This library provides C bindings to more or less all of the python3 C API.
WARNING: Note that the python 3 C API might be quite stable, BUT the ABI is not, which means if you compiled with a certain minor version (3.7.1) you should run your program with the same minor version (3.7.x). (Using docker or nix to package your program is enough to avoid this problem)
The easiest way to get started is to import CPython.Simple
The Simple
API surface is fairly small, so if you're doing something fancy you may need to dip into other parts of CPython
initialize :: IO ()
kicks off talking to Python, and will need to be called before using other functions.
The ToPy
and FromPy
instances are what let us convert Haskell values to and from the corresponding Python values. There are easyToPy
and easyFromPy
helpers to help you easily write your own instances in common cases. If you find an instance for some common Haskell type is missing, please submit a PR!
Arg
is a type representing an argument to a Python function, which lets us use various Haskell types in the same list of arguments.
sampleArgs :: [Arg]
sampleArgs =
[ arg (7 :: Integer)
, arg ("hello" :: Text)
]
The most common use case is to call some Python function, which we can do with call
call
:: FromPy a
=> Text -- ^ module name
-> Text -- ^ function name
-> [Arg] -- ^ args
-> [(Text, Arg)] -- ^ keyword args
-> IO a
For example, if we wanted to wrap Python's random.randint(low, high)
, we could write this:
randint :: Integer -> Integer -> IO Integer
randint low high =
call "random" "randint" [arg low, arg high] []
Because of the FromPy
instance in call
's type signature, we can infer what to do to convert a Python value back into Haskell, if given the type
uniform :: Integer -> Integer -> IO Double
uniform low high =
call "random" "uniform" [arg low, arg high] []
We can also use the TypeApplications
language extension to do this, if needed
call @Double "random" "uniform" [arg low, arg high] []
Calling a function with mixed positional and keyword arguments is also fairly straightforward:
moveToDuration :: Integer -> Integer -> Double -> IO ()
moveToDuration x y seconds =
call "pyautogui" "moveTo" [arg x, arg y] [("duration", arg seconds)]
getAttribute
lets us get the value of an attribute of some Python module
getAttribute
:: FromPy a
=> Text -- ^ module name
-> Text -- ^ attribute name
-> IO a
Here, we get the value of random.BPF
getBpf :: IO Integer
getBpf = getAttribute "random" "BPF"
Likewise, setAttribute
lets us set the value of an attribute
setAttribute
:: ToPy a
=> Text -- ^ module name
-> Text -- ^ attribute name
-> a -- ^ value to set attribute to
-> IO ()
Here's how we can set random.BPF
to some given number n
setBpf :: Integer -> IO ()
setBpf n = setAttribute "random" "BPF" n
Sometimes it might be useful to use the less simpler API, especially if you are already familiar with the CPython C API. This API comes with one-on-one connections between the C API methods and the Haskell methods, but you won't have to write FFI code directly (like calling incref/decref for Python GC).
After you are familiar with the concepts from the C API, you can search for methods in the API docs on hackage
These examples below should help you start with using the API, by showing the equivalent haskell code to implement the same as the python example.
sumWithPy :: [Integer] -> IO Int
sumWithPy intlist = do
testList <- traverse toObj intlist >>= PyList.toList >>= (return . Py.toObject)
builtinsModule <- Py.importModule "builtins"
sumFunc <- PyUnicode.toUnicode "sum" >>= Py.getAttribute builtinsModule
args <- PyTuple.toTuple [testList]
kwargs <- PyDict.new
Py.call sumFunc args kwargs >>= castToNumber >>= Py.toInteger >>= PyInt.fromInteger
where
castToNumber obj = do x <- Py.castToNumber obj
return $ fromMaybe (error "not a number returned from the sum") x
toObj integer = fmap Py.toObject $ PyInt.toInteger integer
This example should show you how different it is to call python from strongly typed code, because you have to handle every bit of the errors, like getting an attribute of a module or just creating new python objects.
intlist = [1, 10, 100, 42]
sum(intlist)
This example is an approach to handle python exceptions, like python would do it, so if an exception comes, we print a traceback
{-# LANGUAGE OverloadedStrings #-}
module Main
( main ) where
import qualified CPython as Py
import qualified CPython.Types.Module as Py
import qualified CPython.Types.Dictionary as PyDict
import qualified CPython.Types.List as PyList
import qualified CPython.Types.Tuple as PyTuple
import qualified CPython.Types.Unicode as PyUnicode
import qualified CPython.Types.Exception as PyExc
import Data.Text()
import Control.Exception(handle)
main :: IO ()
main = handle pyExceptionHandler $ do
Py.initialize
callingSomePython
Py.finalize
where
pyExceptionHandler :: PyExc.Exception -> IO ()
pyExceptionHandler exception = handle pyExceptionHandlerWithoutPythonTraceback $ do
tracebackModule <- Py.importModule "traceback"
print_exc <- PyUnicode.toUnicode "print_exception" >>= Py.getAttribute tracebackModule
kwargs <- PyDict.new
args <- case PyExc.exceptionTraceback exception of
Just tb -> PyTuple.toTuple [PyExc.exceptionType exception, PyExc.exceptionValue exception, tb]
_ -> PyTuple.toTuple [PyExc.exceptionType exception, PyExc.exceptionValue exception]
_ <- Py.call print_exc args kwargs
return ()
pyExceptionHandlerWithoutPythonTraceback :: PyExc.Exception -> IO ()
pyExceptionHandlerWithoutPythonTraceback exception = do
print exception
putStrLn "Unexpected Python exception (Please report a bug)"
callingSomePython :: IO ()
callingSomePython = do ...