The cost of creating of new processes or copying matrices between them if processes are reused overshadows the cost of matrix multiplication. Anyway `numpy.dot()`

can utilize different CPU cores by itself.

Matrix multiplication can be distributed between processes by computing different rows of the result in different processes, e.g., given input matrices `a`

and `b`

then the result `(i,j)`

element is:

```
out[i,j] = sum(a[i,:] * b[:,j])
```

So `i`

-th row can be computed as:

```
import numpy as np
def dot_slice(a, b, out, i):
t = np.empty_like(a[i,:])
for j in xrange(b.shape[1]):
# out[i,j] = sum(a[i,:] * b[:,j])
np.multiply(a[i,:], b[:,j], t).sum(axis=1, out=out[i,j])
```

`numpy`

array accepts a slice as an index, e.g., `a[1:3,:]`

returns the 2nd and 3rd rows.

`a`

, `b`

are readonly so they can be inherited as is by child processes (exploiting copy-on-write on Linux), the result is computed using shared array. Only indexes are copied during computations:

```
import ctypes
import multiprocessing as mp
def dot(a, b, nprocesses=mp.cpu_count()):
"""Perform matrix multiplication using multiple processes."""
if (a.shape[1] != b.shape[0]):
raise ValueError("wrong shape")
# create shared array
mp_arr = mp.RawArray(ctypes.c_double, a.shape[0]*b.shape[1])
# start processes
np_args = mp_arr, (a.shape[0], b.shape[1]), a.dtype
pool = mp.Pool(nprocesses, initializer=init, initargs=(a, b)+np_args)
# perform multiplication
for i in pool.imap_unordered(mpdot_slice, slices(a.shape[0], nprocesses)):
print("done %s" % (i,))
pool.close()
pool.join()
# return result
return tonumpyarray(*np_args)
```

Where:

```
def mpdot_slice(i):
dot_slice(ga, gb, gout, i)
return i
def init(a, b, *np_args):
"""Called on each child process initialization."""
global ga, gb, gout
ga, gb = a, b
gout = tonumpyarray(*np_args)
def tonumpyarray(mp_arr, shape, dtype):
"""Convert shared multiprocessing array to numpy array.
no data copying
"""
return np.frombuffer(mp_arr, dtype=dtype).reshape(shape)
def slices(nitems, mslices):
"""Split nitems on mslices pieces.
>>> list(slices(10, 3))
[slice(0, 4, None), slice(4, 8, None), slice(8, 10, None)]
>>> list(slices(1, 3))
[slice(0, 1, None), slice(1, 1, None), slice(2, 1, None)]
"""
step = nitems // mslices + 1
for i in xrange(mslices):
yield slice(i*step, min(nitems, (i+1)*step))
```

To test it:

```
def test():
n = 100000
a = np.random.rand(50, n)
b = np.random.rand(n, 60)
assert np.allclose(np.dot(a,b), dot(a,b, nprocesses=2))
```

On Linux this multiprocessing version has the same performance as the solution that uses threads and releases GIL (in the C extension) during computations:

```
$ python -mtimeit -s'from test_cydot import a,b,out,np' 'np.dot(a,b,out)'
100 loops, best of 3: 9.05 msec per loop
$ python -mtimeit -s'from test_cydot import a,b,out,cydot' 'cydot.dot(a,b,out)'
10 loops, best of 3: 88.8 msec per loop
$ python -mtimeit -s'from test_cydot import a,b; import mpdot' 'mpdot.dot(a,b)'
done slice(49, 50, None)
..[snip]..
done slice(35, 42, None)
10 loops, best of 3: 82.3 msec per loop
```

Note: the test was changed to use `np.float64`

everywhere.

calculations, not writing to arrays. Why can't your subroutines just return the appropriate results for further handling by the main program? – Lev Levitsky Mar 16 '12 at 18:43