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I just completed a computer graphics course, where we had to program a ray tracer. Though all the results were correct, I was confused about the use of OpenMP (which BTW was not part of the course). I have this loop (C++):

#pragma omp parallel for private(L, ray)
//  for (x = x_from; x < x_till; x++) {
//  printf("Col: %5d\n", x);
//  for (y = y_from; y < y_till; y++) {
  for (int xy = 0; xy < xy_range; xy++) {
    int x = x_from + (xy % x_width);
    int y = y_from + (xy / x_width);
        ray = cam->get_ray_at(x, y);
        L = trace_ray(ray, 0, cam->inter);
    #pragma omp critical
    cam->set_pixel(x, y, L);
//  }

I tried many configurations. But what finally confuses me the most is that the above version, with a combined, single for, was the least efficient of all (150 seconds vs 120s for separate x and y for. The 'critical' does not noticeably change the timing.

More: though I would expect the single for-loop to parallelize each separate iteration, it doesn't. Using this method, 25 loops are executed as groups of 8 - 8 - 8 - 1 (8 cores). In fact the separate y-loops (commented out in listing) seem to distribute the load more efficiently. Removing the 'for' in 'parallel for' does improve slightly (148 vs 150s ;)

Also, I tried local vs global definitions (with the necessary private pragmas). I tried to declare L and ray inside the loops. All to no avail...

I'd appreciate suggestions or pointers...

Here are some more precise data:

Single loop             Yes                     No                      No                      Yes    
'Critical"              No                      No                      Yes                     Yes
                ----------------------  ----------------------  ----------------------  ----------------------
                User    CPU     Mean    User    CPU     Mean    User    CPU     Mean    User    CPU     Mean
Scene 5         37.9    158.9   3.66    26.5    185.5   7.00    27.0    187.7   6.95    38.7    161.8   4.18
Scene 6         18.8    110     5.85    17.7    112     6.32    18.1    113.8   5.29    19.4    112.2   5.78
Scene 7         149     658.8   4.42    114     679.9   5.96    114     653.8   5.73    149     659.8   4.43
Plane           112.0   497.3   4.44    105     520.5   4.95    103.8   525     5.06    113.5   504.8   4.45     
5-balls         126     760.2   6.03    162.3   697.5   4.36    170.3   725.3   4.23    127.3   766.5   6.02

'Mean' is CPU/User, which is the mean core occupation. Note that in several cases, mean is only 4.xx.

Solution, and results:

Single loop             Yes                     No
                ----------------------  ----------------------
                User    CPU     Mean    User    CPU     Mean
Scene 5         23.9    190.1   7.95    24.4    190.7   7.82
Scene 6         14.3    114.2   7.98    14.5    114.9   7.92
Scene 7         85.5    675.9   7.91    106.9   698.8   6.54
Plane           72.7    579.1   7.97    72.6    578.4   7.97
5-balls         104.8   823.3   7.86    103.9   825.1   7.94

This excellent result is obtained by adding schedule(dynamic, 1) to the #pragma omp parallel for line like this:

#pragma omp parallel for schedule(dynamic, 1)

which see to a run-time load distribution for cores (as opposed to compile time).

Just one more note, the ', 1' parameter is to limit the size of the chunks. It can be left out, in which case openmp uses a default value. Maybe adding 1 made the load distribution too fine-grained, but I cannot find any performance difference either way in this case . I guess the raytracing task is too slow and hides any administrative overhead.

share|improve this question
Could you maybe add some code examples of what you mean by "150 seconds vs 120s for separate x and y for"...."In fact the separate y-loops (commented out in listing) seem to distribute the load more efficiently"....and "Removing the 'for' in 'parallel for' does improve slightly"? –  user2088790 May 6 '13 at 20:24
The code is the same as above, uncommented the separate for's and comment the xy-for (and the x/y separator). Separate for-loops, all the rest equal, give 120 seconds exec time. Single goes to 150s. –  jcoppens May 6 '13 at 21:03

1 Answer 1

up vote 3 down vote accepted

I have written a Whitted sytle ray tracer that operates on the full ray tree (reflection and refraction) in OpenCL. I have not done it with OpenMP yet but that's my next goal. If you want to learn OpenMP I would start with some simpler tasks first. But let me make a few comments.

How are you doing your timing? You wrote "Removing the 'for' in 'parallel for' does improve slightly". That makes no sense. Removing the for is going to run the same code on each thread not distribute the treads to different iterations (do some hello world tests to show this). It should be slower not faster. That makes me wonder how you do the timing. I added some code to show how to do the timing.

You should not have to use critical. If each iteration writes to a different pixel then it should not be necessary. Depending on the complexity of your scene critical would likely make it much slower.

Lastly, to get the best performance you're going to want to use SSE/AVX as well and operate on multiple pixels at once. This can be done though what's called packet based ray tracing. See the following link for a good discussion on this http://graphics.stanford.edu/~boulos/papers/cook_gi07.pdf

Edit: Since each pixel can take different times you want to use schedule(dynamic) rather than schedule(static) which is normally (but not necessarily) the default. See the code.

Ingo Wald's PhD thesis: http://www.sci.utah.edu/~wald/PhD/

double dtime = omp_get_wtime();
#pragma omp parallel
    Ray ray;
    Color L;
    #pragma omp for schedule(dynamic)
    for (int xy = 0; xy < xy_range; xy++) {
        int x = x_from + (xy % x_width);
        int y = y_from + (xy / x_width);
        ray = cam->get_ray_at(x, y);
        L = trace_ray(ray, 0, cam->inter);
        cam->set_pixel(x, y, L);
dtime = omp_get_wtime() - dtime;
printf("time %f\n", dtime);
share|improve this answer
Hi raxman... Thanks for the answer. As the times I am measuring are relatively large, in the order of tens or hundreds of seconds, I consider program setup negligible, and simply time the program execution time with 'time' (outside the program itself). I thought that would avoid any problems with openMP itself. I added the critical statement because I had some problems with random erroneous pixels. I also tried removing the 'critical', and timing was basically the same - logical because the array assignment time is again very short. –  jcoppens May 6 '13 at 20:14
If you're getting erroneous pixels and need critical that indicates to me that you may have a race condition which cause performance hits. Is it possible for "set_pixel(x, y, L)" to wrtie to the same pixel for different values of x, y? What is L exactly? –  user2088790 May 6 '13 at 20:29
The problem was that set_pixel wrote the pixel to the wrong location. The value was right, and it was missing from the other (correct) location. Strangely this does not seem to happen anymore (will test that). One of the stranger things I notice is that usage falls from 8 cores to 3 long before the end of the render. The scene is basically constant complexity - no real bottlenecks. So this should not happen. –  jcoppens May 6 '13 at 20:58
Since pixels can take much longer than others in ray tracing then three pixels could keep running after the other threads have finished. The only way to fix that is with better load balancing. One pedantic point. I doubt you have 8 cores. I think you have 4 cores and 8 "hardware" threads (due to hyper threading). The distinction can be important. –  user2088790 May 6 '13 at 21:05
Sorry, I should have mentioned this in the beginning. With ray tracing you should be using schedule(dynamic). –  user2088790 May 7 '13 at 5:42

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