I have implemented scalar matrix addition kernel.

#include <stdio.h>
#include <time.h>
//#include <x86intrin.h>

//loops and iterations:
#define N 128
#define M N
#define NUM_LOOP 1000000

float   __attribute__(( aligned(32))) A[N][M],
        __attribute__(( aligned(32))) B[N][M],
        __attribute__(( aligned(32))) C[N][M];

int main()
int w=0, i, j;
struct timespec tStart, tEnd;//used to record the processiing time
double tTotal , tBest=10000;//minimum of toltal time will asign to the best time

    for( i=0;i<N;i++){
            C[i][j]= A[i][j] + B[i][j];

    tTotal = (tEnd.tv_sec - tStart.tv_sec);
    tTotal += (tEnd.tv_nsec - tStart.tv_nsec) / 1000000000.0;
    } while(w++ < NUM_LOOP);

printf(" The best time: %lf sec in %d repetition for %dX%d matrix\n",tBest,w, N, M);
return 0;

In this case, I've compiled the program with different compiler flag and the assembly output of the inner loop is as follows:

gcc -O2 msse4.2: The best time: 0.000024 sec in 406490 repetition for 128X128 matrix

movss   xmm1, DWORD PTR A[rcx+rax]
addss   xmm1, DWORD PTR B[rcx+rax]
movss   DWORD PTR C[rcx+rax], xmm1

gcc -O2 -mavx: The best time: 0.000009 sec in 1000001 repetition for 128X128 matrix

vmovss  xmm1, DWORD PTR A[rcx+rax]
vaddss  xmm1, xmm1, DWORD PTR B[rcx+rax]
vmovss  DWORD PTR C[rcx+rax], xmm1

AVX version gcc -O2 -mavx:

__m256 vec256;
        vec256 = _mm256_add_ps( _mm256_load_ps(&A[i+1][j]) ,  _mm256_load_ps(&B[i+1][j]));
        _mm256_store_ps(&C[i+1][j], vec256);

SSE version gcc -O2 -sse4.2::

__m128 vec128;
    vec128= _mm_add_ps( _mm_load_ps(&A[i][j]) ,  _mm_load_ps(&B[i][j]));
    _mm_store_ps(&C[i][j], vec128);

In scalar program the speedup of -mavx over msse4.2 is 2.7x. I know the avx improved the ISA efficiently and it might be because of these improvements. But when I implemented the program in intrinsics for both AVX and SSE the speedup is a factor of 3x. The question is: AVX scalar is 2.7x faster than SSE when I vectorized it the speed up is 3x (matrix size is 128x128 for this question). Does it make any sense While using AVX and SSE in scalar mode yield, a 2.7x speedup. but vectorized method must be better because I process eight elements in AVX compared to four elements in SSE. All programs have less than 4.5% of cache misses as perf stat reported.

using gcc -O2 , linux mint, skylake

UPDATE: Briefly, Scalar-AVX is 2.7x faster than Scalar-SSE but AVX-256 is only 3x faster than SSE-128 while it's vectorized. I think it might be because of pipelining. in scalar I have 3 vec-ALU that might not be useable in vectorized mode. I might compare apples to oranges instead of apples to apples and this might be the point that I can not understand the reason.

  • To answer the title question (I can't fully parse the last part of the body): GCC does what you said only when compiling at -O1. When targeting systems with AVX is always a good idea to use the VEX versions of the legacy SSE instructions. – Margaret Bloom Feb 19 '17 at 9:15
  • @MargaretBloom, no gcc -O2 I added to the question. targeting is OK but I'm comparing pure AVX and SSE not AVX-256 with AVX-128. – Martin Feb 19 '17 at 9:51
  • @MargaretBloom, vectorization is enabled at by -ftree-loop-vectorize which is enabled by -O3 but not -O2. This will even vectorized with -O1 -ftree-loop-vectorize – Z boson Feb 19 '17 at 10:00
  • 1
    @MargaretBloom, I agree I don't get the point. The OPs claims are confusing and the update seems contradictory. I don't see any good reason in this case the scalar SSE or AVX code would make a significant difference. I can't reproduce the OPs results so far with GCC 6.2, Ubuntu 16.10, Skylake. I thought maybe the OP was seeing this. – Z boson Feb 19 '17 at 13:36
  • 2
    Sorry to belabor this but I just realized one solution is to only compile with AVX and not worry about non-vex encoding. You can't really test SSE only code on your system because you don't have a system with SSE only. You could try -mprefer-avx128 if you want to compare 128-bit and 256-bit operations. The problem with using __asm__ __volatile__ ( "vzeroupper" : : : ); is that it would crash on a system without AVX. That's why GCC won't let you do it except with asm. If you use that instruction you might as well compile with -mavx. – Z boson Feb 19 '17 at 15:22

The problem you are observing is explained here. On Skylake systems if the upper half of an AVX register is dirty then there is false dependency for non-vex encoded SSE operations on the upper half of the AVX register. In your case it seems there is a bug in your version of glibc 2.23. On my Skylake system with Ubuntu 16.10 and glibc 2.24 I don't have the problem. You can use

__asm__ __volatile__ ( "vzeroupper" : : : ); 

to clean the upper half of the AVX register. I don't think you can use an intrinsic such as _mm256_zeroupper to fix this because GCC will say it's SSE code and not recognize the intrinsic. The options -mvzeroupper won't work either because GCC one again thinks it's SSE code and will not emit the vzeroupper instruction.

BTW, it's Microsoft's fault that the hardware has this problem.


Other people are apparently encountering this problem on Skylake. It has been observed after printf, memset, and clock_gettime.

If your goal is to compare 128-bit operations with 256-bit operations could consider using -mprefer-avx128 -mavx (which is particularly useful on AMD). But then you would be comparing AVX256 vs AVX128 and not AVX256 vs SSE. AVX128 and SSE both use 128-bit operations but their implementations are different. If you benchmark you should mention which one you used.

  • According to the ABI, every function that uses AVX should execute vzeroupper when its done. Seems like the bug is somewhere else. – fuz Feb 19 '17 at 15:27
  • @fuz, did you read the first link I pointed to? The problem goes away when clearing the upper part of the AVX register. I can't reproduce the problem on my system so I can't test it. The OP said the problem did not got away with __asm__ __volatile__ ( "vzeroupper" : : : ); right after main which is what I would have expected but it goes away after when it's used after clock_gettime. In my answer I did not mention this because the only thing I am fairly certain about is that the problem is the upper half being dirty. Can we agree on that? – Z boson Feb 19 '17 at 15:33
  • Read the last few lines of the post you linked, it says basically the same thing I said: Someone must have used AVX instructions without executing vzeroupper afterwards. – fuz Feb 19 '17 at 15:44
  • @fuz, in that link the bug was in _dl_runtime_resolve_avx(), /lib64/ld-linux-x86-64.so.2 – Z boson Feb 19 '17 at 15:51

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.