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I have edited my question after previous comments (especially @Zboson) for better readability

I have always acted on, and observed, the conventional wisdom that the number of openmp threads should roughly match the number of hyper-threads on a machine for optimal performance. However, I am observing odd behaviour on my new laptop with Intel Core i7 4960HQ, 4 cores - 8 threads. (See Intel docs here)

Here is my test code:

#include <math.h>
#include <stdlib.h>
#include <stdio.h>
#include <omp.h>

int main() {
    const int n = 256*8192*100;
    double *A, *B;
    posix_memalign((void**)&A, 64, n*sizeof(double));
    posix_memalign((void**)&B, 64, n*sizeof(double));
    for (int i = 0; i < n; ++i) {
        A[i] = 0.1;
        B[i] = 0.0;
    double start = omp_get_wtime();
    #pragma omp parallel for
    for (int i = 0; i < n; ++i) {
        B[i] = exp(A[i]) + sin(B[i]);
    double end = omp_get_wtime();
    double sum = 0.0;
    for (int i = 0; i < n; ++i) {
        sum += B[i];
    printf("%g %g\n", end - start, sum);
    return 0;

When I compile it using gcc 4.9-4.9-20140209, with the command: gcc -Ofast -march=native -std=c99 -fopenmp -Wa,-q I see the following performance as I change OMP_NUM_THREADS [the points are an average of 5 runs, the error bars (which are hardly visible) are the standard deviations]: Performance as a function of thread count

The plot is clearer when shown as the speed up with respect to OMP_NUM_THREADS=1: Speed up as a function of thread count

The performance more or less monotonically increases with thread number, even when the the number of omp threads very greatly exceeds the core and also hyper-thread count! Usually the performance should drop off when too many threads are used (at least in my previous experience), due to the threading overhead. Especially as the calculation should be cpu (or at least memory) bound and not waiting on I/O.

Even more weirdly, the speed-up is 35 times!

Can anyone explain this?

I also tested this with much smaller arrays 8192*4, and see similar performance scaling.

In case it matters, I am on Mac OS 10.9 and the performance data where obtained by running (under bash):

for i in {1..128}; do
    for k in {1..5}; do
        export OMP_NUM_THREADS=$i;
        echo -ne $i $k "";
done > out

EDIT: Out of curiosity I decided to try much larger numbers of threads. My OS limits this to 2000. The odd results (both speed up and low thread overhead) speak for themselves! Crazy numbers of threads

EDIT: I tried @Zboson latest suggestion in their answer, i.e. putting VZEROUPPER before each math function within the loop, and it did fix the scaling problem! (It also sent the single threaded code from 22 s to 2 s!):

correct scaling

share|improve this question
It may be how indeed OpenMP is assigning the threads, have you tried 3 threads just out of curiosity? It could be that when moving from 1 to 2, that it is assigning both threads to a single ACTUAL core, but because you are truly trying to utilize the same resources within that single core, that it really isn't helping! When moving to 4, you are truly utilizing 2 actual cores (maybe). Also, what happens if you use 8 threads, so we can see what happens when we move from (hopefully) a hyperthread situation to a full core situation + hyperthreads? –  trumpetlicks Feb 22 '14 at 20:44
@trumpetlicks I added the timings you wanted. –  jtravs Feb 22 '14 at 20:57
Also, if you to multiple runs of each (with the exception of the single case), what do the timings come out to. I think that OpenMP and the OS randomly assign to core # (or in your case it could be assigning to a HT or actual core). –  trumpetlicks Feb 22 '14 at 21:11
where you are changing the no. of threads used? –  Devavrata Feb 22 '14 at 21:21
@Neuron by using the OMP_NUM_THREADS environment variable –  jtravs Feb 22 '14 at 21:52

1 Answer 1

up vote 7 down vote accepted

The problem is likely due to the clock() function. It does not return the wall time on Linux. You should use the function omp_get_wtime(). It's more accurate than clock and works on GCC, ICC, and MSVC. In fact I use it for timing code even when I'm not using OpenMP.

I tested your code with it here http://coliru.stacked-crooked.com/a/26f4e8c9fdae5cc2

Edit: Another thing to consider which may be causing your problem is that exp and sin function which you are using are compiled WITHOUT AVX support. Your code is compiled with AVX support (actually AVX2). You can see this from GCC explorer with your code if you compile with -fopenmp -mavx2 -mfma Whenever you call a function without AVX support from code with AVX you need to zero the upper part of the YMM register or pay a large penalty. You can do this with the intrinsic _mm256_zeroupper (VZEROUPPER). Clang does this for you but last I checked GCC does not so you have to do it yourself (see the comments to this question Math functions takes more cycles after running any intel AVX function and also the answer here Using AVX CPU instructions: Poor performance without "/arch:AVX"). So every iteration you are have a large delay due to not calling VZEROUPPER. I'm not sure why this is what matters with multiple threads but if GCC does this each time it starts a new thread then it could help explain what you are seeing.

#include <immintrin.h>

#pragma omp parallel for
for (int i = 0; i < n; ++i) {
    B[i] = sin(B[i]);
    B[i] += exp(A[i]);       

Edit A simpler way to test do this is to instead of compiling with -march=native don't set the arch (gcc -Ofast -std=c99 -fopenmp -Wa) or just use SSE2 (gcc -Ofast -msse2 -std=c99 -fopenmp -Wa).

Edit GCC 4.8 has an option -mvzeroupper which may be the most convenient solution.

This option instructs GCC to emit a vzeroupper instruction before a transfer of control flow out of the function to minimize the AVX to SSE transition penalty as well as remove unnecessary zeroupper intrinsics.

share|improve this answer
time what you ahve to time. Warming up just make sure you forgot to take into account the cost of OpenMP, which is misleading. The coost is the cost, live with it. –  Joel Falcou Feb 23 '14 at 7:57
I could argue that not warming up is misleading. If you're going to use your function several times and you only report the time staring cold then that's misleading. It's best to report a worst case and best case time. That's more accurate. –  Z boson Feb 23 '14 at 8:02
@JoelFalcou, to give you an example. I render the Mandelbrot set several frames per second using OpenMP. The first frame is always the slowest one due to OpenMP warming up. It's not just a question of the cache because I can change what I render (zoom, translate) and go back to the initial setting and it's only the first frame which is so slow. If I only reported the time for the first frame it would be misleading. In this case the best case time is more accurate. –  Z boson Feb 23 '14 at 8:15
usually the best way to do that is to run a large amount of samples then take the median or the first-decile values. Also cache issues is non existant in Mandelbrodt anyway as you only store valeu to tyour destination buffer. So yeah, the first frame is slow becasue of thread starting up + cache beign cold. Median time sis better for that as it remove all outliers and not only the first. –  Joel Falcou Feb 23 '14 at 10:38
@Zboson I only wanted to parallelize one loop as I was comparing the same kernel calculation over many different languages/systems. For the same reason I want to include all openmp overhead. –  jtravs Feb 23 '14 at 10:42

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