17

I am computing eight dot products at once with AVX. In my current code I do something like this (before unrolling):

Ivy-Bridge/Sandy-Bridge

__m256 areg0 = _mm256_set1_ps(a[m]);
for(int i=0; i<n; i++) {        
    __m256 breg0 = _mm256_load_ps(&b[8*i]);
    tmp0 = _mm256_add_ps(_mm256_mul_ps(arge0,breg0), tmp0); 
}

Haswell

__m256 areg0 = _mm256_set1_ps(a[m]);
for(int i=0; i<n; i++) {      
    __m256 breg0 = _mm256_load_ps(&b[8*i]);
    tmp0 = _mm256_fmadd_ps(arge0, breg0, tmp0);
}

How many times do I need to unroll the loop for each case to ensure maximum throughput?

For Haswell using FMA3 I think the answer is here FLOPS per cycle for sandy-bridge and haswell SSE2/AVX/AVX2. I need to unroll the loop 10 times.

For Ivy Bridge I think it's 8. Here is my logic. The AVX addition has a latency of 3 and the multiplication a latency of 5. Ivy Bridge can do one AVX multiplication and one AVX addition at the same time using different ports. Using the notation m for multiplication, a for addition, and x for no operation as well as a number to indicate the partial sum (e.g. m5 means multiplication with the 5th partial sum) I can write:

port0:  m1  m2  m3  m4  m5  m6  m7  m8  m1  m2  m3  m4  m5  ... 
port1:   x   x   x   x   x  a1  a2  a3  a4  a5  a6  a7  a8  ...

So by using 8 partial sums after nine clock cycles (four from the load and five from the multiplication) I can submit one AVX load, one AVX addition and one AVX multiplication every clock cycle.

I guess this means that it's impossible to achieve the maximum throughput for this tasks in 32-bit mode in Ivy Bridge and Haswell since 32-bit mode only has eight AVX registers?

Edit: In regards to the bounty. My main questions still hold. I want to get the maximum throughput of either the Ivy Bridge or Haswell functions above, n can be any value greater than or equal to 64. I think this can only be done using unrolling (eight times for Ivy Bridge and 10 times for Haswell). If you think this can be done with another method then let's see it. In some sense this is a variation of How do I achieve the theoretical maximum of 4 FLOPs per cycle?. But instead of only multiplication and addition I'm looking for one 256-bit load (or two 128-bit loads), one AVX multiplication, and one AVX addition every clock cycle with Ivy Bridge or two 256-bit loads and two FMA3 instructions per clock cycle.

I would also like to know how many registers are necessary. For Ivy Bridge I think it's 10. One for the broadcast, one for the load (only one due to register renaming), and eight for the eight partial sums. So I don't think this can be done in 32-bit mode (and indeed when I run in 32-bit mode the performance drops significantly).

I should point out that the compiler can give misleading results Difference in performance between MSVC and GCC for highly optimized matrix multplication code

The current function I'm using for Ivy Bridge is below. This basically multiplies one row of a 64x64 matrix a with all of a 64x64 matrix b (I run this function 64 times on each row of a to get the full matrix multiply in matrix c).

#include <immintrin.h>
extern "C" void row_m64x64(const float *a, const float *b, float *c) {      
    const int vec_size = 8;
    const int n = 64;
    __m256 tmp0, tmp1, tmp2, tmp3, tmp4, tmp5, tmp6, tmp7;
    tmp0 = _mm256_loadu_ps(&c[0*vec_size]);
    tmp1 = _mm256_loadu_ps(&c[1*vec_size]);
    tmp2 = _mm256_loadu_ps(&c[2*vec_size]);
    tmp3 = _mm256_loadu_ps(&c[3*vec_size]);
    tmp4 = _mm256_loadu_ps(&c[4*vec_size]);
    tmp5 = _mm256_loadu_ps(&c[5*vec_size]);
    tmp6 = _mm256_loadu_ps(&c[6*vec_size]);
    tmp7 = _mm256_loadu_ps(&c[7*vec_size]);

    for(int i=0; i<n; i++) {
        __m256 areg0 = _mm256_set1_ps(a[i]);

        __m256 breg0 = _mm256_loadu_ps(&b[vec_size*(8*i + 0)]);
        tmp0 = _mm256_add_ps(_mm256_mul_ps(areg0,breg0), tmp0);    
        __m256 breg1 = _mm256_loadu_ps(&b[vec_size*(8*i + 1)]);
        tmp1 = _mm256_add_ps(_mm256_mul_ps(areg0,breg1), tmp1);
        __m256 breg2 = _mm256_loadu_ps(&b[vec_size*(8*i + 2)]);
        tmp2 = _mm256_add_ps(_mm256_mul_ps(areg0,breg2), tmp2);    
        __m256 breg3 = _mm256_loadu_ps(&b[vec_size*(8*i + 3)]);
        tmp3 = _mm256_add_ps(_mm256_mul_ps(areg0,breg3), tmp3);   
        __m256 breg4 = _mm256_loadu_ps(&b[vec_size*(8*i + 4)]);
        tmp4 = _mm256_add_ps(_mm256_mul_ps(areg0,breg4), tmp4);    
        __m256 breg5 = _mm256_loadu_ps(&b[vec_size*(8*i + 5)]);
        tmp5 = _mm256_add_ps(_mm256_mul_ps(areg0,breg5), tmp5);    
        __m256 breg6 = _mm256_loadu_ps(&b[vec_size*(8*i + 6)]);
        tmp6 = _mm256_add_ps(_mm256_mul_ps(areg0,breg6), tmp6);    
        __m256 breg7 = _mm256_loadu_ps(&b[vec_size*(8*i + 7)]);
        tmp7 = _mm256_add_ps(_mm256_mul_ps(areg0,breg7), tmp7);    
    }
    _mm256_storeu_ps(&c[0*vec_size], tmp0);
    _mm256_storeu_ps(&c[1*vec_size], tmp1);
    _mm256_storeu_ps(&c[2*vec_size], tmp2);
    _mm256_storeu_ps(&c[3*vec_size], tmp3);
    _mm256_storeu_ps(&c[4*vec_size], tmp4);
    _mm256_storeu_ps(&c[5*vec_size], tmp5);
    _mm256_storeu_ps(&c[6*vec_size], tmp6);
    _mm256_storeu_ps(&c[7*vec_size], tmp7);
}
28
  • 1
    Be aware that unrolling small loops can have a negative effect on performance on Core i7 and later. The Loop Stream Detector can only cache 28 µops on Nehalem - I'm not sure if that size has increased in Ivy Bridge/Haswell.
    – Paul R
    Jan 13, 2014 at 12:21
  • 2
    What exactly do you aim to achieve with unrolling, avoid easily predictable branches? The OOO is able to execute across multiple iterations, you should still be bounded only on the tmp0 dependency
    – Leeor
    Jan 13, 2014 at 13:09
  • 4
    He wasn't talking about the uop cache, the loop stream detector is much smaller (and more effective in terms of bandwidth)
    – Leeor
    Jan 13, 2014 at 13:11
  • 2
    I'm also questioning the necessity of unrolling a dependency chain of such long latency operations like FMAs. The benefit of having the index ready statically is negligible, your performance is governed by the vector unit bandwidth/latency - calculating the indices (and predicting some branches) can be done in parallel with no impact. Only profiling can tell who's right though.
    – Leeor
    Jan 13, 2014 at 13:28
  • 2
    That's only for Sandy/Ivy Bridge. Haswell has can do two 256-bit loads/cycle. I was referring to your original loop where (I thought) you had a broadcast and a load for each FMA.
    – Mysticial
    Jan 13, 2014 at 19:34

2 Answers 2

16
+200

For Sandy/Ivy Bridge you need to unroll by 3:

  • Only FP Add has dependency on the previous iteration of the loop
  • FP Add can issue every cycle
  • FP Add takes three cycles to complete
  • Thus unrolling by 3/1 = 3 completely hides the latency
  • FP Mul and FP Load do not have a dependency on the previous iteration and you can rely on the OoO core to issue them in the near-optimal order. These instructions could affect the unroll factor only if they lowered the throughput of FP Add (not the case here, FP Load + FP Add + FP Mul can issue every cycle).

For Haswell you need to unroll by 10:

  • Only FMA has dependency on the previous iteration of the loop
  • FMA can double-issue every cycle (i.e. on average independent instructions take 0.5 cycles)
  • FMA has latency of 5
  • Thus unrolling by 5/0.5 = 10 completely hides FMA latency
  • The two FP Load microoperations do not have a dependency on the previous iteration, and can co-issue with 2x FMA, so they don't affect the unroll factor.
3
  • I get the logic. It's not clear to me how the OoO logic takes care of this but I know what to do in the code. I'll have to read the Intel manuals to understand more. The fact that I unroll 8 times probably gives the best result due to how I have arranged the memory and the 64x64 matrix. 32-bit is slower because I have required more than eight registers. But this still means with Haswell it's impossible to get the max throughput in 32-bit mode.
    – Z boson
    Feb 5, 2014 at 9:58
  • I just realized that I'm not actually unrolling the loop in my question. I'm doing eight 8-wide dot products (64 dot products). I'm reading/writing one row of the 64 side matrix using eight AVX accumulators. This does not really change the question though. It just becomes how many accumulators are necessary for maximum throughput and the answer is the same.
    – Z boson
    Feb 6, 2014 at 11:57
  • Why does mulss take only 3 cycles on Haswell, different from Agner's instruction tables? (Unrolling FP loops with multiple accumulators) shows that using more accumulators than the bare minimum helps. Apparently scheduling isn't always perfect, and/or absorbing memory latency variations works better with more accumulators. Oct 29, 2019 at 23:31
7

I'm only answering my own question here to add information.

I went ahead and profiled the Ivy Bridge code. When I first tested this in MSVC2012 unrolling by more than two did not help much. However, I suspected that MSVC did not implement the intrinsics optimally based on my observation at Difference in performance between MSVC and GCC for highly optimized matrix multplication code. So I compiled the kernel in GCC with g++ -c -mavx -O3 -mabi=ms, converted the object to COFF64 and dropped it into MSVC and I now get that unrolling by three gives the best result confirming Marat Dunkhan's answer.

Here are the times in seconds, Xeon E5 1620 @3.6GHz MSVC2012

unroll    time default            time with GCC kernel
     1    3.7                     3.2
     2    1.8 (2.0x faster)       1.6 (2.0x faster)
     3    1.6 (2.3x faster)       1.2 (2.7x faster)
     4    1.6 (2.3x faster)       1.2 (2.7x faster)

Here are the times on i5-4250U using fma with GCC in Linux (g++ -mavx -mfma -fopenmp -O3 main.cpp kernel_fma.cpp -o sum_fma)

unroll    time
     1    20.3
     2    10.2 (2.0x faster)
     3     6.7 (3.0x faster) 
     4     5.2 (4.0x faster)
     8     2.9 (7.0x faster)
    10     2.6 (7.8x faster)

The code below is for Sandy-Bridge/Ivy Bridge. For Haswell use e.g. tmp0 = _mm256_fmadd_ps(a8,b8_1,tmp0) instead.

kernel.cpp

#include <immintrin.h>

extern "C" void foo_unroll1(const int n, const float *b, float *c) {      
    __m256 tmp0 = _mm256_set1_ps(0.0f);
    __m256 a8 = _mm256_set1_ps(1.0f);
    for(int i=0; i<n; i+=8) {
        __m256 b8 = _mm256_loadu_ps(&b[i + 0]);
        tmp0 = _mm256_add_ps(_mm256_mul_ps(a8,b8), tmp0);
    }
    _mm256_storeu_ps(c, tmp0);
}

extern "C" void foo_unroll2(const int n, const float *b, float *c) {
    __m256 tmp0 = _mm256_set1_ps(0.0f);
    __m256 tmp1 = _mm256_set1_ps(0.0f);
    __m256 a8 = _mm256_set1_ps(1.0f);
    for(int i=0; i<n; i+=16) {
        __m256 b8_1 = _mm256_loadu_ps(&b[i + 0]);
        tmp0 = _mm256_add_ps(_mm256_mul_ps(a8,b8_1), tmp0);
        __m256 b8_2 = _mm256_loadu_ps(&b[i + 8]);
        tmp1 = _mm256_add_ps(_mm256_mul_ps(a8,b8_2), tmp1);
    }
    tmp0 = _mm256_add_ps(tmp0,tmp1);
    _mm256_storeu_ps(c, tmp0);
}

extern "C" void foo_unroll3(const int n, const float *b, float *c) { 
    __m256 tmp0 = _mm256_set1_ps(0.0f);
    __m256 tmp1 = _mm256_set1_ps(0.0f);
    __m256 tmp2 = _mm256_set1_ps(0.0f);
    __m256 a8 = _mm256_set1_ps(1.0f);
    for(int i=0; i<n; i+=24) {
        __m256 b8_1 = _mm256_loadu_ps(&b[i + 0]);
        tmp0 = _mm256_add_ps(_mm256_mul_ps(a8,b8_1), tmp0);
        __m256 b8_2 = _mm256_loadu_ps(&b[i + 8]);
        tmp1 = _mm256_add_ps(_mm256_mul_ps(a8,b8_2), tmp1);
        __m256 b8_3 = _mm256_loadu_ps(&b[i + 16]);
        tmp2 = _mm256_add_ps(_mm256_mul_ps(a8,b8_3), tmp2);
    }
    tmp0 = _mm256_add_ps(tmp0,_mm256_add_ps(tmp1,tmp2));
    _mm256_storeu_ps(c, tmp0);
}

extern "C" void foo_unroll4(const int n, const float *b, float *c) {      
    __m256 tmp0 = _mm256_set1_ps(0.0f);
    __m256 tmp1 = _mm256_set1_ps(0.0f);
    __m256 tmp2 = _mm256_set1_ps(0.0f);
    __m256 tmp3 = _mm256_set1_ps(0.0f);
    __m256 a8 = _mm256_set1_ps(1.0f);
    for(int i=0; i<n; i+=32) {
        __m256 b8_1 = _mm256_loadu_ps(&b[i + 0]);
        tmp0 = _mm256_add_ps(_mm256_mul_ps(a8,b8_1), tmp0);
        __m256 b8_2 = _mm256_loadu_ps(&b[i + 8]);
        tmp1 = _mm256_add_ps(_mm256_mul_ps(a8,b8_2), tmp1);
        __m256 b8_3 = _mm256_loadu_ps(&b[i + 16]);
        tmp2 = _mm256_add_ps(_mm256_mul_ps(a8,b8_3), tmp2);
        __m256 b8_4 = _mm256_loadu_ps(&b[i + 24]);
        tmp3 = _mm256_add_ps(_mm256_mul_ps(a8,b8_4), tmp3);
    }
    tmp0 = _mm256_add_ps(_mm256_add_ps(tmp0,tmp1),_mm256_add_ps(tmp2,tmp3));
    _mm256_storeu_ps(c, tmp0);
}

main.cpp

#include <stdio.h>
#include <omp.h>
#include <immintrin.h>

extern "C" void foo_unroll1(const int n, const float *b, float *c);
extern "C" void foo_unroll2(const int n, const float *b, float *c);
extern "C" void foo_unroll3(const int n, const float *b, float *c);
extern "C" void foo_unroll4(const int n, const float *b, float *c);

int main() {
    const int n = 3*1<<10;
    const int r = 10000000;
    double dtime;
    float *b = (float*)_mm_malloc(sizeof(float)*n, 64);
    float *c = (float*)_mm_malloc(8, 64);
    for(int i=0; i<n; i++) b[i] = 1.0f;

    __m256 out;
    dtime = omp_get_wtime();    
    for(int i=0; i<r; i++) foo_unroll1(n, b, c);
    dtime = omp_get_wtime() - dtime;
    printf("%f, ", dtime); for(int i=0; i<8; i++) printf("%f ", c[i]); printf("\n");

    dtime = omp_get_wtime();    
    for(int i=0; i<r; i++) foo_unroll2(n, b, c);
    dtime = omp_get_wtime() - dtime;
    printf("%f, ", dtime); for(int i=0; i<8; i++) printf("%f ", c[i]); printf("\n");

    dtime = omp_get_wtime();    
    for(int i=0; i<r; i++) foo_unroll3(n, b, c);
    dtime = omp_get_wtime() - dtime;
    printf("%f, ", dtime); for(int i=0; i<8; i++) printf("%f ", c[i]); printf("\n");

    dtime = omp_get_wtime();    
    for(int i=0; i<r; i++) foo_unroll4(n, b, c);
    dtime = omp_get_wtime() - dtime;
    printf("%f, ", dtime); for(int i=0; i<8; i++) printf("%f ", c[i]); printf("\n");
}
6
  • I'm not certain if it is helpful, but you could add a __restrict to parameter b and c.
    – user678269
    Feb 7, 2014 at 23:17
  • What is the multiplication with 1f for?
    – user678269
    Feb 7, 2014 at 23:21
  • Why are there variables used for b8_1...b8_4 as these expressions are used only once?
    – user678269
    Feb 7, 2014 at 23:23
  • when profiling, how do you make sure the cpu "turbo speed" feature that would effect the execution time, vis a vis modulated clock frequecy?
    – codechimp
    Apr 2, 2015 at 0:58
  • @Z boson FYI, the code doesn't execute exactly as expected. Because A8 is set to all 1's, GCC optimizes away the_mm256_mul_ps operation. Changing A8 some other value, like 5.0f, is required. for unroll1, the missing MULPS step doesn't impact total time but does have a noticable impact at unroll4.
    – codechimp
    Apr 2, 2015 at 20:16

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