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I will preface this by saying that I am a complete beginner at SIMD intrinsics.

Essentially, I have a CPU which supports the AVX2 instrinsic (Intel(R) Core(TM) i5-7500T CPU @ 2.70GHz). I would like to know the fastest way to compute the dot product of two std::vector<float> of size 512.

I have done some digging online and found this and this, and this stack overflow question suggests using the following function __m256 _mm256_dp_ps(__m256 m1, __m256 m2, const int mask);, However, these all suggest different ways of performing the dot product I am not sure what is the correct (and fastest) way to do it.

In particular, I am looking for the fastest way to perform dot product for a vector of size 512 (because I know the vector size effects the implementation).

Thank you for your help

Edit 1: I am also a little confused about the -mavx2 gcc flag. If I use these AVX2 functions, do I need to add the flag when I compile? Also, is gcc able to do these optimizations for me (say if I use the -OFast gcc flag) if I write a naive dot product implementation?

Edit 2 If anyone has the time and energy, I would very much appreciate if you could write a full implementation. I am sure other beginners would also value this information.

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  • 4
    You only want dpps for something like a 3 or 4-element dot product. For larger arrays, you want vertical FMA into multiple accumulators (Why does mulss take only 3 cycles on Haswell, different from Agner's instruction tables? (Unrolling FP loops with multiple accumulators)). You'll want -mfma -mavx2 or better -march=native. And yes, you need to enable target options for any intrinsic you want to use, along with -O3. Dec 27, 2019 at 0:39
  • e.g. How to properly use prefetch instructions? shows the inner loop of a normal SIMD dot product. Dec 27, 2019 at 0:45
  • -O3 can't auto-vectorize a naive dot-product unless you use OpenMP or -ffast-math to tell the compiler to treat FP math as associative. Dec 27, 2019 at 0:47
  • 1
    -Ofast is currently equivalent to -O3 -ffast-math so yes that would work. But unfortunately GCC won't use multiple accumulators even if it does unroll an FP loop, so you'll bottleneck on SIMD FMA latency instead of throughput. (Factor of 8 on Skylake) Dec 27, 2019 at 0:51
  • 3
    Soonts' answer is exactly what I was describing. It requires AVX + FMA, not AVX2. Thanks, @Soonts, for writing it up. I think there's another Q&A somewhere with a good canonical dot-product implementation which I was looking for earlier but didn't find immediately. Dec 27, 2019 at 2:44

3 Answers 3

22

_mm256_dp_ps is only useful for dot-products of 2 to 4 elements; for longer vectors use vertical SIMD in a loop and reduce to scalar at the end. Using _mm256_dp_ps and _mm256_add_ps in a loop would be much slower.


GCC and clang require you to enable (with command line options) ISA extensions that you use intrinsics for, unlike MSVC and ICC.


The code below is probably close to theoretical performance limit of your CPU. Untested.

Compile it with clang or gcc -O3 -march=native. (Requires at least -mavx -mfma, but -mtune options implied by -march are good, too, and so are the other -mpopcnt and other things arch=native enables. Tune options are critical to this compiling efficiently for most CPUs with FMA, specifically -mno-avx256-split-unaligned-load: Why doesn't gcc resolve _mm256_loadu_pd as single vmovupd?)

Or compile it with MSVC -O2 -arch:AVX2

#include <immintrin.h>
#include <vector>
#include <assert.h>

// CPUs support RAM access like this: "ymmword ptr [rax+64]"
// Using templates with offset int argument to make easier for compiler to emit good code.

// Multiply 8 floats by another 8 floats.
template<int offsetRegs>
inline __m256 mul8( const float* p1, const float* p2 )
{
    constexpr int lanes = offsetRegs * 8;
    const __m256 a = _mm256_loadu_ps( p1 + lanes );
    const __m256 b = _mm256_loadu_ps( p2 + lanes );
    return _mm256_mul_ps( a, b );
}

// Returns acc + ( p1 * p2 ), for 8-wide float lanes.
template<int offsetRegs>
inline __m256 fma8( __m256 acc, const float* p1, const float* p2 )
{
    constexpr int lanes = offsetRegs * 8;
    const __m256 a = _mm256_loadu_ps( p1 + lanes );
    const __m256 b = _mm256_loadu_ps( p2 + lanes );
    return _mm256_fmadd_ps( a, b, acc );
}

// Compute dot product of float vectors, using 8-wide FMA instructions.
float dotProductFma( const std::vector<float>& a, const std::vector<float>& b )
{
    assert( a.size() == b.size() );
    assert( 0 == ( a.size() % 32 ) );
    if( a.empty() )
        return 0.0f;

    const float* p1 = a.data();
    const float* const p1End = p1 + a.size();
    const float* p2 = b.data();

    // Process initial 32 values. Nothing to add yet, just multiplying.
    __m256 dot0 = mul8<0>( p1, p2 );
    __m256 dot1 = mul8<1>( p1, p2 );
    __m256 dot2 = mul8<2>( p1, p2 );
    __m256 dot3 = mul8<3>( p1, p2 );
    p1 += 8 * 4;
    p2 += 8 * 4;

    // Process the rest of the data.
    // The code uses FMA instructions to multiply + accumulate, consuming 32 values per loop iteration.
    // Unrolling manually for 2 reasons:
    // 1. To reduce data dependencies. With a single register, every loop iteration would depend on the previous result.
    // 2. Unrolled code checks for exit condition 4x less often, therefore more CPU cycles spent computing useful stuff.
    while( p1 < p1End )
    {
        dot0 = fma8<0>( dot0, p1, p2 );
        dot1 = fma8<1>( dot1, p1, p2 );
        dot2 = fma8<2>( dot2, p1, p2 );
        dot3 = fma8<3>( dot3, p1, p2 );
        p1 += 8 * 4;
        p2 += 8 * 4;
    }

    // Add 32 values into 8
    const __m256 dot01 = _mm256_add_ps( dot0, dot1 );
    const __m256 dot23 = _mm256_add_ps( dot2, dot3 );
    const __m256 dot0123 = _mm256_add_ps( dot01, dot23 );
    // Add 8 values into 4
    const __m128 r4 = _mm_add_ps( _mm256_castps256_ps128( dot0123 ), _mm256_extractf128_ps( dot0123, 1 ) );
    // Add 4 values into 2
    const __m128 r2 = _mm_add_ps( r4, _mm_movehl_ps( r4, r4 ) );
    // Add 2 lower values into the final result
    const __m128 r1 = _mm_add_ss( r2, _mm_movehdup_ps( r2 ) );
    // Return the lowest lane of the result vector.
    // The intrinsic below compiles into noop, modern compilers return floats in the lowest lane of xmm0 register.
    return _mm_cvtss_f32( r1 );
}

Possible further improvements:

  1. Unroll by 8 vectors instead of 4. I’ve checked gcc 9.2 asm output, compiler only used 8 vector registers out of the 16 available.

  2. Make sure both input vectors are aligned, e.g. use a custom allocator which calls _aligned_malloc / _aligned_free on msvc, or aligned_alloc / free on gcc & clang. Then replace _mm256_loadu_ps with _mm256_load_ps.


To auto-vectorize a simple scalar dot product, you'd also need OpenMP SIMD or -ffast-math (implied by -Ofast) to let the compiler treat FP math as associative even though it's not (because of rounding). But GCC won't use multiple accumulators when auto-vectorizing, even if it does unroll, so you'd bottleneck on FMA latency, not load throughput.

(2 loads per FMA means the throughput bottleneck for this code is vector loads, not actual FMA operations.)


Update 2023: because this answer collected many upvotes, here’s another version which supports vectors of arbitrary lengths, not necessarily a multiple of 32 elements. The main loop is the same, the difference is handling of the remainder.

As you see, it’s relatively tricky to handle the remainder in a way which is both performant, and fair with regards to summation order. Summation order affects numerical precision of the result. The key part of the implementation is _mm256_maskload_ps conditional load instruction.

#include <immintrin.h>
#include <vector>
#include <algorithm>
#include <assert.h>
#include <stdint.h>

// CPUs support RAM access like this: "ymmword ptr [rax+64]"
// Using templates with offset int argument to make easier for compiler to emit good code.

// Returns acc + ( p1 * p2 ), for 8 float lanes
template<int offsetRegs>
inline __m256 fma8( __m256 acc, const float* p1, const float* p2 )
{
    constexpr ptrdiff_t lanes = offsetRegs * 8;
    const __m256 a = _mm256_loadu_ps( p1 + lanes );
    const __m256 b = _mm256_loadu_ps( p2 + lanes );
    return _mm256_fmadd_ps( a, b, acc );
}

#ifdef __AVX2__
inline __m256i makeRemainderMask( ptrdiff_t missingLanes )
{
    // Make a mask of 8 bytes
    // These aren't branches, they should compile to conditional moves
    missingLanes = std::max( missingLanes, (ptrdiff_t)0 );
    uint64_t mask = -( missingLanes < 8 );
    mask >>= missingLanes * 8;
    // Sign extend the bytes into int32 lanes in AVX vector
    __m128i tmp = _mm_cvtsi64_si128( (int64_t)mask );
    return _mm256_cvtepi8_epi32( tmp );
}
#else
// Aligned by 64 bytes
// The load will only touch a single cache line, no penalty for unaligned load
static const int alignas( 64 ) s_remainderLoadMask[ 16 ] = {
    -1, -1, -1, -1, -1, -1, -1, -1, 0, 0, 0, 0, 0, 0, 0, 0 };
inline __m256i makeRemainderMask( ptrdiff_t missingLanes )
{
    // These aren't branches, they compile to conditional moves
    missingLanes = std::max( missingLanes, (ptrdiff_t)0 );
    missingLanes = std::min( missingLanes, (ptrdiff_t)8 );
    // Unaligned load from a constant array
    const int* rsi = &s_remainderLoadMask[ missingLanes ];
    return _mm256_loadu_si256( ( const __m256i* )rsi );
}
#endif

// Same as fma8(), load conditionally using the mask
// When the mask has all bits set, an equivalent of fma8(), but 1 instruction longer
// When the mask is a zero vector, the function won't load anything, will return `acc`
template<int offsetRegs>
inline __m256 fma8rem( __m256 acc, const float* p1, const float* p2, ptrdiff_t rem )
{
    constexpr ptrdiff_t lanes = offsetRegs * 8;
    // Generate the mask for conditional loads
    // The implementation depends on whether AVX2 is enabled with compiler switches
    const __m256i mask = makeRemainderMask( ( 8 + lanes ) - rem );
    // These conditional load instructions produce zeros for the masked out lanes
    const __m256 a = _mm256_maskload_ps( p1 + lanes, mask );
    const __m256 b = _mm256_maskload_ps( p2 + lanes, mask );
    return _mm256_fmadd_ps( a, b, acc );
}

// Compute dot product of float vectors, using 8-wide FMA instructions
float dotProductFma( const std::vector<float>& a, const std::vector<float>& b )
{
    assert( a.size() == b.size() );
    const size_t length = a.size();
    if( length == 0 )
        return 0.0f;

    const float* p1 = a.data();
    const float* p2 = b.data();
    // Compute length of the remainder; 
    // We want a remainder of length [ 1 .. 32 ] instead of [ 0 .. 31 ]
    const ptrdiff_t rem = ( ( length - 1 ) % 32 ) + 1;
    const float* const p1End = p1 + length - rem;

    // Initialize accumulators with zeros
    __m256 dot0 = _mm256_setzero_ps();
    __m256 dot1 = _mm256_setzero_ps();
    __m256 dot2 = _mm256_setzero_ps();
    __m256 dot3 = _mm256_setzero_ps();

    // Process the majority of the data.
    // The code uses FMA instructions to multiply + accumulate, consuming 32 values per loop iteration.
    // Unrolling manually for 2 reasons:
    // 1. To reduce data dependencies. With a single register, every loop iteration would depend on the previous result.
    // 2. Unrolled code checks for exit condition 4x less often, therefore more CPU cycles spent computing useful stuff.
    while( p1 < p1End )
    {
        dot0 = fma8<0>( dot0, p1, p2 );
        dot1 = fma8<1>( dot1, p1, p2 );
        dot2 = fma8<2>( dot2, p1, p2 );
        dot3 = fma8<3>( dot3, p1, p2 );
        p1 += 32;
        p2 += 32;
    }

    // Handle the last, possibly incomplete batch of length [ 1 .. 32 ]
    // To save multiple branches, we load that entire batch with `vmaskmovps` conditional loads
    // On modern CPUs, the performance of such loads is pretty close to normal full vector loads
    dot0 = fma8rem<0>( dot0, p1, p2, rem );
    dot1 = fma8rem<1>( dot1, p1, p2, rem );
    dot2 = fma8rem<2>( dot2, p1, p2, rem );
    dot3 = fma8rem<3>( dot3, p1, p2, rem );

    // Add 32 values into 8
    dot0 = _mm256_add_ps( dot0, dot2 );
    dot1 = _mm256_add_ps( dot1, dot3 );
    dot0 = _mm256_add_ps( dot0, dot1 );
    // Add 8 values into 4
    __m128 r4 = _mm_add_ps( _mm256_castps256_ps128( dot0 ),
        _mm256_extractf128_ps( dot0, 1 ) );
    // Add 4 values into 2
    r4 = _mm_add_ps( r4, _mm_movehl_ps( r4, r4 ) );
    // Add 2 lower values into the scalar result
    r4 = _mm_add_ss( r4, _mm_movehdup_ps( r4 ) );

    // Return the lowest lane of the result vector.
    // The intrinsic below compiles into noop, modern compilers return floats in the lowest lane of xmm0 register.
    return _mm_cvtss_f32( r4 );
}
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  • Note that the unroll factor doesn't have to be a power of 2; e.g. unroll by 6 would be fine (e.g. if you were targeting 32-bit mode with only 8 vector regs, you might aim for 1 vmovups load and one vfmadd with a memory source operand, and have the other 7 vector regs as accumulators.) But with a power-of-2 (512) known size, 4 or 8 is fine. Apparently more accumulators can help in practice even though would in theory this would bottleneck on load throughput (2 loads per FMA). But for short vectors, probably best to keep code-size and cleanup compact. Not many total iterations. Dec 27, 2019 at 2:48
  • The template stuff is not necessary for GCC / clang to use a memory source operand for FMA. It could do constant-propagation after inlining if you just did p1+8*1 and so on. Dec 27, 2019 at 2:56
  • I made some edits to your answer; I hope you don't mind the collaboration. If you do, roll it back and let me know so I can repost as my own answer. Dec 27, 2019 at 3:03
  • @PeterCordes Yeah, I think the performance should be OK. However, numerical precision is probably not. For some input data, these intermediate 32-bit floats combined with almost random addition order may result in numerical issues. If I would do what OP is doing, I would consider accumulating in __m256d instead: more complex, slower, but more precise. The best tradeoff depends on the application, obviously.
    – Soonts
    Dec 27, 2019 at 3:09
  • 2
    SIMD + multiple accumulators is part way towards pairwise summation; a recognized technique for mitigating the error of summing an FP array (where adding a small element to a large total is bad). Having many smaller totals reduces rounding error significantly if the elements are mostly similar magnitude, especially if they're all positive. See my answer on Simd matmul program gives different numerical results. Dec 27, 2019 at 3:48
2

An alternative option is Using Vector Instructions through Built-in Functions, which is CPU-agnostic and simple to code, uses fused-multiply-add automatically, but may be not as efficient as hand-coded versions with CPU-specific code. Still, using vector built-ins can often be much cheaper in terms of labour costs, much faster than original scalar version and serve as a baseline for hand-crafted optimization.

An example:

#include <vector>
#include <utility>
#include <cassert>

template<class V, int... i>
auto hsum(V v, std::integer_sequence<int, i...>) noexcept {
    return (v[i] + ...);
}

template<class V>
auto hsum(V v) noexcept {
    return hsum(v, std::make_integer_sequence<int, sizeof v / sizeof v[0]>{});
}

float dotProductFma(const std::vector<float>& a, const std::vector<float>& b) noexcept {
    constexpr int SIMD_BYTES = 64;
    using T = float;
    // Unaligned vector, uses unaligned loads.
    using V = T __attribute__((vector_size(SIMD_BYTES), aligned(alignof(T)))); 
    constexpr auto N = sizeof(V) / sizeof(T);

    auto s = a.size();
    assert(s % N == 0); // Assumes size is a multiple of N;
    decltype(s) i;
    auto* va = reinterpret_cast<V const*>(a.data());
    auto* vb = reinterpret_cast<V const*>(b.data());

    V vdot = {};
    for(i = 0; i < s / N; ++i)
        vdot += va[i] * vb[i];

    return hsum(vdot);
}

Generated assembly code. With -ffast-math the generated code is tighter.


Accumulating dot products into float may suffer from catastrophic cancellation due to limited precision of float when the magnitudes of terms of the sum become different enough. Can be fixed by using multiple sum accumulators or/and accumulate into double vectors.

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  • 1
    (But some CPUs have e.g. 3/clock loads and 2/clock FMA/mul/add, so can benefit from FMAs for throughput even with enough unrolling to hide FP latency. e.g. Alder Lake, or Sapphire Rapids with 2x 512-bit FMA units. And probably Zen 4 and Zen 5.) Oct 1, 2023 at 4:42
  • 1
    Yes, your code depends on -ffast-math for both the vector loop (for small to medium but not tiny problems) and the cleanup to compile efficiently. You should at least mention that in your answer, and include it in the Godbolt link! Also, prefer -march=x86-64-v4 instead of -mavx512f. No CPUs support just AVX-512F without other extensions; you want to give compilers a chance to use AVX-512VL or AVX-512DQ or whatever if relevant. Oct 1, 2023 at 5:07
  • 1
    @PeterCordes For ultimate performance the caller should not require reducing the vector dot product into a scalar. And may be do the dot product in reverse order if the vectors are last/next traversed in forward order, to reuse hottest L1d cache lines. I get cheeky 1%+ speedups in a few places by just reversing the stores of vectors which are next loaded in forward order, with heads being hottest in L1d. Oct 1, 2023 at 6:04
  • 1
    Yeah, I've seen that effect, too, of having one pass forward and the next backward, to get L1d and L2 hits after the turn-around. IIRC it was more than 1% for whatever size I was testing with on Skylake-server when it was new. Of course, this is still admitting defeat in terms of cache-blocking, and being bound by memory bandwidth for most of the dot-product. This sucks, it's a very low computational-intensity problem with 2 loads per FMA. Oct 1, 2023 at 6:27
  • 1
    @PeterCordes My mistake, you're are quite right: align to L1d cache line size boundary. Oct 1, 2023 at 6:33
1

Here's the implementation using vectorclass library which will compile both for AVX2 and AVX512F (in case of targeting more modern hardware), so the code is CPU-agnostic in this regard.

#include "vectorclass.h"

float dotProduct(const std::vector<float>& a, const std::vector<float>& b) {
    if (a.size() != b.size()) {
        std::cout << "Error in dot product!" << '\n';
        return -1;
    }
    Vec16f acc1(0), acc2(0), v1, v2, v3, v4;
    size_t i = 0;
    for (; i + 32 < a.size(); i += 32) {
        v1.load(&a[i]);
        v2.load(&b[i]);
        acc1 = mul_add(v1, v2, acc1);
        v3.load(&a[i + 16]);
        v4.load(&b[i + 16]);
        acc2 = mul_add(v3, v4, acc2);
    }
    auto tmp = 0.0f;
    for (; i < a.size(); i++) {
        tmp += a[i] * b[i];
    }
    auto result = horizontal_add(acc1 + acc2) + tmp;
    return result;
}

Compiling for AVX512F would require only changing -march=x86-64-v3 flag to -march=x86-64-v4.

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  • 1
    You don't need two separate horizontal vector sums. The vector cleanup would be nearly twice as efficient with horizontal_add( acc1 + acc2 ). Also, your loop bound wraps for size < 16, since a.size() is an unsigned type, as well as using 16 where you need 32. A sensible loop condition would be i + 32 < a.size() if that compiles efficiently. (With size_t i, not signed int from using auto i = 0. Deducing the type from a literal constant initializer doesn't usually make sense. Surprised clang -Wall doesn't warn about comparison between different signedness the way GCC does.) Jan 28 at 7:14
  • 1
    Not perfectly efficiently: godbolt.org/z/b7rdq35GG is I think correct but gcc wastes a mov instruction in the loop with that, to save a copy of the before-increment i, instead of something where we calculate an end-point ahead of the loop. Typically pointers are good for this. godbolt.org/z/oEPeTdjrf - this also convinces compilers to avoid indexed addressing-modes, very good on Intel for front-end throughput since it avoids un-lamination of the vfma...ps ymm, ymm, [mem] instructions. Jan 28 at 7:23
  • 1
    Ok, this is reasonable. With AVX-512 masking, the cleanup for odd sizes could be a lot more efficient than scalar, but efficient ways to do that differ between AVX2 and AVX-512 and this is intended to work with either, using VectorClass's Vec16f implemented with two __m256 halves for AVX2 if AVX-512 isn't available. Jan 28 at 19:17

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