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I am a Python novice who is trying to learn a bit about this fantastic programming language. I have tried using scipy.weave.inline to speed up some computation. Just to learn a bit, I tried to implement a matrix multiplication using scipy.weave.inline. I have not included any error handling - just trying it out to better understand it. The code is as follows:

import scipy.weave
def cmatmul(A,B):
    R = numpy.zeros((A.shape[0],B.shape[1]))
    M = R.shape[0]
    N = R.shape[1]
    K = A.shape[1]

    code = \
    for (int i=0; i<M; i++)
        for (int j=0; j<N; j++)
            for (int k=0; k<K; k++)
                R(i,j) += A(i,k) * B(k,j);
    scipy.weave.inline(code, ['R','A','B','M','N','K'], \
                       type_converters=scipy.weave.converters.blitz, \
    return R

When I compare with, I experience that the weave.inline version takes roughly 50x the time as I know that numpy is very fast when it can be applied. The difference is even seen for large matrices such as size 1000 x 1000.

I have checked both and scipy.weave.inline and both appear to use one core 100% when computing. delivers 10.0 GFlops compared to the theoretical 11.6 GFlops of my laptop (double precision). In single precision I measure the double performance as expected. But the scipy.weave.inline is way behind. 1/50 times this performance for scipy.weave.inline.

Is this difference to be expected? Or what am I doing wrong?

share|improve this question
(I am not a performance guru.) numpy objects are low-level already: all the matrix operations are written in fast, compiled code. weave.inline is better than native Python but not as good as the default numpy stuff. – katrielalex Oct 22 '11 at 20:45
on my machine: cmatmul takes 9.7 seconds (or 4.9 if B has fortran memory layout), -- 0.27 for 1000x1000 real matrixes. – J.F. Sebastian Oct 23 '11 at 2:11
OK. Not quite as big a difference as I see but the trend is the same. It is not because I have done something wrong with the code above or omitted some compiler flags? – Lars1 Oct 23 '11 at 6:02
NumPy can use BLAS to calculate dot products, which can involve highly optimized code, so it will probably beat whatever you come up with at first. – Michael Hoffman Oct 23 '11 at 6:16

You implemented a naive matrix multiplication algorithm, which scipy.weave compiles to fast machine code.

However, there are non-obvious, more CPU cache efficient algorithms for matrix multiplication (which usually split the matrix into blocks and deal with those), and additional speed can be gained with CPU-specific optimizations. Numpy by default uses an optimized BLAS library for this operation, if you have one installed. These libraries will likely be fast compared to anything you can code up yourself without doing an amount of research.

share|improve this answer
I know that more efficient algorithms exist than the naive approach with n**2*(2*n-1) multiplications and additions. In most recent GeMM measures I have seen it seems like additions and multiplications are treated equally in terms of cost. But your comment on specific optimizations and probably better cache utilization than the naive approach plays a bigger role than I probably expected. I was just a bit surprised to see such a huge difference. Thanks for your info. – Lars1 Oct 29 '11 at 14:02

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