I would like to use a numpy array in shared memory for use with the multiprocessing module. The difficulty is using it like a numpy array, and not just as a ctypes array.

from multiprocessing import Process, Array
import scipy

def f(a):
    a[0] = -a[0]

if __name__ == '__main__':
    # Create the array
    N = int(10)
    unshared_arr = scipy.rand(N)
    arr = Array('d', unshared_arr)
    print "Originally, the first two elements of arr = %s"%(arr[:2])

    # Create, start, and finish the child processes
    p = Process(target=f, args=(arr,))

    # Printing out the changed values
    print "Now, the first two elements of arr = %s"%arr[:2]

This produces output such as:

Originally, the first two elements of arr = [0.3518653236697369, 0.517794725524976]
Now, the first two elements of arr = [-0.3518653236697369, 0.517794725524976]

The array can be accessed in a ctypes manner, e.g. arr[i] makes sense. However, it is not a numpy array, and I cannot perform operations such as -1*arr, or arr.sum(). I suppose a solution would be to convert the ctypes array into a numpy array. However (besides not being able to make this work), I don't believe it would be shared anymore.

It seems there would be a standard solution to what has to be a common problem.


To add to @unutbu's (not available anymore) and @Henry Gomersall's answers. You could use shared_arr.get_lock() to synchronize access when needed:

shared_arr = mp.Array(ctypes.c_double, N)
# ...
def f(i): # could be anything numpy accepts as an index such another numpy array
    with shared_arr.get_lock(): # synchronize access
        arr = np.frombuffer(shared_arr.get_obj()) # no data copying
        arr[i] = -arr[i]


import ctypes
import logging
import multiprocessing as mp

from contextlib import closing

import numpy as np

info = mp.get_logger().info

def main():
    logger = mp.log_to_stderr()

    # create shared array
    N, M = 100, 11
    shared_arr = mp.Array(ctypes.c_double, N)
    arr = tonumpyarray(shared_arr)

    # fill with random values
    arr[:] = np.random.uniform(size=N)
    arr_orig = arr.copy()

    # write to arr from different processes
    with closing(mp.Pool(initializer=init, initargs=(shared_arr,))) as p:
        # many processes access the same slice
        stop_f = N // 10
        p.map_async(f, [slice(stop_f)]*M)

        # many processes access different slices of the same array
        assert M % 2 # odd
        step = N // 10
        p.map_async(g, [slice(i, i + step) for i in range(stop_f, N, step)])
    assert np.allclose(((-1)**M)*tonumpyarray(shared_arr), arr_orig)

def init(shared_arr_):
    global shared_arr
    shared_arr = shared_arr_ # must be inherited, not passed as an argument

def tonumpyarray(mp_arr):
    return np.frombuffer(mp_arr.get_obj())

def f(i):
    with shared_arr.get_lock(): # synchronize access

def g(i):
    """no synchronization."""
    info("start %s" % (i,))
    arr = tonumpyarray(shared_arr)
    arr[i] = -1 * arr[i]
    info("end   %s" % (i,))

if __name__ == '__main__':

If you don't need synchronized access or you create your own locks then mp.Array() is unnecessary. You could use mp.sharedctypes.RawArray in this case.

  • 2
    Beautiful answer! If I want to have more than one shared array, each separately lockable, but with the number of arrays determined at runtime, is that a straightforward extension of what you've done here?
    – Andrew
    Jan 19 '13 at 4:30
  • 4
    @Andrew: shared arrays should be created before child processes are spawned.
    – jfs
    Jan 19 '13 at 6:13
  • Good point about order of operations. That's what I had in mind, though: create a user-specified number of shared arrays, then spawn a few child processes. Is that straightforward?
    – Andrew
    Jan 19 '13 at 15:49
  • 1
    @Chicony: you can't change the size of the Array. Think of it as a shared block of memory that had to be allocated before child processes are started. You don't need to use all the memory e.g., you could pass count to numpy.frombuffer(). You could try to do it on a lower level using mmap or something like posix_ipc directly to implement a resizable (might involve copying while resizing) RawArray analog (or look for an existing library). Or if your task allows it: copy data in parts (if you don't need all at once). "How to resize a shared memory" is a good separate question.
    – jfs
    Dec 8 '16 at 12:35
  • 1
    @umopapisdn: Pool() defines the number of processes (the number of available CPU cores is used by default). M is the number of times f() function is called.
    – jfs
    Jul 16 '18 at 13:08

The Array object has a get_obj() method associated with it, which returns the ctypes array which presents a buffer interface. I think the following should work...

from multiprocessing import Process, Array
import scipy
import numpy

def f(a):
    a[0] = -a[0]

if __name__ == '__main__':
    # Create the array
    N = int(10)
    unshared_arr = scipy.rand(N)
    a = Array('d', unshared_arr)
    print "Originally, the first two elements of arr = %s"%(a[:2])

    # Create, start, and finish the child process
    p = Process(target=f, args=(a,))

    # Print out the changed values
    print "Now, the first two elements of arr = %s"%a[:2]

    b = numpy.frombuffer(a.get_obj())

    b[0] = 10.0
    print a[0]

When run, this prints out the first element of a now being 10.0, showing a and b are just two views into the same memory.

In order to make sure it is still multiprocessor safe, I believe you will have to use the acquire and release methods that exist on the Array object, a, and its built in lock to make sure its all safely accessed (though I'm not an expert on the multiprocessor module).

  • it won't work without synchronization as @unutbu demonstrated in his (now deleted) answer.
    – jfs
    Oct 26 '11 at 20:40
  • 1
    Presumably, if you just wanted to access the array post processing, it can be done cleanly without worrying about concurrency issues and locking? Oct 26 '11 at 21:28
  • in this case you don't need mp.Array.
    – jfs
    Oct 26 '11 at 21:53
  • 1
    The processing code may require locked arrays, but the post processing interpretation of the data might not necessarily. I guess this comes from understanding what exactly the problem is. Clearly, accessing shared data concurrently is going to require some protection, which I thought would be obvious! Oct 26 '11 at 22:12

While the answers already given are good, there is a much easier solution to this problem provided two conditions are met:

  1. You are on a POSIX-compliant operating system (e.g. Linux, Mac OSX); and
  2. Your child processes need read-only access to the shared array.

In this case you do not need to fiddle with explicitly making variables shared, as the child processes will be created using a fork. A forked child automatically shares the parent's memory space. In the context of Python multiprocessing, this means it shares all module-level variables; note that this does not hold for arguments that you explicitly pass to your child processes or to the functions you call on a multiprocessing.Pool or so.

A simple example:

import multiprocessing
import numpy as np

# will hold the (implicitly mem-shared) data
data_array = None

# child worker function
def job_handler(num):
    # built-in id() returns unique memory ID of a variable
    return id(data_array), np.sum(data_array)

def launch_jobs(data, num_jobs=5, num_worker=4):
    global data_array
    data_array = data

    pool = multiprocessing.Pool(num_worker)
    return pool.map(job_handler, range(num_jobs))

# create some random data and execute the child jobs
mem_ids, sumvals = zip(*launch_jobs(np.random.rand(10)))

# this will print 'True' on POSIX OS, since the data was shared
print(np.all(np.asarray(mem_ids) == id(data_array)))
  • 3
    +1 Really valuable info. Can you explain why it is only module-level vars that are shared? Why are local vars not part of the parent's memory space? E.g., why can't this work if I have a function F with local var V and a function G inside of F which references V? Oct 27 '17 at 1:38
  • 10
    Warning: This answer is a little deceptive. The child process receives a copy of the state of the parent process, including global variables, at the time of the fork. The states are in no way synchronized and will diverge from that moment. This technique may be useful in some scenarios (e.g.: forking off ad-hoc child processes that each handle a snapshot of the parent process and then terminate), but is useless in others (e.g.: long-running child processes that have to share and sync data with the parent process). Apr 7 '18 at 7:50
  • 6
    @EelkeSpaak: Your statement - "a forked child automatically shares the parent's memory space" - is incorrect. If I have a child process that wants to monitor the state of the parent process, in a strictly read-only manner, forking will not get me there: the child only sees a snapshot of the parent state at the moment of forking. In fact, that's precisely what I was trying to do (following your answer) when I discovered this limitation. Hence the postscript on your answer. In a nutshell: The parent state is not "shared," but merely copied to the child. That's not "sharing" in the usual sense. Apr 9 '18 at 3:30
  • 5
    Am I mistaken to think this is a copy-on-write situation, at least on posix systems? That is, after the fork, I think the memory is shared until new data is written, at which point a copy is created. So yes, it's true that the data isn't "shared" exactly, but it can provide a potentially huge performance boost. If your process is read only, then there will be no copying overhead! Have I understood the point correctly?
    – senderle
    Oct 31 '18 at 4:45
  • 2
    @senderle Yes, that is exactly what I meant! Hence my point (2) in the answer about read-only access.
    – EelkeSpaak
    Nov 1 '18 at 8:31

I've written a small python module that uses POSIX shared memory to share numpy arrays between python interpreters. Maybe you will find it handy.


Here's how it works:

import numpy as np
import SharedArray as sa

# Create an array in shared memory
a = sa.create("test1", 10)

# Attach it as a different array. This can be done from another
# python interpreter as long as it runs on the same computer.
b = sa.attach("test1")

# See how they are actually sharing the same memory block
a[0] = 42

# Destroying a does not affect b.
del a

# See how "test1" is still present in shared memory even though we
# destroyed the array a.

# Now destroy the array "test1" from memory.

# The array b is not affected, but once you destroy it then the
# data are lost.

You can use the sharedmem module: https://bitbucket.org/cleemesser/numpy-sharedmem

Here's your original code then, this time using shared memory that behaves like a NumPy array (note the additional last statement calling a NumPy sum() function):

from multiprocessing import Process
import sharedmem
import scipy

def f(a):
    a[0] = -a[0]

if __name__ == '__main__':
    # Create the array
    N = int(10)
    unshared_arr = scipy.rand(N)
    arr = sharedmem.empty(N)
    arr[:] = unshared_arr.copy()
    print "Originally, the first two elements of arr = %s"%(arr[:2])

    # Create, start, and finish the child process
    p = Process(target=f, args=(arr,))

    # Print out the changed values
    print "Now, the first two elements of arr = %s"%arr[:2]

    # Perform some NumPy operation
    print arr.sum()

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