126

For C++, we can use OpenMP to do parallel programming; however, OpenMP will not work for Python. What should I do if I want to parallel some parts of my python program?

The structure of the code may be considered as:

 solve1(A)
 solve2(B)

Where solve1 and solve2 are two independent function. How to run this kind of code in parallel instead of in sequence in order to reduce the running time? Hope someone can help me. Thanks very much in advance. The code is:

def solve(Q, G, n):
    i = 0
    tol = 10 ** -4

    while i < 1000:
        inneropt, partition, x = setinner(Q, G, n)
        outeropt = setouter(Q, G, n)

        if (outeropt - inneropt) / (1 + abs(outeropt) + abs(inneropt)) < tol:
            break

        node1 = partition[0]
        node2 = partition[1]

        G = updateGraph(G, node1, node2)

        if i == 999:
            print "Maximum iteration reaches"
    print inneropt

Where setinner and setouter are two independent functions. That's where I want to parallel...

  • 27
    Take a look at multiprocessing. Note: Python's threads are not suitable for CPU-bound tasks, only for I/O-bound. – 9000 Dec 12 '13 at 16:22
  • 4
    @9000 +100 internets for mentioning the CPU vs I/O dependent tasks. – Hyperboreus Dec 12 '13 at 16:23
  • 6
    @OmarIthawi: why, threads work fine if you have many CPU cores (as usual now). Then your process can run several threads loading all these cores in parallel and sharing common data between them implicitly (that is, without having an explicit shared memory area or inter-process messaging). – 9000 Dec 12 '13 at 17:14
  • 5
    This was marked as a duplicate of a question that already has an answer, but that question has no visible answers. This question is NOT a duplicate and is specific enough to have been answered; that answer has 41 (click), no, 42, upvotes! – Peter K. May 6 '16 at 12:45
  • 1
    @user2134774: Well, yes, my second comment makes little sense. Probably the only C extensions that release the GIL can benefit from that; e.g. parts of NumPy and Pandas do that. On other cases, it is wrong (but I cannot edit it now). – 9000 Jul 23 '16 at 14:48
147

You can use the multiprocessing module. For this case I might use a processing pool:

from multiprocessing import Pool
pool = Pool()
result1 = pool.apply_async(solve1, [A])    # evaluate "solve1(A)" asynchronously
result2 = pool.apply_async(solve2, [B])    # evaluate "solve2(B)" asynchronously
answer1 = result1.get(timeout=10)
answer2 = result2.get(timeout=10)

This will spawn processes that can do generic work for you. Since we did not pass processes, it will spawn one process for each CPU core on your machine. Each CPU core can execute one process simultaneously.

If you want to map a list to a single function you would do this:

args = [A, B]
results = pool.map(solve1, args)

Don't use threads because the GIL locks any operations on python objects.

  • 1
    does pool.map also accepts dictionaries as args? Or only simple lists? – The Bndr Jun 10 '15 at 13:44
  • Just lists I think. But you can just pass in dict.items() which will be a list of key value tuples – Matt Williamson Jun 10 '15 at 14:00
  • Unfortunately this ends in an ` unhashable type: 'list'` error – The Bndr Jun 10 '15 at 14:55
  • in addition to my last comment: ` dict.items()` work. The error raises, because I had to change the handling of the variable insight the process-funktion. Unfortunately the error-message was not very helpful... So: thank you for your hint. :-) – The Bndr Jun 10 '15 at 15:41
  • 2
    What is timeout here? – gamma Aug 7 '16 at 18:22
18

This can be done very elegantly with Ray.

To parallelize your example, you'd need to define your functions with the @ray.remote decorator, and then invoke them with .remote.

import ray

ray.init()

# Define the functions.

@ray.remote
def solve1(a):
    return 1

@ray.remote
def solve2(b):
    return 2

# Start two tasks in the background.
x_id = solve1.remote(0)
y_id = solve2.remote(1)

# Block until the tasks are done and get the results.
x, y = ray.get([x_id, y_id])

There are a number of advantages of this over the multiprocessing module.

  1. The same code will run on a multicore machine as well as a cluster of machines.
  2. Processes share data efficiently through shared memory and zero-copy serialization.
  3. Error messages are propagated nicely.
  4. These function calls can be composed together, e.g.,

    @ray.remote
    def f(x):
        return x + 1
    
    x_id = f.remote(1)
    y_id = f.remote(x_id)
    z_id = f.remote(y_id)
    ray.get(z_id)  # returns 4
    
  5. In addition to invoking functions remotely, classes can be instantiated remotely as actors.

Note that Ray is a framework I've been helping develop.

  • i keep getting an error that says" Could not find a version that satisfies the requirement ray (from versions: ) No matching distribution found for ray" when trying to install the package in python – alwaysaskingquestions Feb 16 '18 at 18:09
  • 2
    Usually this kind of error means that you need to upgrade pip. I'd suggest trying pip install --upgrade pip. If you need to use sudo at all then it's possible that the version of pip that you're using to install ray is not the same one that is getting upgraded. You can check with pip --version. Also, Windows is currently not supported so if you're on Windows that is probably the problem. – Robert Nishihara Feb 17 '18 at 19:18
  • 1
    Just a note this is primarily for distributing concurrent jobs over multiple machines. – Matt Williamson Jul 21 '18 at 2:43
  • 2
    It actually is optimized for both the single-machine case and the cluster setting. A lot of the design decisions (e.g., shared memory, zero-copy serialization) are targeted at supporting single machines well. – Robert Nishihara Jul 22 '18 at 22:55
  • 1
    It would be great if the docs pointed that out more. I got the sense from reading over the docs that it was not really intended for the single machine case. – Sledge Sep 10 at 13:53
4

CPython uses the Global Interpreter Lock which makes parallel programing a bit more interesting than C++

This topic has several useful examples and descriptions of the challenge:

Python Global Interpreter Lock (GIL) workaround on multi-core systems using taskset on Linux?

  • 7
    You call the unability to really run code concurrently "interesting"? :-/ – ManuelSchneid3r May 17 '18 at 11:50
3

The solution, as others have said, is to use multiple processes. Which framework is more appropriate, however, depends on many factors. In addition to the ones already mentioned, there is also charm4py and mpi4py (I am the developer of charm4py).

There is a more efficient way to implement the above example than using the worker pool abstraction. The main loop sends the same parameters (including the complete graph G) over and over to workers in each of the 1000 iterations. Since at least one worker will reside on a different process, this involves copying and sending the arguments to the other process(es). This could be very costly depending on the size of the objects. Instead, it makes sense to have workers store state and simply send the updated information.

For example, in charm4py this can be done like this:

class Worker(Chare):

    def __init__(self, Q, G, n):
        self.G = G
        ...

    def setinner(self, node1, node2):
        self.updateGraph(node1, node2)
        ...


def solve(Q, G, n):
    # create 2 workers, each on a different process, passing the initial state
    worker_a = Chare(Worker, onPE=0, args=[Q, G, n])
    worker_b = Chare(Worker, onPE=1, args=[Q, G, n])
    while i < 1000:
        result_a = worker_a.setinner(node1, node2, ret=True)  # execute setinner on worker A
        result_b = worker_b.setouter(node1, node2, ret=True)  # execute setouter on worker B

        inneropt, partition, x = result_a.get()  # wait for result from worker A
        outeropt = result_b.get()  # wait for result from worker B
        ...

Note that for this example we really only need one worker. The main loop could execute one of the functions, and have the worker execute the other. But my code helps to illustrate a couple of things:

  1. Worker A runs in process 0 (same as the main loop). While result_a.get() is blocked waiting on the result, worker A does the computation in the same process.
  2. Arguments are automatically passed by reference to worker A, since it is in the same process (there is no copying involved).
1

In some cases, it's possible to automatically parallelize loops using Numba, though it only works with a small subset of Python:

from numba import njit, prange

@njit(parallel=True)
def prange_test(A):
    s = 0
    # Without "parallel=True" in the jit-decorator
    # the prange statement is equivalent to range
    for i in prange(A.shape[0]):
        s += A[i]
    return s

Unfortunately, it seems that Numba only works with Numpy arrays, but not with other Python objects. In theory, it might also be possible to compile Python to C++ and then automatically parallelize it using the Intel C++ compiler, though I haven't tried this yet.

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