I'm trying to parallelize the following C function using OpenMP:
struct pixel {
double r, g, b;
};
double min_dist_sum_parallel(struct pixel *pixels, int n_pixels,
struct pixel *centroids, int n_centroids)
{
double t0 = omp_get_wtime();
double min_dist_sum = 0.0;
#pragma omp parallel for reduction(+:min_dist_sum)
for (int i = 0; i < n_pixels; ++i) {
int closest_centroid = 0;
double min_dist = DBL_MAX;
for (int j = 0; j < n_centroids; ++j) {
double dr = pixels[i].r - centroids[j].r;
double dg = pixels[i].g - centroids[j].g;
double db = pixels[i].b - centroids[j].b;
double dist = sqrt(dr * dr + dg * dg + db * db);
if (dist < min_dist) {
closest_centroid = j;
min_dist = dist;
}
}
min_dist_sum += min_dist;
}
return min_dist_sum;
}
I have tested this on a machine with two CPU cores supporting two hyper-threads each. Limiting the maximum number of OpenMP threads to two by setting the OMP_NUM_THREAD environment variable speeds up the program by about a factor of two (as expected) for adequate problem sizes (e.g. n_pixels = 1000000, n_centroids = 10).
Allowing three threads on the other hand does not yield further performance gains, in fact the program then runs on average about 10% slower than in the two-thread case. Performance for four threads is again similar to performance for two threads.
I believe I understand why this is happening: because no especially computationally expensive operations are performed between memory accesses, multiple hyper-threads on the same CPU core are unable to effectively share the workload.
Is this explanation sound? In any case I don't understand how this would explain three OpenMP threads being slower than either two or four.
