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I'm writing a program for matrix multiplication with OpenMP, that, for cache convenience, implements the multiplication A x B(transpose) rows X rows instead of the classic A x B rows x columns, for better cache efficiency. Doing this I faced an interesting fact that for me is illogic: if in this code i parallelize the extern loop the program is slower than if I put the OpenMP directives in the most inner loop, in my computer the times are 10.9 vs 8.1 seconds.

//A and B are double* allocated with malloc, Nu is the lenght of the matrixes 
//which are square

//#pragma omp parallel for
for (i=0; i<Nu; i++){
  for (j=0; j<Nu; j++){
    *(C+(i*Nu+j)) = 0.;
#pragma omp parallel for
    for(k=0;k<Nu ;k++){
      *(C+(i*Nu+j))+=*(A+(i*Nu+k)) * *(B+(j*Nu+k));//C(i,j)=sum(over k) A(i,k)*B(k,j)
share|improve this question
By tweaking omp parameters I've got 200% speed up on my machine. original: llcomp.googlecode.com/hg/examples/mxm.c current: codepad.org/nSfZHp03 –  J.F. Sebastian Jan 18 '11 at 22:01
Nice solution. Yeah, OpenMP is kinda tricky –  Elalfer Jan 18 '11 at 22:04
Code that uses 'fortran' memory layout for the B matrix runs 4-8 faster (the greatest benefit) for 1000x1000 matrices (threaded version takes 0.5 seconds). gist.github.com/790865 –  J.F. Sebastian Jan 22 '11 at 4:52
Have you estimated your Gflops/s? It should be 2.0*n^3/time. Compare that with the max for your CPU: frequency * (SIMD_width)* (2 ILP) * (number of cores). e.g on my 2600k it is (4GHz) * 4(AVX) * 2 (ILP) * 4 cores = 128 DP Gflops/s. Likely your efficiency is less than 10%. –  user2088790 May 26 '13 at 10:47

2 Answers 2

up vote 1 down vote accepted

Try hitting the result less often. This induces cacheline sharing and prevents the operation from running in parallel. Using a local variable instead will allow most of the writes to take place in each core's L1 cache.

Also, use of restrict may help. Otherwise the compiler can't guarantee that writes to C aren't changing A and B.


for (i=0; i<Nu; i++){
  const double* const Arow = A + i*Nu;
  double* const Crow = C + i*Nu;
#pragma omp parallel for
  for (j=0; j<Nu; j++){
    const double* const Bcol = B + j*Nu;
    double sum = 0.0;
    for(k=0;k<Nu ;k++){
      sum += Arow[k] * Bcol[k]; //C(i,j)=sum(over k) A(i,k)*B(k,j)
    Crow[j] = sum;

Also, I think Elalfer is right about needing reduction if you parallelize the innermost loop.

share|improve this answer
thanks for the answer, I'll try then I'll come back –  sdffadsf Jan 18 '11 at 19:03
Incredibile, time has became only 4.2 s with the most inner loop and 4.4 with the most outer (!), while the code with #pragma like in the code you posted time is >17, i don't know why. thanks really to all, even if is don't understand why with the most outer is slightly slower than the most inner –  sdffadsf Jan 18 '11 at 19:25
@RR576: Check the results, you may not have the right output when parallelizing the innermost loop without specifying a reduction operation. –  Ben Voigt Jan 18 '11 at 19:35
yes, you are right even on this. I committed several errors during the program, and your guess is correct, with the reduction the inner works (4.2s) but the most outer is the more efficient (3.9s!), while the central is very slow, around 20, this i think is due to the cacheline (the address varies with i very fast), so the apparent paradox is revealed, tomorrow morning i have the exam on scientific programming...thanks again to you and Elalfer –  sdffadsf Jan 18 '11 at 19:59
there is a typo in Bcol = B + i*Nu it should be j. –  J.F. Sebastian Jan 22 '11 at 4:34

You could probably have some dependencies in the data when you parallelize the outer loop and compiler is not able to figure it out and adds additional locks.

Most probably it decides that different outer loop iterations could write into the same (C+(i*Nu+j)) and it adds access locks to protect it.

Compiler could probably figure out that there are no dependencies if you'll parallelize the 2nd loop. But figuring out that there are no dependencies parallelizing the outer loop is not so trivial for a compiler.


Some performance measurements.

Hi again. It looks like 1000 double * and + is not enough to cover the cost of threads synchronization.

I've done few small tests and simple vector scalar multiplication is not effective with openmp unless the number of elements is less than ~10'000. Basically, larger your array is, more performance will you get from using openmp.

So parallelizing the most inner loop you'll have to separate task between different threads and gather data back 1'000'000 times.

PS. Try Intel ICC, it is kinda free to use for students and open source projects. I remember being using openmp for smaller that 10'000 elements arrays.

UPDATE 2: Reduction example

    double sum = 0.0;
    int k=0;
    double *al = A+i*Nu;
    double *bl = A+j*Nu;
    #pragma omp parallel for shared(al, bl) reduction(+:sum)
    for(k=0;k<Nu ;k++){
        sum +=al[k] * bl[k]; //C(i,j)=sum(over k) A(i,k)*B(k,j)
    C[i*Nu+j] = sum;
share|improve this answer
the loop has no carried dependency, all iterations are independent –  sdffadsf Jan 18 '11 at 17:04
You can see it, but compiler is not an AI and could miss it ;) I'm actually had a lot of battles with OpenMP & icc regarding to this stuff. –  Elalfer Jan 18 '11 at 17:05
sorry for my arrogance, you are surely more expert than me, I'll check. If i parallelize the second loop the result is more than 15 seconds. –  sdffadsf Jan 18 '11 at 17:15
One notice: Have you tried to use reduction clause for the most inner loop? I'll try this code later. It looks like fun to remember how to work with OpenMP. Which compiler are you using? gcc or icc? And what is the size of your matrix? –  Elalfer Jan 18 '11 at 17:18
if you want i can send you my code.The matrix is big (1000x1000). I see no space to use reduction (C is a pointer), in the most outer loop you can't use in every case (on what you reduct?). The problem is that I'm am not a computer engineer, I don't know how the computer memory "works" in a physical way, i know how to use the cache line and as you can see i used that information for the multiplication rows x rows, but my knowledge stops here. For me the problem is in the use of cache, only this feature can add all this time to execute. Thanks for the answer, I'm looking forward for your ideas –  sdffadsf Jan 18 '11 at 17:40

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