This is the official Quil-Lang Quantum Virtual Machine (QVM), a flexible and efficient simulator for Quil.
This directory contains two projects. The first, qvm
, is a classical
implementation of the Quantum Abstract Machine (QAM), called a
"Quantum Virtual Machine" (QVM). The second, qvm-app
, is the
application interface to interacting with the QVM, either directly
through the qvm
binary or via its server interface.
The definition of the QAM was developed at Rigetti in a paper titled A Practical Quantum Instruction Set Architecture.
The QVM library is contained within ./src/
, and provides the
implementation of the Quantum Abstract Machine. It evaluates Quil
programs (parsed and compiled by quilc) on a virtual machine that can
model various characteristics of (though without needing access to) a
true quantum computer.
The library is released under the Apache license 2.0.
The QVM library is available on Quicklisp, but of course may not have the latest features. It can be loaded simply with:
* (ql:quickload :qvm)
Alternatively, one can download and load it manually. Please read and follow
the instructions in lisp-setup.md#install-quicklisp
to get Quicklisp
installed. Pay particular attention to the section "Telling Quicklisp
Where Your Code Is".
Download both this repository and quilc into the
ql:*local-project-directories*
location. If all is correct, the qvm
library can be loaded with
$ sbcl
* (ql:quickload :qvm)
(:QVM)
QVM objects are created with (qvm:make-qvm n)
where n
is the number of
qubits the QVM should support; a program can then be loaded into the
QVM object with (qvm:load-program *qvm* *program*)
where *qvm*
is a
QVM object and *program*
is a cl-quil:parsed-program
object.
Alternatively, the qvm:run-program
function will handle QVM object
creation. For example,
* (setq *qvm* (qvm:run-program 2 (cl-quil:parse-quil "H 0")))
creates a 2-qubit QVM object and on it runs the Quil program H 0
.
The qubit amplitudes can be inspected
* (qvm::amplitudes *qvm*)
#(#C(0.7071067811865475d0 0.0d0) #C(0.7071067811865475d0 0.0d0)
#C(0.0d0 0.0d0) #C(0.0d0 0.0d0))
which shows, as expected, that H 0
has put qubit-0 (the first two
complex numbers above) into an equal superposition of states |0>
and
|1>
.
Measurement of a quantum state causes it to collapse into one of its
basis states (|0>
or |1>
). This can be simulated with
* (qvm:measure-all *qvm*)
#<PURE-STATE-QVM {1004039753}>
(0 0)
Inspecting the QVM object's state shows that this effect mutates the information stored on the QVM; i.e. the previous state information is lost
* (qvm::amplitudes *qvm*)
#(#C(1.0d0 0.0d0) #C(0.0d0 0.0d0)
#C(0.0d0 0.0d0) #C(0.0d0 0.0d0))
Qubit zero's state has collapsed into the state |0>
. Repeating this
process (from creating the QVM object to measuring qubits) would show
that both states would each come up with probability 0.5.
* (loop :with results := (vector 0 0)
:with program := (cl-quil:parse-quil "H 0")
:repeat 100
:for (qvm state) := (multiple-value-list (qvm:measure (qvm:run-program 1 program) 0))
:do (incf (aref results state))
:finally (return results))
#(54 46)
The QVM comes with some example code to illustrate usage of the
QVM. The example code can be found under ./examples/
. To run the
example code, first load qvm-examples
* (ql:quickload :qvm-examples)
(:QVM-EXAMPLES)
The function bit-reversal-circuit
takes a list of qubit indices and
returns a list of instructions that will reverse the qubit amplitudes
in "bit-reversal order" (e.g., the coefficient of |1110>
gets
mapped to |0111>
):
(qvm-examples:bit-reversal-circuit '(1 2 3 4))
(#<SWAP 1 4> #<SWAP 2 3>)
For a given list of qubit indices, the function qft-circuit
returns a
Quantum Fourier transform Quil program ready to be passed to quilc for
compilation.
* (qvm-examples:qft-circuit '(1 2 3 4))
#<CL-QUIL:PARSED-PROGRAM {10040ABEE3}>
To inspect the object, we can use the cl-quil::print-parsed-program
function
* (cl-quil::print-parsed-program (qvm-examples:qft-circuit '(1 2 3 4)))
H 4
CPHASE(pi/2) 3 4
H 3
CPHASE(pi/4) 2 4
CPHASE(pi/2) 2 3
H 2
CPHASE(pi/8) 1 4
CPHASE(pi/4) 1 3
CPHASE(pi/2) 1 2
H 1
SWAP 1 4
SWAP 2 3
The QVM application is contained with ./app/src/
, and provides a
stand-alone interface to the QVM library. It can be invoked directly
with the binary executable, or alternatively it can provide a server
that can be used over the network. Each has their benefits: the former
permits a simplified interface using the command-line switches (see
output of qvm --help
), while the latter allows many remote connections
to a single in-memory QVM.
The application is released under the GNU Affero General Public License v3.0.
To build the QVM application follow instructions in
lisp-setup.md
. In the top-level directory, run
the Makefile
with
$ make qvm
This will produce a binary executable qvm
in the same directory.
In some situtations, using a large number of qubits may cause heap exhaustion. There are two options to ameliorate this.
The first is to increase the memory available for the QVM, recompile and specify the workspace size (in MB)
$ make QVM_WORKSPACE=4096 qvm
$ make install
The second is to use a different allocator when running the QVM, by
using the --default-allocator
argument with "foreign"
. For
example, to run a 30 qubit benchmark on a QVM configured for far less
memory, one can do:
$ qvm --default-allocator "foreign" --benchmark 30 -c
This is not the default since this memory is not fully managed by the application.
The QVM application has a few command-line switches used to configure the QVM. To explore those options, see the output of the following command:
$ qvm --help
By default, the QVM accepts programs from stdin and writes results to stdout. Log messages are written to stderr.
Note: If you're on Windows and using the Command Prompt, the echo command is slightly different to the examples shown below: do not wrap your quil code in quotes. For example, in Command Prompt, you would do
echo H 0 | qvm
notecho "H 0" | qvm
.
$ echo 'H 0' | qvm
******************************
* Welcome to the Rigetti QVM *
******************************
Copyright (c) 2016-2019 Rigetti Computing.
(Configured with 8192 MiB of workspace and 8 workers.)
<134>1 2019-03-07T22:56:55Z workstation.local qvm 21177 - - Selected simulation method: pure-state
<134>1 2019-03-07T22:56:55Z workstation.local qvm 21177 - - Reading program.
<134>1 2019-03-07T22:56:55Z workstation.local qvm 21177 - - Allocating memory for QVM of 1 qubits.
<134>1 2019-03-07T22:56:55Z workstation.local qvm 21177 - - Allocation completed in 7 ms.
<134>1 2019-03-07T22:56:55Z workstation.local qvm 21177 - - Loading quantum program.
<134>1 2019-03-07T22:56:55Z workstation.local qvm 21177 - - Executing quantum program.
<134>1 2019-03-07T22:56:55Z workstation.local qvm 21177 - - Execution completed in 4 ms.
<134>1 2019-03-07T22:56:55Z workstation.local qvm 21177 - - Printing classical memory and 1-qubit state.
Classical memory (low -> high indexes):
No memory.
Amplitudes:
|0>: 0.7071067811865475, P= 50.0%
|1>: 0.7071067811865475, P= 50.0%
Alternatively the QVM can be started as a server that will accept instructions over a network connection
$ qvm -S
******************************
* Welcome to the Rigetti QVM *
******************************
Copyright (c) 2016-2019 Rigetti Computing.
(Configured with 2048 MiB of workspace and 8 workers.)
<134>1 2019-01-28T19:06:07Z workstation.local qvm 3118 - - Selected simulation method: pure-state
<134>1 2019-01-28T19:06:07Z workstation.local qvm 3118 - - Starting server on port 5000.
This is how the pyQuil Python library communicates with a QVM.
Tests can be run from the Makefile
make test
or from within SBCL
* (asdf:test-system :qvm)
Any contribution to this project should foremost not break any current tests (run tests before making a pull request), and should be accompanied by relevant new tests.
Lisp caches a lot of builds so that not every single file needs to be recompiled. In rare instances, there's confusion and the cache doesn't get properly invalidated. (This can happen when moving files across machines, for example.) Lisp's cache and Quicklisp's system index can be cleaned by doing the following command:
make cleanall
This will delete any built executables as well.
The CI pipeline for qvm
produces a Docker image, available at
rigetti/qvm
.
To get the latest stable version of qvm
, run docker pull rigetti/qvm
.
To instead pull a specific version of the QVM, run docker pull rigetti/qvm:VERSION
,
where VERSION
is something like 1.10.0
.
Additionally, all branches and commits for the QVM repository have corresponding
image tags. For example, the image that contains the HEAD of branch "qvm-fixes"
can be pulled with docker pull rigetti/qvm:qvm-fixes
(NOTE: some characters are
invalid in Docker image tags, and are rewritten according to the description of
CI_COMMIT_REF_SLUG
).
The image built from the commit with first eight characters abcd1234
can be
pulled with docker pull rigetti/qvm:abcd1234
.
The Dockerfile for qvm builds from two parent Docker images:
rigetti/lisp
: Contains SBCL, Quicklisp, and third-party libraries.rigetti/quilc
: Contains the Quil Compiler.
The Dockerfile for qvm intentionally pins the versions of these two images, which means that the version numbers must be actively incremented as necessary. If the build for qvm is failing, this is probably the place to look, because the unit tests are run inside of a freshly-built qvm Docker image as part of the GitLab CI pipeline.
However, because the development workflow for the QVM often involves having
a locally cloned copy of quilc master, there are two additional CI jobs that
override the version of quilc and instead build off of rigetti/quilc:edge
,
which corresponds to the HEAD of master. These jobs are optional, meaning that
if they fail the overall CI pipeline will not be marked as a failure, but they
provide additional useful information to those that develop quilc and the QVM
in unison.
As outlined above, the QVM supports two modes of operation: stdin and server.
To run the qvm
in stdin mode, do the following:
echo "H 0" | docker run --rm -i rigetti/qvm
To run the qvm
in server mode, do the following:
docker run --rm -it -p 5000:5000 rigetti/qvm -S
If you would like to change the port of the server to PORT
, you can alter the command as follows:
docker run --rm -it -p PORT:PORT rigetti/qvm -S -p PORT
Port 5000 is exposed using the EXPOSE directive in the rigetti/qvm
image, so you can
additionally use the -P
option to automatically bind this container port to a randomly
assigned host port. You can then inspect the mapping using docker port CONTAINER [PORT]
.
- Update
VERSION.txt
and push the commit tomaster
. - Push a git tag
vX.Y.Z
that contains the same version number as inVERSION.txt
. - Verify that the resulting build (triggered by pushing the tag) completes successfully.
- Publish a release using the tag as the name.
- Close the milestone associated with this release, and migrate incomplete issues to the next one.
- Update the qvm version of downstream dependencies (if applicable, see next section).
Currently, there are a couple different components of the Forest SDK that depend on the QVM:
It is the responsibility of the releaser to verify that the latest QVM release does not break the test suites of these downstream dependencies. All of these repositories pull the latest released version of the QVM as part of their CI pipelines.
The QVM library and application can be built with support for optional
features specified by the *features*
flag in lisp.
Feature Flag | Description |
---|---|
qvm-intrinsics |
Enable assembly intrinsics in the build, enabling optimized functions based on processor support. Currently supports AVX2 matrix multiplication. |
To build with specific flags enabled, set the QVM_FEATURES
variable while building:
$ make QVM_FEATURES='FEATURES' qvm
Note: Cache needs to be cleaned when adding new feature flags to ensure libraries compile with correct flags.