aioprocessing provides asynchronous, asyncio compatible, coroutine
versions of many blocking instance methods on objects in the multiprocessing
library. Here's an example demonstrating the aioprocessing versions of
Event, Queue, and Lock:
import time
import asyncio
import aioprocessing
import multiprocessing
def func(queue, event, lock, items):
""" Demo worker function.
This worker function runs in its own process, and uses
normal blocking calls to aioprocessing objects, exactly
the way you would use oridinary multiprocessing objects.
"""
with lock:
event.set()
for item in items:
time.sleep(3)
queue.put(item+5)
queue.close()
@asyncio.coroutine
def example(queue, event, lock):
l = [1,2,3,4,5]
p = aioprocessing.AioProcess(target=func, args=(queue, event, lock, l))
p.start()
while True:
result = yield from queue.coro_get()
if result is None:
break
print("Got result {}".format(result))
yield from p.coro_join()
@asyncio.coroutine
def example2(queue, event, lock):
yield from event.coro_wait()
with (yield from lock):
yield from queue.coro_put(78)
yield from queue.coro_put(None) # Shut down the worker
if __name__ == "__main__":
loop = asyncio.get_event_loop()
queue = aioprocessing.AioQueue()
lock = aioprocessing.AioLock()
event = aioprocessing.AioEvent()
tasks = [
asyncio.async(example(queue, event, lock)),
asyncio.async(example2(queue, event, lock)),
]
loop.run_until_complete(asyncio.wait(tasks))
loop.close()The aioprocessing objects can be used just like their multiprocessing
equivalents - as they are in func above - but they can also be
seamlessly used inside of asyncio coroutines, without ever blocking
the event loop.
In most cases, this library makes blocking calls to multiprocessing methods
asynchronous by executing the call in a ThreadPoolExecutor, using
asyncio.run_in_executor().
It does not re-implement multiprocessing using asynchronous I/O. This means
there is extra overhead added when you use aioprocessing objects instead of
multiprocessing objects, because each one is generally introducing a
ThreadPoolExecutor containing at least one threading.Thread. It also means
that all the normal risks you get when you mix threads with fork apply here, too
(See http://bugs.python.org/issue6721 for more info).
The one exception to this is aioprocessing.AioPool, which makes use of the
existing callback and error_callback keyword arguments in the various
Pool.*_async methods to run them as asyncio coroutines. Note that
multiprocessing.Pool is actually using threads internally, so the thread/fork
mixing caveat still applies.
Each multiprocessing class is replaced by an equivalent aioprocessing class,
distinguished by the Aio prefix. So, Pool becomes AioPool, etc. All methods
that could block on I/O also have a coroutine version that can be used with asyncio. For example, multiprocessing.Lock.acquire() can be replaced with aioprocessing.AioLock.coro_acquire().
Note that you can also use the aioprocessing synchronization primitives as replacements for their equivalent threading primitives, in single-process, multi-threaded programs that use asyncio.
Most of them! All methods that could do blocking I/O in the following objects
have equivalent versions in aioprocessing that extend the multiprocessing
versions by adding coroutine versions of all the blocking methods.
PoolProcessPipeLockRLockSemaphoreBoundedSemaphoreEventConditionBarrierconnection.Connectionconnection.Listenerconnection.ClientQueueJoinableQueueSimpleQueue- All
managers.SyncManagerProxyversions of the items above (SyncManager.Queue,SyncManager.Lock(), etc.).
aioprocessing will work out of the box on Python 3.4+, and will also work with Python 3.3 if you install the PyPI version of asyncio.
This project is currently in alpha stages, and likely has bugs. Use at your own risk. (I do appreciate bug reports, though :).