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I am trying to do a Matrix-Vector Multiplication on GPU (using Cuda).
I loaded the matrix on my C++ code (CPU), and then I perform the matrix-vector multiplication using cuda. I am also using shared memory to improve the performance.
The matrix is currently loaded as a dense matrix. How can I load them in an efficient way, knowing that my matrix is a sparse matrix, and what are the necessary changes that I have to make on my Cuda code?
Below is my C++ function to load the matrix (I loaded it as a dense matrix):

int readMatrix( char* filename, float* &matrix, unsigned int *dim = NULL, int majority = ROW_MAJOR )
{
    unsigned int w, h, x, y, num_entries;

    float val;

    std::ifstream file( filename );

    if ( file )
    {
        file >> h >> w >> num_entries;
        cout << w << " " << h << " " << num_entries << "\n";

        assert( w == h || w == 1 || h == 1 );

        if( dim != NULL ) *dim = std::max( w, h );

        matrix = new float[ w * h ];

        unsigned int i;
        for( i = 0; i < num_entries; i++ ){

            if( file.eof() ) break;

            file >> y >> x >> val;

            if( majority == ROW_MAJOR ){

                matrix[ w * y + x ] = val;

            } else if( majority == COLUMN_MAJOR ){

                matrix[ h * x + y ] = val;
            }
        }
        file.close();

        if( i == num_entries )
            std::cout << "\nFile read successfully\n"; 
        else
            std::cout << "\nFile read successfully but seems defective:\n num entries read = " << i << ", entries epected = " << num_entries << "\n"; 

        // print first few elements
        if( w == h ){
            for( unsigned int i = 0; i < w; i++ ){

                printf("\n");
                for( unsigned int j = 0; j < h; j++ ){

                    printf("%.2f ", matrix[ j + w * i ] );
                }
            }   
        }
        else{   

            printf("\n");
            for( unsigned int j = 0; j < h; j++ ){

                printf("%.2f ", matrix[ j ] );
            }
        }

    } else {

        std::cout << "Unable to open file\n";
        return false;
    }

    return true;
}

Below is my Cuda Kernel function that handle the matrix-vector multiplication:

__global__ void
_cl_matrix_vector_( float *A, float *b, float *x, int dim )
{
    extern __shared__ float vec[];
    unsigned int idx = blockIdx.x * blockDim.x + threadIdx.x;
    float temp = 0.0;
    int vOffs = 0;

    //load vector into shared memory
    for (int i = 0; i < (dim/blockDim.x) + 1 ; ++i, vOffs+= blockDim.x) {
        vec[vOffs + threadIdx.x] = b[vOffs + threadIdx.x];
    }

    //make sure all threads are synchronized
     __syncthreads();

    if (idx < dim) {
        temp = 0.0;
        //dot product (multiplication)
        for (int i = 0; i < dim; i++){
            temp += A[idx * dim + i] * vec[i];
        }
         x[idx] = temp;
    } 

}

Any ideas on what changes do I have to make knowing that my matrix is a sparse matrix?
Another question, I found out from a forum that we can also use padding to be able to optimize the performance, but this requires me to change the way I read the matrix / sort the matrix.
Any ideas how to implement this padding in the way I read the matrix and perform the calculation?

share|improve this question
1  
The right answer depends completely on the format in which the sparse matrix is stored. See nvidia.com/object/nvidia_research_pub_001.html for a paper which discusses the merits of different sparse formats on GPUs. –  talonmies May 12 '11 at 9:38

1 Answer 1

You might want to have a look at the very good CUSP library. They implement sparse matrices in a variety of formats (coo, csr, ellpack, diagonal and a hybrid between ellpack and coo). Each with their own advantages as described in the documentation. Most of them are "standard" sparse matrix formats about which you can find more information online. Not a complete answer to your question perhaps, but it should provide a starting point.

share|improve this answer
    
CUSP handled the whole thing, even it also defined the Conjugate gradient method. But I need an implementation on Cuda, and I need to do it manually to understand how it work (not just calling a ready made function to handle this). But thanks anyway for your answer, Bart. –  all_by_grace May 11 '11 at 21:23
    
@all_by_grace I didn't mean you should just use CUSP. I meant that it provides an excellent general implementation you could use for inspiration. And of course it uses CUDA. Anyway, good luck with your work. ;) –  Bart May 11 '11 at 21:26

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