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Is there a good way to pass a large chunk of data between two python subprocesses without using the disk? Here's a cartoon example of what I'm hoping to accomplish:

import sys, subprocess, numpy

cmdString = """
import sys, numpy

done = False
while not done:
    cmd = raw_input()
    if cmd == 'done':
        done = True
    elif cmd == 'data':
        ##Fake data. In real life, get data from hardware.
        data = numpy.zeros(1000000, dtype=numpy.uint8)
        data.dump('data.pkl')
        sys.stdout.write('data.pkl' + '\\n')
        sys.stdout.flush()"""

proc = subprocess.Popen( #python vs. pythonw on Windows?
    [sys.executable, '-c %s'%cmdString],
    stdin=subprocess.PIPE,
    stdout=subprocess.PIPE,
    stderr=subprocess.PIPE)

for i in range(3):
    proc.stdin.write('data\n')
    print proc.stdout.readline().rstrip()
    a = numpy.load('data.pkl')
    print a.shape

proc.stdin.write('done\n')

This creates a subprocess which generates a numpy array and saves the array to disk. The parent process then loads the array from disk. It works!

The problem is, our hardware can generate data 10x faster than the disk can read/write. Is there a way to transfer data from one python process to another purely in-memory, maybe even without making a copy of the data? Can I do something like passing-by-reference?

My first attempt at transferring data purely in-memory is pretty lousy:

import sys, subprocess, numpy

cmdString = """
import sys, numpy

done = False
while not done:
    cmd = raw_input()
    if cmd == 'done':
        done = True
    elif cmd == 'data':
        ##Fake data. In real life, get data from hardware.
        data = numpy.zeros(1000000, dtype=numpy.uint8)
        ##Note that this is NFG if there's a '10' in the array:
        sys.stdout.write(data.tostring() + '\\n')
        sys.stdout.flush()"""

proc = subprocess.Popen( #python vs. pythonw on Windows?
    [sys.executable, '-c %s'%cmdString],
    stdin=subprocess.PIPE,
    stdout=subprocess.PIPE,
    stderr=subprocess.PIPE)

for i in range(3):
    proc.stdin.write('data\n')
    a = numpy.fromstring(proc.stdout.readline().rstrip(), dtype=numpy.uint8)
    print a.shape

proc.stdin.write('done\n')

This is extremely slow (much slower than saving to disk) and very, very fragile. There's got to be a better way!

I'm not married to the 'subprocess' module, as long as the data-taking process doesn't block the parent application. I briefly tried 'multiprocessing', but without success so far.

Background: We have a piece of hardware that generates up to ~2 GB/s of data in a series of ctypes buffers. The python code to handle these buffers has its hands full just dealing with the flood of information. I want to coordinate this flow of information with several other pieces of hardware running simultaneously in a 'master' program, without the subprocesses blocking each other. My current approach is to boil the data down a little bit in the subprocess before saving to disk, but it'd be nice to pass the full monty to the 'master' process.

share|improve this question
    
sounds like threading would suit you. –  Asterisk Feb 17 '11 at 19:54
    
why don't you use threading? –  Gabi Purcaru Feb 17 '11 at 19:58
1  
@Gabi Purcaru Because I'm ignorant about threading. Feel free to educate me with an answer! –  Andrew Feb 17 '11 at 20:05
3  
Avoid pickling numpy arrays. Use numpy.save(file, arr) instead. Pickling an array can use lots of intermediate memory (especially by default), and is rather slow. numpy.save is much more efficient. –  Joe Kington Feb 17 '11 at 20:20
    
Andrew, do you know the total size of the data beforehand? Or a maximum size? –  Sven Marnach Feb 17 '11 at 20:54

4 Answers 4

up vote 16 down vote accepted

While googling around for more information about the code Joe Kington posted, I found the numpy-sharedmem package. Judging from this numpy/multiprocessing tutorial it seems to share the same intellectual heritage (maybe largely the same authors? -- I'm not sure).

Using the sharedmem module, you can create a shared-memory numpy array (awesome!), and use it with multiprocessing like this:

import sharedmem as shm
import numpy as np
import multiprocessing as mp

def worker(q,arr):
    done = False
    while not done:
        cmd = q.get()
        if cmd == 'done':
            done = True
        elif cmd == 'data':
            ##Fake data. In real life, get data from hardware.
            rnd=np.random.randint(100)
            print('rnd={0}'.format(rnd))
            arr[:]=rnd
        q.task_done()

if __name__=='__main__':
    N=10
    arr=shm.zeros(N,dtype=np.uint8)
    q=mp.JoinableQueue()    
    proc = mp.Process(target=worker, args=[q,arr])
    proc.daemon=True
    proc.start()

    for i in range(3):
        q.put('data')
        # Wait for the computation to finish
        q.join()   
        print arr.shape
        print(arr)
    q.put('done')
    proc.join()

Running yields

rnd=53
(10,)
[53 53 53 53 53 53 53 53 53 53]
rnd=15
(10,)
[15 15 15 15 15 15 15 15 15 15]
rnd=87
(10,)
[87 87 87 87 87 87 87 87 87 87]
share|improve this answer
    
Thanks, unutbu, this looks great! I'll try it out. –  Andrew Feb 18 '11 at 20:07
    
Sorry it took me so long to accept the answer. I still haven't had time to test it myself, I'll report back here when I do. Thanks again! –  Andrew Mar 4 '11 at 15:26

From the other answers, it seems that numpy-sharedmem is the way to go.

However, if you need a pure python solution, or installing extensions, cython or the like is a (big) hassle, you might want to use the following code which is a simplified version of Nadav's code:

import numpy, ctypes, multiprocessing

_ctypes_to_numpy = {
    ctypes.c_char   : numpy.dtype(numpy.uint8),
    ctypes.c_wchar  : numpy.dtype(numpy.int16),
    ctypes.c_byte   : numpy.dtype(numpy.int8),
    ctypes.c_ubyte  : numpy.dtype(numpy.uint8),
    ctypes.c_short  : numpy.dtype(numpy.int16),
    ctypes.c_ushort : numpy.dtype(numpy.uint16),
    ctypes.c_int    : numpy.dtype(numpy.int32),
    ctypes.c_uint   : numpy.dtype(numpy.uint32),
    ctypes.c_long   : numpy.dtype(numpy.int64),
    ctypes.c_ulong  : numpy.dtype(numpy.uint64),
    ctypes.c_float  : numpy.dtype(numpy.float32),
    ctypes.c_double : numpy.dtype(numpy.float64)}

_numpy_to_ctypes = dict(zip(_ctypes_to_numpy.values(),
                            _ctypes_to_numpy.keys()))


def shm_as_ndarray(mp_array, shape = None):
    '''Given a multiprocessing.Array, returns an ndarray pointing to
    the same data.'''

    # support SynchronizedArray:
    if not hasattr(mp_array, '_type_'):
        mp_array = mp_array.get_obj()

    dtype = _ctypes_to_numpy[mp_array._type_]
    result = numpy.frombuffer(mp_array, dtype)

    if shape is not None:
        result = result.reshape(shape)

    return numpy.asarray(result)


def ndarray_to_shm(array, lock = False):
    '''Generate an 1D multiprocessing.Array containing the data from
    the passed ndarray.  The data will be *copied* into shared
    memory.'''

    array1d = array.ravel(order = 'A')

    try:
        c_type = _numpy_to_ctypes[array1d.dtype]
    except KeyError:
        c_type = _numpy_to_ctypes[numpy.dtype(array1d.dtype)]

    result = multiprocessing.Array(c_type, array1d.size, lock = lock)
    shm_as_ndarray(result)[:] = array1d
    return result

You would use it like this:

  1. Use sa = ndarray_to_shm(a) to convert the ndarray a into a shared multiprocessing.Array.
  2. Use multiprocessing.Process(target = somefunc, args = (sa, ) (and start, maybe join) to call somefunc in a separate process, passing the shared array.
  3. In somefunc, use a = shm_as_ndarray(sa) to get an ndarray pointing to the shared data. (Actually, you may want to do the same in the original process, immediately after creating sa, in order to have two ndarrays referencing the same data.)

AFAICS, you don't need to set lock to True, since shm_as_ndarray will not use the locking anyhow. If you need locking, you would set lock to True and call acquire/release on sa.

Also, if your array is not 1-dimensional, you might want to transfer the shape along with sa (e.g. use args = (sa, a.shape)).

This solution has the advantage that it does not need additional packages or extension modules, except multiprocessing (which is in the standard library).

share|improve this answer
    
I'm getting PicklingError: Can't pickle <class 'multiprocessing.sharedctypes.c_double_Array_<array size>'>: attribute lookup multiprocessing.sharedctypes.c_double_Array_<array size> failed. see my question here stackoverflow.com/questions/16303354/… –  Uri Apr 30 '13 at 15:18
    
I just saw your comment by chance; obviously, I need to check my notification settings. Is there anything I should change in my answer, which was misleading for you? –  hans_meine Sep 27 '13 at 8:22
    
Well it was a long time ago :) –  Uri Sep 27 '13 at 15:36

Basically, you just want to share a block of memory between processes and view it as a numpy array, right?

In that case, have a look at this (Posted to numpy-discussion by Nadav Horesh awhile back, not my work). There are a couple of similar implementations (some more flexible), but they all essentially use this principle.

#    "Using Python, multiprocessing and NumPy/SciPy for parallel numerical computing"
# Modified and corrected by Nadav Horesh, Mar 2010
# No rights reserved


import numpy as N
import ctypes
import multiprocessing as MP

_ctypes_to_numpy = {
    ctypes.c_char   : N.dtype(N.uint8),
    ctypes.c_wchar  : N.dtype(N.int16),
    ctypes.c_byte   : N.dtype(N.int8),
    ctypes.c_ubyte  : N.dtype(N.uint8),
    ctypes.c_short  : N.dtype(N.int16),
    ctypes.c_ushort : N.dtype(N.uint16),
    ctypes.c_int    : N.dtype(N.int32),
    ctypes.c_uint   : N.dtype(N.uint32),
    ctypes.c_long   : N.dtype(N.int64),
    ctypes.c_ulong  : N.dtype(N.uint64),
    ctypes.c_float  : N.dtype(N.float32),
    ctypes.c_double : N.dtype(N.float64)}

_numpy_to_ctypes = dict(zip(_ctypes_to_numpy.values(), _ctypes_to_numpy.keys()))


def shmem_as_ndarray(raw_array, shape=None ):

    address = raw_array._obj._wrapper.get_address()
    size = len(raw_array)
    if (shape is None) or (N.asarray(shape).prod() != size):
        shape = (size,)
    elif type(shape) is int:
        shape = (shape,)
    else:
        shape = tuple(shape)

    dtype = _ctypes_to_numpy[raw_array._obj._type_]
    class Dummy(object): pass
    d = Dummy()
    d.__array_interface__ = {
        'data' : (address, False),
        'typestr' : dtype.str,
        'descr' :   dtype.descr,
        'shape' : shape,
        'strides' : None,
        'version' : 3}
    return N.asarray(d)

def empty_shared_array(shape, dtype, lock=True):
    '''
    Generate an empty MP shared array given ndarray parameters
    '''

    if type(shape) is not int:
        shape = N.asarray(shape).prod()
    try:
        c_type = _numpy_to_ctypes[dtype]
    except KeyError:
        c_type = _numpy_to_ctypes[N.dtype(dtype)]
    return MP.Array(c_type, shape, lock=lock)

def emptylike_shared_array(ndarray, lock=True):
    'Generate a empty shared array with size and dtype of a  given array'
    return empty_shared_array(ndarray.size, ndarray.dtype, lock)
share|improve this answer
    
I don't see how this can be used here. A multiprocessing.Array() would need to be created before spawning the subprocess, but in Andrew's code above the subprocess wants to create it. Am I missing something? –  Sven Marnach Feb 17 '11 at 20:52
    
@Sven - You're right, the code won't work as-is. However, it shouldn't be too hard to tweak things to work (or at least, I think I can make it work without too much trouble). Give me a bit, and I'll see if I can cobble something a bit more complete together... –  Joe Kington Feb 17 '11 at 21:04
    
This looks promising, looking forward to the cobbling. –  Andrew Feb 18 '11 at 0:10
    
@Andrew - For what it's worth, @unutbu's answer is the way to go... –  Joe Kington Feb 18 '11 at 17:54

Use threads. But I guess you are going to get problems with the GIL.

Instead: Choose your poison.

I know from the MPI implementations I work with, that they use shared memory for on-node-communications. You will have to code your own synchronization in that case.

2 GB/s sounds like you will get problems with most "easy" methods, depending on your real-time constraints and available main memory.

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