3

I have code that does the same thing, but the AVX version is considerably SLOWER than the SSE version. Can someone explain that?

What I already did is that I tried to profile the code using VerySleepy, but this was not able to give me any helpful results, it merely confirmed that it's slower...

I already reviewed the commands in an SSE/AVX guide and on my CPU (Haswell) they need the same Latency/Throughput, just the horizontal add needs additional commands for AVX...

** latencies and throughputs **

_mm_mul_ps            -> L 5, T 0.5
_mm256_mul_ps         -> L 5, T 0.5
_mm_hadd_ps           -> L 5, T 2
_mm256_hadd_ps        -> L 5, T ?
_mm256_extractf128_ps -> L 1, T 1

Summary of what the code does: Final1 = SUM( m_Array1 * m_Array1 * m_Array3 * m_Array3 )

Final2 = SUM( m_Array2 * m_Array2 * m_Array3 * m_Array3 )

Final3 = SUM( m_Array1 * m_Array2 * m_Array3 * m_Array3 )

init

float Final1 = 0.0f;
float Final2 = 0.0f;
float Final3 = 0.0f;

float* m_Array1 = (float*)_mm_malloc( 32 * sizeof( float ), 32 );
float* m_Array2 = (float*)_mm_malloc( 32 * sizeof( float ), 32 );
float* m_Array3 = (float*)_mm_malloc( 32 * sizeof( float ), 32 );

SSE:

for ( int k = 0; k < 32; k += 4 )
{

    __m128 g1 = _mm_load_ps( m_Array1 + k );
    __m128 g2 = _mm_load_ps( m_Array2 + k );
    __m128 g3 = _mm_load_ps( m_Array3 + k );

    __m128 g1g3 = _mm_mul_ps( g1, g3 );
    __m128 g2g3 = _mm_mul_ps( g2, g3 );

    __m128 a1 = _mm_mul_ps( g1g3, g1g3 );
    __m128 a2 = _mm_mul_ps( g2g3, g2g3 );
    __m128 a3 = _mm_mul_ps( g1g3, g2g3 );

    // horizontal add
    {
        a1 = _mm_hadd_ps( a1, a1 );
        a1 = _mm_hadd_ps( a1, a1 );
        Final1 += _mm_cvtss_f32( a1 );

        a2 = _mm_hadd_ps( a2, a2 );
        a2 = _mm_hadd_ps( a2, a2 );
        Final2 += _mm_cvtss_f32( a2 );

        a3 = _mm_hadd_ps( a3, a3 );
        a3 = _mm_hadd_ps( a3, a3 );
        Final3 += _mm_cvtss_f32( a3 );

    }

}

AVX:

for ( int k = 0; k < 32; k += 8 )
{
    __m256 g1 = _mm256_load_ps( m_Array1 + k );
    __m256 g2 = _mm256_load_ps( m_Array2 + k );
    __m256 g3 = _mm256_load_ps( m_Array3 + k );

    __m256 g1g3 = _mm256_mul_ps( g1, g3 );
    __m256 g2g3 = _mm256_mul_ps( g2, g3 );

    __m256 a1 = _mm256_mul_ps( g1g3, g1g3 );
    __m256 a2 = _mm256_mul_ps( g2g3, g2g3 );
    __m256 a3 = _mm256_mul_ps( g1g3, g2g3 );

    // horizontal add1
    {
        __m256 t1 = _mm256_hadd_ps( a1, a1 );
        __m256 t2 = _mm256_hadd_ps( t1, t1 );
        __m128 t3 = _mm256_extractf128_ps( t2, 1 );
        __m128 t4 = _mm_add_ss( _mm256_castps256_ps128( t2 ), t3 );
        Final1 += _mm_cvtss_f32( t4 );
    }
    // horizontal add2
    {
        __m256 t1 = _mm256_hadd_ps( a2, a2 );
        __m256 t2 = _mm256_hadd_ps( t1, t1 );
        __m128 t3 = _mm256_extractf128_ps( t2, 1 );
        __m128 t4 = _mm_add_ss( _mm256_castps256_ps128( t2 ), t3 );
        Final2 += _mm_cvtss_f32( t4 );
    }
    // horizontal add3
    {
        __m256 t1 = _mm256_hadd_ps( a3, a3 );
        __m256 t2 = _mm256_hadd_ps( t1, t1 );
        __m128 t3 = _mm256_extractf128_ps( t2, 1 );
        __m128 t4 = _mm_add_ss( _mm256_castps256_ps128( t2 ), t3 );
        Final3 += _mm_cvtss_f32( t4 );
    }

}
16
  • 1
    You need a much bigger loop to reliably benchmark these two code fragments. Also the horizontal adds and final scalar value extraction should be outside the loop in both cases.
    – Paul R
    Mar 13 '15 at 11:40
  • It's just a minimal example. Replace the 32's by "some-integer-times-eight", the problem remains the same
    – S.H
    Mar 13 '15 at 11:43
  • 1
    @S.H: sure, but your code is very inefficient in both cases - if you move the horizontal adds and scalar extraction out of the loop and just use normal (vertical) adds within the loop then you'll get more efficient code in both cases and the relative performance may also change due to the different instruction mix.
    – Paul R
    Mar 13 '15 at 11:46
  • 1
    Why do you even do it this way though? You can easily do it almost completely vertically, only summing horizontally once after the loop
    – harold
    Mar 13 '15 at 11:46
  • 1
    @S.H: since you're just summing all the products you can just do a vertical add within the loop, giving four partial sums, then do a single horizontal add after the loop to combine these four partial sums. This will be much more efficient and avoids the aforementioned high latency instructions.
    – Paul R
    Mar 13 '15 at 11:56
5

I took your code and put it in a test harness, compiled it clang -O3 and timed it. I also implemented faster versions of the two routines, with the horizontal add moved out of the loop:

#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <sys/time.h>   // gettimeofday
#include <immintrin.h>

static void sse(const float *m_Array1, const float *m_Array2, const float *m_Array3, size_t n, float *Final1, float *Final2, float *Final3)
{
    *Final1 = *Final2 = *Final3 = 0.0f;
    for (int k = 0; k < n; k += 4)
    {
        __m128 g1 = _mm_load_ps( m_Array1 + k );
        __m128 g2 = _mm_load_ps( m_Array2 + k );
        __m128 g3 = _mm_load_ps( m_Array3 + k );

        __m128 g1g3 = _mm_mul_ps( g1, g3 );
        __m128 g2g3 = _mm_mul_ps( g2, g3 );

        __m128 a1 = _mm_mul_ps( g1g3, g1g3 );
        __m128 a2 = _mm_mul_ps( g2g3, g2g3 );
        __m128 a3 = _mm_mul_ps( g1g3, g2g3 );

        // horizontal add
        {
            a1 = _mm_hadd_ps( a1, a1 );
            a1 = _mm_hadd_ps( a1, a1 );
            *Final1 += _mm_cvtss_f32( a1 );

            a2 = _mm_hadd_ps( a2, a2 );
            a2 = _mm_hadd_ps( a2, a2 );
            *Final2 += _mm_cvtss_f32( a2 );

            a3 = _mm_hadd_ps( a3, a3 );
            a3 = _mm_hadd_ps( a3, a3 );
            *Final3 += _mm_cvtss_f32( a3 );
        }
    }
}

static void sse_fast(const float *m_Array1, const float *m_Array2, const float *m_Array3, size_t n, float *Final1, float *Final2, float *Final3)
{
    *Final1 = *Final2 = *Final3 = 0.0f;
    __m128 a1 = _mm_setzero_ps();
    __m128 a2 = _mm_setzero_ps();
    __m128 a3 = _mm_setzero_ps();
    for (int k = 0; k < n; k += 4)
    {
        __m128 g1 = _mm_load_ps( m_Array1 + k );
        __m128 g2 = _mm_load_ps( m_Array2 + k );
        __m128 g3 = _mm_load_ps( m_Array3 + k );

        __m128 g1g3 = _mm_mul_ps( g1, g3 );
        __m128 g2g3 = _mm_mul_ps( g2, g3 );

        a1 = _mm_add_ps(a1, _mm_mul_ps( g1g3, g1g3 ));
        a2 = _mm_add_ps(a2, _mm_mul_ps( g2g3, g2g3 ));
        a3 = _mm_add_ps(a3, _mm_mul_ps( g1g3, g2g3 ));
    }
    // horizontal add
    a1 = _mm_hadd_ps( a1, a1 );
    a1 = _mm_hadd_ps( a1, a1 );
    *Final1 += _mm_cvtss_f32( a1 );

    a2 = _mm_hadd_ps( a2, a2 );
    a2 = _mm_hadd_ps( a2, a2 );
    *Final2 += _mm_cvtss_f32( a2 );

    a3 = _mm_hadd_ps( a3, a3 );
    a3 = _mm_hadd_ps( a3, a3 );
    *Final3 += _mm_cvtss_f32( a3 );
}

static void avx(const float *m_Array1, const float *m_Array2, const float *m_Array3, size_t n, float *Final1, float *Final2, float *Final3)
{
    *Final1 = *Final2 = *Final3 = 0.0f;
    for (int k = 0; k < n; k += 8 )
    {
        __m256 g1 = _mm256_load_ps( m_Array1 + k );
        __m256 g2 = _mm256_load_ps( m_Array2 + k );
        __m256 g3 = _mm256_load_ps( m_Array3 + k );

        __m256 g1g3 = _mm256_mul_ps( g1, g3 );
        __m256 g2g3 = _mm256_mul_ps( g2, g3 );

        __m256 a1 = _mm256_mul_ps( g1g3, g1g3 );
        __m256 a2 = _mm256_mul_ps( g2g3, g2g3 );
        __m256 a3 = _mm256_mul_ps( g1g3, g2g3 );

        // horizontal add1
        {
            __m256 t1 = _mm256_hadd_ps( a1, a1 );
            __m256 t2 = _mm256_hadd_ps( t1, t1 );
            __m128 t3 = _mm256_extractf128_ps( t2, 1 );
            __m128 t4 = _mm_add_ss( _mm256_castps256_ps128( t2 ), t3 );
            *Final1 += _mm_cvtss_f32( t4 );
        }
        // horizontal add2
        {
            __m256 t1 = _mm256_hadd_ps( a2, a2 );
            __m256 t2 = _mm256_hadd_ps( t1, t1 );
            __m128 t3 = _mm256_extractf128_ps( t2, 1 );
            __m128 t4 = _mm_add_ss( _mm256_castps256_ps128( t2 ), t3 );
            *Final2 += _mm_cvtss_f32( t4 );
        }
        // horizontal add3
        {
            __m256 t1 = _mm256_hadd_ps( a3, a3 );
            __m256 t2 = _mm256_hadd_ps( t1, t1 );
            __m128 t3 = _mm256_extractf128_ps( t2, 1 );
            __m128 t4 = _mm_add_ss( _mm256_castps256_ps128( t2 ), t3 );
            *Final3 += _mm_cvtss_f32( t4 );
        }
    }
}

static void avx_fast(const float *m_Array1, const float *m_Array2, const float *m_Array3, size_t n, float *Final1, float *Final2, float *Final3)
{
    *Final1 = *Final2 = *Final3 = 0.0f;
    __m256 a1 = _mm256_setzero_ps();
    __m256 a2 = _mm256_setzero_ps();
    __m256 a3 = _mm256_setzero_ps();
    for (int k = 0; k < n; k += 8 )
    {
        __m256 g1 = _mm256_load_ps( m_Array1 + k );
        __m256 g2 = _mm256_load_ps( m_Array2 + k );
        __m256 g3 = _mm256_load_ps( m_Array3 + k );

        __m256 g1g3 = _mm256_mul_ps( g1, g3 );
        __m256 g2g3 = _mm256_mul_ps( g2, g3 );

        a1 = _mm256_add_ps(a1, _mm256_mul_ps( g1g3, g1g3 ));
        a2 = _mm256_add_ps(a2, _mm256_mul_ps( g2g3, g2g3 ));
        a3 = _mm256_add_ps(a3, _mm256_mul_ps( g1g3, g2g3 ));
    }

    // horizontal add1

    {
        __m256 t1 = _mm256_hadd_ps( a1, a1 );
        __m256 t2 = _mm256_hadd_ps( t1, t1 );
        __m128 t3 = _mm256_extractf128_ps( t2, 1 );
        __m128 t4 = _mm_add_ss( _mm256_castps256_ps128( t2 ), t3 );
        *Final1 += _mm_cvtss_f32( t4 );
    }

    // horizontal add2

    {
        __m256 t1 = _mm256_hadd_ps( a2, a2 );
        __m256 t2 = _mm256_hadd_ps( t1, t1 );
        __m128 t3 = _mm256_extractf128_ps( t2, 1 );
        __m128 t4 = _mm_add_ss( _mm256_castps256_ps128( t2 ), t3 );
        *Final2 += _mm_cvtss_f32( t4 );
    }

    // horizontal add3

    {
        __m256 t1 = _mm256_hadd_ps( a3, a3 );
        __m256 t2 = _mm256_hadd_ps( t1, t1 );
        __m128 t3 = _mm256_extractf128_ps( t2, 1 );
        __m128 t4 = _mm_add_ss( _mm256_castps256_ps128( t2 ), t3 );
        *Final3 += _mm_cvtss_f32( t4 );
    }

}

int main(int argc, char *argv[])
{
    size_t n = 4096;

    if (argc > 1) n = atoi(argv[1]);

    float *in_1 = valloc(n * sizeof(in_1[0]));
    float *in_2 = valloc(n * sizeof(in_2[0]));
    float *in_3 = valloc(n * sizeof(in_3[0]));
    float out_1, out_2, out_3;

    struct timeval t0, t1;
    double t_ms;

    for (int i = 0; i < n; ++i)
    {
        in_1[i] = (float)rand() / (float)(RAND_MAX / 2);
        in_2[i] = (float)rand() / (float)(RAND_MAX / 2);
        in_3[i] = (float)rand() / (float)(RAND_MAX / 2);
    }

    sse(in_1, in_2, in_3, n, &out_1, &out_2, &out_3);
    printf("sse     : %g, %g, %g\n", out_1, out_2, out_3);
    sse_fast(in_1, in_2, in_3, n, &out_1, &out_2, &out_3);
    printf("sse_fast: %g, %g, %g\n", out_1, out_2, out_3);
    avx(in_1, in_2, in_3, n, &out_1, &out_2, &out_3);
    printf("avx     : %g, %g, %g\n", out_1, out_2, out_3);
    avx_fast(in_1, in_2, in_3, n, &out_1, &out_2, &out_3);
    printf("avx_fast: %g, %g, %g\n", out_1, out_2, out_3);

    gettimeofday(&t0, NULL);
    for (int k = 0; k < 100; ++k) sse(in_1, in_2, in_3, n, &out_1, &out_2, &out_3);
    gettimeofday(&t1, NULL);
    t_ms = ((double)(t1.tv_sec - t0.tv_sec) + (double)(t1.tv_usec - t0.tv_usec) * 1.0e-6) * 1.0e3;
    printf("sse     : %g, %g, %g, %g ms\n", out_1, out_2, out_3, t_ms);

    gettimeofday(&t0, NULL);
    for (int k = 0; k < 100; ++k) sse_fast(in_1, in_2, in_3, n, &out_1, &out_2, &out_3);
    gettimeofday(&t1, NULL);
    t_ms = ((double)(t1.tv_sec - t0.tv_sec) + (double)(t1.tv_usec - t0.tv_usec) * 1.0e-6) * 1.0e3;
    printf("sse_fast: %g, %g, %g, %g ms\n", out_1, out_2, out_3, t_ms);

    gettimeofday(&t0, NULL);
    for (int k = 0; k < 100; ++k) avx(in_1, in_2, in_3, n, &out_1, &out_2, &out_3);
    gettimeofday(&t1, NULL);
    t_ms = ((double)(t1.tv_sec - t0.tv_sec) + (double)(t1.tv_usec - t0.tv_usec) * 1.0e-6) * 1.0e3;
    printf("avx     : %g, %g, %g, %g ms\n", out_1, out_2, out_3, t_ms);

    gettimeofday(&t0, NULL);
    for (int k = 0; k < 100; ++k) avx_fast(in_1, in_2, in_3, n, &out_1, &out_2, &out_3);
    gettimeofday(&t1, NULL);
    t_ms = ((double)(t1.tv_sec - t0.tv_sec) + (double)(t1.tv_usec - t0.tv_usec) * 1.0e-6) * 1.0e3;
    printf("avx_fast: %g, %g, %g, %g ms\n", out_1, out_2, out_3, t_ms);

    return 0;
}

Results on my 2.6 GHz Haswell (MacBook Pro) were:

sse     : 0.439 ms
sse_fast: 0.153 ms
avx     : 0.309 ms
avx_fast: 0.085 ms

So the AVX version does indeed appear to faster than the SSE version, both for the original implementations and the optimised implementations. The optimised implementations are significantly faster than the original versions, however, by an even greater margin.

I can only guess that either your compiler is not generating very good code for AVX (or maybe you forgot to enable compiler optimisations ?), or perhaps there is something suspect about your benchmarking method.

15
  • It's really weird, I'll check and post my results - if any
    – S.H
    Mar 13 '15 at 12:28
  • 1
    With your code I understood what you meant by "moving the hadd out of the loop". I thought you wanted to somehow only multiply first (without the last add) and the magically sum them up. THANKS!
    – S.H
    Mar 13 '15 at 12:51
  • Yes, as a rule of thumb horizontal operations should generally be avoided in SIMD code, and when they can't be avoided they should ideally be outside any performance-critical loops.
    – Paul R
    Mar 13 '15 at 13:16
  • I am compiling with VS2012, "-O3" and "/arch:AVX". Could that be an issue?
    – S.H
    Mar 13 '15 at 13:51
  • I would have thought that either /O2 or /Ox would be fine with Visual Studio, but I don't really do much work on Windows and I'm not sure how good Visual Studio is when it comes to AVX code generation. gcc, clang and Intel's ICC all generate pretty good AVX code, so you might want to consider trying a different compiler. You might also want to review your benchmarking methods, as there are many pitfalls for the unwary. If you can get my test harness above to compile with Visual Studio then it would be interesting to see what numbers you get for the timing.
    – Paul R
    Mar 13 '15 at 14:44

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