# Need advice on parallel MGS (Modified Gram-Schmidt) algorithm

I need to parallelise a MGS (Modified Gram-Schmidt) algorithm. Right now I have a parallel region at the second half of the algorithm (see code). It gives the right results but it runs slower than the serial version. I think this is due to the overhead created when creating and destroying theads.

When I try to move '#pragma omp parallel' to the beginning (i.e. the k loop), to try minimise my overhead, the algorithm gives wrong results. Even after trying different shared and private variables.

Can I please have some advice on how to solve this problem and how to write an efficient parallel MGS algorithm?

Thanks

``````void run_mgs(double ** q, int m, int n){

/* Modified Gram-Schmidt algorithm */

double s;
double start, finish;

int i, j, k;

start = timer();
for( k = 0; k < m; k++ ) {
for( i = 0; i < k; i++ ) {
/* s = q_i(T) * q_k */
s = 0.0;
for( j = 0; j < n; j++ ) {
s += q[ i ][ j ] * q[ k ][ j ];
}
/* q_k = q_k - s*q_i */
for( j = 0; j < n; j++ ) {
q[ k ][ j ] -= s * q[ i ][ j ];
}
}
s = 0.0;
/* s = q_k(T) * q_k */
#pragma omp parallel shared(q, m, n, i, k, s)  private(j)
{
#pragma omp for reduction(+:s)
for( j = 0; j < n; j++ ) {
s += pow( q[ k ][ j ], 2 );
}
/* q_k = q_k / Sqrt( s ) */
#pragma omp for
for( j = 0; j < n; j++ ) {
q[ k ][ j ] /= sqrt( s );
}
}
}
finish = timer();

fprintf( stdout,
"Maximum error in orthonormalisation for MGS : %20.16f\n",
check_orthonorm( n, m, q ) );
fprintf( stdout, "Time for MGS : %9.4f\n", finish - start );
}
``````
-
First of all: What is your problem size? If it is to small you will never get faster with parallelization. Second what schedule mode is used for the `omp for`? –  Grizzly May 1 '12 at 13:54
@Grizzly The problem size is big, I know it won't run faster if it's only solving small problems. I believe the default scheduling used is dynamic. However I can always change this. –  lamba May 1 '12 at 14:08
`dynamic` uses a default chunk size of `1`, so that would mean that the iterations are assigned to threads one at a time, which would be very bad for performance (due to a) schedule overhead beeing higher then calc cost and b) false sharing in your second loop). And for the problem size: with big you mean n > 10000, right (more would be better of course)? –  Grizzly May 1 '12 at 14:19
@Grizzly I tried using static, but it's not a lot faster (only 0.1 second faster than before). I ran the code for 10000 order of vector and 1000 vectors, there is hardly any difference between the serial c ode and the parallel code. I believe the main problem is that I'm creating and destroying threads multiple times in the middle of the algorithm rather than at the start and the end of the algorithm. –  lamba May 1 '12 at 14:37
I think most openmp implementations might actually reuse the threads, so that overhead might not be as bad as you think. If you really want to you could put the `openmp parallel` outside of the loop and do your work distribution your self (`omp for` does not work for nested loops) and try it though. Do you use openmp 3.0 or better (for `omp task`)? In that case it's pretty easy, otherwise you'll simply need quite a few barriers. Btw: I don't see how you will get any measurable speedup without parallelising the first two inner loops too. –  Grizzly May 1 '12 at 16:05