hpx::process::here() is called in fibonacci2

  • +
  • Issue #102 - unknown_component_address in int_object_semaphore_client

  • +
  • Issue #114 - marduk raises assertion with default parameters

  • +
  • Issue #115 - Logging messages for SMP runs (on the console) shouldn’t be +buffered

  • +
  • Issue #119 - marduk linking strategy breaks other applications

  • +
  • Issue #121 - pbsdsh problem

  • +
  • Issue #123 - marduk, dataflow and adaptive1d fail to build

  • +
  • Issue #124 - Lower default preprocessing arity

  • +
  • Issue #125 - Move hpx::detail::diagnostic_information out of the detail +namespace

  • +
  • Issue #126 - Test definitions for AGAS reference counting

  • +
  • Issue #128 - Add averaging performance counter

  • +
  • Issue #129 - Error with endian.hpp while building adaptive1d

  • +
  • Issue #130 - Bad initialization of performance counters

  • +
  • Issue #131 - Add global startup/shutdown functions to component modules

  • +
  • Issue #132 - Avoid using auto_ptr

  • +
  • Issue #133 - On Windows hpx.dll doesn’t get installed

  • +
  • Issue #134 - HPX_LIBRARY does not reflect real library name (on Windows)

  • +
  • Issue #135 - Add detection of unique_ptr to build system

  • +
  • Issue #137 - Add command line option allowing to repeatedly evaluate +performance counters

  • +
  • Issue #139 - Logging is broken

  • +
  • Issue #140 - CMake problem on windows

  • +
  • Issue #141 - Move all non-component libraries into $PREFIX/lib/hpx

  • +
  • Issue #143 - adaptive1d throws an exception with the default command +line options

  • +
  • Issue #146 - Early exception handling is broken

  • +
  • Issue #147 - Sheneos doesn’t link on Linux

  • +
  • Issue #149 - sheneos_test hangs

  • +
  • Issue #154 - Compilation fails for r5661

  • +
  • Issue #155 - Sine performance counters example chokes on chrono headers

  • +
  • Issue #156 - Add build type to –version

  • +
  • Issue #157 - Extend AGAS caching to store gid ranges

  • +
  • Issue #158 - r5691 doesn’t compile

  • +
  • Issue #160 - Re-add AGAS function for resolving a locality to its prefix

  • +
  • Issue #168 - Managed components should be able to access their own GID

  • +
  • Issue #169 - Rewrite AGAS future pool

  • +
  • Issue #179 - Complete switch to request class for AGAS server interface

  • +
  • Issue #182 - Sine performance counter is loaded by other examples

  • +
  • Issue #185 - Write tests for symbol namespace reference counting

  • +
  • Issue #191 - Assignment of read-only variable in point_geometry

  • +
  • Issue #200 - Seg faults when querying performance counters

  • +
  • Issue #204 - –ifnames and suffix stripping needs to be more generic

  • +
  • Issue #205 - –list-* and –print-counter-* options do not work together +and produce no warning

  • +
  • Issue #207 - Implement decrement entry merging

  • +
  • Issue #208 - Replace the spinlocks in AGAS with hpx::lcos::local_mutexes

  • +
  • Issue #210 - Add an –ifprefix option

  • +
  • Issue #214 - Performance test for PX-thread creation

  • +
  • Issue #216 - VS2010 compilation

  • +
  • Issue #222 - r6045 context_linux_x86.hpp

  • +
  • Issue #223 - fibonacci hangs when changing the state of an active thread

  • +
  • Issue #225 - Active threads end up in the FEB wait queue

  • +
  • Issue #226 - VS Build Error for Accumulator Client

  • +
  • Issue #228 - Move all traits into namespace hpx::traits

  • +
  • Issue #229 - Invalid initialization of reference in thread_init_data

  • +
  • Issue #235 - Invalid GID in iostreams

  • +
  • Issue #238 - Demangle type names for the default implementation of +get_action_name

  • +
  • Issue #241 - C++11 support breaks GCC 4.5

  • +
  • Issue #247 - Reference to temporary with GCC 4.4

  • +
  • Issue #248 - Seg fault at shutdown with GCC 4.4

  • +
  • Issue #253 - Default component action registration kills compiler

  • +
  • Issue #272 - G++ unrecognized command line option

  • +
  • Issue #273 - quicksort example doesn’t compile

  • +
  • Issue #277 - Invalid CMake logic for Windows

  • +
+
+
+
+
+
+

Namespace changes#

+
+
+
HPX V1.9.0 Namespace changes#
+

The latest release includes amongst others changes in the namespaces so that HPX +facilities correspond to the C++ Standard Library. The old namespaces are +deprecated. Below is a comprehensive list of the namespace changes.

+ + ++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 186 Namespace changes in V1.9.0#

Old namespace

New namespace

hpx::util::mem_fn

hpx::mem_fn

hpx::util::invoke

hpx::invoke

hpx::util::invoke_r

hpx::invoke_r

hpx::util::invoke_fused

hpx::invoke_fused

hpx::util::invoke_fused_r

hpx::invoke_fused_r

hpx::util::unlock_guard

hpx::unlock_guard

hpx::parallel::v1::reduce_by_key

hpx::experimental::reduce_by_key

hpx::parallel::v1::sort_by_key

hpx::experimental::sort_by_key

hpx::parallel::task_canceled_exception

hpx::experimental::task_canceled_exception

hpx::parallel::task_block

hpx::experimental::task_block

hpx::parallel::define_task_block

hpx::experimental::define_task_block |

hpx::parallel::define_task_block_restore_thread

hpx::experimental::define_task_block_restore_thread

hpx::execution::experimental::task_group

hpx::experimental::task_group

+
+
+
+
+
+

Citing HPX#

+

Please cite HPX whenever you use it for publications. Use our paper in The +Journal of Open Source Software as the main citation for HPX: JOSS Paper about HPX. Use +the Zenodo entry for referring to the latest version of HPX: Latest software release of HPX. +Entries for citing specific versions of HPX can also be found at Latest software release of HPX.

+
+
+

HPX users#

+

A list of institutions and projects using HPX can be found on the +HPX Users page.

+
+
+

About HPX#

+
+
+

History#

+

The development of High Performance ParalleX (HPX) began in 2007. At that +time, Hartmut Kaiser became interested in the work done by the ParalleX group at +the Center for Computation and Technology (CCT), a multi-disciplinary research institute at Louisiana State University (LSU). The ParalleX +group was working to develop a new and experimental execution model for future +high performance computing architectures. This model was christened ParalleX. +The first implementations of ParalleX were crude, and many of those designs had +to be discarded entirely. However, over time the team learned quite a bit about +how to design a parallel, distributed runtime system which implements the +concepts of ParalleX.

+

From the very beginning, this endeavour has been a group effort. In addition to +a handful of interested researchers, there have always been graduate and +undergraduate students participating in the discussions, design, and +implementation of HPX. In 2011 we decided to formalize our collective research +efforts by creating the STE||AR group (Systems Technology, Emergent Parallelism, and Algorithm Research). Over time, the +team grew to include researchers around the country and the world. In 2014, the +STE||AR Group was reorganized to become the international community it is +today. This consortium of researchers aims to develop stable, sustainable, and +scalable tools which will enable application developers to exploit the +parallelism latent in the machines of today and tomorrow. Our goal of the HPX +project is to create a high quality, freely available, open source +implementation of ParalleX concepts for conventional and future systems by +building a modular and standards conforming runtime system for SMP and +distributed application environments. The API exposed by HPX is conformant to +the interfaces defined by the C++ ISO Standard and adheres to the programming +guidelines used by the Boost collection of C++ libraries. We steer the +development of HPX with real world applications and aim to provide a smooth +migration path for domain scientists.

+

To learn more about STE||AR and ParalleX, see People and Why HPX?.

+
+
+

People#

+

The STE||AR Group (pronounced as stellar) stands for “Systems Technology, Emergent Parallelism, and Algorithm Research”. We are an international group of faculty, researchers, and +students working at various institutions around the world. The goal of the +STE||AR Group is to promote the development of scalable parallel applications +by providing a community for ideas, a framework for collaboration, and a +platform for communicating these concepts to the broader community.

+

Our work is focused on building technologies for scalable parallel applications. +HPX, our general purpose C++ runtime system for parallel and distributed +applications, is no exception. We use HPX for a broad range of scientific +applications, helping scientists and developers to write code which scales +better and shows better performance compared to more conventional programming +models such as MPI.

+

HPX is based on ParalleX which is a new (and still experimental) parallel +execution model aiming to overcome the limitations imposed by the current +hardware and the techniques we use to write applications today. Our group +focuses on two types of applications - those requiring excellent strong scaling, +allowing for a dramatic reduction of execution time for fixed workloads and +those needing highest level of sustained performance through massive +parallelism. These applications are presently unable (through conventional +practices) to effectively exploit a relatively small number of cores in a +multi-core system. By extension, these application will not be able to exploit +high-end exascale computing systems which are likely to employ hundreds of +millions of such cores by the end of this decade.

+

Critical bottlenecks to the effective use of new generation high performance +computing (HPC) systems include:

+
    +
  • Starvation: due to lack of usable application parallelism and means of +managing it,

  • +
  • Overhead: reduction to permit strong scalability, improve efficiency, and +enable dynamic resource management,

  • +
  • Latency: from remote access across system or to local memories,

  • +
  • Contention: due to multicore chip I/O pins, memory banks, and system +interconnects.

  • +
+

The ParalleX model has been devised to address these challenges by enabling a +new computing dynamic through the application of message-driven computation in a +global address space context with lightweight synchronization. The work on HPX +is centered around implementing the concepts as defined by the ParalleX model. +HPX is currently targeted at conventional machines, such as classical Linux +based Beowulf clusters and SMP nodes.

+

We fully understand that the success of HPX (and ParalleX) is very much the +result of the work of many people. To see a list of who is contributing see our +tables below.

+
+
HPX contributors#
+ + +++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 187 Contributors#

Name

Institution

Email

Hartmut Kaiser

Center for Computation and Technology (CCT), Louisiana State University (LSU)

email_hkaiser

Thomas Heller

Department of Computer Science 3 - Computer Architecture, Friedrich-Alexander University Erlangen-Nuremberg (FAU)

email_theller

Agustin Berge

email_aberge

Mikael Simberg

Swiss National Supercomputing Centre

email_msimberg

John Biddiscombe

Swiss National Supercomputing Centre

email_jbiddiscombe

Anton Bikineev

Center for Computation and Technology (CCT), Louisiana State University (LSU)

email_abikineev

Martin Stumpf

Department of Computer Science 3 - Computer Architecture, Friedrich-Alexander University Erlangen-Nuremberg (FAU)

email_mstumpf

Bryce Adelstein Lelbach

email_blelbach

Shuangyang Yang

Center for Computation and Technology (CCT), Louisiana State University (LSU)

email_syang

Jeroen Habraken

email_jhabraken

Steven Brandt

Center for Computation and Technology (CCT), Louisiana State University (LSU)

email_sbrandt

Antoine Tran Tan

Paris-Saclay University,

email_atrantan

Adrian S. Lemoine

AMD

email_alemoine

Maciej Brodowicz

email_mbrodowicz

Giannis Gonidelis

Center for Computation and Technology (CCT), Louisiana State University (LSU)

email_ggonidelis

+
+
+
Contributors to this document#
+ + +++++ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Table 188 Documentation authors#

Name

Institution

Email

Hartmut Kaiser

Center for Computation and Technology (CCT), Louisiana State University (LSU)

email_hkaiser

Thomas Heller

Department of Computer Science 3 - Computer Architecture, Friedrich-Alexander University Erlangen-Nuremberg (FAU)

email_theller

Bryce Adelstein Lelbach

email_blelbach

Vinay C Amatya

Center for Computation and Technology (CCT), Louisiana State University (LSU)

email_vamatya

Steven Brandt

Center for Computation and Technology (CCT), Louisiana State University (LSU)

email_sbrandt

Maciej Brodowicz

email_mbrodowicz

Adrian S. Lemoine

AMD

email_alemoine

Rebecca Stobaugh

email_rstobaugh

Dimitra Karatza

Faculty of Electrical Engineering, Mathematics & Computer Science, Delft University of Technology

email_dkaratza

Bhumit Attarde

email_bhumitattarde

+
+
+
Acknowledgements#
+

Thanks also to the following people who contributed directly or indirectly to +the project through discussions, pull requests, documentation patches, etc.

+
    +
  • Panos Syskakis for benchmarking and optimizing our parallel algorithms.

  • +
  • Shreyas Atre, for contributing fixes to our implementation of +senders/receivers and extending our coroutines integration with senders/receivers.

  • +
  • Alexander Neumann, for contributing fixes to the cmake build system.

  • +
  • Dimitra Karatza, for her work on refactoring the documentation and providing +a new user-friendly environment during and after Google Season of Docs 2021.

  • +
  • Srinivas Yadav, for his work on SIMD support in algorithms before and during +Google Summer of Code 2021.

  • +
  • Akhil Nair, for his work on adapting algorithms to C++20 before and during +Google Summer of Code 2021.

  • +
  • Alexander Toktarev, for updating the parallel algorithm customization points +to use tag_fallback_invoke for the default implementations.

  • +
  • Brice Goglin, for reporting and helping fix issues related to the integration +of hwloc in HPX.

  • +
  • Giannis Gonidelis, for his work on the ranges adaptation during the +Google Summer of Code 2020.

  • +
  • Auriane Reverdell (Swiss National Supercomputing Centre), for her tireless work on refactoring our CMake +setup and modularizing HPX.

  • +
  • Christopher Hinz, for his work on refactoring our CMake setup.

  • +
  • Weile Wei, for fixing HPX builds with CUDA on Summit.

  • +
  • Severin Strobl, for fixing our CMake setup related to linking and adding new +entry points to the HPX runtime.

  • +
  • Rebecca Stobaugh, for her major documentation review and contributions +during and after the 2019 Google Season of Documentation.

  • +
  • Jan Melech, for adding automatic serialization of simple structs.

  • +
  • Austin McCartney, for adding concept emulation of the Ranges TS bidirectional +and random access iterator concepts.

  • +
  • Marco Diers, reporting and fixing issues related PMIx.

  • +
  • Maximilian Bremer, for reporting multiple issues and extending the component +migration tests.

  • +
  • Piotr Mikolajczyk, for his improvements and fixes to the set and count +algorithms.

  • +
  • Grant Rostig, for reporting several deficiencies on our web pages.

  • +
  • Jakub Golinowski, for implementing an HPX backend for OpenCV and in the +process improving documentation and reporting issues.

  • +
  • Mikael Simberg (Swiss National Supercomputing Centre), for his tireless help cleaning up and maintaining +HPX.

  • +
  • Tianyi Zhang, for his work on HPXMP.

  • +
  • Shahrzad Shirzad, for her contributions related to Phylanx.

  • +
  • Christopher Ogle, for his contributions to the parallel algorithms.

  • +
  • Surya Priy, for his work with statistic performance counters.

  • +
  • Anushi Maheshwari, for her work on random number generation.

  • +
  • Bruno Pitrus, for his work with parallel algorithms.

  • +
  • Nikunj Gupta, for rewriting the implementation of hpx_main.hpp and for his +fixes for tests.

  • +
  • Christopher Taylor, for his interest in HPX and the fixes he provided. Chris +also contributed support for RISC-V architectures.

  • +
  • Shoshana Jakobovits, for her work on the resource partitioner.

  • +
  • Denis Blank, who re-wrote our unwrapped function to accept plain values +arbitrary containers, and properly deal with nested futures.

  • +
  • Ajai V. George, who implemented several of the parallel algorithms.

  • +
  • Taeguk Kwon, who worked on implementing parallel algorithms as well as +adapting the parallel algorithms to the Ranges TS.

  • +
  • Zach Byerly (Louisiana State University (LSU)), who in his work developing applications on top of HPX +opened tickets and contributed to the HPX examples.

  • +
  • Daniel Estermann, for his work porting HPX to the Raspberry Pi.

  • +
  • Alireza Kheirkhahan (Louisiana State University (LSU)), who built and administered our local cluster as +well as his work in distributed IO.

  • +
  • Abhimanyu Rawat, who worked on stack overflow detection.

  • +
  • David Pfander, who improved signal handling in HPX, provided his +optimization expertise, and worked on incorporating the Vc vectorization into +HPX.

  • +
  • Denis Demidov, who contributed his insights with VexCL.

  • +
  • Khalid Hasanov, who contributed changes which allowed to run HPX on 64Bit +power-pc architectures.

  • +
  • Zahra Khatami (Louisiana State University (LSU)), who contributed the prefetching iterators and the +persistent auto chunking executor parameters implementation.

  • +
  • Marcin Copik, who worked on implementing GPU support for C++AMP and HCC. He +also worked on implementing a HCC backend for HPX.Compute.

  • +
  • Minh-Khanh Do, who contributed the implementation of several segmented +algorithms.

  • +
  • Bibek Wagle (Louisiana State University (LSU)), who worked on fixing and analyzing the performance of +the parcel coalescing plugin in HPX.

  • +
  • Lukas Troska, who reported several problems and contributed various test cases +allowing to reproduce the corresponding issues.

  • +
  • Andreas Schaefer, who worked on integrating his library (LibGeoDecomp) with HPX. +He reported various problems and submitted several patches to fix issues +allowing for a better integration with LibGeoDecomp.

  • +
  • Satyaki Upadhyay, who contributed several examples to HPX.

  • +
  • Brandon Cordes, who contributed several improvements to the inspect tool.

  • +
  • Harris Brakmic, who contributed an extensive build system description for +building HPX with Visual Studio.

  • +
  • Parsa Amini (Louisiana State University (LSU)), who refactored and simplified the implementation of +AGAS in HPX and who works on its implementation and optimization.

  • +
  • Luis Martinez de Bartolome who implemented a build system extension for HPX +integrating it with the Conan C/C++ package manager.

  • +
  • Vinay C Amatya (Louisiana State University (LSU)), who contributed to the documentation and provided +some of the HPX examples.

  • +
  • Kevin Huck and Nick Chaimov (University of Oregon), who contributed the integration of APEX +(Autonomic Performance Environment for eXascale) with HPX.

  • +
  • Francisco Jose Tapia, who helped with implementing the parallel sort algorithm +for HPX.

  • +
  • Patrick Diehl, who worked on implementing CUDA support for our companion +library targeting GPGPUs (HPXCL).

  • +
  • Eric Lemanissier contributed fixes to allow compilation using the MingW +toolchain.

  • +
  • Nidhi Makhijani who helped cleaning up some enum consistencies in HPX and +contributed to the resource manager used in the thread scheduling subsystem. +She also worked on HPX in the context of the Google Summer of Code 2015.

  • +
  • Larry Xiao, Devang Bacharwar, Marcin Copik, and Konstantin Kronfeldner who +worked on HPX in the context of the Google Summer of Code program 2015.

  • +
  • Daniel Bourgeois (Center for Computation and Technology (CCT)) who contributed to HPX the implementation of +several parallel algorithms (as proposed by N4313).

  • +
  • Anuj Sharma and Christopher Bross (Department of Computer Science 3 - Computer Architecture), who worked on HPX in the +context of the Google Summer of Code program 2014.

  • +
  • Martin Stumpf (Department of Computer Science 3 - Computer Architecture), who rebuilt our contiguous testing infrastructure +(see the HPX Buildbot Website). Martin is also working on HPXCL (mainly all work +related to OpenCL) and implementing an HPX backend for POCL, a +portable computing language solution based on OpenCL.

  • +
  • Grant Mercer (University of Nevada, Las Vegas), who helped creating many of the parallel algorithms +(as proposed by N4313).

  • +
  • Damond Howard (Louisiana State University (LSU)), who works on HPXCL (mainly all work related to +CUDA).

  • +
  • Christoph Junghans (Los Alamos National Lab), who helped making our +buildsystem more portable.

  • +
  • Antoine Tran Tan (Laboratoire de Recherche en Informatique, Paris), who worked +on integrating HPX as a backend for NT2. He also contributed an +implementation of an API similar to Fortran co-arrays on top of HPX.

  • +
  • John Biddiscombe (Swiss National Supercomputing Centre), who helped with the BlueGene/Q port of HPX, +implemented the parallel sort algorithm, and made several other contributions.

  • +
  • Erik Schnetter (Perimeter Institute for Theoretical Physics), who greatly +helped to make HPX more robust by submitting a large amount of problem +reports, feature requests, and made several direct contributions.

  • +
  • Mathias Gaunard (Metascale), who contributed several patches to reduce compile +time warnings generated while compiling HPX.

  • +
  • Andreas Buhr, who helped with improving our documentation, especially by +suggesting some fixes for inconsistencies.

  • +
  • Patricia Grubel (New Mexico State University), who contributed the description of the different +HPX thread scheduler policies and is working on the performance analysis of +our thread scheduling subsystem.

  • +
  • Lars Viklund, whose wit, passion for testing, and love of odd architectures +has been an amazing contribution to our team. He has also contributed platform +specific patches for FreeBSD and MSVC12.

  • +
  • Agustin Berge, who contributed patches fixing some very nasty hidden template +meta-programming issues. He rewrote large parts of the API elements ensuring +strict conformance with the C++ ISO Standard.

  • +
  • Anton Bikineev for contributing changes to make using boost::lexical_cast +safer, he also contributed a thread safety fix to the iostreams module. He +also contributed a complete rewrite of the serialization infrastructure +replacing Boost.Serialization inside HPX.

  • +
  • Pyry Jahkola, who contributed the Mac OS build system and build documentation +on how to build HPX using Clang and libc++.

  • +
  • Mario Mulansky, who created an HPX backend for his Boost.Odeint library, and +who submitted several test cases allowing us to reproduce and fix problems in +HPX.

  • +
  • Rekha Raj, who contributed changes to the description of the Windows build +instructions.

  • +
  • Jeremy Kemp how worked on an HPX OpenMP backend and added regression tests.

  • +
  • Alex Nagelberg for his work on implementing a C wrapper API for HPX.

  • +
  • Chen Guo, helvihartmann, Nicholas Pezolano, and John West who added and +improved examples in HPX.

  • +
  • Joseph Kleinhenz, Markus Elfring, Kirill Kropivyansky, Alexander Neundorf, +Bryant Lam, and Alex Hirsch who improved our CMake.

  • +
  • Tapasweni Pathak, Praveen Velliengiri, Jean-Loup Tastet, Michael Levine, Aalekh Nigam, +HadrienG2, Prayag Verma, lslada, Alex Myczko, and Avyav Kumar +who improved the documentation.

  • +
  • Jayesh Badwaik, J. F. Bastien, Christoph Garth, Christopher Hinz, Brandon +Kohn, Mario Lang, Maikel Nadolski, pierrele, hendrx, Dekken, woodmeister123, +xaguilar, Andrew Kemp, Dylan Stark, Matthew Anderson, Jeremy Wilke, Jiazheng +Yuan, CyberDrudge, david8dixon, Maxwell Reeser, Raffaele Solca, Marco +Ippolito, Jules Penuchot, Weile Wei, Severin Strobl, Kor de Jong, albestro, +Jeff Trull, Yuri Victorovich, and Gregor Daiß who contributed to the general +improvement of HPX.

  • +
+

HPX Funding Acknowledgements lists current and past funding sources for HPX. Special thanks to +Google Summer of Code and Google Season of Docs for the continuous support they provide which helps us enhance both our +code and our documentation.

+
+
+
+
+
+
+
+

Index#

+ +
+
+ + +
+ +