3

simd pragma can be used with icc compiler to perform a reduction operator:

#pragma simd
#pragma simd reduction(+:acc)
#pragma ivdep
for(int i( 0 ); i < N; ++i )
{
  acc += x[i];
}

Is there any equivalent solution in msvc or/and gcc?

Ref(p28): http://d3f8ykwhia686p.cloudfront.net/1live/intel/CompilerAutovectorizationGuide.pdf

2

GCC definitely can vectorize. Suppose you have file reduc.c with contents:

int foo(int *x, int N)
  {
    int acc, i;

    for( i = 0; i < N; ++i )
      {
        acc += x[i];
      }

    return acc;
  }

Compile it (I used gcc 4.7.2) with command line:

$ gcc -O3 -S reduc.c -ftree-vectorize -msse2

Now you can see vectorized loop in assembler.

Also you may switch on verbose vectorizer output say with

$ gcc -O3 -S reduc.c -ftree-vectorize -msse2 -ftree-vectorizer-verbose=1

Now you will get console report:

Analyzing loop at reduc.c:5
Vectorizing loop at reduc.c:5
5: LOOP VECTORIZED.
reduc.c:1: note: vectorized 1 loops in function.

Look at the official docs to better understand cases where GCC can and cannot vectorize.

  • when the type of acc become double, this way does not work! – wonder Jul 12 '13 at 15:32
  • sorry, I missed this: "To enable vectorization of floating point reductions use -ffast-math or -fassociative-math." – wonder Jul 13 '13 at 11:13
3

For Visual Studio 2012: With options /O1 /O2/GL, to report vectorization use /Qvec-report:(1/2)

int s = 0; 
for ( int i = 0; i < 1000; ++i ) 
{ 
s += A[i]; // vectorizable 
}

In the case of reductions over "float" or "double" types, vectorization requires that the /fp:fast switch is thrown. This is because vectorizing the reduction operation depends upon "floating point reassociation". Reassociation is only allowed when /fp:fast is thrown

Ref(associated doc;p12) http://blogs.msdn.com/b/nativeconcurrency/archive/2012/07/10/auto-vectorizer-in-visual-studio-11-cookbook.aspx

1

gcc requires -ffast-math to enable this optimization (as mentioned in the reference given above), regardless of use of #pragma omp simd reduction. icc is becoming less reliant on pragma for this optimization (except that /fp:fast is needed in absence of pragma), but the extra ivdep and simd pragmas in the original post are undesirable. icc may do bad things when given a pragma simd which doesn't include all relevant reduction, firstprivate, and lastprivate clauses (and gcc may break with -ffast-math, particularly in combination with -march or -mavx). msvc 2012/2013 are very limited in auto-vectorization. There are no simd reductions, no vectorization within OpenMP parallel regions, no vectorization of conditionals, and no advantage is taken of __restrict in vectorizations (there is some run-time check to vectorize less efficiently but safely without __restrict).

  • The combination gcc -fopenmp -march=native -funsafe-math-optimizations -O3 fails for me. If I remove any of those 3 options or cut back to -march=corei7 or -O2, the case succeeds. -march=native is much more aggressive for avx and avx2 architectures, so its influence may not be a total surprise. – tim18 May 24 '15 at 1:05
  • I think it's documented somewhere that -O3 -ffast-math is required for some of these optimizations, so it's not surprising that -ffast-math isn't so risky with -O2. – tim18 May 24 '15 at 1:12
  • In the benchmark posted to github.com/tprince/lcd I split the C source files into those which need -ffast-math and those which need -fopenmp. For various Intel compilers I use the same options throughout for each source language. – tim18 May 24 '15 at 16:53
  • The problem of conflict between -fopenmp and -ffast-math showed up with g++ as well, on a Westmere platform, solved similarly. The C++ build is set up for MSVC as well. – tim18 May 25 '15 at 13:41

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