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# CUSP CG convergence

I use CUSP conjugate gradient method to solve my symmetric sparse matrix. And I have no idea why it doesn't converge. Dimensions of matrices I use are not that large (1K to 100K). The same linear systems are easily solved by MKL, so the matrix is not ill-conditioned. However I tried adding preconditioner, but it gave no results:

diagonal preconditioner and AINV (incomplete Cholesky) gave unlimited growth of residual (as long as cg and bicgstab)

Here's my code:

``````cusp::csr_matrix <int, float, cusp::device_memory> A (n, n, nnz);

for (i = 0; i < n + 1; i++)
A.row_offsets[i] = csrRowPtr[i] - 1;
for (i = 0; i < nnz; i++)
A.values[i] = csrVal[i];
for (i = 0; i < nnz; i++)
A.column_indices[i] = csrColInd[i] - 1;

cusp::array1d <float, cusp::device_memory> x (A.num_rows, 0);
cusp::array1d <float, cusp::device_memory> b (A.num_rows, 1);

for (i = 0; i < n; i++)
b[i] = b_host[i];

cusp::verbose_monitor<float> monitor(b, 100, 1e-3);
cusp::identity_operator<float, MemorySpace> M(A.num_rows, A.num_rows);
/*
cusp::precond::diagonal<float, MemorySpace> M(A);
cusp::precond::scaled_bridson_ainv<float, MemorySpace> M(A, .1);
*/
cusp::krylov::cg(A, x, b, monitor, M);

for (i = 0; i < n; i++)
x_host[i] = x[i];
``````

Why isn't it working correctly?

P.S. As I understand CUSP supposes zero-based index, that's why I decrease csrRowPtr and csrColInd. When I used nVidia cuSparse library there was an option to set other parameters like matrix type and fill mode. How can I be sure they are set correctly in CUSP?

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What method in MKL is successfully solving the system? – talonmies Feb 9 '14 at 15:35
Preconditioned CG. But I also solved these systems (under 40K) with a sample conjugate gradient from CUDA SDK. – Max Feb 9 '14 at 15:48
Are you sure that you are not doing anything wrong on the cusp side? Since you are using MKL and the CUDA SDK and both converge, I assume you know the solution. What does it happen if you use cusp's cg starting from the solution point you already have (I'm not a cusp user, so I don't know if this is possible)? Does cusp gets stuck at the starting point, which is what one should expect? This is a consistency test I typically do to check for bugs in my optimization algorithms. – JackOLantern Feb 9 '14 at 17:51
This code appears to be largely lifted from the cusp sample code. Is there some reason you can't provide a full compilable example code that shows the problem? Your suggestion seems to be that the cg solver fails on a variety of sample problems you try, so how about the synthetic case given in the cusp sample or the CG SDK sample? Do you have a typedef for MemorySpace somewhere? Please provide a complete sample like the cusp or SDK CG samples. – Robert Crovella Feb 9 '14 at 21:19
I suspect a problem in your `A` matrix assembly. Try using the CSR matrix verification available in `cusp/verify.h`. Here's a complete worked example showing the assembly of the `A` matrix using the routine from the cuda SDK sample. It seems to converge quickly for me. – Robert Crovella Feb 9 '14 at 23:59

Only elements from the upper triangle are stored in MKL's CSR format, but all the elements must be stored in CUSP's CSR format even if you are solving a symmetric linear system.

Also I think

``````for (i = 0; i < n; i++)
x_host[i] = x[i];
``````

is not a good idea; first transfer it back to host_memory

``````cusp::array1d<float, cusp::host_memory> _x = x;
``````

then copy it back to x_host or whatever your result array is

``````for (i = 0; i < n; i++)
x_host[i] = _x[i];
``````
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