Hiding communication in Matrix Vector Product with MPI

I have to solve a huge linear equation for multiple right sides (Let's say 20 to 200). The Matrix is stored in a sparse format and distributed over multiple MPI nodes (Let's say 16 to 64). I run a CG solver on the rank 0 node. It's not possible to solve the linear equation directly, because the system matrix would be dense (Sys = A^T * S * A).

The basic Matrix-Vector multiplication is implemented as:

``````broadcast x
y = A_part * x
reduce y
``````

While the collective operations are reasonably fast (OpenMPI seems to use a binary tree like communication pattern + Infiniband), it still accounts for a quite large part of the runtime. For performance reasons we already calculate 8 right sides per iteration (Basicly SpM * DenseMatrix, just to be complete).

I'm trying to come up with a good scheme to hide the communication latency, but I did not have a good idea yet. I also try to refrain from doing 1:n communication, although I did not yet measure if scaling would be a problem.

Any suggestions are welcome!

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If you're not entirely committed to using MPI, this would be substantially easier in Charm++ or some other more dynamic environment. –  Novelocrat Oct 5 '11 at 20:44

If your matrix is already distributed, would it be possible to use a distributed sparse linear solver instead of running it only on rank 0 and then broadcasting the result (if I'm reading your description correctly..). There's plenty of libraries for that, e.g. SuperLU_DIST, MUMPS, PARDISO, Aztec(OO), etc.

The "multiple rhs" optimization is supported by at least SuperLU and MUMPS (haven't checked the others, but I'd be VERY surprised if they didn't support it!), since they solve AX=B where X and B are matrices with potentially > 1 column. That is, each "rhs" is stored as a column vector in B.

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Unfortunately this is not an option. In reality the multiplication with the system matrix involves 2 multiplications with A, as we do not calculate the system matrix. That would involve a SpM * SpM product. Also most of those libaries are direct solvers and/or do not provide optimizations for multiple rhs. –  ebo Oct 5 '11 at 14:37
@ebo: I'm a bit unsure about your terminology. System matrix == A? If so, can't you precompute it? As for the "multiple rhs" optimization, see my edit. –  janneb Oct 5 '11 at 15:09
Something like A^T * S * A. The matrix A is sparse, does not fit on a single node, does not have a exploitable structure and A^T * S * A would be dense. –  ebo Oct 5 '11 at 15:15

If you don't need to have the results of an old right-hand-side before starting the next run you could try to use non-blocking communication (ISend, IRecv) and communicate the result while calculating the next right-hand-side already.

But make sure you call MPI_Wait before reading the content of the communicated array, in order to be sure you're not reading "old" data.

If the matrices are big enough (i.e. it takes long enough to calculate the matrix-product) you don't have any communication delay at all with this approach.

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That would be 1:n communication. Using 'simple' direct communication would mean losing the efficient broadcast and reduce ops. –  ebo Oct 5 '11 at 15:19
MPI is currently working on rolling out MPI-3. With that standard you will have MPI_IBcast. This is not yet available though. –  sta Oct 5 '11 at 15:26