I have written an MPI routine to parallelize matrix-vector multiplication. The speed up has been disappointing to non-existent. I have found a lot of routines on the net, and I am handling this about the same way that most of them do. What I haven't been able to find is much data on real speed up on real machines. I am working with what I guess is a modest sized problem -- a matrix ranging in size from 100x100 to 1000x1000 and number of processors from 2 up to 64. I am decomposing the matrix in a roughly square, checkerboard fashion. Can anyone point me to any data on what kind of speed up I can realistically hope for in this range of problem size and processor number? Thanks.
Every parallelisation technology introduces some kind of overhead. It only makes sense to employ such technology if this overhead is substantially smaller than the amount of work being done by each processing element (= CPU core).
If you increase the matrix size, you end with up with problem that takes more time and therefore the overhead would be relatively less. But you would end up with a completely different problem - memory bandwidth. Matrix-vector multiplication is a memory bound problem and on modern CPUs the bandwidth of a single socket could easily be "eaten" by one or two threads doing the multiplication. Having more threads would do nothing since there simply won't be enough memory bandwidth to feed the threads with data. Only adding additional CPU sockets would improve the performance since it will effectively increase the available memory bandwidth.
That's it - matrix-vector multiplication is a very simple but also very tricky problem when it comes to parallelisation.