# Improving the efficiency of Standard Matrix Multiplication Algorithm?

How can I improve the efficiency of standard matrix multiplication algorithm?

The main operation involved in this approach is: `C[i][j]+=A[i][p]*B[p][j]`

What can be done to improve the efficiency of the algorithm?

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@xtremer: What kind of matrix? Square? Almost-square? Power-of-two sides? Tall-and-skinny? Sparse? etc. –  Mehrdad Aug 1 '11 at 15:37

You might want to have a look at using a BLAS (Basic Linear Algebra Subroutine) library, specifically Intel offer their MKL here, AMD have their ACML here and there's also the (opensource) Goto BLAS here.

The (dense) matrix-matrix multiply kernel will be a `?GEMM` call, where the `?` indicates the floating point type. For example `DGEMM` will call the `double` routine.

Unless you're extremely confident you know what you're doing with low-level optimisations, these libraries will probably offer better performance than something you can code by hand.

If you do want to have a go at coding this yourself then you may want to consider the following:

1. Use "vector" instructions. `SSE, SSE2..4` instructions are widely supported, some newer `CPU`'s will also support `AVX` instructions.
2. Nested loop unrolling to maximise the ratio of floating point operations to load/store operations.
3. Block-wise algorithms to ensure effective cache use.

This reference might give you an idea of the current state of things:

High-performance implementation of the level-3 BLAS - K Goto.

Hope this helps.

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+1 I've discovered if the matrix is small, DGEMM can blow a large fraction of time checking its character arguments, which are there to make it general purpose. So for small matrices I save a good amount of execution time by doing it the plain-old hand-coded way. Sometimes completely unrolled. –  Mike Dunlavey Aug 2 '11 at 2:22

I would suggest reading Chapter 1 of Golub and Van Loan, which addresses this exact question.

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1. Cache blocking - making sure you're properly using and reusing values in the cache
2. Better algorithm - the "by-definition" way to multiply matrices is not optimal, take a look at Strassen's algorithm
3. Parallelization - if your machine has more than one core and/or processor, you can divide and conquer
4. SIMD - take advantage of SSE vector instructions in modern CPU architectures
5. GPGPU - modern GPUs are optimized to do just this sort of thing. Look into CUDA and OpenCL.

Note that using these methods does not guarantee better performance. There is a lot of tuning required give a significant speedup. There is a lot of money going into figuring out how to multiply matrices quickly so there is no shortage of journal articles on the subject.

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