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I have recently downloaded and installed the Intel C++ compiler, Composer XE 2013, for Linux which is free to use for non-commercial development. http://software.intel.com/en-us/non-commercial-software-development

I'm running on a ivy bridge system (which has AVX). I have two versions of a function which do the same thing. One does not use SSE/AVX. The other version uses AVX. In GCC the AVX code is about four times faster than the scalar code. However, with the Intel C++ compiler the performance is much worse. With GCC I compile like this

gcc m6.cpp -o m6_gcc -O3 -mavx -fopenmp -Wall -pedantic

With Intel I compile like this

icc m6.cpp -o m6_gcc -O3 -mavx -fopenmp -Wall -pedantic

I'm only using OpenMP for timing (with omp_get_wtime()) at this point. The strange thing is that if I change the avx option to say msse2 the code fails to compile with GCC but compiles just fine with ICC. In fact I can drop the mavx all together and it still compiles. It seems no matter what options I try it compiles but does not make optimal use of the AVX code. So I'm wondering if I'm doing something wrong in enabling/disabling SSE/AVX with ICC?

Here is the the function with AVX that I'm using.

inline void prod_block4_unroll2_AVX(double *x, double *M, double *y, double *result) {
    __m256d sum4_1 = _mm256_set1_pd(0.0f);
    __m256d sum4_2 = _mm256_set1_pd(0.0f);

    __m256d yrow[6];
    for(int i=0; i<6; i++) {
        yrow[i] = _mm256_load_pd(&y[4*i]);
    for(int i=0; i<6; i++) {
        __m256d x4 = _mm256_load_pd(&x[4*i]);
        for(int j=0; j<6; j+=2) {
            __m256d brod1 = _mm256_set1_pd(M[i*6 + j]);
            sum4_1 = _mm256_add_pd(sum4_1, _mm256_mul_pd(_mm256_mul_pd(x4, brod1), yrow[j]));
            __m256d brod2 = _mm256_set1_pd(M[i*6 + j+1]);
            sum4_2 = _mm256_add_pd(sum4_2, _mm256_mul_pd(_mm256_mul_pd(x4, brod2), yrow[j+1]));
    sum4_1 = _mm256_add_pd(sum4_1, sum4_2);
    _mm256_store_pd(result, sum4_1);

Here is timing information in seconds. I run over three ranges corresponding to L1, L2, and L3 cache ranges. I only get 4x in the L1 region. Note that ICC has much faster scalar code but slower AVX code.

nvec 2000, repeat 100000
time scalar 5.847293
time SIMD 1.463820
time scalar/SIMD 3.994543

nvec 32000, repeat 10000
time scalar 9.529597
time SIMD 2.616296
time scalar/SIMD 3.642400
difference 0.000000

nvec 5000000, repeat 100
time scalar 15.105612
time SIMD 4.530891
time scalar/SIMD 3.333917
difference -0.000000

nvec 2000, repeat 100000
time scalar 3.715568
time SIMD 2.025883
time scalar/SIMD 1.834049

nvec 32000, repeat 10000
time scalar 6.128615
time SIMD 3.509130
time scalar/SIMD 1.746477

nvec 5000000, repeat 100
time scalar 9.844096
time SIMD 5.782332
time scalar/SIMD 1.702444
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1 Answer 1

Two points:

(1) It appears you are using intel intrinsics in your code -- g++ and icpc do not necessarily implement the same intrinsics (but most of them overlap). Check the header files that need to be imported (g++ may need the hint to define the inartistic for you). Does g++ give an error message when it fails?

(2) The compiler flags do does not mean that instructions will be generated (from icpc --help): -msse3 May generate Intel(R) SSE3, SSE2, and SSE instructions

These flags are usually just hints to the compiler. You may want to look at -xHost and -fast.

It seems no matter what options I try it compiles but does not make optimal use of the AVX code.

How have you checked this? You may not see a 4x speedup if there are other bottlenecks (such as memory bandwidth).

EDIT (based on question edits):

It looks like icc scalar is faster than gcc scalar -- it is possible that icc is vectorizing the scalar code. If this is the case, I would not expect a 4x speedup from icc when manually coding the vectorization.

As far the the difference between icc at 5.782332s and gcc at 3.509130s (for nvec 5000000); this is unexpected. I cannot tell based on the information I have what why there is a difference in the runtime between the two compilers. I would recommend looking at the emitted code (http://www.delorie.com/djgpp/v2faq/faq8_20.html) from both compilers. Also, make sure that your measurements are reproducible (e.g. memory layout on multi-socket machines, hot/cold caches, background processes, etc.).

share|improve this answer
Thanks for the comments. I'm including "#include <immintrin.h>". GCC says e.g. "__m256d’ was not declared in this scope" if I don't use -mavx. I tried -xHost -fast -xavx. It makes no difference. I'm starting to wonder about the CPU dispatcher with this free version of the intel compiler. I don't have the full version to compare with. –  user2088790 Jun 10 '13 at 20:44
According the the FAQ it should include the same features as the commerical version so that's not likely the problem. "Do the features vary between the non-commercial and commercial product? At the current time, the non-commercial product offerings have the same features as the commercial product." software.intel.com/en-us/articles/non-commercial-software-faq/… –  user2088790 Jun 10 '13 at 20:47
" GCC says e.g. "__m256d’ was not declared in this scope" if I don't use -mavx." Just means gcc does not define the intrinsic if you do not pass the flag. –  hazydev Jun 10 '13 at 20:51
When you say it makes no difference, what are you comparing? Are you comparing the compiled code with and without the -mavx flag? –  hazydev Jun 10 '13 at 20:52
okay, but GCC is getting a 4x speedup. I have the scalar code and the AVX code and I time both. The intel AVX code is significantly slower than the GCC code (however the Intel scalar code is faster than the GCC scalar code). –  user2088790 Jun 10 '13 at 20:54

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