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Suppose I have a large in memory numpy array, I have a function func that takes in this giant array as input (together with some other parameters). func with different paremeters can be run in parallel. For example

def func(arr, param):
    # do stuff to arr, param

# build array arr

pool = Pool(processes = 6)
results = [pool.apply_async(func, [arr, param]) for param in all_params]
output = [res.get() for res in results]

If I use multiprocessing libary, then that giant array will be copied for multiple times into different processes.

Is there a way to let different processes share the same array? This array object is read-only and will never be modified.

What's more complicated, if arr is not an array, but an arbitrary python object, is there a way to share it?


I read the answer but I am still a bit confused. Since fork() is copy-on-write, we should not invoke any additional cost when spawning new processes in python multiprocessing library. But the following code suggests there is a huge overhead:

from multiprocessing import Pool, Manager
import numpy as np; 
import time

def f(arr):
    return len(arr)

t = time.time()
arr = np.arange(10000000)
print "construct array = ", time.time() - t;

pool = Pool(processes = 6)

t = time.time()
res = pool.apply_async(f, [arr,])
print "multiprocessing overhead = ", time.time() - t;

output (and by the way, the cost increases as the size of the array increases, so I suspect there is still overhead related to memory copying):

construct array =  0.0178790092468
multiprocessing overhead =  0.252444982529

Why is there such huge overhead, if we didn't copy the array? And what part does the shared memory save me?

share|improve this question
You have looked at the docs‌​, right? –  Lev Levitsky May 23 '12 at 14:35
@FrancisAvila is there a way to share not just array, but arbitrary python objects? –  CodeNoob May 23 '12 at 15:10
@LevLevitsky I have to ask, is there a way to share not just array, but arbitrary python objects? –  CodeNoob May 23 '12 at 15:10
This answer explains nicely why arbitrary Python objects can't be shared. –  Janne Karila May 23 '12 at 16:37

2 Answers 2

up vote 37 down vote accepted

If you use an operating system that uses copy-on-write fork() semantics (like any common unix), then as long as you never alter your data structure it will be available to all child processes without taking up additional memory. You will not have to do anything special (except make absolutely sure you don't alter the object).

The most efficient thing you can do for your problem would be to pack your array into an efficient array structure (using numpy or array), place that in shared memory, wrap it with multiprocessing.Array, and pass that to your functions. This answer shows how to do that.

If you want a writeable shared object, then you will need to wrap it with some kind of synchronization or locking. multiprocessing provides two methods of doing this: one using shared memory (suitable for simple values, arrays, or ctypes) or a Manager proxy, where one process holds the memory and a manager arbitrates access to it from other processes (even over a network).

The Manager approach can be used with arbitrary Python objects, but will be slower than the equivalent using shared memory because the objects need to be serialized/deserialized and sent between processes.

There are a wealth of parallel processing libraries and approaches available in Python. multiprocessing is an excellent and well rounded library, but if you have special needs perhaps one of the other approaches may be better.

share|improve this answer
Just to note, on Python fork() actually means copy on access (because just accessing the object will change its ref-count). –  Fabio Zadrozny Jun 7 '12 at 17:30
@FabioZadrozny Would it actually copy the entire object, or just the memory page containing its refcount? –  zigg Jan 2 '13 at 17:38
AFAIK, only the memory page containing the refcount (so, 4kb on each object access). –  Fabio Zadrozny Jan 2 '13 at 18:02
@max Use a closure. The function given to apply_async should reference the shared object in scope directly instead of through its arguments. –  Francis Avila Feb 3 at 22:44
@FrancisAvila how do you use a closure? Shouldn't the function that you give to apply_async be pickable? Or this is only a map_async restriction? –  GermanK Mar 29 at 9:42

I run into the same problem and wrote a little shared-memory utility class to work around it.

I'm using multiprocessing.RawArray (lockfree), and also the access to the arrays is not synchronized at all (lockfree), be careful not to shoot your own feet.

With the solution I get speedups by a factor of approx 3 on a quad-core i7.

Here's the code: Feel free to use and improve it, and please report back any bugs.

Created on 14.05.2013

@author: martin

import multiprocessing
import ctypes
import numpy as np

class SharedNumpyMemManagerError(Exception):

Singleton Pattern
class SharedNumpyMemManager:    

    _initSize = 1024

    _instance = None

    def __new__(cls, *args, **kwargs):
        if not cls._instance:
            cls._instance = super(SharedNumpyMemManager, cls).__new__(
                                cls, *args, **kwargs)
        return cls._instance        

    def __init__(self):
        self.lock = multiprocessing.Lock()
        self.cur = 0
        self.cnt = 0
        self.shared_arrays = [None] * SharedNumpyMemManager._initSize

    def __createArray(self, dimensions, ctype=ctypes.c_double):


        # double size if necessary
        if (self.cnt >= len(self.shared_arrays)):
            self.shared_arrays = self.shared_arrays + [None] * len(self.shared_arrays)

        # next handle

        # create array in shared memory segment
        shared_array_base = multiprocessing.RawArray(ctype, np.prod(dimensions))

        # convert to numpy array vie ctypeslib
        self.shared_arrays[self.cur] = np.ctypeslib.as_array(shared_array_base)

        # do a reshape for correct dimensions            
        # Returns a masked array containing the same data, but with a new shape.
        # The result is a view on the original array
        self.shared_arrays[self.cur] = self.shared_arrays[self.cnt].reshape(dimensions)

        # update cnt
        self.cnt += 1


        # return handle to the shared memory numpy array
        return self.cur

    def __getNextFreeHdl(self):
        orgCur = self.cur
        while self.shared_arrays[self.cur] is not None:
            self.cur = (self.cur + 1) % len(self.shared_arrays)
            if orgCur == self.cur:
                raise SharedNumpyMemManagerError('Max Number of Shared Numpy Arrays Exceeded!')

    def __freeArray(self, hdl):
        # set reference to None
        if self.shared_arrays[hdl] is not None: # consider multiple calls to free
            self.shared_arrays[hdl] = None
            self.cnt -= 1

    def __getArray(self, i):
        return self.shared_arrays[i]

    def getInstance():
        if not SharedNumpyMemManager._instance:
            SharedNumpyMemManager._instance = SharedNumpyMemManager()
        return SharedNumpyMemManager._instance

    def createArray(*args, **kwargs):
        return SharedNumpyMemManager.getInstance().__createArray(*args, **kwargs)

    def getArray(*args, **kwargs):
        return SharedNumpyMemManager.getInstance().__getArray(*args, **kwargs)

    def freeArray(*args, **kwargs):
        return SharedNumpyMemManager.getInstance().__freeArray(*args, **kwargs)

# Init Singleton on module load

if __name__ == '__main__':

    import timeit

    N_PROC = 8
    INNER_LOOP = 10000
    N = 1000

    def propagate(t):
        i, shm_hdl, evidence = t
        a = SharedNumpyMemManager.getArray(shm_hdl)
        for j in range(INNER_LOOP):
            a[i] = i

    class Parallel_Dummy_PF:

        def __init__(self, N):
            self.N = N
            self.arrayHdl = SharedNumpyMemManager.createArray(self.N, ctype=ctypes.c_double)            
            self.pool = multiprocessing.Pool(processes=N_PROC)

        def update_par(self, evidence):
            self.pool.map(propagate, zip(range(self.N), [self.arrayHdl] * self.N, [evidence] * self.N))

        def update_seq(self, evidence):
            for i in range(self.N):
                propagate((i, self.arrayHdl, evidence))

        def getArray(self):
            return SharedNumpyMemManager.getArray(self.arrayHdl)

    def parallelExec():
        pf = Parallel_Dummy_PF(N)

    def sequentialExec():
        pf = Parallel_Dummy_PF(N)

    t1 = timeit.Timer("sequentialExec()", "from __main__ import sequentialExec")
    t2 = timeit.Timer("parallelExec()", "from __main__ import parallelExec")

    print("Sequential: ", t1.timeit(number=1))    
    print("Parallel: ", t2.timeit(number=1))
share|improve this answer
Just realized that you have to set up your shared memory arrays before you create the multiprocessing Pool, don't know why yet but it definitly won't work the other way round. –  martin.preinfalk Oct 24 '13 at 15:53

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