# matrix multiplication in c code

I have a code needs to do some matrix multiplication like

``````    ML2=ML+uMc+c1+c2
MC2=v*ML+(u*v+1)*Mc+c2
``````

Where ML is MXM matrix of

``````    ML=[1 1 1 1....1;2 2 2 2...2......;M M M.....M]
MC=[1 2 3 4 ...M;1 2 3 4...M......;1 2 3.....M]
``````

u,v,c1 and c2 are constant of 8 bit.

I want to find the values of ML2,MC2 in fast execution time using any fast library

-
I think this question will help you out. –  Josh Jun 17 '13 at 13:37

You did not state the platform you want this for but for matrix operations nothing is faster than the Intel Math Kernel Library for Intel CPUs

http://software.intel.com/en-us/intel-mkl

This gets as close as I have seen to the peak flops possible on the CPU. MKL, however, is expensive and closed source. If you want a good open sourced and free alternative then check out Eigen. This uses C++ but I don't know if you're really restricted to C only code. Eigen also works well on other hardware such as AMD (Intel cripples it's library on AMD CPUs) and ARM.

http://eigen.tuxfamily.org/index.php?title=3.0

A third option to write one yourself. After a few weeks of effort it should not be too difficult to beat Eigen with AVX and OpenMP (Eigen only supports SSE) but it's highly unlikely you will beat MKL.

-
Thanks for all, But I need fast free library to make matrix multiplication in C code, not other languages, also the op is windows 32 bit –  Mousa Farajallah Jun 17 '13 at 14:22

For multiplication of matrixA(AxB) and matrixB(BxC) matrix to result in matrixC(AxC)

``````for(int i=0;i<l;i++)
{
for(int j=0;j<n;j++)
{
matrixC[i][j]=0;
for(int k=0;k<m;k++)
{
matrixC[i][j]=matrixC[i][j]+(matrixA[i][k] * matrixB[k][j]);
}
}
}
``````
-
That's the naive implementation of matrix multiplication which is highly inefficient. It's likely to get less than 1% of the efficiency of the peak FLOPS/s of the CPU. The OP asked for a fast library. –  user2088790 Jun 17 '13 at 14:00

Since ML is bunch of identical vectors 1:M, and MC is just the transpose of ML, you don't need general matrix multiplication. You can take algebraic short-cuts.

-