# Effective Matrix-Vector multiplication in cuSparse

I use jCUSPARSE (cuSparse library wrapper) to make matrix-vector multiplication and I have a problem with function

``````cusparseDcsrmv(handle, cusparseOperation.CUSPARSE_OPERATION_NON_TRANSPOSE, matrixSize, matrixSize, alpha, descra, d_csrValA, d_rowPtrA, d_colIndA, x, beta, y);
``````

If I use for descriptor initialization

``````cusparseSetMatType(descra, cusparseMatrixType.CUSPARSE_MATRIX_TYPE_GENERAL);
``````

it works in 5-10 times faster then I use

``````cusparseSetMatType(descra, cusparseMatrixType.CUSPARSE_MATRIX_TYPE_SYMMETRIC);
``````

I've tested it on a little symmetric matrix 5x5 and GENERAL works in 4 times faster then symmetric

I've tested it on a symmetric matrix 10000x10000 and GENERAL works in 10 times faster then symmetric

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The matrices are both symmetric and square? –  Tudor Nov 2 '11 at 16:04
I have the same problem with the complex counterparts (CUSPARSE_MATRIX_TYPE_HERMITIAN). –  leftaroundabout Apr 4 '12 at 16:47

It appears the OP took this question down a side channel and got an official answer from njuffa:

I checked with the CUDA library team, and they supplied the following explanation:

1. For the nonsymmetric sparse matrix-vector multiplication the operation `y = A*x` is performed (`A` is stored explicitly).

2. For the symmetric matrix only its lower (or upper) triangular part of the matrix A is stored. We can write `y = A*x = (L+D)*x + L^{T}*x`, where`A = (L+D) + L^{T}` with `L` being strictly lower triangular part of the matrix and D being the diagonal. Since only `L+D` is stored, we need to perform an operation with the matrix transpose `(L^{T})` to compute the resulting vector `y`. This operation uses atomics because matrix rows need to be interpreted as columns, and as multiple threads are traversing them, different threads might add values to the same memory location in the resulting vector `y`. This is the reason why the matrix-vector multiplication with the matrix transpose and symmetric matrix is slower than with the nonsymmetric matrix.

The best way to speed up the computation (unless you are limited by memory) would be to transform the symmetric into the nonsymmetric matrix and call the appropriate `CUSPARSE` routine on it

In short: it's bottlenecking on shared memory. Not surprising, but interesting. :)

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Pity. In my problem I can't really afford transforming to nonsymmetric because memory is a major limitation. I suppose I'll have to live with the slower calculation then! Or would there be another possibility that does not cost too much memory? –  leftaroundabout Apr 8 '12 at 8:24
@leftaroundabout Intuitively, optimizing the matrix for only the parts that are being used would be ideal. Unfortunately, I don't know how to do this with the current API short of slipstreaming in a few low-level extensions, which are a bit over my head. I'll need to leave this to someone a bit cleverer and cognizant with CUDA internals than I, sorry! –  MrGomez Apr 8 '12 at 21:09