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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
do{
    clock_gettime(CLOCK_MONOTONIC,&tStart);

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

    clock_gettime(CLOCK_MONOTONIC,&tEnd);
    tTotal = (tEnd.tv_sec - tStart.tv_sec);
    tTotal += (tEnd.tv_nsec - tStart.tv_nsec) / 1000000000.0;
    if(tTotal<tBest)
        tBest=tTotal;
    } 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;
for(i=0;i<N;i++){   
    for(j=0;j<M;j+=8){
        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;
for(i=0;i<N;i++){   
    for(j=0;j<M;j+=4){
    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
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    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
3

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.


Update:

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

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