# Sparse Matrix-Vector Multiplication on Cuda - performance optimization

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 )
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;

for (int i = 0; i < (dim/blockDim.x) + 1 ; ++i, vOffs+= blockDim.x) {
}

//make sure all threads are synchronized

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?

-
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