# Parallel matrix operations

This is not a post with classic question, I'm just asking for an advice. I'm doing an application for my thesis, it uses a parallel computing, by OpenCL, to solve this problem:

A - Square matrix, size: a*a

x - Vector containing variables, lenght: a

B - Square matrix, size: a*a

Ax=B <=> (A^-1)Ax = (A^-1)B <=> x = (A^-1)B

But I know, that matrix inversion is very resource-consumming.

I'd like to ask You if this is a propper way of doing this for parallel computing? Or Should I use some other method? Do You know about any resources that can help me?

Also, wich algorithm would be most efficient?

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Matrix inversion is the operation at which OpenCL gives its maximum performance. Iwould go that way –  DarkZeros Oct 25 at 12:23
In general computational scientists try very hard to avoid explicitly inverting matrices, doing so is computationally very expensive and surprisingly tricky. So no, matrix inversion is not a `proper` thing to be doing. Your best resource is Golub and Van Loan's book Matrix Computations. And your question, soliciting advice rather than asking for help with programming, is off-topic here. –  High Performance Mark Oct 25 at 13:22
It is unefficient to invert matrixes, I agree. But in the shown case. It is the only way to proceed. So, it is better to do matrix inverse, than appliying some clever algorithm that can't or highly unlikely can't be applyed to OpenCL. I agree with @HighPerformanceMark that in the first place matrix inverse should be avoided. Try to reshape your algorithm first if possible. –  DarkZeros Oct 25 at 14:41
Matrix inversion is certainly not the only way to proceed, the Jacobi method is applicable here and there is plenty of published material on using OpenCL to implement the method. And there are many other methods, some of them relatively straightforward to parallelise. –  High Performance Mark Oct 25 at 14:51
Thanks, I'll have a look on Jacobis method implementation and compare it with traditional matrix inversion when set to desired accuracy. –  Kowalski Paweł Oct 29 at 22:30

Use the fastest GPU library MAGMA. Here is example code for 1 column b (matrix A should be stored in column order) :

``````#include <cuda_runtime_api.h>
#include <cublas.h>
#include "flops.h"
#include "magma.h"
#include "magma_lapack.h"
#include "testings.h"
void solveMAGMA(double *A, int n, double *b, double *x)
{
clock_t t1,t2;
double *d_A, *d_B, *work, Rnorm, Anorm, Xnorm, error;
int lddn = ((n+31)/32)*32, info, nrhs=1;
int* ipiv = malloc(n*sizeof(int));

double c_one = MAGMA_D_ONE;
double c_neg_one = MAGMA_D_NEG_ONE;

TESTING_INIT();

t1 = clock();
TESTING_DEVALLOC( d_A, double, lddn*n );
TESTING_DEVALLOC( d_B, double, lddn*1 );
magma_dsetmatrix( n, n, A, n, d_A, lddn );
magma_dsetmatrix( n, 1, b, n, d_B, lddn );

magma_dgesv_gpu( n, 1, d_A, lddn, ipiv, d_B, lddn, &info );
if (info != 0)  printf("magma_dgesv_gpu returned error %d: %s.\n", (int) info, magma_strerror( info ));
magma_dgetmatrix( n, 1, d_B, lddn, x, n );

t2 = clock();
double gflops = ( FLOPS_DGETRF( n, n ) + FLOPS_DGETRS( n, 1 ) ) / 1e9;
double t = ((double)t2-t1) / CLOCKS_PER_SEC;
printf("Time of solveMAGMA = %f,   GFlop = %f\nGFlop/s = %f, %% from theory = %f%%\n", t, gflops, gflops/t, gflops/t/515*100);
}
``````

Add to include path following directories:

cuda/include

magma-1.4.0/include

magma-1.4.0/testing

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Thank's, I'll try this one. But, as fas as I can see it's not working with OpenCl on Windows. Anyway, looks interesting and worth knowing –  Kowalski Paweł Oct 29 at 22:25