SIMD: Accumulate Adjacent Pairs

I'm learning how to use SIMD intrinsics and autovectorization. Luckily, I have a useful project I'm working on that seems extremely amenable to SIMD, but is still tricky for a newbie like me.

I'm writing a filter for images that computes the average of 2x2 pixels. I'm doing part of the computation by accumulating the sum of two pixels into a single pixel.

``````template <typename T, typename U>
inline void accumulate_2x2_x_pass(
T* channel, U* accum,
const size_t sx, const size_t sy,
const size_t osx, const size_t osy,
const size_t yoff, const size_t oyoff
) {

const bool odd_x = (sx & 0x01);

size_t i_idx, o_idx;

// Should be vectorizable somehow...
for (size_t x = 0, ox = 0; x < sx - (size_t)odd_x; x += 2, ox++) {
i_idx = x + yoff;
o_idx = ox + oyoff;
accum[o_idx] += channel[i_idx];
accum[o_idx] += channel[i_idx + 1];
}

if (odd_x) {
// << 1 bc we need to multiply by two on the edge
// to avoid darkening during render
accum[(osx - 1) + oyoff] += (U)(channel[(sx - 1) + yoff]) * 2;
}
}
``````

However, godbolt shows that my loop is not autovectorizable. (https://godbolt.org/z/qZxvof) How would I construct SIMD intrinsics to solve this issue? I have control of the alignment for accum, but not channel.

(I know there's an average intrinsic, but it's not appropriate here because I need to generate multiple mip levels and that command would cause loss of precision for the next level.)

Thanks everyone. :)

• Looks like a use-case for SSSE3 `_mm_hadd_epi32` or `_mm_hadd_epi16` T is `int16_t` instead of `int`. It costs the same as 2 shuffles + a vertical add, but you need that anyway to pack 2 inputs to 1. If you want to work around a shuffle-port bottleneck on Intel CPUs, you could consider using qword shifts on the inputs and then shuffling together the result with `shufps`. Commented Mar 8, 2019 at 6:55
• Wow, that's pretty cool! I had been under the impression that "horizontal" operations were not possible in SIMD. I'll give this a try tomorrow. For what it's worth, the dominant use case for this operation is uint8_t -> uint16_t Commented Mar 8, 2019 at 6:57
• I didn't realize you were widening, that changes things entirely. (Also, you showed short -> int on Godbolt; what SSE/AVX version are you targeting? You used `-march=native` on Godbolt, which is Skylake-AVX512 = AVX512BW). Anyway, `_mm_hadd_*` isn't useful when `U` is not the same width as `T`. You probably want `pmaddwd` or `pmaddubsw` with a multiplier of 1 to add horizontal pairs into a wider result. Commented Mar 8, 2019 at 7:19
• You should always use `-march=haswell` or similar if you know that's what you're targeting. That sets important tuning options as well as instruction sets. And don't use `-march=corei7`, it's kind of meaningless / confusing because it's basically `-march=nehalem` (the first generation of core i7). Commented Mar 8, 2019 at 7:36
• On Godbolt you can `#include <stddef.h>` and use `size_t` like a normal person. And notice that gcc did auto-vectorize your code for uint8_t -> uint16_t. Not particularly well, but it did it. Commented Mar 8, 2019 at 7:39

The widening case with the narrow type `T` = `uint8_t` or `uint16_t` is probably best implemented with SSSE3 `pmaddubsw` or SSE2 `pmaddwd` with a multiplier of `1`. (Intrinsics guide) Those instructions are single-uop and do exactly the horizontal widening add you need more efficiently than shuffling.

If you're horizontally summing across 8 or more u8 elements, use `psadbw` (sum of absolute differences) against a zeroed vector. `_mm_sad_epu8` to get sums at the bottom of each 64-bit element. (A good first step if hsumming a whole vector, or summing a whole u8 array without overflow.)

If you can do so without losing precision, do the vertical add between rows first, before widening horizontal add. (e.g. 10, 12, or 14-bit pixel components in `[u]int16_t` can't overflow). Load and vertical-add have 2 per clock throughput (or more) on most CPUs, vs. 1 per clock for `pmadd*` only having 2-per-clock throughput on Skylake and later. And it means you only need 1x add + 1x pmadd vs. 2x pmadd + 1x add so it's a significant win even on Skylake. (For the 2nd way, both loads can fold into memory operands for pmadd, if you have AVX. For the add before pmadd way, you'll need a pure load first and then fold the 2nd load into add, so you might not save front-end uops, unless you use indexed addressing modes and they un-laminate.)

And ideally you don't need to `+=` into an accumulator array, and instead can just read 2 rows in parallel and accumulator is write-only, so your loop has only 2 input streams and 1 output stream.

``````// SSSE3
__m128i hadd_widen8_to_16(__m128i a) {
// uint8_t, int8_t  (doesn't matter when multiplier is +1)
}

// SSE2
__m128i hadd_widen16_to_32(__m128i a) {
// int16_t, int16_t
}
``````

These port to 256-bit AVX2 directly, because the input and output width is the same. No shuffle needed to fix up in-lane packing.

Yes really, they're both `_epi16`. Intel can be wildly inconsistent with intrinsic names. asm mnemonics are more consistent and easier to remember what's what. (`ubsw` = unsigned byte to signed word, except that one of the inputs is signed bytes. `pmaddwd` is packed multiply add word to dword, same naming scheme as `punpcklwd` etc.)

The T=U case with `uint16_t` or `uint32_t` is a a use-case for SSSE3 `_mm_hadd_epi16` or `_mm_hadd_epi32`. It costs the same as 2 shuffles + a vertical add, but you need that anyway to pack 2 inputs to 1.

If you want to work around a shuffle-port bottleneck on Haswell and later, you could consider using qword shifts on the inputs and then shuffling together the result with `shufps` (`_mm_shuffle_ps` + some casting). This could possibly be a win on Skylake (with 2 per clock shift throughput), even though it costs more 5 total uops instead of 3. It can run at best 5/3 cycles per vector of output instead of 2 cycles per vector if there's no front-end bottleneck.

``````// UNTESTED

//Only any good with AVX, otherwise the extra movdqa instructions kill this
//Only worth considering for Skylake, not Haswell (1/c shifts) or Sandybridge (2/c shuffle)
__m128i hadd32_emulated(__m128i a, __m128i b) {
__m128i a_shift = _mm_srli_epi64(a, 32);
__m128i b_shift = _mm_srli_epi64(b, 32);
a = _mm_add_epi32(a, a_shift);
b = _mm_add_epi32(b, b_shift);
__m128 combined = _mm_shuffle_ps(_mm_castsi128_ps(a), _mm_castsi128_ps(b), _MM_SHUFFLE(2,0,2,0));
return _mm_castps_si128(combined);
}
``````

Ice Lake and later Intel, and AMD, have better than 1/clock throughput for some shuffles but not all. For example, `vphaddd` is 2 uops for p1 or p5 on Ice Lake or later, plus 1 uop for any of p015. But `vhaddps`'s 2 shuffle uops can only run on port 5, even though you can precisely emulate `vhaddps` with 2x `vshufps` (with `_MM_SHUFFLE(2,0,2,0)` for evens and `_MM_SHUFFLE(3,1,3,1)` for odds, as shown in another answer), and `vshufps` runs on p1/p5 (unlike `vunpcklps` for some reason). And AMD CPUs run `vhaddps` less efficiently than you'd expect as well. So if you have a lot of pairwise summing of FP data, you might consider manually using shuffles that clang won't "optimize" into `vhaddps`.

But for integer `vphaddd` on Ice Lake / Alder Lake and Zen 3 / Zen 4, things seem ok. At least with YMM vectors; Zen 3/4 at least take an extra uop for `vphaddd xmm, xmm, xmm` according to https://uops.info/ measurements.

For an AVX2 version you'd need a lane-crossing shuffle to fixup a `vphadd` result. So emulating hadd with shifts might be a bigger win.

``````// 3x shuffle 1x add uops
__m256i hadd32_avx2(__m256i a, __m256i b) {
return _mm256_permutex_epi64( hadd, _MM_SHUFFLE(3,1,2,0) );
}

// UNTESTED
// 2x shift, 2x add, 1x blend-immediate (any ALU port), 1x shuffle
__m256i hadd32_emulated_avx2(__m256i a, __m256i b)
{
__m256i a_shift = _mm256_srli_epi64(a, 32);  // useful result in the low half of each qword
__m256i b_shift = _mm256_slli_epi64(b, 32);  // ... high half of each qword
a = _mm256_add_epi32(a, a_shift);
b = _mm256_add_epi32(b, b_shift);
__m256i blended = _mm256_blend_epi32(a,b, 0b10101010);  // alternating low/high results
return _mm256_permutexvar_epi32(_mm256_set_epi32(7,5,3,1, 6,4,2,0),  blended);
}
``````

On Haswell and Skylake, `hadd32_emulated_avx2` can run at 1 per 2 clocks (saturating all vector ALU ports). The extra `add_epi32` to sum into `accum[]` will slow it down to at best 7/3 cycles per 256-bit vector of results, and you'll need to unroll (or use a compiler that unrolls) to not just bottleneck on the front-end.

`hadd32_avx2` can run at 1 per 3 clocks (bottlenecked on port 5 for shuffles). The load + store + extra `add_epi32` uops to implement your loop can run in the shadow of that easily.