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Diffstat (limited to 'third_party/highway/hwy/ops/x86_512-inl.h')
| -rw-r--r-- | third_party/highway/hwy/ops/x86_512-inl.h | 4605 |
1 files changed, 4605 insertions, 0 deletions
diff --git a/third_party/highway/hwy/ops/x86_512-inl.h b/third_party/highway/hwy/ops/x86_512-inl.h new file mode 100644 index 0000000000..5f3b34c357 --- /dev/null +++ b/third_party/highway/hwy/ops/x86_512-inl.h @@ -0,0 +1,4605 @@ +// Copyright 2019 Google LLC +// SPDX-License-Identifier: Apache-2.0 +// +// Licensed under the Apache License, Version 2.0 (the "License"); +// you may not use this file except in compliance with the License. +// You may obtain a copy of the License at +// +// http://www.apache.org/licenses/LICENSE-2.0 +// +// Unless required by applicable law or agreed to in writing, software +// distributed under the License is distributed on an "AS IS" BASIS, +// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. +// See the License for the specific language governing permissions and +// limitations under the License. + +// 512-bit AVX512 vectors and operations. +// External include guard in highway.h - see comment there. + +// WARNING: most operations do not cross 128-bit block boundaries. In +// particular, "Broadcast", pack and zip behavior may be surprising. + +// Must come before HWY_DIAGNOSTICS and HWY_COMPILER_CLANGCL +#include "hwy/base.h" + +// Avoid uninitialized warnings in GCC's avx512fintrin.h - see +// https://github.com/google/highway/issues/710) +HWY_DIAGNOSTICS(push) +#if HWY_COMPILER_GCC_ACTUAL +HWY_DIAGNOSTICS_OFF(disable : 4701, ignored "-Wuninitialized") +HWY_DIAGNOSTICS_OFF(disable : 4703 6001 26494, ignored "-Wmaybe-uninitialized") +#endif + +#include <immintrin.h> // AVX2+ + +#if HWY_COMPILER_CLANGCL +// Including <immintrin.h> should be enough, but Clang's headers helpfully skip +// including these headers when _MSC_VER is defined, like when using clang-cl. +// Include these directly here. +// clang-format off +#include <smmintrin.h> + +#include <avxintrin.h> +#include <avx2intrin.h> +#include <f16cintrin.h> +#include <fmaintrin.h> + +#include <avx512fintrin.h> +#include <avx512vlintrin.h> +#include <avx512bwintrin.h> +#include <avx512dqintrin.h> +#include <avx512vlbwintrin.h> +#include <avx512vldqintrin.h> +#include <avx512bitalgintrin.h> +#include <avx512vlbitalgintrin.h> +#include <avx512vpopcntdqintrin.h> +#include <avx512vpopcntdqvlintrin.h> +// clang-format on +#endif // HWY_COMPILER_CLANGCL + +#include <stddef.h> +#include <stdint.h> + +#if HWY_IS_MSAN +#include <sanitizer/msan_interface.h> +#endif + +// For half-width vectors. Already includes base.h and shared-inl.h. +#include "hwy/ops/x86_256-inl.h" + +HWY_BEFORE_NAMESPACE(); +namespace hwy { +namespace HWY_NAMESPACE { + +namespace detail { + +template <typename T> +struct Raw512 { + using type = __m512i; +}; +template <> +struct Raw512<float> { + using type = __m512; +}; +template <> +struct Raw512<double> { + using type = __m512d; +}; + +// Template arg: sizeof(lane type) +template <size_t size> +struct RawMask512 {}; +template <> +struct RawMask512<1> { + using type = __mmask64; +}; +template <> +struct RawMask512<2> { + using type = __mmask32; +}; +template <> +struct RawMask512<4> { + using type = __mmask16; +}; +template <> +struct RawMask512<8> { + using type = __mmask8; +}; + +} // namespace detail + +template <typename T> +class Vec512 { + using Raw = typename detail::Raw512<T>::type; + + public: + using PrivateT = T; // only for DFromV + static constexpr size_t kPrivateN = 64 / sizeof(T); // only for DFromV + + // Compound assignment. Only usable if there is a corresponding non-member + // binary operator overload. For example, only f32 and f64 support division. + HWY_INLINE Vec512& operator*=(const Vec512 other) { + return *this = (*this * other); + } + HWY_INLINE Vec512& operator/=(const Vec512 other) { + return *this = (*this / other); + } + HWY_INLINE Vec512& operator+=(const Vec512 other) { + return *this = (*this + other); + } + HWY_INLINE Vec512& operator-=(const Vec512 other) { + return *this = (*this - other); + } + HWY_INLINE Vec512& operator&=(const Vec512 other) { + return *this = (*this & other); + } + HWY_INLINE Vec512& operator|=(const Vec512 other) { + return *this = (*this | other); + } + HWY_INLINE Vec512& operator^=(const Vec512 other) { + return *this = (*this ^ other); + } + + Raw raw; +}; + +// Mask register: one bit per lane. +template <typename T> +struct Mask512 { + using Raw = typename detail::RawMask512<sizeof(T)>::type; + Raw raw; +}; + +template <typename T> +using Full512 = Simd<T, 64 / sizeof(T), 0>; + +// ------------------------------ BitCast + +namespace detail { + +HWY_INLINE __m512i BitCastToInteger(__m512i v) { return v; } +HWY_INLINE __m512i BitCastToInteger(__m512 v) { return _mm512_castps_si512(v); } +HWY_INLINE __m512i BitCastToInteger(__m512d v) { + return _mm512_castpd_si512(v); +} + +template <typename T> +HWY_INLINE Vec512<uint8_t> BitCastToByte(Vec512<T> v) { + return Vec512<uint8_t>{BitCastToInteger(v.raw)}; +} + +// Cannot rely on function overloading because return types differ. +template <typename T> +struct BitCastFromInteger512 { + HWY_INLINE __m512i operator()(__m512i v) { return v; } +}; +template <> +struct BitCastFromInteger512<float> { + HWY_INLINE __m512 operator()(__m512i v) { return _mm512_castsi512_ps(v); } +}; +template <> +struct BitCastFromInteger512<double> { + HWY_INLINE __m512d operator()(__m512i v) { return _mm512_castsi512_pd(v); } +}; + +template <typename T> +HWY_INLINE Vec512<T> BitCastFromByte(Full512<T> /* tag */, Vec512<uint8_t> v) { + return Vec512<T>{BitCastFromInteger512<T>()(v.raw)}; +} + +} // namespace detail + +template <typename T, typename FromT> +HWY_API Vec512<T> BitCast(Full512<T> d, Vec512<FromT> v) { + return detail::BitCastFromByte(d, detail::BitCastToByte(v)); +} + +// ------------------------------ Set + +// Returns an all-zero vector. +template <typename T> +HWY_API Vec512<T> Zero(Full512<T> /* tag */) { + return Vec512<T>{_mm512_setzero_si512()}; +} +HWY_API Vec512<float> Zero(Full512<float> /* tag */) { + return Vec512<float>{_mm512_setzero_ps()}; +} +HWY_API Vec512<double> Zero(Full512<double> /* tag */) { + return Vec512<double>{_mm512_setzero_pd()}; +} + +// Returns a vector with all lanes set to "t". +HWY_API Vec512<uint8_t> Set(Full512<uint8_t> /* tag */, const uint8_t t) { + return Vec512<uint8_t>{_mm512_set1_epi8(static_cast<char>(t))}; // NOLINT +} +HWY_API Vec512<uint16_t> Set(Full512<uint16_t> /* tag */, const uint16_t t) { + return Vec512<uint16_t>{_mm512_set1_epi16(static_cast<short>(t))}; // NOLINT +} +HWY_API Vec512<uint32_t> Set(Full512<uint32_t> /* tag */, const uint32_t t) { + return Vec512<uint32_t>{_mm512_set1_epi32(static_cast<int>(t))}; +} +HWY_API Vec512<uint64_t> Set(Full512<uint64_t> /* tag */, const uint64_t t) { + return Vec512<uint64_t>{ + _mm512_set1_epi64(static_cast<long long>(t))}; // NOLINT +} +HWY_API Vec512<int8_t> Set(Full512<int8_t> /* tag */, const int8_t t) { + return Vec512<int8_t>{_mm512_set1_epi8(static_cast<char>(t))}; // NOLINT +} +HWY_API Vec512<int16_t> Set(Full512<int16_t> /* tag */, const int16_t t) { + return Vec512<int16_t>{_mm512_set1_epi16(static_cast<short>(t))}; // NOLINT +} +HWY_API Vec512<int32_t> Set(Full512<int32_t> /* tag */, const int32_t t) { + return Vec512<int32_t>{_mm512_set1_epi32(t)}; +} +HWY_API Vec512<int64_t> Set(Full512<int64_t> /* tag */, const int64_t t) { + return Vec512<int64_t>{ + _mm512_set1_epi64(static_cast<long long>(t))}; // NOLINT +} +HWY_API Vec512<float> Set(Full512<float> /* tag */, const float t) { + return Vec512<float>{_mm512_set1_ps(t)}; +} +HWY_API Vec512<double> Set(Full512<double> /* tag */, const double t) { + return Vec512<double>{_mm512_set1_pd(t)}; +} + +HWY_DIAGNOSTICS(push) +HWY_DIAGNOSTICS_OFF(disable : 4700, ignored "-Wuninitialized") + +// Returns a vector with uninitialized elements. +template <typename T> +HWY_API Vec512<T> Undefined(Full512<T> /* tag */) { + // Available on Clang 6.0, GCC 6.2, ICC 16.03, MSVC 19.14. All but ICC + // generate an XOR instruction. + return Vec512<T>{_mm512_undefined_epi32()}; +} +HWY_API Vec512<float> Undefined(Full512<float> /* tag */) { + return Vec512<float>{_mm512_undefined_ps()}; +} +HWY_API Vec512<double> Undefined(Full512<double> /* tag */) { + return Vec512<double>{_mm512_undefined_pd()}; +} + +HWY_DIAGNOSTICS(pop) + +// ================================================== LOGICAL + +// ------------------------------ Not + +template <typename T> +HWY_API Vec512<T> Not(const Vec512<T> v) { + using TU = MakeUnsigned<T>; + const __m512i vu = BitCast(Full512<TU>(), v).raw; + return BitCast(Full512<T>(), + Vec512<TU>{_mm512_ternarylogic_epi32(vu, vu, vu, 0x55)}); +} + +// ------------------------------ And + +template <typename T> +HWY_API Vec512<T> And(const Vec512<T> a, const Vec512<T> b) { + return Vec512<T>{_mm512_and_si512(a.raw, b.raw)}; +} + +HWY_API Vec512<float> And(const Vec512<float> a, const Vec512<float> b) { + return Vec512<float>{_mm512_and_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> And(const Vec512<double> a, const Vec512<double> b) { + return Vec512<double>{_mm512_and_pd(a.raw, b.raw)}; +} + +// ------------------------------ AndNot + +// Returns ~not_mask & mask. +template <typename T> +HWY_API Vec512<T> AndNot(const Vec512<T> not_mask, const Vec512<T> mask) { + return Vec512<T>{_mm512_andnot_si512(not_mask.raw, mask.raw)}; +} +HWY_API Vec512<float> AndNot(const Vec512<float> not_mask, + const Vec512<float> mask) { + return Vec512<float>{_mm512_andnot_ps(not_mask.raw, mask.raw)}; +} +HWY_API Vec512<double> AndNot(const Vec512<double> not_mask, + const Vec512<double> mask) { + return Vec512<double>{_mm512_andnot_pd(not_mask.raw, mask.raw)}; +} + +// ------------------------------ Or + +template <typename T> +HWY_API Vec512<T> Or(const Vec512<T> a, const Vec512<T> b) { + return Vec512<T>{_mm512_or_si512(a.raw, b.raw)}; +} + +HWY_API Vec512<float> Or(const Vec512<float> a, const Vec512<float> b) { + return Vec512<float>{_mm512_or_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> Or(const Vec512<double> a, const Vec512<double> b) { + return Vec512<double>{_mm512_or_pd(a.raw, b.raw)}; +} + +// ------------------------------ Xor + +template <typename T> +HWY_API Vec512<T> Xor(const Vec512<T> a, const Vec512<T> b) { + return Vec512<T>{_mm512_xor_si512(a.raw, b.raw)}; +} + +HWY_API Vec512<float> Xor(const Vec512<float> a, const Vec512<float> b) { + return Vec512<float>{_mm512_xor_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> Xor(const Vec512<double> a, const Vec512<double> b) { + return Vec512<double>{_mm512_xor_pd(a.raw, b.raw)}; +} + +// ------------------------------ Xor3 +template <typename T> +HWY_API Vec512<T> Xor3(Vec512<T> x1, Vec512<T> x2, Vec512<T> x3) { + const Full512<T> d; + const RebindToUnsigned<decltype(d)> du; + using VU = VFromD<decltype(du)>; + const __m512i ret = _mm512_ternarylogic_epi64( + BitCast(du, x1).raw, BitCast(du, x2).raw, BitCast(du, x3).raw, 0x96); + return BitCast(d, VU{ret}); +} + +// ------------------------------ Or3 +template <typename T> +HWY_API Vec512<T> Or3(Vec512<T> o1, Vec512<T> o2, Vec512<T> o3) { + const Full512<T> d; + const RebindToUnsigned<decltype(d)> du; + using VU = VFromD<decltype(du)>; + const __m512i ret = _mm512_ternarylogic_epi64( + BitCast(du, o1).raw, BitCast(du, o2).raw, BitCast(du, o3).raw, 0xFE); + return BitCast(d, VU{ret}); +} + +// ------------------------------ OrAnd +template <typename T> +HWY_API Vec512<T> OrAnd(Vec512<T> o, Vec512<T> a1, Vec512<T> a2) { + const Full512<T> d; + const RebindToUnsigned<decltype(d)> du; + using VU = VFromD<decltype(du)>; + const __m512i ret = _mm512_ternarylogic_epi64( + BitCast(du, o).raw, BitCast(du, a1).raw, BitCast(du, a2).raw, 0xF8); + return BitCast(d, VU{ret}); +} + +// ------------------------------ IfVecThenElse +template <typename T> +HWY_API Vec512<T> IfVecThenElse(Vec512<T> mask, Vec512<T> yes, Vec512<T> no) { + const Full512<T> d; + const RebindToUnsigned<decltype(d)> du; + using VU = VFromD<decltype(du)>; + return BitCast(d, VU{_mm512_ternarylogic_epi64(BitCast(du, mask).raw, + BitCast(du, yes).raw, + BitCast(du, no).raw, 0xCA)}); +} + +// ------------------------------ Operator overloads (internal-only if float) + +template <typename T> +HWY_API Vec512<T> operator&(const Vec512<T> a, const Vec512<T> b) { + return And(a, b); +} + +template <typename T> +HWY_API Vec512<T> operator|(const Vec512<T> a, const Vec512<T> b) { + return Or(a, b); +} + +template <typename T> +HWY_API Vec512<T> operator^(const Vec512<T> a, const Vec512<T> b) { + return Xor(a, b); +} + +// ------------------------------ PopulationCount + +// 8/16 require BITALG, 32/64 require VPOPCNTDQ. +#if HWY_TARGET == HWY_AVX3_DL + +#ifdef HWY_NATIVE_POPCNT +#undef HWY_NATIVE_POPCNT +#else +#define HWY_NATIVE_POPCNT +#endif + +namespace detail { + +template <typename T> +HWY_INLINE Vec512<T> PopulationCount(hwy::SizeTag<1> /* tag */, Vec512<T> v) { + return Vec512<T>{_mm512_popcnt_epi8(v.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> PopulationCount(hwy::SizeTag<2> /* tag */, Vec512<T> v) { + return Vec512<T>{_mm512_popcnt_epi16(v.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> PopulationCount(hwy::SizeTag<4> /* tag */, Vec512<T> v) { + return Vec512<T>{_mm512_popcnt_epi32(v.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> PopulationCount(hwy::SizeTag<8> /* tag */, Vec512<T> v) { + return Vec512<T>{_mm512_popcnt_epi64(v.raw)}; +} + +} // namespace detail + +template <typename T> +HWY_API Vec512<T> PopulationCount(Vec512<T> v) { + return detail::PopulationCount(hwy::SizeTag<sizeof(T)>(), v); +} + +#endif // HWY_TARGET == HWY_AVX3_DL + +// ================================================== SIGN + +// ------------------------------ CopySign + +template <typename T> +HWY_API Vec512<T> CopySign(const Vec512<T> magn, const Vec512<T> sign) { + static_assert(IsFloat<T>(), "Only makes sense for floating-point"); + + const Full512<T> d; + const auto msb = SignBit(d); + + const Rebind<MakeUnsigned<T>, decltype(d)> du; + // Truth table for msb, magn, sign | bitwise msb ? sign : mag + // 0 0 0 | 0 + // 0 0 1 | 0 + // 0 1 0 | 1 + // 0 1 1 | 1 + // 1 0 0 | 0 + // 1 0 1 | 1 + // 1 1 0 | 0 + // 1 1 1 | 1 + // The lane size does not matter because we are not using predication. + const __m512i out = _mm512_ternarylogic_epi32( + BitCast(du, msb).raw, BitCast(du, magn).raw, BitCast(du, sign).raw, 0xAC); + return BitCast(d, decltype(Zero(du)){out}); +} + +template <typename T> +HWY_API Vec512<T> CopySignToAbs(const Vec512<T> abs, const Vec512<T> sign) { + // AVX3 can also handle abs < 0, so no extra action needed. + return CopySign(abs, sign); +} + +// ================================================== MASK + +// ------------------------------ FirstN + +// Possibilities for constructing a bitmask of N ones: +// - kshift* only consider the lowest byte of the shift count, so they would +// not correctly handle large n. +// - Scalar shifts >= 64 are UB. +// - BZHI has the desired semantics; we assume AVX-512 implies BMI2. However, +// we need 64-bit masks for sizeof(T) == 1, so special-case 32-bit builds. + +#if HWY_ARCH_X86_32 +namespace detail { + +// 32 bit mask is sufficient for lane size >= 2. +template <typename T, HWY_IF_NOT_LANE_SIZE(T, 1)> +HWY_INLINE Mask512<T> FirstN(size_t n) { + Mask512<T> m; + const uint32_t all = ~uint32_t{0}; + // BZHI only looks at the lower 8 bits of n! + m.raw = static_cast<decltype(m.raw)>((n > 255) ? all : _bzhi_u32(all, n)); + return m; +} + +template <typename T, HWY_IF_LANE_SIZE(T, 1)> +HWY_INLINE Mask512<T> FirstN(size_t n) { + const uint64_t bits = n < 64 ? ((1ULL << n) - 1) : ~uint64_t{0}; + return Mask512<T>{static_cast<__mmask64>(bits)}; +} + +} // namespace detail +#endif // HWY_ARCH_X86_32 + +template <typename T> +HWY_API Mask512<T> FirstN(const Full512<T> /*tag*/, size_t n) { +#if HWY_ARCH_X86_64 + Mask512<T> m; + const uint64_t all = ~uint64_t{0}; + // BZHI only looks at the lower 8 bits of n! + m.raw = static_cast<decltype(m.raw)>((n > 255) ? all : _bzhi_u64(all, n)); + return m; +#else + return detail::FirstN<T>(n); +#endif // HWY_ARCH_X86_64 +} + +// ------------------------------ IfThenElse + +// Returns mask ? b : a. + +namespace detail { + +// Templates for signed/unsigned integer of a particular size. +template <typename T> +HWY_INLINE Vec512<T> IfThenElse(hwy::SizeTag<1> /* tag */, + const Mask512<T> mask, const Vec512<T> yes, + const Vec512<T> no) { + return Vec512<T>{_mm512_mask_mov_epi8(no.raw, mask.raw, yes.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> IfThenElse(hwy::SizeTag<2> /* tag */, + const Mask512<T> mask, const Vec512<T> yes, + const Vec512<T> no) { + return Vec512<T>{_mm512_mask_mov_epi16(no.raw, mask.raw, yes.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> IfThenElse(hwy::SizeTag<4> /* tag */, + const Mask512<T> mask, const Vec512<T> yes, + const Vec512<T> no) { + return Vec512<T>{_mm512_mask_mov_epi32(no.raw, mask.raw, yes.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> IfThenElse(hwy::SizeTag<8> /* tag */, + const Mask512<T> mask, const Vec512<T> yes, + const Vec512<T> no) { + return Vec512<T>{_mm512_mask_mov_epi64(no.raw, mask.raw, yes.raw)}; +} + +} // namespace detail + +template <typename T> +HWY_API Vec512<T> IfThenElse(const Mask512<T> mask, const Vec512<T> yes, + const Vec512<T> no) { + return detail::IfThenElse(hwy::SizeTag<sizeof(T)>(), mask, yes, no); +} +HWY_API Vec512<float> IfThenElse(const Mask512<float> mask, + const Vec512<float> yes, + const Vec512<float> no) { + return Vec512<float>{_mm512_mask_mov_ps(no.raw, mask.raw, yes.raw)}; +} +HWY_API Vec512<double> IfThenElse(const Mask512<double> mask, + const Vec512<double> yes, + const Vec512<double> no) { + return Vec512<double>{_mm512_mask_mov_pd(no.raw, mask.raw, yes.raw)}; +} + +namespace detail { + +template <typename T> +HWY_INLINE Vec512<T> IfThenElseZero(hwy::SizeTag<1> /* tag */, + const Mask512<T> mask, + const Vec512<T> yes) { + return Vec512<T>{_mm512_maskz_mov_epi8(mask.raw, yes.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> IfThenElseZero(hwy::SizeTag<2> /* tag */, + const Mask512<T> mask, + const Vec512<T> yes) { + return Vec512<T>{_mm512_maskz_mov_epi16(mask.raw, yes.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> IfThenElseZero(hwy::SizeTag<4> /* tag */, + const Mask512<T> mask, + const Vec512<T> yes) { + return Vec512<T>{_mm512_maskz_mov_epi32(mask.raw, yes.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> IfThenElseZero(hwy::SizeTag<8> /* tag */, + const Mask512<T> mask, + const Vec512<T> yes) { + return Vec512<T>{_mm512_maskz_mov_epi64(mask.raw, yes.raw)}; +} + +} // namespace detail + +template <typename T> +HWY_API Vec512<T> IfThenElseZero(const Mask512<T> mask, const Vec512<T> yes) { + return detail::IfThenElseZero(hwy::SizeTag<sizeof(T)>(), mask, yes); +} +HWY_API Vec512<float> IfThenElseZero(const Mask512<float> mask, + const Vec512<float> yes) { + return Vec512<float>{_mm512_maskz_mov_ps(mask.raw, yes.raw)}; +} +HWY_API Vec512<double> IfThenElseZero(const Mask512<double> mask, + const Vec512<double> yes) { + return Vec512<double>{_mm512_maskz_mov_pd(mask.raw, yes.raw)}; +} + +namespace detail { + +template <typename T> +HWY_INLINE Vec512<T> IfThenZeroElse(hwy::SizeTag<1> /* tag */, + const Mask512<T> mask, const Vec512<T> no) { + // xor_epi8/16 are missing, but we have sub, which is just as fast for u8/16. + return Vec512<T>{_mm512_mask_sub_epi8(no.raw, mask.raw, no.raw, no.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> IfThenZeroElse(hwy::SizeTag<2> /* tag */, + const Mask512<T> mask, const Vec512<T> no) { + return Vec512<T>{_mm512_mask_sub_epi16(no.raw, mask.raw, no.raw, no.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> IfThenZeroElse(hwy::SizeTag<4> /* tag */, + const Mask512<T> mask, const Vec512<T> no) { + return Vec512<T>{_mm512_mask_xor_epi32(no.raw, mask.raw, no.raw, no.raw)}; +} +template <typename T> +HWY_INLINE Vec512<T> IfThenZeroElse(hwy::SizeTag<8> /* tag */, + const Mask512<T> mask, const Vec512<T> no) { + return Vec512<T>{_mm512_mask_xor_epi64(no.raw, mask.raw, no.raw, no.raw)}; +} + +} // namespace detail + +template <typename T> +HWY_API Vec512<T> IfThenZeroElse(const Mask512<T> mask, const Vec512<T> no) { + return detail::IfThenZeroElse(hwy::SizeTag<sizeof(T)>(), mask, no); +} +HWY_API Vec512<float> IfThenZeroElse(const Mask512<float> mask, + const Vec512<float> no) { + return Vec512<float>{_mm512_mask_xor_ps(no.raw, mask.raw, no.raw, no.raw)}; +} +HWY_API Vec512<double> IfThenZeroElse(const Mask512<double> mask, + const Vec512<double> no) { + return Vec512<double>{_mm512_mask_xor_pd(no.raw, mask.raw, no.raw, no.raw)}; +} + +template <typename T> +HWY_API Vec512<T> IfNegativeThenElse(Vec512<T> v, Vec512<T> yes, Vec512<T> no) { + static_assert(IsSigned<T>(), "Only works for signed/float"); + // AVX3 MaskFromVec only looks at the MSB + return IfThenElse(MaskFromVec(v), yes, no); +} + +template <typename T, HWY_IF_FLOAT(T)> +HWY_API Vec512<T> ZeroIfNegative(const Vec512<T> v) { + // AVX3 MaskFromVec only looks at the MSB + return IfThenZeroElse(MaskFromVec(v), v); +} + +// ================================================== ARITHMETIC + +// ------------------------------ Addition + +// Unsigned +HWY_API Vec512<uint8_t> operator+(const Vec512<uint8_t> a, + const Vec512<uint8_t> b) { + return Vec512<uint8_t>{_mm512_add_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<uint16_t> operator+(const Vec512<uint16_t> a, + const Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_add_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<uint32_t> operator+(const Vec512<uint32_t> a, + const Vec512<uint32_t> b) { + return Vec512<uint32_t>{_mm512_add_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<uint64_t> operator+(const Vec512<uint64_t> a, + const Vec512<uint64_t> b) { + return Vec512<uint64_t>{_mm512_add_epi64(a.raw, b.raw)}; +} + +// Signed +HWY_API Vec512<int8_t> operator+(const Vec512<int8_t> a, + const Vec512<int8_t> b) { + return Vec512<int8_t>{_mm512_add_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<int16_t> operator+(const Vec512<int16_t> a, + const Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_add_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<int32_t> operator+(const Vec512<int32_t> a, + const Vec512<int32_t> b) { + return Vec512<int32_t>{_mm512_add_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<int64_t> operator+(const Vec512<int64_t> a, + const Vec512<int64_t> b) { + return Vec512<int64_t>{_mm512_add_epi64(a.raw, b.raw)}; +} + +// Float +HWY_API Vec512<float> operator+(const Vec512<float> a, const Vec512<float> b) { + return Vec512<float>{_mm512_add_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> operator+(const Vec512<double> a, + const Vec512<double> b) { + return Vec512<double>{_mm512_add_pd(a.raw, b.raw)}; +} + +// ------------------------------ Subtraction + +// Unsigned +HWY_API Vec512<uint8_t> operator-(const Vec512<uint8_t> a, + const Vec512<uint8_t> b) { + return Vec512<uint8_t>{_mm512_sub_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<uint16_t> operator-(const Vec512<uint16_t> a, + const Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_sub_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<uint32_t> operator-(const Vec512<uint32_t> a, + const Vec512<uint32_t> b) { + return Vec512<uint32_t>{_mm512_sub_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<uint64_t> operator-(const Vec512<uint64_t> a, + const Vec512<uint64_t> b) { + return Vec512<uint64_t>{_mm512_sub_epi64(a.raw, b.raw)}; +} + +// Signed +HWY_API Vec512<int8_t> operator-(const Vec512<int8_t> a, + const Vec512<int8_t> b) { + return Vec512<int8_t>{_mm512_sub_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<int16_t> operator-(const Vec512<int16_t> a, + const Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_sub_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<int32_t> operator-(const Vec512<int32_t> a, + const Vec512<int32_t> b) { + return Vec512<int32_t>{_mm512_sub_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<int64_t> operator-(const Vec512<int64_t> a, + const Vec512<int64_t> b) { + return Vec512<int64_t>{_mm512_sub_epi64(a.raw, b.raw)}; +} + +// Float +HWY_API Vec512<float> operator-(const Vec512<float> a, const Vec512<float> b) { + return Vec512<float>{_mm512_sub_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> operator-(const Vec512<double> a, + const Vec512<double> b) { + return Vec512<double>{_mm512_sub_pd(a.raw, b.raw)}; +} + +// ------------------------------ SumsOf8 +HWY_API Vec512<uint64_t> SumsOf8(const Vec512<uint8_t> v) { + return Vec512<uint64_t>{_mm512_sad_epu8(v.raw, _mm512_setzero_si512())}; +} + +// ------------------------------ SaturatedAdd + +// Returns a + b clamped to the destination range. + +// Unsigned +HWY_API Vec512<uint8_t> SaturatedAdd(const Vec512<uint8_t> a, + const Vec512<uint8_t> b) { + return Vec512<uint8_t>{_mm512_adds_epu8(a.raw, b.raw)}; +} +HWY_API Vec512<uint16_t> SaturatedAdd(const Vec512<uint16_t> a, + const Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_adds_epu16(a.raw, b.raw)}; +} + +// Signed +HWY_API Vec512<int8_t> SaturatedAdd(const Vec512<int8_t> a, + const Vec512<int8_t> b) { + return Vec512<int8_t>{_mm512_adds_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<int16_t> SaturatedAdd(const Vec512<int16_t> a, + const Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_adds_epi16(a.raw, b.raw)}; +} + +// ------------------------------ SaturatedSub + +// Returns a - b clamped to the destination range. + +// Unsigned +HWY_API Vec512<uint8_t> SaturatedSub(const Vec512<uint8_t> a, + const Vec512<uint8_t> b) { + return Vec512<uint8_t>{_mm512_subs_epu8(a.raw, b.raw)}; +} +HWY_API Vec512<uint16_t> SaturatedSub(const Vec512<uint16_t> a, + const Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_subs_epu16(a.raw, b.raw)}; +} + +// Signed +HWY_API Vec512<int8_t> SaturatedSub(const Vec512<int8_t> a, + const Vec512<int8_t> b) { + return Vec512<int8_t>{_mm512_subs_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<int16_t> SaturatedSub(const Vec512<int16_t> a, + const Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_subs_epi16(a.raw, b.raw)}; +} + +// ------------------------------ Average + +// Returns (a + b + 1) / 2 + +// Unsigned +HWY_API Vec512<uint8_t> AverageRound(const Vec512<uint8_t> a, + const Vec512<uint8_t> b) { + return Vec512<uint8_t>{_mm512_avg_epu8(a.raw, b.raw)}; +} +HWY_API Vec512<uint16_t> AverageRound(const Vec512<uint16_t> a, + const Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_avg_epu16(a.raw, b.raw)}; +} + +// ------------------------------ Abs (Sub) + +// Returns absolute value, except that LimitsMin() maps to LimitsMax() + 1. +HWY_API Vec512<int8_t> Abs(const Vec512<int8_t> v) { +#if HWY_COMPILER_MSVC + // Workaround for incorrect codegen? (untested due to internal compiler error) + const auto zero = Zero(Full512<int8_t>()); + return Vec512<int8_t>{_mm512_max_epi8(v.raw, (zero - v).raw)}; +#else + return Vec512<int8_t>{_mm512_abs_epi8(v.raw)}; +#endif +} +HWY_API Vec512<int16_t> Abs(const Vec512<int16_t> v) { + return Vec512<int16_t>{_mm512_abs_epi16(v.raw)}; +} +HWY_API Vec512<int32_t> Abs(const Vec512<int32_t> v) { + return Vec512<int32_t>{_mm512_abs_epi32(v.raw)}; +} +HWY_API Vec512<int64_t> Abs(const Vec512<int64_t> v) { + return Vec512<int64_t>{_mm512_abs_epi64(v.raw)}; +} + +// These aren't native instructions, they also involve AND with constant. +HWY_API Vec512<float> Abs(const Vec512<float> v) { + return Vec512<float>{_mm512_abs_ps(v.raw)}; +} +HWY_API Vec512<double> Abs(const Vec512<double> v) { + return Vec512<double>{_mm512_abs_pd(v.raw)}; +} +// ------------------------------ ShiftLeft + +template <int kBits> +HWY_API Vec512<uint16_t> ShiftLeft(const Vec512<uint16_t> v) { + return Vec512<uint16_t>{_mm512_slli_epi16(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<uint32_t> ShiftLeft(const Vec512<uint32_t> v) { + return Vec512<uint32_t>{_mm512_slli_epi32(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<uint64_t> ShiftLeft(const Vec512<uint64_t> v) { + return Vec512<uint64_t>{_mm512_slli_epi64(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<int16_t> ShiftLeft(const Vec512<int16_t> v) { + return Vec512<int16_t>{_mm512_slli_epi16(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<int32_t> ShiftLeft(const Vec512<int32_t> v) { + return Vec512<int32_t>{_mm512_slli_epi32(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<int64_t> ShiftLeft(const Vec512<int64_t> v) { + return Vec512<int64_t>{_mm512_slli_epi64(v.raw, kBits)}; +} + +template <int kBits, typename T, HWY_IF_LANE_SIZE(T, 1)> +HWY_API Vec512<T> ShiftLeft(const Vec512<T> v) { + const Full512<T> d8; + const RepartitionToWide<decltype(d8)> d16; + const auto shifted = BitCast(d8, ShiftLeft<kBits>(BitCast(d16, v))); + return kBits == 1 + ? (v + v) + : (shifted & Set(d8, static_cast<T>((0xFF << kBits) & 0xFF))); +} + +// ------------------------------ ShiftRight + +template <int kBits> +HWY_API Vec512<uint16_t> ShiftRight(const Vec512<uint16_t> v) { + return Vec512<uint16_t>{_mm512_srli_epi16(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<uint32_t> ShiftRight(const Vec512<uint32_t> v) { + return Vec512<uint32_t>{_mm512_srli_epi32(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<uint64_t> ShiftRight(const Vec512<uint64_t> v) { + return Vec512<uint64_t>{_mm512_srli_epi64(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<uint8_t> ShiftRight(const Vec512<uint8_t> v) { + const Full512<uint8_t> d8; + // Use raw instead of BitCast to support N=1. + const Vec512<uint8_t> shifted{ShiftRight<kBits>(Vec512<uint16_t>{v.raw}).raw}; + return shifted & Set(d8, 0xFF >> kBits); +} + +template <int kBits> +HWY_API Vec512<int16_t> ShiftRight(const Vec512<int16_t> v) { + return Vec512<int16_t>{_mm512_srai_epi16(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<int32_t> ShiftRight(const Vec512<int32_t> v) { + return Vec512<int32_t>{_mm512_srai_epi32(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<int64_t> ShiftRight(const Vec512<int64_t> v) { + return Vec512<int64_t>{_mm512_srai_epi64(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<int8_t> ShiftRight(const Vec512<int8_t> v) { + const Full512<int8_t> di; + const Full512<uint8_t> du; + const auto shifted = BitCast(di, ShiftRight<kBits>(BitCast(du, v))); + const auto shifted_sign = BitCast(di, Set(du, 0x80 >> kBits)); + return (shifted ^ shifted_sign) - shifted_sign; +} + +// ------------------------------ RotateRight + +template <int kBits> +HWY_API Vec512<uint32_t> RotateRight(const Vec512<uint32_t> v) { + static_assert(0 <= kBits && kBits < 32, "Invalid shift count"); + return Vec512<uint32_t>{_mm512_ror_epi32(v.raw, kBits)}; +} + +template <int kBits> +HWY_API Vec512<uint64_t> RotateRight(const Vec512<uint64_t> v) { + static_assert(0 <= kBits && kBits < 64, "Invalid shift count"); + return Vec512<uint64_t>{_mm512_ror_epi64(v.raw, kBits)}; +} + +// ------------------------------ ShiftLeftSame + +HWY_API Vec512<uint16_t> ShiftLeftSame(const Vec512<uint16_t> v, + const int bits) { + return Vec512<uint16_t>{_mm512_sll_epi16(v.raw, _mm_cvtsi32_si128(bits))}; +} +HWY_API Vec512<uint32_t> ShiftLeftSame(const Vec512<uint32_t> v, + const int bits) { + return Vec512<uint32_t>{_mm512_sll_epi32(v.raw, _mm_cvtsi32_si128(bits))}; +} +HWY_API Vec512<uint64_t> ShiftLeftSame(const Vec512<uint64_t> v, + const int bits) { + return Vec512<uint64_t>{_mm512_sll_epi64(v.raw, _mm_cvtsi32_si128(bits))}; +} + +HWY_API Vec512<int16_t> ShiftLeftSame(const Vec512<int16_t> v, const int bits) { + return Vec512<int16_t>{_mm512_sll_epi16(v.raw, _mm_cvtsi32_si128(bits))}; +} + +HWY_API Vec512<int32_t> ShiftLeftSame(const Vec512<int32_t> v, const int bits) { + return Vec512<int32_t>{_mm512_sll_epi32(v.raw, _mm_cvtsi32_si128(bits))}; +} + +HWY_API Vec512<int64_t> ShiftLeftSame(const Vec512<int64_t> v, const int bits) { + return Vec512<int64_t>{_mm512_sll_epi64(v.raw, _mm_cvtsi32_si128(bits))}; +} + +template <typename T, HWY_IF_LANE_SIZE(T, 1)> +HWY_API Vec512<T> ShiftLeftSame(const Vec512<T> v, const int bits) { + const Full512<T> d8; + const RepartitionToWide<decltype(d8)> d16; + const auto shifted = BitCast(d8, ShiftLeftSame(BitCast(d16, v), bits)); + return shifted & Set(d8, static_cast<T>((0xFF << bits) & 0xFF)); +} + +// ------------------------------ ShiftRightSame + +HWY_API Vec512<uint16_t> ShiftRightSame(const Vec512<uint16_t> v, + const int bits) { + return Vec512<uint16_t>{_mm512_srl_epi16(v.raw, _mm_cvtsi32_si128(bits))}; +} +HWY_API Vec512<uint32_t> ShiftRightSame(const Vec512<uint32_t> v, + const int bits) { + return Vec512<uint32_t>{_mm512_srl_epi32(v.raw, _mm_cvtsi32_si128(bits))}; +} +HWY_API Vec512<uint64_t> ShiftRightSame(const Vec512<uint64_t> v, + const int bits) { + return Vec512<uint64_t>{_mm512_srl_epi64(v.raw, _mm_cvtsi32_si128(bits))}; +} + +HWY_API Vec512<uint8_t> ShiftRightSame(Vec512<uint8_t> v, const int bits) { + const Full512<uint8_t> d8; + const RepartitionToWide<decltype(d8)> d16; + const auto shifted = BitCast(d8, ShiftRightSame(BitCast(d16, v), bits)); + return shifted & Set(d8, static_cast<uint8_t>(0xFF >> bits)); +} + +HWY_API Vec512<int16_t> ShiftRightSame(const Vec512<int16_t> v, + const int bits) { + return Vec512<int16_t>{_mm512_sra_epi16(v.raw, _mm_cvtsi32_si128(bits))}; +} + +HWY_API Vec512<int32_t> ShiftRightSame(const Vec512<int32_t> v, + const int bits) { + return Vec512<int32_t>{_mm512_sra_epi32(v.raw, _mm_cvtsi32_si128(bits))}; +} +HWY_API Vec512<int64_t> ShiftRightSame(const Vec512<int64_t> v, + const int bits) { + return Vec512<int64_t>{_mm512_sra_epi64(v.raw, _mm_cvtsi32_si128(bits))}; +} + +HWY_API Vec512<int8_t> ShiftRightSame(Vec512<int8_t> v, const int bits) { + const Full512<int8_t> di; + const Full512<uint8_t> du; + const auto shifted = BitCast(di, ShiftRightSame(BitCast(du, v), bits)); + const auto shifted_sign = + BitCast(di, Set(du, static_cast<uint8_t>(0x80 >> bits))); + return (shifted ^ shifted_sign) - shifted_sign; +} + +// ------------------------------ Shl + +HWY_API Vec512<uint16_t> operator<<(const Vec512<uint16_t> v, + const Vec512<uint16_t> bits) { + return Vec512<uint16_t>{_mm512_sllv_epi16(v.raw, bits.raw)}; +} + +HWY_API Vec512<uint32_t> operator<<(const Vec512<uint32_t> v, + const Vec512<uint32_t> bits) { + return Vec512<uint32_t>{_mm512_sllv_epi32(v.raw, bits.raw)}; +} + +HWY_API Vec512<uint64_t> operator<<(const Vec512<uint64_t> v, + const Vec512<uint64_t> bits) { + return Vec512<uint64_t>{_mm512_sllv_epi64(v.raw, bits.raw)}; +} + +// Signed left shift is the same as unsigned. +template <typename T, HWY_IF_SIGNED(T)> +HWY_API Vec512<T> operator<<(const Vec512<T> v, const Vec512<T> bits) { + const Full512<T> di; + const Full512<MakeUnsigned<T>> du; + return BitCast(di, BitCast(du, v) << BitCast(du, bits)); +} + +// ------------------------------ Shr + +HWY_API Vec512<uint16_t> operator>>(const Vec512<uint16_t> v, + const Vec512<uint16_t> bits) { + return Vec512<uint16_t>{_mm512_srlv_epi16(v.raw, bits.raw)}; +} + +HWY_API Vec512<uint32_t> operator>>(const Vec512<uint32_t> v, + const Vec512<uint32_t> bits) { + return Vec512<uint32_t>{_mm512_srlv_epi32(v.raw, bits.raw)}; +} + +HWY_API Vec512<uint64_t> operator>>(const Vec512<uint64_t> v, + const Vec512<uint64_t> bits) { + return Vec512<uint64_t>{_mm512_srlv_epi64(v.raw, bits.raw)}; +} + +HWY_API Vec512<int16_t> operator>>(const Vec512<int16_t> v, + const Vec512<int16_t> bits) { + return Vec512<int16_t>{_mm512_srav_epi16(v.raw, bits.raw)}; +} + +HWY_API Vec512<int32_t> operator>>(const Vec512<int32_t> v, + const Vec512<int32_t> bits) { + return Vec512<int32_t>{_mm512_srav_epi32(v.raw, bits.raw)}; +} + +HWY_API Vec512<int64_t> operator>>(const Vec512<int64_t> v, + const Vec512<int64_t> bits) { + return Vec512<int64_t>{_mm512_srav_epi64(v.raw, bits.raw)}; +} + +// ------------------------------ Minimum + +// Unsigned +HWY_API Vec512<uint8_t> Min(const Vec512<uint8_t> a, const Vec512<uint8_t> b) { + return Vec512<uint8_t>{_mm512_min_epu8(a.raw, b.raw)}; +} +HWY_API Vec512<uint16_t> Min(const Vec512<uint16_t> a, + const Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_min_epu16(a.raw, b.raw)}; +} +HWY_API Vec512<uint32_t> Min(const Vec512<uint32_t> a, + const Vec512<uint32_t> b) { + return Vec512<uint32_t>{_mm512_min_epu32(a.raw, b.raw)}; +} +HWY_API Vec512<uint64_t> Min(const Vec512<uint64_t> a, + const Vec512<uint64_t> b) { + return Vec512<uint64_t>{_mm512_min_epu64(a.raw, b.raw)}; +} + +// Signed +HWY_API Vec512<int8_t> Min(const Vec512<int8_t> a, const Vec512<int8_t> b) { + return Vec512<int8_t>{_mm512_min_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<int16_t> Min(const Vec512<int16_t> a, const Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_min_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<int32_t> Min(const Vec512<int32_t> a, const Vec512<int32_t> b) { + return Vec512<int32_t>{_mm512_min_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<int64_t> Min(const Vec512<int64_t> a, const Vec512<int64_t> b) { + return Vec512<int64_t>{_mm512_min_epi64(a.raw, b.raw)}; +} + +// Float +HWY_API Vec512<float> Min(const Vec512<float> a, const Vec512<float> b) { + return Vec512<float>{_mm512_min_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> Min(const Vec512<double> a, const Vec512<double> b) { + return Vec512<double>{_mm512_min_pd(a.raw, b.raw)}; +} + +// ------------------------------ Maximum + +// Unsigned +HWY_API Vec512<uint8_t> Max(const Vec512<uint8_t> a, const Vec512<uint8_t> b) { + return Vec512<uint8_t>{_mm512_max_epu8(a.raw, b.raw)}; +} +HWY_API Vec512<uint16_t> Max(const Vec512<uint16_t> a, + const Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_max_epu16(a.raw, b.raw)}; +} +HWY_API Vec512<uint32_t> Max(const Vec512<uint32_t> a, + const Vec512<uint32_t> b) { + return Vec512<uint32_t>{_mm512_max_epu32(a.raw, b.raw)}; +} +HWY_API Vec512<uint64_t> Max(const Vec512<uint64_t> a, + const Vec512<uint64_t> b) { + return Vec512<uint64_t>{_mm512_max_epu64(a.raw, b.raw)}; +} + +// Signed +HWY_API Vec512<int8_t> Max(const Vec512<int8_t> a, const Vec512<int8_t> b) { + return Vec512<int8_t>{_mm512_max_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<int16_t> Max(const Vec512<int16_t> a, const Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_max_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<int32_t> Max(const Vec512<int32_t> a, const Vec512<int32_t> b) { + return Vec512<int32_t>{_mm512_max_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<int64_t> Max(const Vec512<int64_t> a, const Vec512<int64_t> b) { + return Vec512<int64_t>{_mm512_max_epi64(a.raw, b.raw)}; +} + +// Float +HWY_API Vec512<float> Max(const Vec512<float> a, const Vec512<float> b) { + return Vec512<float>{_mm512_max_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> Max(const Vec512<double> a, const Vec512<double> b) { + return Vec512<double>{_mm512_max_pd(a.raw, b.raw)}; +} + +// ------------------------------ Integer multiplication + +// Unsigned +HWY_API Vec512<uint16_t> operator*(Vec512<uint16_t> a, Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_mullo_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<uint32_t> operator*(Vec512<uint32_t> a, Vec512<uint32_t> b) { + return Vec512<uint32_t>{_mm512_mullo_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<uint64_t> operator*(Vec512<uint64_t> a, Vec512<uint64_t> b) { + return Vec512<uint64_t>{_mm512_mullo_epi64(a.raw, b.raw)}; +} +HWY_API Vec256<uint64_t> operator*(Vec256<uint64_t> a, Vec256<uint64_t> b) { + return Vec256<uint64_t>{_mm256_mullo_epi64(a.raw, b.raw)}; +} +HWY_API Vec128<uint64_t> operator*(Vec128<uint64_t> a, Vec128<uint64_t> b) { + return Vec128<uint64_t>{_mm_mullo_epi64(a.raw, b.raw)}; +} + +// Per-target flag to prevent generic_ops-inl.h from defining i64 operator*. +#ifdef HWY_NATIVE_I64MULLO +#undef HWY_NATIVE_I64MULLO +#else +#define HWY_NATIVE_I64MULLO +#endif + +// Signed +HWY_API Vec512<int16_t> operator*(Vec512<int16_t> a, Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_mullo_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<int32_t> operator*(Vec512<int32_t> a, Vec512<int32_t> b) { + return Vec512<int32_t>{_mm512_mullo_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<int64_t> operator*(Vec512<int64_t> a, Vec512<int64_t> b) { + return Vec512<int64_t>{_mm512_mullo_epi64(a.raw, b.raw)}; +} +HWY_API Vec256<int64_t> operator*(Vec256<int64_t> a, Vec256<int64_t> b) { + return Vec256<int64_t>{_mm256_mullo_epi64(a.raw, b.raw)}; +} +HWY_API Vec128<int64_t> operator*(Vec128<int64_t> a, Vec128<int64_t> b) { + return Vec128<int64_t>{_mm_mullo_epi64(a.raw, b.raw)}; +} +// Returns the upper 16 bits of a * b in each lane. +HWY_API Vec512<uint16_t> MulHigh(Vec512<uint16_t> a, Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_mulhi_epu16(a.raw, b.raw)}; +} +HWY_API Vec512<int16_t> MulHigh(Vec512<int16_t> a, Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_mulhi_epi16(a.raw, b.raw)}; +} + +HWY_API Vec512<int16_t> MulFixedPoint15(Vec512<int16_t> a, Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_mulhrs_epi16(a.raw, b.raw)}; +} + +// Multiplies even lanes (0, 2 ..) and places the double-wide result into +// even and the upper half into its odd neighbor lane. +HWY_API Vec512<int64_t> MulEven(Vec512<int32_t> a, Vec512<int32_t> b) { + return Vec512<int64_t>{_mm512_mul_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<uint64_t> MulEven(Vec512<uint32_t> a, Vec512<uint32_t> b) { + return Vec512<uint64_t>{_mm512_mul_epu32(a.raw, b.raw)}; +} + +// ------------------------------ Neg (Sub) + +template <typename T, HWY_IF_FLOAT(T)> +HWY_API Vec512<T> Neg(const Vec512<T> v) { + return Xor(v, SignBit(Full512<T>())); +} + +template <typename T, HWY_IF_NOT_FLOAT(T)> +HWY_API Vec512<T> Neg(const Vec512<T> v) { + return Zero(Full512<T>()) - v; +} + +// ------------------------------ Floating-point mul / div + +HWY_API Vec512<float> operator*(const Vec512<float> a, const Vec512<float> b) { + return Vec512<float>{_mm512_mul_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> operator*(const Vec512<double> a, + const Vec512<double> b) { + return Vec512<double>{_mm512_mul_pd(a.raw, b.raw)}; +} + +HWY_API Vec512<float> operator/(const Vec512<float> a, const Vec512<float> b) { + return Vec512<float>{_mm512_div_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> operator/(const Vec512<double> a, + const Vec512<double> b) { + return Vec512<double>{_mm512_div_pd(a.raw, b.raw)}; +} + +// Approximate reciprocal +HWY_API Vec512<float> ApproximateReciprocal(const Vec512<float> v) { + return Vec512<float>{_mm512_rcp14_ps(v.raw)}; +} + +// Absolute value of difference. +HWY_API Vec512<float> AbsDiff(const Vec512<float> a, const Vec512<float> b) { + return Abs(a - b); +} + +// ------------------------------ Floating-point multiply-add variants + +// Returns mul * x + add +HWY_API Vec512<float> MulAdd(const Vec512<float> mul, const Vec512<float> x, + const Vec512<float> add) { + return Vec512<float>{_mm512_fmadd_ps(mul.raw, x.raw, add.raw)}; +} +HWY_API Vec512<double> MulAdd(const Vec512<double> mul, const Vec512<double> x, + const Vec512<double> add) { + return Vec512<double>{_mm512_fmadd_pd(mul.raw, x.raw, add.raw)}; +} + +// Returns add - mul * x +HWY_API Vec512<float> NegMulAdd(const Vec512<float> mul, const Vec512<float> x, + const Vec512<float> add) { + return Vec512<float>{_mm512_fnmadd_ps(mul.raw, x.raw, add.raw)}; +} +HWY_API Vec512<double> NegMulAdd(const Vec512<double> mul, + const Vec512<double> x, + const Vec512<double> add) { + return Vec512<double>{_mm512_fnmadd_pd(mul.raw, x.raw, add.raw)}; +} + +// Returns mul * x - sub +HWY_API Vec512<float> MulSub(const Vec512<float> mul, const Vec512<float> x, + const Vec512<float> sub) { + return Vec512<float>{_mm512_fmsub_ps(mul.raw, x.raw, sub.raw)}; +} +HWY_API Vec512<double> MulSub(const Vec512<double> mul, const Vec512<double> x, + const Vec512<double> sub) { + return Vec512<double>{_mm512_fmsub_pd(mul.raw, x.raw, sub.raw)}; +} + +// Returns -mul * x - sub +HWY_API Vec512<float> NegMulSub(const Vec512<float> mul, const Vec512<float> x, + const Vec512<float> sub) { + return Vec512<float>{_mm512_fnmsub_ps(mul.raw, x.raw, sub.raw)}; +} +HWY_API Vec512<double> NegMulSub(const Vec512<double> mul, + const Vec512<double> x, + const Vec512<double> sub) { + return Vec512<double>{_mm512_fnmsub_pd(mul.raw, x.raw, sub.raw)}; +} + +// ------------------------------ Floating-point square root + +// Full precision square root +HWY_API Vec512<float> Sqrt(const Vec512<float> v) { + return Vec512<float>{_mm512_sqrt_ps(v.raw)}; +} +HWY_API Vec512<double> Sqrt(const Vec512<double> v) { + return Vec512<double>{_mm512_sqrt_pd(v.raw)}; +} + +// Approximate reciprocal square root +HWY_API Vec512<float> ApproximateReciprocalSqrt(const Vec512<float> v) { + return Vec512<float>{_mm512_rsqrt14_ps(v.raw)}; +} + +// ------------------------------ Floating-point rounding + +// Work around warnings in the intrinsic definitions (passing -1 as a mask). +HWY_DIAGNOSTICS(push) +HWY_DIAGNOSTICS_OFF(disable : 4245 4365, ignored "-Wsign-conversion") + +// Toward nearest integer, tie to even +HWY_API Vec512<float> Round(const Vec512<float> v) { + return Vec512<float>{_mm512_roundscale_ps( + v.raw, _MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)}; +} +HWY_API Vec512<double> Round(const Vec512<double> v) { + return Vec512<double>{_mm512_roundscale_pd( + v.raw, _MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)}; +} + +// Toward zero, aka truncate +HWY_API Vec512<float> Trunc(const Vec512<float> v) { + return Vec512<float>{ + _mm512_roundscale_ps(v.raw, _MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)}; +} +HWY_API Vec512<double> Trunc(const Vec512<double> v) { + return Vec512<double>{ + _mm512_roundscale_pd(v.raw, _MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)}; +} + +// Toward +infinity, aka ceiling +HWY_API Vec512<float> Ceil(const Vec512<float> v) { + return Vec512<float>{ + _mm512_roundscale_ps(v.raw, _MM_FROUND_TO_POS_INF | _MM_FROUND_NO_EXC)}; +} +HWY_API Vec512<double> Ceil(const Vec512<double> v) { + return Vec512<double>{ + _mm512_roundscale_pd(v.raw, _MM_FROUND_TO_POS_INF | _MM_FROUND_NO_EXC)}; +} + +// Toward -infinity, aka floor +HWY_API Vec512<float> Floor(const Vec512<float> v) { + return Vec512<float>{ + _mm512_roundscale_ps(v.raw, _MM_FROUND_TO_NEG_INF | _MM_FROUND_NO_EXC)}; +} +HWY_API Vec512<double> Floor(const Vec512<double> v) { + return Vec512<double>{ + _mm512_roundscale_pd(v.raw, _MM_FROUND_TO_NEG_INF | _MM_FROUND_NO_EXC)}; +} + +HWY_DIAGNOSTICS(pop) + +// ================================================== COMPARE + +// Comparisons set a mask bit to 1 if the condition is true, else 0. + +template <typename TFrom, typename TTo> +HWY_API Mask512<TTo> RebindMask(Full512<TTo> /*tag*/, Mask512<TFrom> m) { + static_assert(sizeof(TFrom) == sizeof(TTo), "Must have same size"); + return Mask512<TTo>{m.raw}; +} + +namespace detail { + +template <typename T> +HWY_INLINE Mask512<T> TestBit(hwy::SizeTag<1> /*tag*/, const Vec512<T> v, + const Vec512<T> bit) { + return Mask512<T>{_mm512_test_epi8_mask(v.raw, bit.raw)}; +} +template <typename T> +HWY_INLINE Mask512<T> TestBit(hwy::SizeTag<2> /*tag*/, const Vec512<T> v, + const Vec512<T> bit) { + return Mask512<T>{_mm512_test_epi16_mask(v.raw, bit.raw)}; +} +template <typename T> +HWY_INLINE Mask512<T> TestBit(hwy::SizeTag<4> /*tag*/, const Vec512<T> v, + const Vec512<T> bit) { + return Mask512<T>{_mm512_test_epi32_mask(v.raw, bit.raw)}; +} +template <typename T> +HWY_INLINE Mask512<T> TestBit(hwy::SizeTag<8> /*tag*/, const Vec512<T> v, + const Vec512<T> bit) { + return Mask512<T>{_mm512_test_epi64_mask(v.raw, bit.raw)}; +} + +} // namespace detail + +template <typename T> +HWY_API Mask512<T> TestBit(const Vec512<T> v, const Vec512<T> bit) { + static_assert(!hwy::IsFloat<T>(), "Only integer vectors supported"); + return detail::TestBit(hwy::SizeTag<sizeof(T)>(), v, bit); +} + +// ------------------------------ Equality + +template <typename T, HWY_IF_LANE_SIZE(T, 1)> +HWY_API Mask512<T> operator==(Vec512<T> a, Vec512<T> b) { + return Mask512<T>{_mm512_cmpeq_epi8_mask(a.raw, b.raw)}; +} +template <typename T, HWY_IF_LANE_SIZE(T, 2)> +HWY_API Mask512<T> operator==(Vec512<T> a, Vec512<T> b) { + return Mask512<T>{_mm512_cmpeq_epi16_mask(a.raw, b.raw)}; +} +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Mask512<T> operator==(Vec512<T> a, Vec512<T> b) { + return Mask512<T>{_mm512_cmpeq_epi32_mask(a.raw, b.raw)}; +} +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Mask512<T> operator==(Vec512<T> a, Vec512<T> b) { + return Mask512<T>{_mm512_cmpeq_epi64_mask(a.raw, b.raw)}; +} + +HWY_API Mask512<float> operator==(Vec512<float> a, Vec512<float> b) { + return Mask512<float>{_mm512_cmp_ps_mask(a.raw, b.raw, _CMP_EQ_OQ)}; +} + +HWY_API Mask512<double> operator==(Vec512<double> a, Vec512<double> b) { + return Mask512<double>{_mm512_cmp_pd_mask(a.raw, b.raw, _CMP_EQ_OQ)}; +} + +// ------------------------------ Inequality + +template <typename T, HWY_IF_LANE_SIZE(T, 1)> +HWY_API Mask512<T> operator!=(Vec512<T> a, Vec512<T> b) { + return Mask512<T>{_mm512_cmpneq_epi8_mask(a.raw, b.raw)}; +} +template <typename T, HWY_IF_LANE_SIZE(T, 2)> +HWY_API Mask512<T> operator!=(Vec512<T> a, Vec512<T> b) { + return Mask512<T>{_mm512_cmpneq_epi16_mask(a.raw, b.raw)}; +} +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Mask512<T> operator!=(Vec512<T> a, Vec512<T> b) { + return Mask512<T>{_mm512_cmpneq_epi32_mask(a.raw, b.raw)}; +} +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Mask512<T> operator!=(Vec512<T> a, Vec512<T> b) { + return Mask512<T>{_mm512_cmpneq_epi64_mask(a.raw, b.raw)}; +} + +HWY_API Mask512<float> operator!=(Vec512<float> a, Vec512<float> b) { + return Mask512<float>{_mm512_cmp_ps_mask(a.raw, b.raw, _CMP_NEQ_OQ)}; +} + +HWY_API Mask512<double> operator!=(Vec512<double> a, Vec512<double> b) { + return Mask512<double>{_mm512_cmp_pd_mask(a.raw, b.raw, _CMP_NEQ_OQ)}; +} + +// ------------------------------ Strict inequality + +HWY_API Mask512<uint8_t> operator>(Vec512<uint8_t> a, Vec512<uint8_t> b) { + return Mask512<uint8_t>{_mm512_cmpgt_epu8_mask(a.raw, b.raw)}; +} +HWY_API Mask512<uint16_t> operator>(Vec512<uint16_t> a, Vec512<uint16_t> b) { + return Mask512<uint16_t>{_mm512_cmpgt_epu16_mask(a.raw, b.raw)}; +} +HWY_API Mask512<uint32_t> operator>(Vec512<uint32_t> a, Vec512<uint32_t> b) { + return Mask512<uint32_t>{_mm512_cmpgt_epu32_mask(a.raw, b.raw)}; +} +HWY_API Mask512<uint64_t> operator>(Vec512<uint64_t> a, Vec512<uint64_t> b) { + return Mask512<uint64_t>{_mm512_cmpgt_epu64_mask(a.raw, b.raw)}; +} + +HWY_API Mask512<int8_t> operator>(Vec512<int8_t> a, Vec512<int8_t> b) { + return Mask512<int8_t>{_mm512_cmpgt_epi8_mask(a.raw, b.raw)}; +} +HWY_API Mask512<int16_t> operator>(Vec512<int16_t> a, Vec512<int16_t> b) { + return Mask512<int16_t>{_mm512_cmpgt_epi16_mask(a.raw, b.raw)}; +} +HWY_API Mask512<int32_t> operator>(Vec512<int32_t> a, Vec512<int32_t> b) { + return Mask512<int32_t>{_mm512_cmpgt_epi32_mask(a.raw, b.raw)}; +} +HWY_API Mask512<int64_t> operator>(Vec512<int64_t> a, Vec512<int64_t> b) { + return Mask512<int64_t>{_mm512_cmpgt_epi64_mask(a.raw, b.raw)}; +} + +HWY_API Mask512<float> operator>(Vec512<float> a, Vec512<float> b) { + return Mask512<float>{_mm512_cmp_ps_mask(a.raw, b.raw, _CMP_GT_OQ)}; +} +HWY_API Mask512<double> operator>(Vec512<double> a, Vec512<double> b) { + return Mask512<double>{_mm512_cmp_pd_mask(a.raw, b.raw, _CMP_GT_OQ)}; +} + +// ------------------------------ Weak inequality + +HWY_API Mask512<float> operator>=(Vec512<float> a, Vec512<float> b) { + return Mask512<float>{_mm512_cmp_ps_mask(a.raw, b.raw, _CMP_GE_OQ)}; +} +HWY_API Mask512<double> operator>=(Vec512<double> a, Vec512<double> b) { + return Mask512<double>{_mm512_cmp_pd_mask(a.raw, b.raw, _CMP_GE_OQ)}; +} + +// ------------------------------ Reversed comparisons + +template <typename T> +HWY_API Mask512<T> operator<(Vec512<T> a, Vec512<T> b) { + return b > a; +} + +template <typename T> +HWY_API Mask512<T> operator<=(Vec512<T> a, Vec512<T> b) { + return b >= a; +} + +// ------------------------------ Mask + +namespace detail { + +template <typename T> +HWY_INLINE Mask512<T> MaskFromVec(hwy::SizeTag<1> /*tag*/, const Vec512<T> v) { + return Mask512<T>{_mm512_movepi8_mask(v.raw)}; +} +template <typename T> +HWY_INLINE Mask512<T> MaskFromVec(hwy::SizeTag<2> /*tag*/, const Vec512<T> v) { + return Mask512<T>{_mm512_movepi16_mask(v.raw)}; +} +template <typename T> +HWY_INLINE Mask512<T> MaskFromVec(hwy::SizeTag<4> /*tag*/, const Vec512<T> v) { + return Mask512<T>{_mm512_movepi32_mask(v.raw)}; +} +template <typename T> +HWY_INLINE Mask512<T> MaskFromVec(hwy::SizeTag<8> /*tag*/, const Vec512<T> v) { + return Mask512<T>{_mm512_movepi64_mask(v.raw)}; +} + +} // namespace detail + +template <typename T> +HWY_API Mask512<T> MaskFromVec(const Vec512<T> v) { + return detail::MaskFromVec(hwy::SizeTag<sizeof(T)>(), v); +} +// There do not seem to be native floating-point versions of these instructions. +HWY_API Mask512<float> MaskFromVec(const Vec512<float> v) { + return Mask512<float>{MaskFromVec(BitCast(Full512<int32_t>(), v)).raw}; +} +HWY_API Mask512<double> MaskFromVec(const Vec512<double> v) { + return Mask512<double>{MaskFromVec(BitCast(Full512<int64_t>(), v)).raw}; +} + +HWY_API Vec512<uint8_t> VecFromMask(const Mask512<uint8_t> v) { + return Vec512<uint8_t>{_mm512_movm_epi8(v.raw)}; +} +HWY_API Vec512<int8_t> VecFromMask(const Mask512<int8_t> v) { + return Vec512<int8_t>{_mm512_movm_epi8(v.raw)}; +} + +HWY_API Vec512<uint16_t> VecFromMask(const Mask512<uint16_t> v) { + return Vec512<uint16_t>{_mm512_movm_epi16(v.raw)}; +} +HWY_API Vec512<int16_t> VecFromMask(const Mask512<int16_t> v) { + return Vec512<int16_t>{_mm512_movm_epi16(v.raw)}; +} + +HWY_API Vec512<uint32_t> VecFromMask(const Mask512<uint32_t> v) { + return Vec512<uint32_t>{_mm512_movm_epi32(v.raw)}; +} +HWY_API Vec512<int32_t> VecFromMask(const Mask512<int32_t> v) { + return Vec512<int32_t>{_mm512_movm_epi32(v.raw)}; +} +HWY_API Vec512<float> VecFromMask(const Mask512<float> v) { + return Vec512<float>{_mm512_castsi512_ps(_mm512_movm_epi32(v.raw))}; +} + +HWY_API Vec512<uint64_t> VecFromMask(const Mask512<uint64_t> v) { + return Vec512<uint64_t>{_mm512_movm_epi64(v.raw)}; +} +HWY_API Vec512<int64_t> VecFromMask(const Mask512<int64_t> v) { + return Vec512<int64_t>{_mm512_movm_epi64(v.raw)}; +} +HWY_API Vec512<double> VecFromMask(const Mask512<double> v) { + return Vec512<double>{_mm512_castsi512_pd(_mm512_movm_epi64(v.raw))}; +} + +template <typename T> +HWY_API Vec512<T> VecFromMask(Full512<T> /* tag */, const Mask512<T> v) { + return VecFromMask(v); +} + +// ------------------------------ Mask logical + +namespace detail { + +template <typename T> +HWY_INLINE Mask512<T> Not(hwy::SizeTag<1> /*tag*/, const Mask512<T> m) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_knot_mask64(m.raw)}; +#else + return Mask512<T>{~m.raw}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> Not(hwy::SizeTag<2> /*tag*/, const Mask512<T> m) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_knot_mask32(m.raw)}; +#else + return Mask512<T>{~m.raw}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> Not(hwy::SizeTag<4> /*tag*/, const Mask512<T> m) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_knot_mask16(m.raw)}; +#else + return Mask512<T>{static_cast<uint16_t>(~m.raw & 0xFFFF)}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> Not(hwy::SizeTag<8> /*tag*/, const Mask512<T> m) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_knot_mask8(m.raw)}; +#else + return Mask512<T>{static_cast<uint8_t>(~m.raw & 0xFF)}; +#endif +} + +template <typename T> +HWY_INLINE Mask512<T> And(hwy::SizeTag<1> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kand_mask64(a.raw, b.raw)}; +#else + return Mask512<T>{a.raw & b.raw}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> And(hwy::SizeTag<2> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kand_mask32(a.raw, b.raw)}; +#else + return Mask512<T>{a.raw & b.raw}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> And(hwy::SizeTag<4> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kand_mask16(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<uint16_t>(a.raw & b.raw)}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> And(hwy::SizeTag<8> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kand_mask8(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<uint8_t>(a.raw & b.raw)}; +#endif +} + +template <typename T> +HWY_INLINE Mask512<T> AndNot(hwy::SizeTag<1> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kandn_mask64(a.raw, b.raw)}; +#else + return Mask512<T>{~a.raw & b.raw}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> AndNot(hwy::SizeTag<2> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kandn_mask32(a.raw, b.raw)}; +#else + return Mask512<T>{~a.raw & b.raw}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> AndNot(hwy::SizeTag<4> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kandn_mask16(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<uint16_t>(~a.raw & b.raw)}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> AndNot(hwy::SizeTag<8> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kandn_mask8(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<uint8_t>(~a.raw & b.raw)}; +#endif +} + +template <typename T> +HWY_INLINE Mask512<T> Or(hwy::SizeTag<1> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kor_mask64(a.raw, b.raw)}; +#else + return Mask512<T>{a.raw | b.raw}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> Or(hwy::SizeTag<2> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kor_mask32(a.raw, b.raw)}; +#else + return Mask512<T>{a.raw | b.raw}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> Or(hwy::SizeTag<4> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kor_mask16(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<uint16_t>(a.raw | b.raw)}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> Or(hwy::SizeTag<8> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kor_mask8(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<uint8_t>(a.raw | b.raw)}; +#endif +} + +template <typename T> +HWY_INLINE Mask512<T> Xor(hwy::SizeTag<1> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kxor_mask64(a.raw, b.raw)}; +#else + return Mask512<T>{a.raw ^ b.raw}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> Xor(hwy::SizeTag<2> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kxor_mask32(a.raw, b.raw)}; +#else + return Mask512<T>{a.raw ^ b.raw}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> Xor(hwy::SizeTag<4> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kxor_mask16(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<uint16_t>(a.raw ^ b.raw)}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> Xor(hwy::SizeTag<8> /*tag*/, const Mask512<T> a, + const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kxor_mask8(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<uint8_t>(a.raw ^ b.raw)}; +#endif +} + +template <typename T> +HWY_INLINE Mask512<T> ExclusiveNeither(hwy::SizeTag<1> /*tag*/, + const Mask512<T> a, const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kxnor_mask64(a.raw, b.raw)}; +#else + return Mask512<T>{~(a.raw ^ b.raw)}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> ExclusiveNeither(hwy::SizeTag<2> /*tag*/, + const Mask512<T> a, const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kxnor_mask32(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<__mmask32>(~(a.raw ^ b.raw) & 0xFFFFFFFF)}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> ExclusiveNeither(hwy::SizeTag<4> /*tag*/, + const Mask512<T> a, const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kxnor_mask16(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<__mmask16>(~(a.raw ^ b.raw) & 0xFFFF)}; +#endif +} +template <typename T> +HWY_INLINE Mask512<T> ExclusiveNeither(hwy::SizeTag<8> /*tag*/, + const Mask512<T> a, const Mask512<T> b) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return Mask512<T>{_kxnor_mask8(a.raw, b.raw)}; +#else + return Mask512<T>{static_cast<__mmask8>(~(a.raw ^ b.raw) & 0xFF)}; +#endif +} + +} // namespace detail + +template <typename T> +HWY_API Mask512<T> Not(const Mask512<T> m) { + return detail::Not(hwy::SizeTag<sizeof(T)>(), m); +} + +template <typename T> +HWY_API Mask512<T> And(const Mask512<T> a, Mask512<T> b) { + return detail::And(hwy::SizeTag<sizeof(T)>(), a, b); +} + +template <typename T> +HWY_API Mask512<T> AndNot(const Mask512<T> a, Mask512<T> b) { + return detail::AndNot(hwy::SizeTag<sizeof(T)>(), a, b); +} + +template <typename T> +HWY_API Mask512<T> Or(const Mask512<T> a, Mask512<T> b) { + return detail::Or(hwy::SizeTag<sizeof(T)>(), a, b); +} + +template <typename T> +HWY_API Mask512<T> Xor(const Mask512<T> a, Mask512<T> b) { + return detail::Xor(hwy::SizeTag<sizeof(T)>(), a, b); +} + +template <typename T> +HWY_API Mask512<T> ExclusiveNeither(const Mask512<T> a, Mask512<T> b) { + return detail::ExclusiveNeither(hwy::SizeTag<sizeof(T)>(), a, b); +} + +// ------------------------------ BroadcastSignBit (ShiftRight, compare, mask) + +HWY_API Vec512<int8_t> BroadcastSignBit(const Vec512<int8_t> v) { + return VecFromMask(v < Zero(Full512<int8_t>())); +} + +HWY_API Vec512<int16_t> BroadcastSignBit(const Vec512<int16_t> v) { + return ShiftRight<15>(v); +} + +HWY_API Vec512<int32_t> BroadcastSignBit(const Vec512<int32_t> v) { + return ShiftRight<31>(v); +} + +HWY_API Vec512<int64_t> BroadcastSignBit(const Vec512<int64_t> v) { + return Vec512<int64_t>{_mm512_srai_epi64(v.raw, 63)}; +} + +// ------------------------------ Floating-point classification (Not) + +HWY_API Mask512<float> IsNaN(const Vec512<float> v) { + return Mask512<float>{_mm512_fpclass_ps_mask(v.raw, 0x81)}; +} +HWY_API Mask512<double> IsNaN(const Vec512<double> v) { + return Mask512<double>{_mm512_fpclass_pd_mask(v.raw, 0x81)}; +} + +HWY_API Mask512<float> IsInf(const Vec512<float> v) { + return Mask512<float>{_mm512_fpclass_ps_mask(v.raw, 0x18)}; +} +HWY_API Mask512<double> IsInf(const Vec512<double> v) { + return Mask512<double>{_mm512_fpclass_pd_mask(v.raw, 0x18)}; +} + +// Returns whether normal/subnormal/zero. fpclass doesn't have a flag for +// positive, so we have to check for inf/NaN and negate. +HWY_API Mask512<float> IsFinite(const Vec512<float> v) { + return Not(Mask512<float>{_mm512_fpclass_ps_mask(v.raw, 0x99)}); +} +HWY_API Mask512<double> IsFinite(const Vec512<double> v) { + return Not(Mask512<double>{_mm512_fpclass_pd_mask(v.raw, 0x99)}); +} + +// ================================================== MEMORY + +// ------------------------------ Load + +template <typename T> +HWY_API Vec512<T> Load(Full512<T> /* tag */, const T* HWY_RESTRICT aligned) { + return Vec512<T>{_mm512_load_si512(aligned)}; +} +HWY_API Vec512<float> Load(Full512<float> /* tag */, + const float* HWY_RESTRICT aligned) { + return Vec512<float>{_mm512_load_ps(aligned)}; +} +HWY_API Vec512<double> Load(Full512<double> /* tag */, + const double* HWY_RESTRICT aligned) { + return Vec512<double>{_mm512_load_pd(aligned)}; +} + +template <typename T> +HWY_API Vec512<T> LoadU(Full512<T> /* tag */, const T* HWY_RESTRICT p) { + return Vec512<T>{_mm512_loadu_si512(p)}; +} +HWY_API Vec512<float> LoadU(Full512<float> /* tag */, + const float* HWY_RESTRICT p) { + return Vec512<float>{_mm512_loadu_ps(p)}; +} +HWY_API Vec512<double> LoadU(Full512<double> /* tag */, + const double* HWY_RESTRICT p) { + return Vec512<double>{_mm512_loadu_pd(p)}; +} + +// ------------------------------ MaskedLoad + +template <typename T, HWY_IF_LANE_SIZE(T, 1)> +HWY_API Vec512<T> MaskedLoad(Mask512<T> m, Full512<T> /* tag */, + const T* HWY_RESTRICT p) { + return Vec512<T>{_mm512_maskz_loadu_epi8(m.raw, p)}; +} + +template <typename T, HWY_IF_LANE_SIZE(T, 2)> +HWY_API Vec512<T> MaskedLoad(Mask512<T> m, Full512<T> /* tag */, + const T* HWY_RESTRICT p) { + return Vec512<T>{_mm512_maskz_loadu_epi16(m.raw, p)}; +} + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> MaskedLoad(Mask512<T> m, Full512<T> /* tag */, + const T* HWY_RESTRICT p) { + return Vec512<T>{_mm512_maskz_loadu_epi32(m.raw, p)}; +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> MaskedLoad(Mask512<T> m, Full512<T> /* tag */, + const T* HWY_RESTRICT p) { + return Vec512<T>{_mm512_maskz_loadu_epi64(m.raw, p)}; +} + +HWY_API Vec512<float> MaskedLoad(Mask512<float> m, Full512<float> /* tag */, + const float* HWY_RESTRICT p) { + return Vec512<float>{_mm512_maskz_loadu_ps(m.raw, p)}; +} + +HWY_API Vec512<double> MaskedLoad(Mask512<double> m, Full512<double> /* tag */, + const double* HWY_RESTRICT p) { + return Vec512<double>{_mm512_maskz_loadu_pd(m.raw, p)}; +} + +// ------------------------------ LoadDup128 + +// Loads 128 bit and duplicates into both 128-bit halves. This avoids the +// 3-cycle cost of moving data between 128-bit halves and avoids port 5. +template <typename T> +HWY_API Vec512<T> LoadDup128(Full512<T> /* tag */, + const T* const HWY_RESTRICT p) { + const auto x4 = LoadU(Full128<T>(), p); + return Vec512<T>{_mm512_broadcast_i32x4(x4.raw)}; +} +HWY_API Vec512<float> LoadDup128(Full512<float> /* tag */, + const float* const HWY_RESTRICT p) { + const __m128 x4 = _mm_loadu_ps(p); + return Vec512<float>{_mm512_broadcast_f32x4(x4)}; +} + +HWY_API Vec512<double> LoadDup128(Full512<double> /* tag */, + const double* const HWY_RESTRICT p) { + const __m128d x2 = _mm_loadu_pd(p); + return Vec512<double>{_mm512_broadcast_f64x2(x2)}; +} + +// ------------------------------ Store + +template <typename T> +HWY_API void Store(const Vec512<T> v, Full512<T> /* tag */, + T* HWY_RESTRICT aligned) { + _mm512_store_si512(reinterpret_cast<__m512i*>(aligned), v.raw); +} +HWY_API void Store(const Vec512<float> v, Full512<float> /* tag */, + float* HWY_RESTRICT aligned) { + _mm512_store_ps(aligned, v.raw); +} +HWY_API void Store(const Vec512<double> v, Full512<double> /* tag */, + double* HWY_RESTRICT aligned) { + _mm512_store_pd(aligned, v.raw); +} + +template <typename T> +HWY_API void StoreU(const Vec512<T> v, Full512<T> /* tag */, + T* HWY_RESTRICT p) { + _mm512_storeu_si512(reinterpret_cast<__m512i*>(p), v.raw); +} +HWY_API void StoreU(const Vec512<float> v, Full512<float> /* tag */, + float* HWY_RESTRICT p) { + _mm512_storeu_ps(p, v.raw); +} +HWY_API void StoreU(const Vec512<double> v, Full512<double>, + double* HWY_RESTRICT p) { + _mm512_storeu_pd(p, v.raw); +} + +// ------------------------------ BlendedStore + +template <typename T, HWY_IF_LANE_SIZE(T, 1)> +HWY_API void BlendedStore(Vec512<T> v, Mask512<T> m, Full512<T> /* tag */, + T* HWY_RESTRICT p) { + _mm512_mask_storeu_epi8(p, m.raw, v.raw); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 2)> +HWY_API void BlendedStore(Vec512<T> v, Mask512<T> m, Full512<T> /* tag */, + T* HWY_RESTRICT p) { + _mm512_mask_storeu_epi16(p, m.raw, v.raw); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API void BlendedStore(Vec512<T> v, Mask512<T> m, Full512<T> /* tag */, + T* HWY_RESTRICT p) { + _mm512_mask_storeu_epi32(p, m.raw, v.raw); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API void BlendedStore(Vec512<T> v, Mask512<T> m, Full512<T> /* tag */, + T* HWY_RESTRICT p) { + _mm512_mask_storeu_epi64(p, m.raw, v.raw); +} + +HWY_API void BlendedStore(Vec512<float> v, Mask512<float> m, + Full512<float> /* tag */, float* HWY_RESTRICT p) { + _mm512_mask_storeu_ps(p, m.raw, v.raw); +} + +HWY_API void BlendedStore(Vec512<double> v, Mask512<double> m, + Full512<double> /* tag */, double* HWY_RESTRICT p) { + _mm512_mask_storeu_pd(p, m.raw, v.raw); +} + +// ------------------------------ Non-temporal stores + +template <typename T> +HWY_API void Stream(const Vec512<T> v, Full512<T> /* tag */, + T* HWY_RESTRICT aligned) { + _mm512_stream_si512(reinterpret_cast<__m512i*>(aligned), v.raw); +} +HWY_API void Stream(const Vec512<float> v, Full512<float> /* tag */, + float* HWY_RESTRICT aligned) { + _mm512_stream_ps(aligned, v.raw); +} +HWY_API void Stream(const Vec512<double> v, Full512<double>, + double* HWY_RESTRICT aligned) { + _mm512_stream_pd(aligned, v.raw); +} + +// ------------------------------ Scatter + +// Work around warnings in the intrinsic definitions (passing -1 as a mask). +HWY_DIAGNOSTICS(push) +HWY_DIAGNOSTICS_OFF(disable : 4245 4365, ignored "-Wsign-conversion") + +namespace detail { + +template <typename T> +HWY_INLINE void ScatterOffset(hwy::SizeTag<4> /* tag */, Vec512<T> v, + Full512<T> /* tag */, T* HWY_RESTRICT base, + const Vec512<int32_t> offset) { + _mm512_i32scatter_epi32(base, offset.raw, v.raw, 1); +} +template <typename T> +HWY_INLINE void ScatterIndex(hwy::SizeTag<4> /* tag */, Vec512<T> v, + Full512<T> /* tag */, T* HWY_RESTRICT base, + const Vec512<int32_t> index) { + _mm512_i32scatter_epi32(base, index.raw, v.raw, 4); +} + +template <typename T> +HWY_INLINE void ScatterOffset(hwy::SizeTag<8> /* tag */, Vec512<T> v, + Full512<T> /* tag */, T* HWY_RESTRICT base, + const Vec512<int64_t> offset) { + _mm512_i64scatter_epi64(base, offset.raw, v.raw, 1); +} +template <typename T> +HWY_INLINE void ScatterIndex(hwy::SizeTag<8> /* tag */, Vec512<T> v, + Full512<T> /* tag */, T* HWY_RESTRICT base, + const Vec512<int64_t> index) { + _mm512_i64scatter_epi64(base, index.raw, v.raw, 8); +} + +} // namespace detail + +template <typename T, typename Offset> +HWY_API void ScatterOffset(Vec512<T> v, Full512<T> d, T* HWY_RESTRICT base, + const Vec512<Offset> offset) { + static_assert(sizeof(T) == sizeof(Offset), "Must match for portability"); + return detail::ScatterOffset(hwy::SizeTag<sizeof(T)>(), v, d, base, offset); +} +template <typename T, typename Index> +HWY_API void ScatterIndex(Vec512<T> v, Full512<T> d, T* HWY_RESTRICT base, + const Vec512<Index> index) { + static_assert(sizeof(T) == sizeof(Index), "Must match for portability"); + return detail::ScatterIndex(hwy::SizeTag<sizeof(T)>(), v, d, base, index); +} + +HWY_API void ScatterOffset(Vec512<float> v, Full512<float> /* tag */, + float* HWY_RESTRICT base, + const Vec512<int32_t> offset) { + _mm512_i32scatter_ps(base, offset.raw, v.raw, 1); +} +HWY_API void ScatterIndex(Vec512<float> v, Full512<float> /* tag */, + float* HWY_RESTRICT base, + const Vec512<int32_t> index) { + _mm512_i32scatter_ps(base, index.raw, v.raw, 4); +} + +HWY_API void ScatterOffset(Vec512<double> v, Full512<double> /* tag */, + double* HWY_RESTRICT base, + const Vec512<int64_t> offset) { + _mm512_i64scatter_pd(base, offset.raw, v.raw, 1); +} +HWY_API void ScatterIndex(Vec512<double> v, Full512<double> /* tag */, + double* HWY_RESTRICT base, + const Vec512<int64_t> index) { + _mm512_i64scatter_pd(base, index.raw, v.raw, 8); +} + +// ------------------------------ Gather + +namespace detail { + +template <typename T> +HWY_INLINE Vec512<T> GatherOffset(hwy::SizeTag<4> /* tag */, + Full512<T> /* tag */, + const T* HWY_RESTRICT base, + const Vec512<int32_t> offset) { + return Vec512<T>{_mm512_i32gather_epi32(offset.raw, base, 1)}; +} +template <typename T> +HWY_INLINE Vec512<T> GatherIndex(hwy::SizeTag<4> /* tag */, + Full512<T> /* tag */, + const T* HWY_RESTRICT base, + const Vec512<int32_t> index) { + return Vec512<T>{_mm512_i32gather_epi32(index.raw, base, 4)}; +} + +template <typename T> +HWY_INLINE Vec512<T> GatherOffset(hwy::SizeTag<8> /* tag */, + Full512<T> /* tag */, + const T* HWY_RESTRICT base, + const Vec512<int64_t> offset) { + return Vec512<T>{_mm512_i64gather_epi64(offset.raw, base, 1)}; +} +template <typename T> +HWY_INLINE Vec512<T> GatherIndex(hwy::SizeTag<8> /* tag */, + Full512<T> /* tag */, + const T* HWY_RESTRICT base, + const Vec512<int64_t> index) { + return Vec512<T>{_mm512_i64gather_epi64(index.raw, base, 8)}; +} + +} // namespace detail + +template <typename T, typename Offset> +HWY_API Vec512<T> GatherOffset(Full512<T> d, const T* HWY_RESTRICT base, + const Vec512<Offset> offset) { + static_assert(sizeof(T) == sizeof(Offset), "Must match for portability"); + return detail::GatherOffset(hwy::SizeTag<sizeof(T)>(), d, base, offset); +} +template <typename T, typename Index> +HWY_API Vec512<T> GatherIndex(Full512<T> d, const T* HWY_RESTRICT base, + const Vec512<Index> index) { + static_assert(sizeof(T) == sizeof(Index), "Must match for portability"); + return detail::GatherIndex(hwy::SizeTag<sizeof(T)>(), d, base, index); +} + +HWY_API Vec512<float> GatherOffset(Full512<float> /* tag */, + const float* HWY_RESTRICT base, + const Vec512<int32_t> offset) { + return Vec512<float>{_mm512_i32gather_ps(offset.raw, base, 1)}; +} +HWY_API Vec512<float> GatherIndex(Full512<float> /* tag */, + const float* HWY_RESTRICT base, + const Vec512<int32_t> index) { + return Vec512<float>{_mm512_i32gather_ps(index.raw, base, 4)}; +} + +HWY_API Vec512<double> GatherOffset(Full512<double> /* tag */, + const double* HWY_RESTRICT base, + const Vec512<int64_t> offset) { + return Vec512<double>{_mm512_i64gather_pd(offset.raw, base, 1)}; +} +HWY_API Vec512<double> GatherIndex(Full512<double> /* tag */, + const double* HWY_RESTRICT base, + const Vec512<int64_t> index) { + return Vec512<double>{_mm512_i64gather_pd(index.raw, base, 8)}; +} + +HWY_DIAGNOSTICS(pop) + +// ================================================== SWIZZLE + +// ------------------------------ LowerHalf + +template <typename T> +HWY_API Vec256<T> LowerHalf(Full256<T> /* tag */, Vec512<T> v) { + return Vec256<T>{_mm512_castsi512_si256(v.raw)}; +} +HWY_API Vec256<float> LowerHalf(Full256<float> /* tag */, Vec512<float> v) { + return Vec256<float>{_mm512_castps512_ps256(v.raw)}; +} +HWY_API Vec256<double> LowerHalf(Full256<double> /* tag */, Vec512<double> v) { + return Vec256<double>{_mm512_castpd512_pd256(v.raw)}; +} + +template <typename T> +HWY_API Vec256<T> LowerHalf(Vec512<T> v) { + return LowerHalf(Full256<T>(), v); +} + +// ------------------------------ UpperHalf + +template <typename T> +HWY_API Vec256<T> UpperHalf(Full256<T> /* tag */, Vec512<T> v) { + return Vec256<T>{_mm512_extracti32x8_epi32(v.raw, 1)}; +} +HWY_API Vec256<float> UpperHalf(Full256<float> /* tag */, Vec512<float> v) { + return Vec256<float>{_mm512_extractf32x8_ps(v.raw, 1)}; +} +HWY_API Vec256<double> UpperHalf(Full256<double> /* tag */, Vec512<double> v) { + return Vec256<double>{_mm512_extractf64x4_pd(v.raw, 1)}; +} + +// ------------------------------ ExtractLane (Store) +template <typename T> +HWY_API T ExtractLane(const Vec512<T> v, size_t i) { + const Full512<T> d; + HWY_DASSERT(i < Lanes(d)); + alignas(64) T lanes[64 / sizeof(T)]; + Store(v, d, lanes); + return lanes[i]; +} + +// ------------------------------ InsertLane (Store) +template <typename T> +HWY_API Vec512<T> InsertLane(const Vec512<T> v, size_t i, T t) { + const Full512<T> d; + HWY_DASSERT(i < Lanes(d)); + alignas(64) T lanes[64 / sizeof(T)]; + Store(v, d, lanes); + lanes[i] = t; + return Load(d, lanes); +} + +// ------------------------------ GetLane (LowerHalf) +template <typename T> +HWY_API T GetLane(const Vec512<T> v) { + return GetLane(LowerHalf(v)); +} + +// ------------------------------ ZeroExtendVector + +template <typename T> +HWY_API Vec512<T> ZeroExtendVector(Full512<T> /* tag */, Vec256<T> lo) { +#if HWY_HAVE_ZEXT // See definition/comment in x86_256-inl.h. + return Vec512<T>{_mm512_zextsi256_si512(lo.raw)}; +#else + return Vec512<T>{_mm512_inserti32x8(_mm512_setzero_si512(), lo.raw, 0)}; +#endif +} +HWY_API Vec512<float> ZeroExtendVector(Full512<float> /* tag */, + Vec256<float> lo) { +#if HWY_HAVE_ZEXT + return Vec512<float>{_mm512_zextps256_ps512(lo.raw)}; +#else + return Vec512<float>{_mm512_insertf32x8(_mm512_setzero_ps(), lo.raw, 0)}; +#endif +} +HWY_API Vec512<double> ZeroExtendVector(Full512<double> /* tag */, + Vec256<double> lo) { +#if HWY_HAVE_ZEXT + return Vec512<double>{_mm512_zextpd256_pd512(lo.raw)}; +#else + return Vec512<double>{_mm512_insertf64x4(_mm512_setzero_pd(), lo.raw, 0)}; +#endif +} + +// ------------------------------ Combine + +template <typename T> +HWY_API Vec512<T> Combine(Full512<T> d, Vec256<T> hi, Vec256<T> lo) { + const auto lo512 = ZeroExtendVector(d, lo); + return Vec512<T>{_mm512_inserti32x8(lo512.raw, hi.raw, 1)}; +} +HWY_API Vec512<float> Combine(Full512<float> d, Vec256<float> hi, + Vec256<float> lo) { + const auto lo512 = ZeroExtendVector(d, lo); + return Vec512<float>{_mm512_insertf32x8(lo512.raw, hi.raw, 1)}; +} +HWY_API Vec512<double> Combine(Full512<double> d, Vec256<double> hi, + Vec256<double> lo) { + const auto lo512 = ZeroExtendVector(d, lo); + return Vec512<double>{_mm512_insertf64x4(lo512.raw, hi.raw, 1)}; +} + +// ------------------------------ ShiftLeftBytes + +template <int kBytes, typename T> +HWY_API Vec512<T> ShiftLeftBytes(Full512<T> /* tag */, const Vec512<T> v) { + static_assert(0 <= kBytes && kBytes <= 16, "Invalid kBytes"); + return Vec512<T>{_mm512_bslli_epi128(v.raw, kBytes)}; +} + +template <int kBytes, typename T> +HWY_API Vec512<T> ShiftLeftBytes(const Vec512<T> v) { + return ShiftLeftBytes<kBytes>(Full512<T>(), v); +} + +// ------------------------------ ShiftLeftLanes + +template <int kLanes, typename T> +HWY_API Vec512<T> ShiftLeftLanes(Full512<T> d, const Vec512<T> v) { + const Repartition<uint8_t, decltype(d)> d8; + return BitCast(d, ShiftLeftBytes<kLanes * sizeof(T)>(BitCast(d8, v))); +} + +template <int kLanes, typename T> +HWY_API Vec512<T> ShiftLeftLanes(const Vec512<T> v) { + return ShiftLeftLanes<kLanes>(Full512<T>(), v); +} + +// ------------------------------ ShiftRightBytes +template <int kBytes, typename T> +HWY_API Vec512<T> ShiftRightBytes(Full512<T> /* tag */, const Vec512<T> v) { + static_assert(0 <= kBytes && kBytes <= 16, "Invalid kBytes"); + return Vec512<T>{_mm512_bsrli_epi128(v.raw, kBytes)}; +} + +// ------------------------------ ShiftRightLanes +template <int kLanes, typename T> +HWY_API Vec512<T> ShiftRightLanes(Full512<T> d, const Vec512<T> v) { + const Repartition<uint8_t, decltype(d)> d8; + return BitCast(d, ShiftRightBytes<kLanes * sizeof(T)>(d8, BitCast(d8, v))); +} + +// ------------------------------ CombineShiftRightBytes + +template <int kBytes, typename T, class V = Vec512<T>> +HWY_API V CombineShiftRightBytes(Full512<T> d, V hi, V lo) { + const Repartition<uint8_t, decltype(d)> d8; + return BitCast(d, Vec512<uint8_t>{_mm512_alignr_epi8( + BitCast(d8, hi).raw, BitCast(d8, lo).raw, kBytes)}); +} + +// ------------------------------ Broadcast/splat any lane + +// Unsigned +template <int kLane> +HWY_API Vec512<uint16_t> Broadcast(const Vec512<uint16_t> v) { + static_assert(0 <= kLane && kLane < 8, "Invalid lane"); + if (kLane < 4) { + const __m512i lo = _mm512_shufflelo_epi16(v.raw, (0x55 * kLane) & 0xFF); + return Vec512<uint16_t>{_mm512_unpacklo_epi64(lo, lo)}; + } else { + const __m512i hi = + _mm512_shufflehi_epi16(v.raw, (0x55 * (kLane - 4)) & 0xFF); + return Vec512<uint16_t>{_mm512_unpackhi_epi64(hi, hi)}; + } +} +template <int kLane> +HWY_API Vec512<uint32_t> Broadcast(const Vec512<uint32_t> v) { + static_assert(0 <= kLane && kLane < 4, "Invalid lane"); + constexpr _MM_PERM_ENUM perm = static_cast<_MM_PERM_ENUM>(0x55 * kLane); + return Vec512<uint32_t>{_mm512_shuffle_epi32(v.raw, perm)}; +} +template <int kLane> +HWY_API Vec512<uint64_t> Broadcast(const Vec512<uint64_t> v) { + static_assert(0 <= kLane && kLane < 2, "Invalid lane"); + constexpr _MM_PERM_ENUM perm = kLane ? _MM_PERM_DCDC : _MM_PERM_BABA; + return Vec512<uint64_t>{_mm512_shuffle_epi32(v.raw, perm)}; +} + +// Signed +template <int kLane> +HWY_API Vec512<int16_t> Broadcast(const Vec512<int16_t> v) { + static_assert(0 <= kLane && kLane < 8, "Invalid lane"); + if (kLane < 4) { + const __m512i lo = _mm512_shufflelo_epi16(v.raw, (0x55 * kLane) & 0xFF); + return Vec512<int16_t>{_mm512_unpacklo_epi64(lo, lo)}; + } else { + const __m512i hi = + _mm512_shufflehi_epi16(v.raw, (0x55 * (kLane - 4)) & 0xFF); + return Vec512<int16_t>{_mm512_unpackhi_epi64(hi, hi)}; + } +} +template <int kLane> +HWY_API Vec512<int32_t> Broadcast(const Vec512<int32_t> v) { + static_assert(0 <= kLane && kLane < 4, "Invalid lane"); + constexpr _MM_PERM_ENUM perm = static_cast<_MM_PERM_ENUM>(0x55 * kLane); + return Vec512<int32_t>{_mm512_shuffle_epi32(v.raw, perm)}; +} +template <int kLane> +HWY_API Vec512<int64_t> Broadcast(const Vec512<int64_t> v) { + static_assert(0 <= kLane && kLane < 2, "Invalid lane"); + constexpr _MM_PERM_ENUM perm = kLane ? _MM_PERM_DCDC : _MM_PERM_BABA; + return Vec512<int64_t>{_mm512_shuffle_epi32(v.raw, perm)}; +} + +// Float +template <int kLane> +HWY_API Vec512<float> Broadcast(const Vec512<float> v) { + static_assert(0 <= kLane && kLane < 4, "Invalid lane"); + constexpr _MM_PERM_ENUM perm = static_cast<_MM_PERM_ENUM>(0x55 * kLane); + return Vec512<float>{_mm512_shuffle_ps(v.raw, v.raw, perm)}; +} +template <int kLane> +HWY_API Vec512<double> Broadcast(const Vec512<double> v) { + static_assert(0 <= kLane && kLane < 2, "Invalid lane"); + constexpr _MM_PERM_ENUM perm = static_cast<_MM_PERM_ENUM>(0xFF * kLane); + return Vec512<double>{_mm512_shuffle_pd(v.raw, v.raw, perm)}; +} + +// ------------------------------ Hard-coded shuffles + +// Notation: let Vec512<int32_t> have lanes 7,6,5,4,3,2,1,0 (0 is +// least-significant). Shuffle0321 rotates four-lane blocks one lane to the +// right (the previous least-significant lane is now most-significant => +// 47650321). These could also be implemented via CombineShiftRightBytes but +// the shuffle_abcd notation is more convenient. + +// Swap 32-bit halves in 64-bit halves. +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> Shuffle2301(const Vec512<T> v) { + return Vec512<T>{_mm512_shuffle_epi32(v.raw, _MM_PERM_CDAB)}; +} +HWY_API Vec512<float> Shuffle2301(const Vec512<float> v) { + return Vec512<float>{_mm512_shuffle_ps(v.raw, v.raw, _MM_PERM_CDAB)}; +} + +namespace detail { + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> Shuffle2301(const Vec512<T> a, const Vec512<T> b) { + const Full512<T> d; + const RebindToFloat<decltype(d)> df; + return BitCast( + d, Vec512<float>{_mm512_shuffle_ps(BitCast(df, a).raw, BitCast(df, b).raw, + _MM_PERM_CDAB)}); +} +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> Shuffle1230(const Vec512<T> a, const Vec512<T> b) { + const Full512<T> d; + const RebindToFloat<decltype(d)> df; + return BitCast( + d, Vec512<float>{_mm512_shuffle_ps(BitCast(df, a).raw, BitCast(df, b).raw, + _MM_PERM_BCDA)}); +} +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> Shuffle3012(const Vec512<T> a, const Vec512<T> b) { + const Full512<T> d; + const RebindToFloat<decltype(d)> df; + return BitCast( + d, Vec512<float>{_mm512_shuffle_ps(BitCast(df, a).raw, BitCast(df, b).raw, + _MM_PERM_DABC)}); +} + +} // namespace detail + +// Swap 64-bit halves +HWY_API Vec512<uint32_t> Shuffle1032(const Vec512<uint32_t> v) { + return Vec512<uint32_t>{_mm512_shuffle_epi32(v.raw, _MM_PERM_BADC)}; +} +HWY_API Vec512<int32_t> Shuffle1032(const Vec512<int32_t> v) { + return Vec512<int32_t>{_mm512_shuffle_epi32(v.raw, _MM_PERM_BADC)}; +} +HWY_API Vec512<float> Shuffle1032(const Vec512<float> v) { + // Shorter encoding than _mm512_permute_ps. + return Vec512<float>{_mm512_shuffle_ps(v.raw, v.raw, _MM_PERM_BADC)}; +} +HWY_API Vec512<uint64_t> Shuffle01(const Vec512<uint64_t> v) { + return Vec512<uint64_t>{_mm512_shuffle_epi32(v.raw, _MM_PERM_BADC)}; +} +HWY_API Vec512<int64_t> Shuffle01(const Vec512<int64_t> v) { + return Vec512<int64_t>{_mm512_shuffle_epi32(v.raw, _MM_PERM_BADC)}; +} +HWY_API Vec512<double> Shuffle01(const Vec512<double> v) { + // Shorter encoding than _mm512_permute_pd. + return Vec512<double>{_mm512_shuffle_pd(v.raw, v.raw, _MM_PERM_BBBB)}; +} + +// Rotate right 32 bits +HWY_API Vec512<uint32_t> Shuffle0321(const Vec512<uint32_t> v) { + return Vec512<uint32_t>{_mm512_shuffle_epi32(v.raw, _MM_PERM_ADCB)}; +} +HWY_API Vec512<int32_t> Shuffle0321(const Vec512<int32_t> v) { + return Vec512<int32_t>{_mm512_shuffle_epi32(v.raw, _MM_PERM_ADCB)}; +} +HWY_API Vec512<float> Shuffle0321(const Vec512<float> v) { + return Vec512<float>{_mm512_shuffle_ps(v.raw, v.raw, _MM_PERM_ADCB)}; +} +// Rotate left 32 bits +HWY_API Vec512<uint32_t> Shuffle2103(const Vec512<uint32_t> v) { + return Vec512<uint32_t>{_mm512_shuffle_epi32(v.raw, _MM_PERM_CBAD)}; +} +HWY_API Vec512<int32_t> Shuffle2103(const Vec512<int32_t> v) { + return Vec512<int32_t>{_mm512_shuffle_epi32(v.raw, _MM_PERM_CBAD)}; +} +HWY_API Vec512<float> Shuffle2103(const Vec512<float> v) { + return Vec512<float>{_mm512_shuffle_ps(v.raw, v.raw, _MM_PERM_CBAD)}; +} + +// Reverse +HWY_API Vec512<uint32_t> Shuffle0123(const Vec512<uint32_t> v) { + return Vec512<uint32_t>{_mm512_shuffle_epi32(v.raw, _MM_PERM_ABCD)}; +} +HWY_API Vec512<int32_t> Shuffle0123(const Vec512<int32_t> v) { + return Vec512<int32_t>{_mm512_shuffle_epi32(v.raw, _MM_PERM_ABCD)}; +} +HWY_API Vec512<float> Shuffle0123(const Vec512<float> v) { + return Vec512<float>{_mm512_shuffle_ps(v.raw, v.raw, _MM_PERM_ABCD)}; +} + +// ------------------------------ TableLookupLanes + +// Returned by SetTableIndices/IndicesFromVec for use by TableLookupLanes. +template <typename T> +struct Indices512 { + __m512i raw; +}; + +template <typename T, typename TI> +HWY_API Indices512<T> IndicesFromVec(Full512<T> /* tag */, Vec512<TI> vec) { + static_assert(sizeof(T) == sizeof(TI), "Index size must match lane"); +#if HWY_IS_DEBUG_BUILD + const Full512<TI> di; + HWY_DASSERT(AllFalse(di, Lt(vec, Zero(di))) && + AllTrue(di, Lt(vec, Set(di, static_cast<TI>(64 / sizeof(T)))))); +#endif + return Indices512<T>{vec.raw}; +} + +template <typename T, typename TI> +HWY_API Indices512<T> SetTableIndices(const Full512<T> d, const TI* idx) { + const Rebind<TI, decltype(d)> di; + return IndicesFromVec(d, LoadU(di, idx)); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> TableLookupLanes(Vec512<T> v, Indices512<T> idx) { + return Vec512<T>{_mm512_permutexvar_epi32(idx.raw, v.raw)}; +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> TableLookupLanes(Vec512<T> v, Indices512<T> idx) { + return Vec512<T>{_mm512_permutexvar_epi64(idx.raw, v.raw)}; +} + +HWY_API Vec512<float> TableLookupLanes(Vec512<float> v, Indices512<float> idx) { + return Vec512<float>{_mm512_permutexvar_ps(idx.raw, v.raw)}; +} + +HWY_API Vec512<double> TableLookupLanes(Vec512<double> v, + Indices512<double> idx) { + return Vec512<double>{_mm512_permutexvar_pd(idx.raw, v.raw)}; +} + +// ------------------------------ Reverse + +template <typename T, HWY_IF_LANE_SIZE(T, 2)> +HWY_API Vec512<T> Reverse(Full512<T> d, const Vec512<T> v) { + const RebindToSigned<decltype(d)> di; + alignas(64) constexpr int16_t kReverse[32] = { + 31, 30, 29, 28, 27, 26, 25, 24, 23, 22, 21, 20, 19, 18, 17, 16, + 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0}; + const Vec512<int16_t> idx = Load(di, kReverse); + return BitCast(d, Vec512<int16_t>{ + _mm512_permutexvar_epi16(idx.raw, BitCast(di, v).raw)}); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> Reverse(Full512<T> d, const Vec512<T> v) { + alignas(64) constexpr int32_t kReverse[16] = {15, 14, 13, 12, 11, 10, 9, 8, + 7, 6, 5, 4, 3, 2, 1, 0}; + return TableLookupLanes(v, SetTableIndices(d, kReverse)); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> Reverse(Full512<T> d, const Vec512<T> v) { + alignas(64) constexpr int64_t kReverse[8] = {7, 6, 5, 4, 3, 2, 1, 0}; + return TableLookupLanes(v, SetTableIndices(d, kReverse)); +} + +// ------------------------------ Reverse2 + +template <typename T, HWY_IF_LANE_SIZE(T, 2)> +HWY_API Vec512<T> Reverse2(Full512<T> d, const Vec512<T> v) { + const Full512<uint32_t> du32; + return BitCast(d, RotateRight<16>(BitCast(du32, v))); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> Reverse2(Full512<T> /* tag */, const Vec512<T> v) { + return Shuffle2301(v); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> Reverse2(Full512<T> /* tag */, const Vec512<T> v) { + return Shuffle01(v); +} + +// ------------------------------ Reverse4 + +template <typename T, HWY_IF_LANE_SIZE(T, 2)> +HWY_API Vec512<T> Reverse4(Full512<T> d, const Vec512<T> v) { + const RebindToSigned<decltype(d)> di; + alignas(64) constexpr int16_t kReverse4[32] = { + 3, 2, 1, 0, 7, 6, 5, 4, 11, 10, 9, 8, 15, 14, 13, 12, + 19, 18, 17, 16, 23, 22, 21, 20, 27, 26, 25, 24, 31, 30, 29, 28}; + const Vec512<int16_t> idx = Load(di, kReverse4); + return BitCast(d, Vec512<int16_t>{ + _mm512_permutexvar_epi16(idx.raw, BitCast(di, v).raw)}); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> Reverse4(Full512<T> /* tag */, const Vec512<T> v) { + return Shuffle0123(v); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> Reverse4(Full512<T> /* tag */, const Vec512<T> v) { + return Vec512<T>{_mm512_permutex_epi64(v.raw, _MM_SHUFFLE(0, 1, 2, 3))}; +} +HWY_API Vec512<double> Reverse4(Full512<double> /* tag */, Vec512<double> v) { + return Vec512<double>{_mm512_permutex_pd(v.raw, _MM_SHUFFLE(0, 1, 2, 3))}; +} + +// ------------------------------ Reverse8 + +template <typename T, HWY_IF_LANE_SIZE(T, 2)> +HWY_API Vec512<T> Reverse8(Full512<T> d, const Vec512<T> v) { + const RebindToSigned<decltype(d)> di; + alignas(64) constexpr int16_t kReverse8[32] = { + 7, 6, 5, 4, 3, 2, 1, 0, 15, 14, 13, 12, 11, 10, 9, 8, + 23, 22, 21, 20, 19, 18, 17, 16, 31, 30, 29, 28, 27, 26, 25, 24}; + const Vec512<int16_t> idx = Load(di, kReverse8); + return BitCast(d, Vec512<int16_t>{ + _mm512_permutexvar_epi16(idx.raw, BitCast(di, v).raw)}); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> Reverse8(Full512<T> d, const Vec512<T> v) { + const RebindToSigned<decltype(d)> di; + alignas(64) constexpr int32_t kReverse8[16] = {7, 6, 5, 4, 3, 2, 1, 0, + 15, 14, 13, 12, 11, 10, 9, 8}; + const Vec512<int32_t> idx = Load(di, kReverse8); + return BitCast(d, Vec512<int32_t>{ + _mm512_permutexvar_epi32(idx.raw, BitCast(di, v).raw)}); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> Reverse8(Full512<T> d, const Vec512<T> v) { + return Reverse(d, v); +} + +// ------------------------------ InterleaveLower + +// Interleaves lanes from halves of the 128-bit blocks of "a" (which provides +// the least-significant lane) and "b". To concatenate two half-width integers +// into one, use ZipLower/Upper instead (also works with scalar). + +HWY_API Vec512<uint8_t> InterleaveLower(const Vec512<uint8_t> a, + const Vec512<uint8_t> b) { + return Vec512<uint8_t>{_mm512_unpacklo_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<uint16_t> InterleaveLower(const Vec512<uint16_t> a, + const Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_unpacklo_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<uint32_t> InterleaveLower(const Vec512<uint32_t> a, + const Vec512<uint32_t> b) { + return Vec512<uint32_t>{_mm512_unpacklo_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<uint64_t> InterleaveLower(const Vec512<uint64_t> a, + const Vec512<uint64_t> b) { + return Vec512<uint64_t>{_mm512_unpacklo_epi64(a.raw, b.raw)}; +} + +HWY_API Vec512<int8_t> InterleaveLower(const Vec512<int8_t> a, + const Vec512<int8_t> b) { + return Vec512<int8_t>{_mm512_unpacklo_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<int16_t> InterleaveLower(const Vec512<int16_t> a, + const Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_unpacklo_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<int32_t> InterleaveLower(const Vec512<int32_t> a, + const Vec512<int32_t> b) { + return Vec512<int32_t>{_mm512_unpacklo_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<int64_t> InterleaveLower(const Vec512<int64_t> a, + const Vec512<int64_t> b) { + return Vec512<int64_t>{_mm512_unpacklo_epi64(a.raw, b.raw)}; +} + +HWY_API Vec512<float> InterleaveLower(const Vec512<float> a, + const Vec512<float> b) { + return Vec512<float>{_mm512_unpacklo_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> InterleaveLower(const Vec512<double> a, + const Vec512<double> b) { + return Vec512<double>{_mm512_unpacklo_pd(a.raw, b.raw)}; +} + +// ------------------------------ InterleaveUpper + +// All functions inside detail lack the required D parameter. +namespace detail { + +HWY_API Vec512<uint8_t> InterleaveUpper(const Vec512<uint8_t> a, + const Vec512<uint8_t> b) { + return Vec512<uint8_t>{_mm512_unpackhi_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<uint16_t> InterleaveUpper(const Vec512<uint16_t> a, + const Vec512<uint16_t> b) { + return Vec512<uint16_t>{_mm512_unpackhi_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<uint32_t> InterleaveUpper(const Vec512<uint32_t> a, + const Vec512<uint32_t> b) { + return Vec512<uint32_t>{_mm512_unpackhi_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<uint64_t> InterleaveUpper(const Vec512<uint64_t> a, + const Vec512<uint64_t> b) { + return Vec512<uint64_t>{_mm512_unpackhi_epi64(a.raw, b.raw)}; +} + +HWY_API Vec512<int8_t> InterleaveUpper(const Vec512<int8_t> a, + const Vec512<int8_t> b) { + return Vec512<int8_t>{_mm512_unpackhi_epi8(a.raw, b.raw)}; +} +HWY_API Vec512<int16_t> InterleaveUpper(const Vec512<int16_t> a, + const Vec512<int16_t> b) { + return Vec512<int16_t>{_mm512_unpackhi_epi16(a.raw, b.raw)}; +} +HWY_API Vec512<int32_t> InterleaveUpper(const Vec512<int32_t> a, + const Vec512<int32_t> b) { + return Vec512<int32_t>{_mm512_unpackhi_epi32(a.raw, b.raw)}; +} +HWY_API Vec512<int64_t> InterleaveUpper(const Vec512<int64_t> a, + const Vec512<int64_t> b) { + return Vec512<int64_t>{_mm512_unpackhi_epi64(a.raw, b.raw)}; +} + +HWY_API Vec512<float> InterleaveUpper(const Vec512<float> a, + const Vec512<float> b) { + return Vec512<float>{_mm512_unpackhi_ps(a.raw, b.raw)}; +} +HWY_API Vec512<double> InterleaveUpper(const Vec512<double> a, + const Vec512<double> b) { + return Vec512<double>{_mm512_unpackhi_pd(a.raw, b.raw)}; +} + +} // namespace detail + +template <typename T, class V = Vec512<T>> +HWY_API V InterleaveUpper(Full512<T> /* tag */, V a, V b) { + return detail::InterleaveUpper(a, b); +} + +// ------------------------------ ZipLower/ZipUpper (InterleaveLower) + +// Same as Interleave*, except that the return lanes are double-width integers; +// this is necessary because the single-lane scalar cannot return two values. +template <typename T, typename TW = MakeWide<T>> +HWY_API Vec512<TW> ZipLower(Vec512<T> a, Vec512<T> b) { + return BitCast(Full512<TW>(), InterleaveLower(a, b)); +} +template <typename T, typename TW = MakeWide<T>> +HWY_API Vec512<TW> ZipLower(Full512<TW> /* d */, Vec512<T> a, Vec512<T> b) { + return BitCast(Full512<TW>(), InterleaveLower(a, b)); +} + +template <typename T, typename TW = MakeWide<T>> +HWY_API Vec512<TW> ZipUpper(Full512<TW> d, Vec512<T> a, Vec512<T> b) { + return BitCast(Full512<TW>(), InterleaveUpper(d, a, b)); +} + +// ------------------------------ Concat* halves + +// hiH,hiL loH,loL |-> hiL,loL (= lower halves) +template <typename T> +HWY_API Vec512<T> ConcatLowerLower(Full512<T> /* tag */, const Vec512<T> hi, + const Vec512<T> lo) { + return Vec512<T>{_mm512_shuffle_i32x4(lo.raw, hi.raw, _MM_PERM_BABA)}; +} +HWY_API Vec512<float> ConcatLowerLower(Full512<float> /* tag */, + const Vec512<float> hi, + const Vec512<float> lo) { + return Vec512<float>{_mm512_shuffle_f32x4(lo.raw, hi.raw, _MM_PERM_BABA)}; +} +HWY_API Vec512<double> ConcatLowerLower(Full512<double> /* tag */, + const Vec512<double> hi, + const Vec512<double> lo) { + return Vec512<double>{_mm512_shuffle_f64x2(lo.raw, hi.raw, _MM_PERM_BABA)}; +} + +// hiH,hiL loH,loL |-> hiH,loH (= upper halves) +template <typename T> +HWY_API Vec512<T> ConcatUpperUpper(Full512<T> /* tag */, const Vec512<T> hi, + const Vec512<T> lo) { + return Vec512<T>{_mm512_shuffle_i32x4(lo.raw, hi.raw, _MM_PERM_DCDC)}; +} +HWY_API Vec512<float> ConcatUpperUpper(Full512<float> /* tag */, + const Vec512<float> hi, + const Vec512<float> lo) { + return Vec512<float>{_mm512_shuffle_f32x4(lo.raw, hi.raw, _MM_PERM_DCDC)}; +} +HWY_API Vec512<double> ConcatUpperUpper(Full512<double> /* tag */, + const Vec512<double> hi, + const Vec512<double> lo) { + return Vec512<double>{_mm512_shuffle_f64x2(lo.raw, hi.raw, _MM_PERM_DCDC)}; +} + +// hiH,hiL loH,loL |-> hiL,loH (= inner halves / swap blocks) +template <typename T> +HWY_API Vec512<T> ConcatLowerUpper(Full512<T> /* tag */, const Vec512<T> hi, + const Vec512<T> lo) { + return Vec512<T>{_mm512_shuffle_i32x4(lo.raw, hi.raw, _MM_PERM_BADC)}; +} +HWY_API Vec512<float> ConcatLowerUpper(Full512<float> /* tag */, + const Vec512<float> hi, + const Vec512<float> lo) { + return Vec512<float>{_mm512_shuffle_f32x4(lo.raw, hi.raw, _MM_PERM_BADC)}; +} +HWY_API Vec512<double> ConcatLowerUpper(Full512<double> /* tag */, + const Vec512<double> hi, + const Vec512<double> lo) { + return Vec512<double>{_mm512_shuffle_f64x2(lo.raw, hi.raw, _MM_PERM_BADC)}; +} + +// hiH,hiL loH,loL |-> hiH,loL (= outer halves) +template <typename T> +HWY_API Vec512<T> ConcatUpperLower(Full512<T> /* tag */, const Vec512<T> hi, + const Vec512<T> lo) { + // There are no imm8 blend in AVX512. Use blend16 because 32-bit masks + // are efficiently loaded from 32-bit regs. + const __mmask32 mask = /*_cvtu32_mask32 */ (0x0000FFFF); + return Vec512<T>{_mm512_mask_blend_epi16(mask, hi.raw, lo.raw)}; +} +HWY_API Vec512<float> ConcatUpperLower(Full512<float> /* tag */, + const Vec512<float> hi, + const Vec512<float> lo) { + const __mmask16 mask = /*_cvtu32_mask16 */ (0x00FF); + return Vec512<float>{_mm512_mask_blend_ps(mask, hi.raw, lo.raw)}; +} +HWY_API Vec512<double> ConcatUpperLower(Full512<double> /* tag */, + const Vec512<double> hi, + const Vec512<double> lo) { + const __mmask8 mask = /*_cvtu32_mask8 */ (0x0F); + return Vec512<double>{_mm512_mask_blend_pd(mask, hi.raw, lo.raw)}; +} + +// ------------------------------ ConcatOdd + +template <typename T, HWY_IF_LANE_SIZE(T, 1)> +HWY_API Vec512<T> ConcatOdd(Full512<T> d, Vec512<T> hi, Vec512<T> lo) { + const RebindToUnsigned<decltype(d)> du; +#if HWY_TARGET == HWY_AVX3_DL + alignas(64) constexpr uint8_t kIdx[64] = { + 1, 3, 5, 7, 9, 11, 13, 15, 17, 19, 21, 23, 25, + 27, 29, 31, 33, 35, 37, 39, 41, 43, 45, 47, 49, 51, + 53, 55, 57, 59, 61, 63, 65, 67, 69, 71, 73, 75, 77, + 79, 81, 83, 85, 87, 89, 91, 93, 95, 97, 99, 101, 103, + 105, 107, 109, 111, 113, 115, 117, 119, 121, 123, 125, 127}; + return BitCast(d, + Vec512<uint8_t>{_mm512_mask2_permutex2var_epi8( + BitCast(du, lo).raw, Load(du, kIdx).raw, + __mmask64{0xFFFFFFFFFFFFFFFFull}, BitCast(du, hi).raw)}); +#else + const RepartitionToWide<decltype(du)> dw; + // Right-shift 8 bits per u16 so we can pack. + const Vec512<uint16_t> uH = ShiftRight<8>(BitCast(dw, hi)); + const Vec512<uint16_t> uL = ShiftRight<8>(BitCast(dw, lo)); + const Vec512<uint64_t> u8{_mm512_packus_epi16(uL.raw, uH.raw)}; + // Undo block interleave: lower half = even u64 lanes, upper = odd u64 lanes. + const Full512<uint64_t> du64; + alignas(64) constexpr uint64_t kIdx[8] = {0, 2, 4, 6, 1, 3, 5, 7}; + return BitCast(d, TableLookupLanes(u8, SetTableIndices(du64, kIdx))); +#endif +} + +template <typename T, HWY_IF_LANE_SIZE(T, 2)> +HWY_API Vec512<T> ConcatOdd(Full512<T> d, Vec512<T> hi, Vec512<T> lo) { + const RebindToUnsigned<decltype(d)> du; + alignas(64) constexpr uint16_t kIdx[32] = { + 1, 3, 5, 7, 9, 11, 13, 15, 17, 19, 21, 23, 25, 27, 29, 31, + 33, 35, 37, 39, 41, 43, 45, 47, 49, 51, 53, 55, 57, 59, 61, 63}; + return BitCast(d, Vec512<uint16_t>{_mm512_mask2_permutex2var_epi16( + BitCast(du, lo).raw, Load(du, kIdx).raw, + __mmask32{0xFFFFFFFFu}, BitCast(du, hi).raw)}); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> ConcatOdd(Full512<T> d, Vec512<T> hi, Vec512<T> lo) { + const RebindToUnsigned<decltype(d)> du; + alignas(64) constexpr uint32_t kIdx[16] = {1, 3, 5, 7, 9, 11, 13, 15, + 17, 19, 21, 23, 25, 27, 29, 31}; + return BitCast(d, Vec512<uint32_t>{_mm512_mask2_permutex2var_epi32( + BitCast(du, lo).raw, Load(du, kIdx).raw, + __mmask16{0xFFFF}, BitCast(du, hi).raw)}); +} + +HWY_API Vec512<float> ConcatOdd(Full512<float> d, Vec512<float> hi, + Vec512<float> lo) { + const RebindToUnsigned<decltype(d)> du; + alignas(64) constexpr uint32_t kIdx[16] = {1, 3, 5, 7, 9, 11, 13, 15, + 17, 19, 21, 23, 25, 27, 29, 31}; + return Vec512<float>{_mm512_mask2_permutex2var_ps(lo.raw, Load(du, kIdx).raw, + __mmask16{0xFFFF}, hi.raw)}; +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> ConcatOdd(Full512<T> d, Vec512<T> hi, Vec512<T> lo) { + const RebindToUnsigned<decltype(d)> du; + alignas(64) constexpr uint64_t kIdx[8] = {1, 3, 5, 7, 9, 11, 13, 15}; + return BitCast(d, Vec512<uint64_t>{_mm512_mask2_permutex2var_epi64( + BitCast(du, lo).raw, Load(du, kIdx).raw, __mmask8{0xFF}, + BitCast(du, hi).raw)}); +} + +HWY_API Vec512<double> ConcatOdd(Full512<double> d, Vec512<double> hi, + Vec512<double> lo) { + const RebindToUnsigned<decltype(d)> du; + alignas(64) constexpr uint64_t kIdx[8] = {1, 3, 5, 7, 9, 11, 13, 15}; + return Vec512<double>{_mm512_mask2_permutex2var_pd(lo.raw, Load(du, kIdx).raw, + __mmask8{0xFF}, hi.raw)}; +} + +// ------------------------------ ConcatEven + +template <typename T, HWY_IF_LANE_SIZE(T, 1)> +HWY_API Vec512<T> ConcatEven(Full512<T> d, Vec512<T> hi, Vec512<T> lo) { + const RebindToUnsigned<decltype(d)> du; +#if HWY_TARGET == HWY_AVX3_DL + alignas(64) constexpr uint8_t kIdx[64] = { + 0, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, + 26, 28, 30, 32, 34, 36, 38, 40, 42, 44, 46, 48, 50, + 52, 54, 56, 58, 60, 62, 64, 66, 68, 70, 72, 74, 76, + 78, 80, 82, 84, 86, 88, 90, 92, 94, 96, 98, 100, 102, + 104, 106, 108, 110, 112, 114, 116, 118, 120, 122, 124, 126}; + return BitCast(d, + Vec512<uint32_t>{_mm512_mask2_permutex2var_epi8( + BitCast(du, lo).raw, Load(du, kIdx).raw, + __mmask64{0xFFFFFFFFFFFFFFFFull}, BitCast(du, hi).raw)}); +#else + const RepartitionToWide<decltype(du)> dw; + // Isolate lower 8 bits per u16 so we can pack. + const Vec512<uint16_t> mask = Set(dw, 0x00FF); + const Vec512<uint16_t> uH = And(BitCast(dw, hi), mask); + const Vec512<uint16_t> uL = And(BitCast(dw, lo), mask); + const Vec512<uint64_t> u8{_mm512_packus_epi16(uL.raw, uH.raw)}; + // Undo block interleave: lower half = even u64 lanes, upper = odd u64 lanes. + const Full512<uint64_t> du64; + alignas(64) constexpr uint64_t kIdx[8] = {0, 2, 4, 6, 1, 3, 5, 7}; + return BitCast(d, TableLookupLanes(u8, SetTableIndices(du64, kIdx))); +#endif +} + +template <typename T, HWY_IF_LANE_SIZE(T, 2)> +HWY_API Vec512<T> ConcatEven(Full512<T> d, Vec512<T> hi, Vec512<T> lo) { + const RebindToUnsigned<decltype(d)> du; + alignas(64) constexpr uint16_t kIdx[32] = { + 0, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28, 30, + 32, 34, 36, 38, 40, 42, 44, 46, 48, 50, 52, 54, 56, 58, 60, 62}; + return BitCast(d, Vec512<uint32_t>{_mm512_mask2_permutex2var_epi16( + BitCast(du, lo).raw, Load(du, kIdx).raw, + __mmask32{0xFFFFFFFFu}, BitCast(du, hi).raw)}); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> ConcatEven(Full512<T> d, Vec512<T> hi, Vec512<T> lo) { + const RebindToUnsigned<decltype(d)> du; + alignas(64) constexpr uint32_t kIdx[16] = {0, 2, 4, 6, 8, 10, 12, 14, + 16, 18, 20, 22, 24, 26, 28, 30}; + return BitCast(d, Vec512<uint32_t>{_mm512_mask2_permutex2var_epi32( + BitCast(du, lo).raw, Load(du, kIdx).raw, + __mmask16{0xFFFF}, BitCast(du, hi).raw)}); +} + +HWY_API Vec512<float> ConcatEven(Full512<float> d, Vec512<float> hi, + Vec512<float> lo) { + const RebindToUnsigned<decltype(d)> du; + alignas(64) constexpr uint32_t kIdx[16] = {0, 2, 4, 6, 8, 10, 12, 14, + 16, 18, 20, 22, 24, 26, 28, 30}; + return Vec512<float>{_mm512_mask2_permutex2var_ps(lo.raw, Load(du, kIdx).raw, + __mmask16{0xFFFF}, hi.raw)}; +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> ConcatEven(Full512<T> d, Vec512<T> hi, Vec512<T> lo) { + const RebindToUnsigned<decltype(d)> du; + alignas(64) constexpr uint64_t kIdx[8] = {0, 2, 4, 6, 8, 10, 12, 14}; + return BitCast(d, Vec512<uint64_t>{_mm512_mask2_permutex2var_epi64( + BitCast(du, lo).raw, Load(du, kIdx).raw, __mmask8{0xFF}, + BitCast(du, hi).raw)}); +} + +HWY_API Vec512<double> ConcatEven(Full512<double> d, Vec512<double> hi, + Vec512<double> lo) { + const RebindToUnsigned<decltype(d)> du; + alignas(64) constexpr uint64_t kIdx[8] = {0, 2, 4, 6, 8, 10, 12, 14}; + return Vec512<double>{_mm512_mask2_permutex2var_pd(lo.raw, Load(du, kIdx).raw, + __mmask8{0xFF}, hi.raw)}; +} + +// ------------------------------ DupEven (InterleaveLower) + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> DupEven(Vec512<T> v) { + return Vec512<T>{_mm512_shuffle_epi32(v.raw, _MM_PERM_CCAA)}; +} +HWY_API Vec512<float> DupEven(Vec512<float> v) { + return Vec512<float>{_mm512_shuffle_ps(v.raw, v.raw, _MM_PERM_CCAA)}; +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> DupEven(const Vec512<T> v) { + return InterleaveLower(Full512<T>(), v, v); +} + +// ------------------------------ DupOdd (InterleaveUpper) + +template <typename T, HWY_IF_LANE_SIZE(T, 4)> +HWY_API Vec512<T> DupOdd(Vec512<T> v) { + return Vec512<T>{_mm512_shuffle_epi32(v.raw, _MM_PERM_DDBB)}; +} +HWY_API Vec512<float> DupOdd(Vec512<float> v) { + return Vec512<float>{_mm512_shuffle_ps(v.raw, v.raw, _MM_PERM_DDBB)}; +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> DupOdd(const Vec512<T> v) { + return InterleaveUpper(Full512<T>(), v, v); +} + +// ------------------------------ OddEven + +template <typename T> +HWY_API Vec512<T> OddEven(const Vec512<T> a, const Vec512<T> b) { + constexpr size_t s = sizeof(T); + constexpr int shift = s == 1 ? 0 : s == 2 ? 32 : s == 4 ? 48 : 56; + return IfThenElse(Mask512<T>{0x5555555555555555ull >> shift}, b, a); +} + +// ------------------------------ OddEvenBlocks + +template <typename T> +HWY_API Vec512<T> OddEvenBlocks(Vec512<T> odd, Vec512<T> even) { + return Vec512<T>{_mm512_mask_blend_epi64(__mmask8{0x33u}, odd.raw, even.raw)}; +} + +HWY_API Vec512<float> OddEvenBlocks(Vec512<float> odd, Vec512<float> even) { + return Vec512<float>{ + _mm512_mask_blend_ps(__mmask16{0x0F0Fu}, odd.raw, even.raw)}; +} + +HWY_API Vec512<double> OddEvenBlocks(Vec512<double> odd, Vec512<double> even) { + return Vec512<double>{ + _mm512_mask_blend_pd(__mmask8{0x33u}, odd.raw, even.raw)}; +} + +// ------------------------------ SwapAdjacentBlocks + +template <typename T> +HWY_API Vec512<T> SwapAdjacentBlocks(Vec512<T> v) { + return Vec512<T>{_mm512_shuffle_i32x4(v.raw, v.raw, _MM_PERM_CDAB)}; +} + +HWY_API Vec512<float> SwapAdjacentBlocks(Vec512<float> v) { + return Vec512<float>{_mm512_shuffle_f32x4(v.raw, v.raw, _MM_PERM_CDAB)}; +} + +HWY_API Vec512<double> SwapAdjacentBlocks(Vec512<double> v) { + return Vec512<double>{_mm512_shuffle_f64x2(v.raw, v.raw, _MM_PERM_CDAB)}; +} + +// ------------------------------ ReverseBlocks + +template <typename T> +HWY_API Vec512<T> ReverseBlocks(Full512<T> /* tag */, Vec512<T> v) { + return Vec512<T>{_mm512_shuffle_i32x4(v.raw, v.raw, _MM_PERM_ABCD)}; +} +HWY_API Vec512<float> ReverseBlocks(Full512<float> /* tag */, Vec512<float> v) { + return Vec512<float>{_mm512_shuffle_f32x4(v.raw, v.raw, _MM_PERM_ABCD)}; +} +HWY_API Vec512<double> ReverseBlocks(Full512<double> /* tag */, + Vec512<double> v) { + return Vec512<double>{_mm512_shuffle_f64x2(v.raw, v.raw, _MM_PERM_ABCD)}; +} + +// ------------------------------ TableLookupBytes (ZeroExtendVector) + +// Both full +template <typename T, typename TI> +HWY_API Vec512<TI> TableLookupBytes(Vec512<T> bytes, Vec512<TI> indices) { + return Vec512<TI>{_mm512_shuffle_epi8(bytes.raw, indices.raw)}; +} + +// Partial index vector +template <typename T, typename TI, size_t NI> +HWY_API Vec128<TI, NI> TableLookupBytes(Vec512<T> bytes, Vec128<TI, NI> from) { + const Full512<TI> d512; + const Half<decltype(d512)> d256; + const Half<decltype(d256)> d128; + // First expand to full 128, then 256, then 512. + const Vec128<TI> from_full{from.raw}; + const auto from_512 = + ZeroExtendVector(d512, ZeroExtendVector(d256, from_full)); + const auto tbl_full = TableLookupBytes(bytes, from_512); + // Shrink to 256, then 128, then partial. + return Vec128<TI, NI>{LowerHalf(d128, LowerHalf(d256, tbl_full)).raw}; +} +template <typename T, typename TI> +HWY_API Vec256<TI> TableLookupBytes(Vec512<T> bytes, Vec256<TI> from) { + const auto from_512 = ZeroExtendVector(Full512<TI>(), from); + return LowerHalf(Full256<TI>(), TableLookupBytes(bytes, from_512)); +} + +// Partial table vector +template <typename T, size_t N, typename TI> +HWY_API Vec512<TI> TableLookupBytes(Vec128<T, N> bytes, Vec512<TI> from) { + const Full512<TI> d512; + const Half<decltype(d512)> d256; + const Half<decltype(d256)> d128; + // First expand to full 128, then 256, then 512. + const Vec128<T> bytes_full{bytes.raw}; + const auto bytes_512 = + ZeroExtendVector(d512, ZeroExtendVector(d256, bytes_full)); + return TableLookupBytes(bytes_512, from); +} +template <typename T, typename TI> +HWY_API Vec512<TI> TableLookupBytes(Vec256<T> bytes, Vec512<TI> from) { + const auto bytes_512 = ZeroExtendVector(Full512<T>(), bytes); + return TableLookupBytes(bytes_512, from); +} + +// Partial both are handled by x86_128/256. + +// ================================================== CONVERT + +// ------------------------------ Promotions (part w/ narrow lanes -> full) + +// Unsigned: zero-extend. +// Note: these have 3 cycle latency; if inputs are already split across the +// 128 bit blocks (in their upper/lower halves), then Zip* would be faster. +HWY_API Vec512<uint16_t> PromoteTo(Full512<uint16_t> /* tag */, + Vec256<uint8_t> v) { + return Vec512<uint16_t>{_mm512_cvtepu8_epi16(v.raw)}; +} +HWY_API Vec512<uint32_t> PromoteTo(Full512<uint32_t> /* tag */, + Vec128<uint8_t> v) { + return Vec512<uint32_t>{_mm512_cvtepu8_epi32(v.raw)}; +} +HWY_API Vec512<int16_t> PromoteTo(Full512<int16_t> /* tag */, + Vec256<uint8_t> v) { + return Vec512<int16_t>{_mm512_cvtepu8_epi16(v.raw)}; +} +HWY_API Vec512<int32_t> PromoteTo(Full512<int32_t> /* tag */, + Vec128<uint8_t> v) { + return Vec512<int32_t>{_mm512_cvtepu8_epi32(v.raw)}; +} +HWY_API Vec512<uint32_t> PromoteTo(Full512<uint32_t> /* tag */, + Vec256<uint16_t> v) { + return Vec512<uint32_t>{_mm512_cvtepu16_epi32(v.raw)}; +} +HWY_API Vec512<int32_t> PromoteTo(Full512<int32_t> /* tag */, + Vec256<uint16_t> v) { + return Vec512<int32_t>{_mm512_cvtepu16_epi32(v.raw)}; +} +HWY_API Vec512<uint64_t> PromoteTo(Full512<uint64_t> /* tag */, + Vec256<uint32_t> v) { + return Vec512<uint64_t>{_mm512_cvtepu32_epi64(v.raw)}; +} + +// Signed: replicate sign bit. +// Note: these have 3 cycle latency; if inputs are already split across the +// 128 bit blocks (in their upper/lower halves), then ZipUpper/lo followed by +// signed shift would be faster. +HWY_API Vec512<int16_t> PromoteTo(Full512<int16_t> /* tag */, + Vec256<int8_t> v) { + return Vec512<int16_t>{_mm512_cvtepi8_epi16(v.raw)}; +} +HWY_API Vec512<int32_t> PromoteTo(Full512<int32_t> /* tag */, + Vec128<int8_t> v) { + return Vec512<int32_t>{_mm512_cvtepi8_epi32(v.raw)}; +} +HWY_API Vec512<int32_t> PromoteTo(Full512<int32_t> /* tag */, + Vec256<int16_t> v) { + return Vec512<int32_t>{_mm512_cvtepi16_epi32(v.raw)}; +} +HWY_API Vec512<int64_t> PromoteTo(Full512<int64_t> /* tag */, + Vec256<int32_t> v) { + return Vec512<int64_t>{_mm512_cvtepi32_epi64(v.raw)}; +} + +// Float +HWY_API Vec512<float> PromoteTo(Full512<float> /* tag */, + const Vec256<float16_t> v) { + return Vec512<float>{_mm512_cvtph_ps(v.raw)}; +} + +HWY_API Vec512<float> PromoteTo(Full512<float> df32, + const Vec256<bfloat16_t> v) { + const Rebind<uint16_t, decltype(df32)> du16; + const RebindToSigned<decltype(df32)> di32; + return BitCast(df32, ShiftLeft<16>(PromoteTo(di32, BitCast(du16, v)))); +} + +HWY_API Vec512<double> PromoteTo(Full512<double> /* tag */, Vec256<float> v) { + return Vec512<double>{_mm512_cvtps_pd(v.raw)}; +} + +HWY_API Vec512<double> PromoteTo(Full512<double> /* tag */, Vec256<int32_t> v) { + return Vec512<double>{_mm512_cvtepi32_pd(v.raw)}; +} + +// ------------------------------ Demotions (full -> part w/ narrow lanes) + +HWY_API Vec256<uint16_t> DemoteTo(Full256<uint16_t> /* tag */, + const Vec512<int32_t> v) { + const Vec512<uint16_t> u16{_mm512_packus_epi32(v.raw, v.raw)}; + + // Compress even u64 lanes into 256 bit. + alignas(64) static constexpr uint64_t kLanes[8] = {0, 2, 4, 6, 0, 2, 4, 6}; + const auto idx64 = Load(Full512<uint64_t>(), kLanes); + const Vec512<uint16_t> even{_mm512_permutexvar_epi64(idx64.raw, u16.raw)}; + return LowerHalf(even); +} + +HWY_API Vec256<int16_t> DemoteTo(Full256<int16_t> /* tag */, + const Vec512<int32_t> v) { + const Vec512<int16_t> i16{_mm512_packs_epi32(v.raw, v.raw)}; + + // Compress even u64 lanes into 256 bit. + alignas(64) static constexpr uint64_t kLanes[8] = {0, 2, 4, 6, 0, 2, 4, 6}; + const auto idx64 = Load(Full512<uint64_t>(), kLanes); + const Vec512<int16_t> even{_mm512_permutexvar_epi64(idx64.raw, i16.raw)}; + return LowerHalf(even); +} + +HWY_API Vec128<uint8_t, 16> DemoteTo(Full128<uint8_t> /* tag */, + const Vec512<int32_t> v) { + const Vec512<uint16_t> u16{_mm512_packus_epi32(v.raw, v.raw)}; + // packus treats the input as signed; we want unsigned. Clear the MSB to get + // unsigned saturation to u8. + const Vec512<int16_t> i16{ + _mm512_and_si512(u16.raw, _mm512_set1_epi16(0x7FFF))}; + const Vec512<uint8_t> u8{_mm512_packus_epi16(i16.raw, i16.raw)}; + + alignas(16) static constexpr uint32_t kLanes[4] = {0, 4, 8, 12}; + const auto idx32 = LoadDup128(Full512<uint32_t>(), kLanes); + const Vec512<uint8_t> fixed{_mm512_permutexvar_epi32(idx32.raw, u8.raw)}; + return LowerHalf(LowerHalf(fixed)); +} + +HWY_API Vec256<uint8_t> DemoteTo(Full256<uint8_t> /* tag */, + const Vec512<int16_t> v) { + const Vec512<uint8_t> u8{_mm512_packus_epi16(v.raw, v.raw)}; + + // Compress even u64 lanes into 256 bit. + alignas(64) static constexpr uint64_t kLanes[8] = {0, 2, 4, 6, 0, 2, 4, 6}; + const auto idx64 = Load(Full512<uint64_t>(), kLanes); + const Vec512<uint8_t> even{_mm512_permutexvar_epi64(idx64.raw, u8.raw)}; + return LowerHalf(even); +} + +HWY_API Vec128<int8_t, 16> DemoteTo(Full128<int8_t> /* tag */, + const Vec512<int32_t> v) { + const Vec512<int16_t> i16{_mm512_packs_epi32(v.raw, v.raw)}; + const Vec512<int8_t> i8{_mm512_packs_epi16(i16.raw, i16.raw)}; + + alignas(16) static constexpr uint32_t kLanes[16] = {0, 4, 8, 12, 0, 4, 8, 12, + 0, 4, 8, 12, 0, 4, 8, 12}; + const auto idx32 = LoadDup128(Full512<uint32_t>(), kLanes); + const Vec512<int8_t> fixed{_mm512_permutexvar_epi32(idx32.raw, i8.raw)}; + return LowerHalf(LowerHalf(fixed)); +} + +HWY_API Vec256<int8_t> DemoteTo(Full256<int8_t> /* tag */, + const Vec512<int16_t> v) { + const Vec512<int8_t> u8{_mm512_packs_epi16(v.raw, v.raw)}; + + // Compress even u64 lanes into 256 bit. + alignas(64) static constexpr uint64_t kLanes[8] = {0, 2, 4, 6, 0, 2, 4, 6}; + const auto idx64 = Load(Full512<uint64_t>(), kLanes); + const Vec512<int8_t> even{_mm512_permutexvar_epi64(idx64.raw, u8.raw)}; + return LowerHalf(even); +} + +HWY_API Vec256<float16_t> DemoteTo(Full256<float16_t> /* tag */, + const Vec512<float> v) { + // Work around warnings in the intrinsic definitions (passing -1 as a mask). + HWY_DIAGNOSTICS(push) + HWY_DIAGNOSTICS_OFF(disable : 4245 4365, ignored "-Wsign-conversion") + return Vec256<float16_t>{_mm512_cvtps_ph(v.raw, _MM_FROUND_NO_EXC)}; + HWY_DIAGNOSTICS(pop) +} + +HWY_API Vec256<bfloat16_t> DemoteTo(Full256<bfloat16_t> dbf16, + const Vec512<float> v) { + // TODO(janwas): _mm512_cvtneps_pbh once we have avx512bf16. + const Rebind<int32_t, decltype(dbf16)> di32; + const Rebind<uint32_t, decltype(dbf16)> du32; // for logical shift right + const Rebind<uint16_t, decltype(dbf16)> du16; + const auto bits_in_32 = BitCast(di32, ShiftRight<16>(BitCast(du32, v))); + return BitCast(dbf16, DemoteTo(du16, bits_in_32)); +} + +HWY_API Vec512<bfloat16_t> ReorderDemote2To(Full512<bfloat16_t> dbf16, + Vec512<float> a, Vec512<float> b) { + // TODO(janwas): _mm512_cvtne2ps_pbh once we have avx512bf16. + const RebindToUnsigned<decltype(dbf16)> du16; + const Repartition<uint32_t, decltype(dbf16)> du32; + const Vec512<uint32_t> b_in_even = ShiftRight<16>(BitCast(du32, b)); + return BitCast(dbf16, OddEven(BitCast(du16, a), BitCast(du16, b_in_even))); +} + +HWY_API Vec512<int16_t> ReorderDemote2To(Full512<int16_t> /*d16*/, + Vec512<int32_t> a, Vec512<int32_t> b) { + return Vec512<int16_t>{_mm512_packs_epi32(a.raw, b.raw)}; +} + +HWY_API Vec256<float> DemoteTo(Full256<float> /* tag */, + const Vec512<double> v) { + return Vec256<float>{_mm512_cvtpd_ps(v.raw)}; +} + +HWY_API Vec256<int32_t> DemoteTo(Full256<int32_t> /* tag */, + const Vec512<double> v) { + const auto clamped = detail::ClampF64ToI32Max(Full512<double>(), v); + return Vec256<int32_t>{_mm512_cvttpd_epi32(clamped.raw)}; +} + +// For already range-limited input [0, 255]. +HWY_API Vec128<uint8_t, 16> U8FromU32(const Vec512<uint32_t> v) { + const Full512<uint32_t> d32; + // In each 128 bit block, gather the lower byte of 4 uint32_t lanes into the + // lowest 4 bytes. + alignas(16) static constexpr uint32_t k8From32[4] = {0x0C080400u, ~0u, ~0u, + ~0u}; + const auto quads = TableLookupBytes(v, LoadDup128(d32, k8From32)); + // Gather the lowest 4 bytes of 4 128-bit blocks. + alignas(16) static constexpr uint32_t kIndex32[4] = {0, 4, 8, 12}; + const Vec512<uint8_t> bytes{ + _mm512_permutexvar_epi32(LoadDup128(d32, kIndex32).raw, quads.raw)}; + return LowerHalf(LowerHalf(bytes)); +} + +// ------------------------------ Truncations + +HWY_API Vec128<uint8_t, 8> TruncateTo(Simd<uint8_t, 8, 0> d, + const Vec512<uint64_t> v) { +#if HWY_TARGET == HWY_AVX3_DL + (void)d; + const Full512<uint8_t> d8; + alignas(16) static constexpr uint8_t k8From64[16] = { + 0, 8, 16, 24, 32, 40, 48, 56, 0, 8, 16, 24, 32, 40, 48, 56}; + const Vec512<uint8_t> bytes{ + _mm512_permutexvar_epi8(LoadDup128(d8, k8From64).raw, v.raw)}; + return LowerHalf(LowerHalf(LowerHalf(bytes))); +#else + const Full512<uint32_t> d32; + alignas(64) constexpr uint32_t kEven[16] = {0, 2, 4, 6, 8, 10, 12, 14, + 0, 2, 4, 6, 8, 10, 12, 14}; + const Vec512<uint32_t> even{ + _mm512_permutexvar_epi32(Load(d32, kEven).raw, v.raw)}; + return TruncateTo(d, LowerHalf(even)); +#endif +} + +HWY_API Vec128<uint16_t, 8> TruncateTo(Simd<uint16_t, 8, 0> /* tag */, + const Vec512<uint64_t> v) { + const Full512<uint16_t> d16; + alignas(16) static constexpr uint16_t k16From64[8] = { + 0, 4, 8, 12, 16, 20, 24, 28}; + const Vec512<uint16_t> bytes{ + _mm512_permutexvar_epi16(LoadDup128(d16, k16From64).raw, v.raw)}; + return LowerHalf(LowerHalf(bytes)); +} + +HWY_API Vec256<uint32_t> TruncateTo(Simd<uint32_t, 8, 0> /* tag */, + const Vec512<uint64_t> v) { + const Full512<uint32_t> d32; + alignas(64) constexpr uint32_t kEven[16] = {0, 2, 4, 6, 8, 10, 12, 14, + 0, 2, 4, 6, 8, 10, 12, 14}; + const Vec512<uint32_t> even{ + _mm512_permutexvar_epi32(Load(d32, kEven).raw, v.raw)}; + return LowerHalf(even); +} + +HWY_API Vec128<uint8_t, 16> TruncateTo(Simd<uint8_t, 16, 0> /* tag */, + const Vec512<uint32_t> v) { +#if HWY_TARGET == HWY_AVX3_DL + const Full512<uint8_t> d8; + alignas(16) static constexpr uint8_t k8From32[16] = { + 0, 4, 8, 12, 16, 20, 24, 28, 32, 36, 40, 44, 48, 52, 56, 60}; + const Vec512<uint8_t> bytes{ + _mm512_permutexvar_epi32(LoadDup128(d8, k8From32).raw, v.raw)}; +#else + const Full512<uint32_t> d32; + // In each 128 bit block, gather the lower byte of 4 uint32_t lanes into the + // lowest 4 bytes. + alignas(16) static constexpr uint32_t k8From32[4] = {0x0C080400u, ~0u, ~0u, + ~0u}; + const auto quads = TableLookupBytes(v, LoadDup128(d32, k8From32)); + // Gather the lowest 4 bytes of 4 128-bit blocks. + alignas(16) static constexpr uint32_t kIndex32[4] = {0, 4, 8, 12}; + const Vec512<uint8_t> bytes{ + _mm512_permutexvar_epi32(LoadDup128(d32, kIndex32).raw, quads.raw)}; +#endif + return LowerHalf(LowerHalf(bytes)); +} + +HWY_API Vec256<uint16_t> TruncateTo(Simd<uint16_t, 16, 0> /* tag */, + const Vec512<uint32_t> v) { + const Full512<uint16_t> d16; + alignas(64) static constexpr uint16_t k16From32[32] = { + 0, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28, 30, + 0, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28, 30}; + const Vec512<uint16_t> bytes{ + _mm512_permutexvar_epi16(Load(d16, k16From32).raw, v.raw)}; + return LowerHalf(bytes); +} + +HWY_API Vec256<uint8_t> TruncateTo(Simd<uint8_t, 32, 0> /* tag */, + const Vec512<uint16_t> v) { +#if HWY_TARGET == HWY_AVX3_DL + const Full512<uint8_t> d8; + alignas(64) static constexpr uint8_t k8From16[64] = { + 0, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28, 30, + 32, 34, 36, 38, 40, 42, 44, 46, 48, 50, 52, 54, 56, 58, 60, 62, + 0, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28, 30, + 32, 34, 36, 38, 40, 42, 44, 46, 48, 50, 52, 54, 56, 58, 60, 62}; + const Vec512<uint8_t> bytes{ + _mm512_permutexvar_epi8(Load(d8, k8From16).raw, v.raw)}; +#else + const Full512<uint32_t> d32; + alignas(16) static constexpr uint32_t k16From32[4] = { + 0x06040200u, 0x0E0C0A08u, 0x06040200u, 0x0E0C0A08u}; + const auto quads = TableLookupBytes(v, LoadDup128(d32, k16From32)); + alignas(64) static constexpr uint32_t kIndex32[16] = { + 0, 1, 4, 5, 8, 9, 12, 13, 0, 1, 4, 5, 8, 9, 12, 13}; + const Vec512<uint8_t> bytes{ + _mm512_permutexvar_epi32(Load(d32, kIndex32).raw, quads.raw)}; +#endif + return LowerHalf(bytes); +} + +// ------------------------------ Convert integer <=> floating point + +HWY_API Vec512<float> ConvertTo(Full512<float> /* tag */, + const Vec512<int32_t> v) { + return Vec512<float>{_mm512_cvtepi32_ps(v.raw)}; +} + +HWY_API Vec512<double> ConvertTo(Full512<double> /* tag */, + const Vec512<int64_t> v) { + return Vec512<double>{_mm512_cvtepi64_pd(v.raw)}; +} + +HWY_API Vec512<float> ConvertTo(Full512<float> /* tag*/, + const Vec512<uint32_t> v) { + return Vec512<float>{_mm512_cvtepu32_ps(v.raw)}; +} + +HWY_API Vec512<double> ConvertTo(Full512<double> /* tag*/, + const Vec512<uint64_t> v) { + return Vec512<double>{_mm512_cvtepu64_pd(v.raw)}; +} + +// Truncates (rounds toward zero). +HWY_API Vec512<int32_t> ConvertTo(Full512<int32_t> d, const Vec512<float> v) { + return detail::FixConversionOverflow(d, v, _mm512_cvttps_epi32(v.raw)); +} +HWY_API Vec512<int64_t> ConvertTo(Full512<int64_t> di, const Vec512<double> v) { + return detail::FixConversionOverflow(di, v, _mm512_cvttpd_epi64(v.raw)); +} + +HWY_API Vec512<int32_t> NearestInt(const Vec512<float> v) { + const Full512<int32_t> di; + return detail::FixConversionOverflow(di, v, _mm512_cvtps_epi32(v.raw)); +} + +// ================================================== CRYPTO + +#if !defined(HWY_DISABLE_PCLMUL_AES) + +// Per-target flag to prevent generic_ops-inl.h from defining AESRound. +#ifdef HWY_NATIVE_AES +#undef HWY_NATIVE_AES +#else +#define HWY_NATIVE_AES +#endif + +HWY_API Vec512<uint8_t> AESRound(Vec512<uint8_t> state, + Vec512<uint8_t> round_key) { +#if HWY_TARGET == HWY_AVX3_DL + return Vec512<uint8_t>{_mm512_aesenc_epi128(state.raw, round_key.raw)}; +#else + const Full512<uint8_t> d; + const Half<decltype(d)> d2; + return Combine(d, AESRound(UpperHalf(d2, state), UpperHalf(d2, round_key)), + AESRound(LowerHalf(state), LowerHalf(round_key))); +#endif +} + +HWY_API Vec512<uint8_t> AESLastRound(Vec512<uint8_t> state, + Vec512<uint8_t> round_key) { +#if HWY_TARGET == HWY_AVX3_DL + return Vec512<uint8_t>{_mm512_aesenclast_epi128(state.raw, round_key.raw)}; +#else + const Full512<uint8_t> d; + const Half<decltype(d)> d2; + return Combine(d, + AESLastRound(UpperHalf(d2, state), UpperHalf(d2, round_key)), + AESLastRound(LowerHalf(state), LowerHalf(round_key))); +#endif +} + +HWY_API Vec512<uint64_t> CLMulLower(Vec512<uint64_t> va, Vec512<uint64_t> vb) { +#if HWY_TARGET == HWY_AVX3_DL + return Vec512<uint64_t>{_mm512_clmulepi64_epi128(va.raw, vb.raw, 0x00)}; +#else + alignas(64) uint64_t a[8]; + alignas(64) uint64_t b[8]; + const Full512<uint64_t> d; + const Full128<uint64_t> d128; + Store(va, d, a); + Store(vb, d, b); + for (size_t i = 0; i < 8; i += 2) { + const auto mul = CLMulLower(Load(d128, a + i), Load(d128, b + i)); + Store(mul, d128, a + i); + } + return Load(d, a); +#endif +} + +HWY_API Vec512<uint64_t> CLMulUpper(Vec512<uint64_t> va, Vec512<uint64_t> vb) { +#if HWY_TARGET == HWY_AVX3_DL + return Vec512<uint64_t>{_mm512_clmulepi64_epi128(va.raw, vb.raw, 0x11)}; +#else + alignas(64) uint64_t a[8]; + alignas(64) uint64_t b[8]; + const Full512<uint64_t> d; + const Full128<uint64_t> d128; + Store(va, d, a); + Store(vb, d, b); + for (size_t i = 0; i < 8; i += 2) { + const auto mul = CLMulUpper(Load(d128, a + i), Load(d128, b + i)); + Store(mul, d128, a + i); + } + return Load(d, a); +#endif +} + +#endif // HWY_DISABLE_PCLMUL_AES + +// ================================================== MISC + +// Returns a vector with lane i=[0, N) set to "first" + i. +template <typename T, typename T2> +Vec512<T> Iota(const Full512<T> d, const T2 first) { + HWY_ALIGN T lanes[64 / sizeof(T)]; + for (size_t i = 0; i < 64 / sizeof(T); ++i) { + lanes[i] = + AddWithWraparound(hwy::IsFloatTag<T>(), static_cast<T>(first), i); + } + return Load(d, lanes); +} + +// ------------------------------ Mask testing + +// Beware: the suffix indicates the number of mask bits, not lane size! + +namespace detail { + +template <typename T> +HWY_INLINE bool AllFalse(hwy::SizeTag<1> /*tag*/, const Mask512<T> mask) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return _kortestz_mask64_u8(mask.raw, mask.raw); +#else + return mask.raw == 0; +#endif +} +template <typename T> +HWY_INLINE bool AllFalse(hwy::SizeTag<2> /*tag*/, const Mask512<T> mask) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return _kortestz_mask32_u8(mask.raw, mask.raw); +#else + return mask.raw == 0; +#endif +} +template <typename T> +HWY_INLINE bool AllFalse(hwy::SizeTag<4> /*tag*/, const Mask512<T> mask) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return _kortestz_mask16_u8(mask.raw, mask.raw); +#else + return mask.raw == 0; +#endif +} +template <typename T> +HWY_INLINE bool AllFalse(hwy::SizeTag<8> /*tag*/, const Mask512<T> mask) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return _kortestz_mask8_u8(mask.raw, mask.raw); +#else + return mask.raw == 0; +#endif +} + +} // namespace detail + +template <typename T> +HWY_API bool AllFalse(const Full512<T> /* tag */, const Mask512<T> mask) { + return detail::AllFalse(hwy::SizeTag<sizeof(T)>(), mask); +} + +namespace detail { + +template <typename T> +HWY_INLINE bool AllTrue(hwy::SizeTag<1> /*tag*/, const Mask512<T> mask) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return _kortestc_mask64_u8(mask.raw, mask.raw); +#else + return mask.raw == 0xFFFFFFFFFFFFFFFFull; +#endif +} +template <typename T> +HWY_INLINE bool AllTrue(hwy::SizeTag<2> /*tag*/, const Mask512<T> mask) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return _kortestc_mask32_u8(mask.raw, mask.raw); +#else + return mask.raw == 0xFFFFFFFFull; +#endif +} +template <typename T> +HWY_INLINE bool AllTrue(hwy::SizeTag<4> /*tag*/, const Mask512<T> mask) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return _kortestc_mask16_u8(mask.raw, mask.raw); +#else + return mask.raw == 0xFFFFull; +#endif +} +template <typename T> +HWY_INLINE bool AllTrue(hwy::SizeTag<8> /*tag*/, const Mask512<T> mask) { +#if HWY_COMPILER_HAS_MASK_INTRINSICS + return _kortestc_mask8_u8(mask.raw, mask.raw); +#else + return mask.raw == 0xFFull; +#endif +} + +} // namespace detail + +template <typename T> +HWY_API bool AllTrue(const Full512<T> /* tag */, const Mask512<T> mask) { + return detail::AllTrue(hwy::SizeTag<sizeof(T)>(), mask); +} + +// `p` points to at least 8 readable bytes, not all of which need be valid. +template <typename T> +HWY_API Mask512<T> LoadMaskBits(const Full512<T> /* tag */, + const uint8_t* HWY_RESTRICT bits) { + Mask512<T> mask; + CopyBytes<8 / sizeof(T)>(bits, &mask.raw); + // N >= 8 (= 512 / 64), so no need to mask invalid bits. + return mask; +} + +// `p` points to at least 8 writable bytes. +template <typename T> +HWY_API size_t StoreMaskBits(const Full512<T> /* tag */, const Mask512<T> mask, + uint8_t* bits) { + const size_t kNumBytes = 8 / sizeof(T); + CopyBytes<kNumBytes>(&mask.raw, bits); + // N >= 8 (= 512 / 64), so no need to mask invalid bits. + return kNumBytes; +} + +template <typename T> +HWY_API size_t CountTrue(const Full512<T> /* tag */, const Mask512<T> mask) { + return PopCount(static_cast<uint64_t>(mask.raw)); +} + +template <typename T, HWY_IF_NOT_LANE_SIZE(T, 1)> +HWY_API size_t FindKnownFirstTrue(const Full512<T> /* tag */, + const Mask512<T> mask) { + return Num0BitsBelowLS1Bit_Nonzero32(mask.raw); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 1)> +HWY_API size_t FindKnownFirstTrue(const Full512<T> /* tag */, + const Mask512<T> mask) { + return Num0BitsBelowLS1Bit_Nonzero64(mask.raw); +} + +template <typename T> +HWY_API intptr_t FindFirstTrue(const Full512<T> d, const Mask512<T> mask) { + return mask.raw ? static_cast<intptr_t>(FindKnownFirstTrue(d, mask)) + : intptr_t{-1}; +} + +// ------------------------------ Compress + +// Always implement 8-bit here even if we lack VBMI2 because we can do better +// than generic_ops (8 at a time) via the native 32-bit compress (16 at a time). +#ifdef HWY_NATIVE_COMPRESS8 +#undef HWY_NATIVE_COMPRESS8 +#else +#define HWY_NATIVE_COMPRESS8 +#endif + +namespace detail { + +#if HWY_TARGET == HWY_AVX3_DL // VBMI2 +template <size_t N> +HWY_INLINE Vec128<uint8_t, N> NativeCompress(const Vec128<uint8_t, N> v, + const Mask128<uint8_t, N> mask) { + return Vec128<uint8_t, N>{_mm_maskz_compress_epi8(mask.raw, v.raw)}; +} +HWY_INLINE Vec256<uint8_t> NativeCompress(const Vec256<uint8_t> v, + const Mask256<uint8_t> mask) { + return Vec256<uint8_t>{_mm256_maskz_compress_epi8(mask.raw, v.raw)}; +} +HWY_INLINE Vec512<uint8_t> NativeCompress(const Vec512<uint8_t> v, + const Mask512<uint8_t> mask) { + return Vec512<uint8_t>{_mm512_maskz_compress_epi8(mask.raw, v.raw)}; +} + +template <size_t N> +HWY_INLINE Vec128<uint16_t, N> NativeCompress(const Vec128<uint16_t, N> v, + const Mask128<uint16_t, N> mask) { + return Vec128<uint16_t, N>{_mm_maskz_compress_epi16(mask.raw, v.raw)}; +} +HWY_INLINE Vec256<uint16_t> NativeCompress(const Vec256<uint16_t> v, + const Mask256<uint16_t> mask) { + return Vec256<uint16_t>{_mm256_maskz_compress_epi16(mask.raw, v.raw)}; +} +HWY_INLINE Vec512<uint16_t> NativeCompress(const Vec512<uint16_t> v, + const Mask512<uint16_t> mask) { + return Vec512<uint16_t>{_mm512_maskz_compress_epi16(mask.raw, v.raw)}; +} + +template <size_t N> +HWY_INLINE void NativeCompressStore(Vec128<uint8_t, N> v, + Mask128<uint8_t, N> mask, + Simd<uint8_t, N, 0> /* d */, + uint8_t* HWY_RESTRICT unaligned) { + _mm_mask_compressstoreu_epi8(unaligned, mask.raw, v.raw); +} +HWY_INLINE void NativeCompressStore(Vec256<uint8_t> v, Mask256<uint8_t> mask, + Full256<uint8_t> /* d */, + uint8_t* HWY_RESTRICT unaligned) { + _mm256_mask_compressstoreu_epi8(unaligned, mask.raw, v.raw); +} +HWY_INLINE void NativeCompressStore(Vec512<uint8_t> v, Mask512<uint8_t> mask, + Full512<uint8_t> /* d */, + uint8_t* HWY_RESTRICT unaligned) { + _mm512_mask_compressstoreu_epi8(unaligned, mask.raw, v.raw); +} + +template <size_t N> +HWY_INLINE void NativeCompressStore(Vec128<uint16_t, N> v, + Mask128<uint16_t, N> mask, + Simd<uint16_t, N, 0> /* d */, + uint16_t* HWY_RESTRICT unaligned) { + _mm_mask_compressstoreu_epi16(unaligned, mask.raw, v.raw); +} +HWY_INLINE void NativeCompressStore(Vec256<uint16_t> v, Mask256<uint16_t> mask, + Full256<uint16_t> /* d */, + uint16_t* HWY_RESTRICT unaligned) { + _mm256_mask_compressstoreu_epi16(unaligned, mask.raw, v.raw); +} +HWY_INLINE void NativeCompressStore(Vec512<uint16_t> v, Mask512<uint16_t> mask, + Full512<uint16_t> /* d */, + uint16_t* HWY_RESTRICT unaligned) { + _mm512_mask_compressstoreu_epi16(unaligned, mask.raw, v.raw); +} + +#endif // HWY_TARGET == HWY_AVX3_DL + +template <size_t N> +HWY_INLINE Vec128<uint32_t, N> NativeCompress(const Vec128<uint32_t, N> v, + const Mask128<uint32_t, N> mask) { + return Vec128<uint32_t, N>{_mm_maskz_compress_epi32(mask.raw, v.raw)}; +} +HWY_INLINE Vec256<uint32_t> NativeCompress(Vec256<uint32_t> v, + Mask256<uint32_t> mask) { + return Vec256<uint32_t>{_mm256_maskz_compress_epi32(mask.raw, v.raw)}; +} +HWY_INLINE Vec512<uint32_t> NativeCompress(Vec512<uint32_t> v, + Mask512<uint32_t> mask) { + return Vec512<uint32_t>{_mm512_maskz_compress_epi32(mask.raw, v.raw)}; +} +// We use table-based compress for 64-bit lanes, see CompressIsPartition. + +template <size_t N> +HWY_INLINE void NativeCompressStore(Vec128<uint32_t, N> v, + Mask128<uint32_t, N> mask, + Simd<uint32_t, N, 0> /* d */, + uint32_t* HWY_RESTRICT unaligned) { + _mm_mask_compressstoreu_epi32(unaligned, mask.raw, v.raw); +} +HWY_INLINE void NativeCompressStore(Vec256<uint32_t> v, Mask256<uint32_t> mask, + Full256<uint32_t> /* d */, + uint32_t* HWY_RESTRICT unaligned) { + _mm256_mask_compressstoreu_epi32(unaligned, mask.raw, v.raw); +} +HWY_INLINE void NativeCompressStore(Vec512<uint32_t> v, Mask512<uint32_t> mask, + Full512<uint32_t> /* d */, + uint32_t* HWY_RESTRICT unaligned) { + _mm512_mask_compressstoreu_epi32(unaligned, mask.raw, v.raw); +} + +template <size_t N> +HWY_INLINE void NativeCompressStore(Vec128<uint64_t, N> v, + Mask128<uint64_t, N> mask, + Simd<uint64_t, N, 0> /* d */, + uint64_t* HWY_RESTRICT unaligned) { + _mm_mask_compressstoreu_epi64(unaligned, mask.raw, v.raw); +} +HWY_INLINE void NativeCompressStore(Vec256<uint64_t> v, Mask256<uint64_t> mask, + Full256<uint64_t> /* d */, + uint64_t* HWY_RESTRICT unaligned) { + _mm256_mask_compressstoreu_epi64(unaligned, mask.raw, v.raw); +} +HWY_INLINE void NativeCompressStore(Vec512<uint64_t> v, Mask512<uint64_t> mask, + Full512<uint64_t> /* d */, + uint64_t* HWY_RESTRICT unaligned) { + _mm512_mask_compressstoreu_epi64(unaligned, mask.raw, v.raw); +} + +// For u8x16 and <= u16x16 we can avoid store+load for Compress because there is +// only a single compressed vector (u32x16). Other EmuCompress are implemented +// after the EmuCompressStore they build upon. +template <size_t N> +HWY_INLINE Vec128<uint8_t, N> EmuCompress(Vec128<uint8_t, N> v, + Mask128<uint8_t, N> mask) { + const Simd<uint8_t, N, 0> d; + const Rebind<uint32_t, decltype(d)> d32; + const auto v0 = PromoteTo(d32, v); + + const uint64_t mask_bits{mask.raw}; + // Mask type is __mmask16 if v is full 128, else __mmask8. + using M32 = MFromD<decltype(d32)>; + const M32 m0{static_cast<typename M32::Raw>(mask_bits)}; + return TruncateTo(d, Compress(v0, m0)); +} + +template <size_t N> +HWY_INLINE Vec128<uint16_t, N> EmuCompress(Vec128<uint16_t, N> v, + Mask128<uint16_t, N> mask) { + const Simd<uint16_t, N, 0> d; + const Rebind<int32_t, decltype(d)> di32; + const RebindToUnsigned<decltype(di32)> du32; + const MFromD<decltype(du32)> mask32{static_cast<__mmask8>(mask.raw)}; + // DemoteTo is 2 ops, but likely lower latency than TruncateTo on SKX. + // Only i32 -> u16 is supported, whereas NativeCompress expects u32. + const VFromD<decltype(du32)> v32 = BitCast(du32, PromoteTo(di32, v)); + return DemoteTo(d, BitCast(di32, NativeCompress(v32, mask32))); +} + +HWY_INLINE Vec256<uint16_t> EmuCompress(Vec256<uint16_t> v, + Mask256<uint16_t> mask) { + const Full256<uint16_t> d; + const Rebind<int32_t, decltype(d)> di32; + const RebindToUnsigned<decltype(di32)> du32; + const Mask512<uint32_t> mask32{static_cast<__mmask16>(mask.raw)}; + const Vec512<uint32_t> v32 = BitCast(du32, PromoteTo(di32, v)); + return DemoteTo(d, BitCast(di32, NativeCompress(v32, mask32))); +} + +// See above - small-vector EmuCompressStore are implemented via EmuCompress. +template <typename T, size_t N> +HWY_INLINE void EmuCompressStore(Vec128<T, N> v, Mask128<T, N> mask, + Simd<T, N, 0> d, T* HWY_RESTRICT unaligned) { + StoreU(EmuCompress(v, mask), d, unaligned); +} + +HWY_INLINE void EmuCompressStore(Vec256<uint16_t> v, Mask256<uint16_t> mask, + Full256<uint16_t> d, + uint16_t* HWY_RESTRICT unaligned) { + StoreU(EmuCompress(v, mask), d, unaligned); +} + +// Main emulation logic for wider vector, starting with EmuCompressStore because +// it is most convenient to merge pieces using memory (concatenating vectors at +// byte offsets is difficult). +HWY_INLINE void EmuCompressStore(Vec256<uint8_t> v, Mask256<uint8_t> mask, + Full256<uint8_t> d, + uint8_t* HWY_RESTRICT unaligned) { + const uint64_t mask_bits{mask.raw}; + const Half<decltype(d)> dh; + const Rebind<uint32_t, decltype(dh)> d32; + const Vec512<uint32_t> v0 = PromoteTo(d32, LowerHalf(v)); + const Vec512<uint32_t> v1 = PromoteTo(d32, UpperHalf(dh, v)); + const Mask512<uint32_t> m0{static_cast<__mmask16>(mask_bits & 0xFFFFu)}; + const Mask512<uint32_t> m1{static_cast<__mmask16>(mask_bits >> 16)}; + const Vec128<uint8_t> c0 = TruncateTo(dh, NativeCompress(v0, m0)); + const Vec128<uint8_t> c1 = TruncateTo(dh, NativeCompress(v1, m1)); + uint8_t* HWY_RESTRICT pos = unaligned; + StoreU(c0, dh, pos); + StoreU(c1, dh, pos + CountTrue(d32, m0)); +} + +HWY_INLINE void EmuCompressStore(Vec512<uint8_t> v, Mask512<uint8_t> mask, + Full512<uint8_t> d, + uint8_t* HWY_RESTRICT unaligned) { + const uint64_t mask_bits{mask.raw}; + const Half<Half<decltype(d)>> dq; + const Rebind<uint32_t, decltype(dq)> d32; + HWY_ALIGN uint8_t lanes[64]; + Store(v, d, lanes); + const Vec512<uint32_t> v0 = PromoteTo(d32, LowerHalf(LowerHalf(v))); + const Vec512<uint32_t> v1 = PromoteTo(d32, Load(dq, lanes + 16)); + const Vec512<uint32_t> v2 = PromoteTo(d32, Load(dq, lanes + 32)); + const Vec512<uint32_t> v3 = PromoteTo(d32, Load(dq, lanes + 48)); + const Mask512<uint32_t> m0{static_cast<__mmask16>(mask_bits & 0xFFFFu)}; + const Mask512<uint32_t> m1{ + static_cast<uint16_t>((mask_bits >> 16) & 0xFFFFu)}; + const Mask512<uint32_t> m2{ + static_cast<uint16_t>((mask_bits >> 32) & 0xFFFFu)}; + const Mask512<uint32_t> m3{static_cast<__mmask16>(mask_bits >> 48)}; + const Vec128<uint8_t> c0 = TruncateTo(dq, NativeCompress(v0, m0)); + const Vec128<uint8_t> c1 = TruncateTo(dq, NativeCompress(v1, m1)); + const Vec128<uint8_t> c2 = TruncateTo(dq, NativeCompress(v2, m2)); + const Vec128<uint8_t> c3 = TruncateTo(dq, NativeCompress(v3, m3)); + uint8_t* HWY_RESTRICT pos = unaligned; + StoreU(c0, dq, pos); + pos += CountTrue(d32, m0); + StoreU(c1, dq, pos); + pos += CountTrue(d32, m1); + StoreU(c2, dq, pos); + pos += CountTrue(d32, m2); + StoreU(c3, dq, pos); +} + +HWY_INLINE void EmuCompressStore(Vec512<uint16_t> v, Mask512<uint16_t> mask, + Full512<uint16_t> d, + uint16_t* HWY_RESTRICT unaligned) { + const Repartition<int32_t, decltype(d)> di32; + const RebindToUnsigned<decltype(di32)> du32; + const Half<decltype(d)> dh; + const Vec512<uint32_t> promoted0 = + BitCast(du32, PromoteTo(di32, LowerHalf(dh, v))); + const Vec512<uint32_t> promoted1 = + BitCast(du32, PromoteTo(di32, UpperHalf(dh, v))); + + const uint64_t mask_bits{mask.raw}; + const uint64_t maskL = mask_bits & 0xFFFF; + const uint64_t maskH = mask_bits >> 16; + const Mask512<uint32_t> mask0{static_cast<__mmask16>(maskL)}; + const Mask512<uint32_t> mask1{static_cast<__mmask16>(maskH)}; + const Vec512<uint32_t> compressed0 = NativeCompress(promoted0, mask0); + const Vec512<uint32_t> compressed1 = NativeCompress(promoted1, mask1); + + const Vec256<uint16_t> demoted0 = DemoteTo(dh, BitCast(di32, compressed0)); + const Vec256<uint16_t> demoted1 = DemoteTo(dh, BitCast(di32, compressed1)); + + // Store 256-bit halves + StoreU(demoted0, dh, unaligned); + StoreU(demoted1, dh, unaligned + PopCount(maskL)); +} + +// Finally, the remaining EmuCompress for wide vectors, using EmuCompressStore. +template <typename T> // 1 or 2 bytes +HWY_INLINE Vec512<T> EmuCompress(Vec512<T> v, Mask512<T> mask) { + const Full512<T> d; + HWY_ALIGN T buf[2 * 64 / sizeof(T)]; + EmuCompressStore(v, mask, d, buf); + return Load(d, buf); +} + +HWY_INLINE Vec256<uint8_t> EmuCompress(Vec256<uint8_t> v, + const Mask256<uint8_t> mask) { + const Full256<uint8_t> d; + HWY_ALIGN uint8_t buf[2 * 32 / sizeof(uint8_t)]; + EmuCompressStore(v, mask, d, buf); + return Load(d, buf); +} + +} // namespace detail + +template <class V, class M, HWY_IF_LANE_SIZE_ONE_OF_V(V, 0x6)> // 1 or 2 bytes +HWY_API V Compress(V v, const M mask) { + const DFromV<decltype(v)> d; + const RebindToUnsigned<decltype(d)> du; + const auto mu = RebindMask(du, mask); +#if HWY_TARGET == HWY_AVX3_DL // VBMI2 + return BitCast(d, detail::NativeCompress(BitCast(du, v), mu)); +#else + return BitCast(d, detail::EmuCompress(BitCast(du, v), mu)); +#endif +} + +template <class V, class M, HWY_IF_LANE_SIZE_V(V, 4)> +HWY_API V Compress(V v, const M mask) { + const DFromV<decltype(v)> d; + const RebindToUnsigned<decltype(d)> du; + const auto mu = RebindMask(du, mask); + return BitCast(d, detail::NativeCompress(BitCast(du, v), mu)); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> Compress(Vec512<T> v, Mask512<T> mask) { + // See CompressIsPartition. u64 is faster than u32. + alignas(16) constexpr uint64_t packed_array[256] = { + // From PrintCompress32x8Tables, without the FirstN extension (there is + // no benefit to including them because 64-bit CompressStore is anyway + // masked, but also no harm because TableLookupLanes ignores the MSB). + 0x76543210, 0x76543210, 0x76543201, 0x76543210, 0x76543102, 0x76543120, + 0x76543021, 0x76543210, 0x76542103, 0x76542130, 0x76542031, 0x76542310, + 0x76541032, 0x76541320, 0x76540321, 0x76543210, 0x76532104, 0x76532140, + 0x76532041, 0x76532410, 0x76531042, 0x76531420, 0x76530421, 0x76534210, + 0x76521043, 0x76521430, 0x76520431, 0x76524310, 0x76510432, 0x76514320, + 0x76504321, 0x76543210, 0x76432105, 0x76432150, 0x76432051, 0x76432510, + 0x76431052, 0x76431520, 0x76430521, 0x76435210, 0x76421053, 0x76421530, + 0x76420531, 0x76425310, 0x76410532, 0x76415320, 0x76405321, 0x76453210, + 0x76321054, 0x76321540, 0x76320541, 0x76325410, 0x76310542, 0x76315420, + 0x76305421, 0x76354210, 0x76210543, 0x76215430, 0x76205431, 0x76254310, + 0x76105432, 0x76154320, 0x76054321, 0x76543210, 0x75432106, 0x75432160, + 0x75432061, 0x75432610, 0x75431062, 0x75431620, 0x75430621, 0x75436210, + 0x75421063, 0x75421630, 0x75420631, 0x75426310, 0x75410632, 0x75416320, + 0x75406321, 0x75463210, 0x75321064, 0x75321640, 0x75320641, 0x75326410, + 0x75310642, 0x75316420, 0x75306421, 0x75364210, 0x75210643, 0x75216430, + 0x75206431, 0x75264310, 0x75106432, 0x75164320, 0x75064321, 0x75643210, + 0x74321065, 0x74321650, 0x74320651, 0x74326510, 0x74310652, 0x74316520, + 0x74306521, 0x74365210, 0x74210653, 0x74216530, 0x74206531, 0x74265310, + 0x74106532, 0x74165320, 0x74065321, 0x74653210, 0x73210654, 0x73216540, + 0x73206541, 0x73265410, 0x73106542, 0x73165420, 0x73065421, 0x73654210, + 0x72106543, 0x72165430, 0x72065431, 0x72654310, 0x71065432, 0x71654320, + 0x70654321, 0x76543210, 0x65432107, 0x65432170, 0x65432071, 0x65432710, + 0x65431072, 0x65431720, 0x65430721, 0x65437210, 0x65421073, 0x65421730, + 0x65420731, 0x65427310, 0x65410732, 0x65417320, 0x65407321, 0x65473210, + 0x65321074, 0x65321740, 0x65320741, 0x65327410, 0x65310742, 0x65317420, + 0x65307421, 0x65374210, 0x65210743, 0x65217430, 0x65207431, 0x65274310, + 0x65107432, 0x65174320, 0x65074321, 0x65743210, 0x64321075, 0x64321750, + 0x64320751, 0x64327510, 0x64310752, 0x64317520, 0x64307521, 0x64375210, + 0x64210753, 0x64217530, 0x64207531, 0x64275310, 0x64107532, 0x64175320, + 0x64075321, 0x64753210, 0x63210754, 0x63217540, 0x63207541, 0x63275410, + 0x63107542, 0x63175420, 0x63075421, 0x63754210, 0x62107543, 0x62175430, + 0x62075431, 0x62754310, 0x61075432, 0x61754320, 0x60754321, 0x67543210, + 0x54321076, 0x54321760, 0x54320761, 0x54327610, 0x54310762, 0x54317620, + 0x54307621, 0x54376210, 0x54210763, 0x54217630, 0x54207631, 0x54276310, + 0x54107632, 0x54176320, 0x54076321, 0x54763210, 0x53210764, 0x53217640, + 0x53207641, 0x53276410, 0x53107642, 0x53176420, 0x53076421, 0x53764210, + 0x52107643, 0x52176430, 0x52076431, 0x52764310, 0x51076432, 0x51764320, + 0x50764321, 0x57643210, 0x43210765, 0x43217650, 0x43207651, 0x43276510, + 0x43107652, 0x43176520, 0x43076521, 0x43765210, 0x42107653, 0x42176530, + 0x42076531, 0x42765310, 0x41076532, 0x41765320, 0x40765321, 0x47653210, + 0x32107654, 0x32176540, 0x32076541, 0x32765410, 0x31076542, 0x31765420, + 0x30765421, 0x37654210, 0x21076543, 0x21765430, 0x20765431, 0x27654310, + 0x10765432, 0x17654320, 0x07654321, 0x76543210}; + + // For lane i, shift the i-th 4-bit index down to bits [0, 3) - + // _mm512_permutexvar_epi64 will ignore the upper bits. + const Full512<T> d; + const RebindToUnsigned<decltype(d)> du64; + const auto packed = Set(du64, packed_array[mask.raw]); + alignas(64) constexpr uint64_t shifts[8] = {0, 4, 8, 12, 16, 20, 24, 28}; + const auto indices = Indices512<T>{(packed >> Load(du64, shifts)).raw}; + return TableLookupLanes(v, indices); +} + +// ------------------------------ CompressNot + +template <class V, class M, HWY_IF_NOT_LANE_SIZE_V(V, 8)> +HWY_API V CompressNot(V v, const M mask) { + return Compress(v, Not(mask)); +} + +template <typename T, HWY_IF_LANE_SIZE(T, 8)> +HWY_API Vec512<T> CompressNot(Vec512<T> v, Mask512<T> mask) { + // See CompressIsPartition. u64 is faster than u32. + alignas(16) constexpr uint64_t packed_array[256] = { + // From PrintCompressNot32x8Tables, without the FirstN extension (there is + // no benefit to including them because 64-bit CompressStore is anyway + // masked, but also no harm because TableLookupLanes ignores the MSB). + 0x76543210, 0x07654321, 0x17654320, 0x10765432, 0x27654310, 0x20765431, + 0x21765430, 0x21076543, 0x37654210, 0x30765421, 0x31765420, 0x31076542, + 0x32765410, 0x32076541, 0x32176540, 0x32107654, 0x47653210, 0x40765321, + 0x41765320, 0x41076532, 0x42765310, 0x42076531, 0x42176530, 0x42107653, + 0x43765210, 0x43076521, 0x43176520, 0x43107652, 0x43276510, 0x43207651, + 0x43217650, 0x43210765, 0x57643210, 0x50764321, 0x51764320, 0x51076432, + 0x52764310, 0x52076431, 0x52176430, 0x52107643, 0x53764210, 0x53076421, + 0x53176420, 0x53107642, 0x53276410, 0x53207641, 0x53217640, 0x53210764, + 0x54763210, 0x54076321, 0x54176320, 0x54107632, 0x54276310, 0x54207631, + 0x54217630, 0x54210763, 0x54376210, 0x54307621, 0x54317620, 0x54310762, + 0x54327610, 0x54320761, 0x54321760, 0x54321076, 0x67543210, 0x60754321, + 0x61754320, 0x61075432, 0x62754310, 0x62075431, 0x62175430, 0x62107543, + 0x63754210, 0x63075421, 0x63175420, 0x63107542, 0x63275410, 0x63207541, + 0x63217540, 0x63210754, 0x64753210, 0x64075321, 0x64175320, 0x64107532, + 0x64275310, 0x64207531, 0x64217530, 0x64210753, 0x64375210, 0x64307521, + 0x64317520, 0x64310752, 0x64327510, 0x64320751, 0x64321750, 0x64321075, + 0x65743210, 0x65074321, 0x65174320, 0x65107432, 0x65274310, 0x65207431, + 0x65217430, 0x65210743, 0x65374210, 0x65307421, 0x65317420, 0x65310742, + 0x65327410, 0x65320741, 0x65321740, 0x65321074, 0x65473210, 0x65407321, + 0x65417320, 0x65410732, 0x65427310, 0x65420731, 0x65421730, 0x65421073, + 0x65437210, 0x65430721, 0x65431720, 0x65431072, 0x65432710, 0x65432071, + 0x65432170, 0x65432107, 0x76543210, 0x70654321, 0x71654320, 0x71065432, + 0x72654310, 0x72065431, 0x72165430, 0x72106543, 0x73654210, 0x73065421, + 0x73165420, 0x73106542, 0x73265410, 0x73206541, 0x73216540, 0x73210654, + 0x74653210, 0x74065321, 0x74165320, 0x74106532, 0x74265310, 0x74206531, + 0x74216530, 0x74210653, 0x74365210, 0x74306521, 0x74316520, 0x74310652, + 0x74326510, 0x74320651, 0x74321650, 0x74321065, 0x75643210, 0x75064321, + 0x75164320, 0x75106432, 0x75264310, 0x75206431, 0x75216430, 0x75210643, + 0x75364210, 0x75306421, 0x75316420, 0x75310642, 0x75326410, 0x75320641, + 0x75321640, 0x75321064, 0x75463210, 0x75406321, 0x75416320, 0x75410632, + 0x75426310, 0x75420631, 0x75421630, 0x75421063, 0x75436210, 0x75430621, + 0x75431620, 0x75431062, 0x75432610, 0x75432061, 0x75432160, 0x75432106, + 0x76543210, 0x76054321, 0x76154320, 0x76105432, 0x76254310, 0x76205431, + 0x76215430, 0x76210543, 0x76354210, 0x76305421, 0x76315420, 0x76310542, + 0x76325410, 0x76320541, 0x76321540, 0x76321054, 0x76453210, 0x76405321, + 0x76415320, 0x76410532, 0x76425310, 0x76420531, 0x76421530, 0x76421053, + 0x76435210, 0x76430521, 0x76431520, 0x76431052, 0x76432510, 0x76432051, + 0x76432150, 0x76432105, 0x76543210, 0x76504321, 0x76514320, 0x76510432, + 0x76524310, 0x76520431, 0x76521430, 0x76521043, 0x76534210, 0x76530421, + 0x76531420, 0x76531042, 0x76532410, 0x76532041, 0x76532140, 0x76532104, + 0x76543210, 0x76540321, 0x76541320, 0x76541032, 0x76542310, 0x76542031, + 0x76542130, 0x76542103, 0x76543210, 0x76543021, 0x76543120, 0x76543102, + 0x76543210, 0x76543201, 0x76543210, 0x76543210}; + + // For lane i, shift the i-th 4-bit index down to bits [0, 3) - + // _mm512_permutexvar_epi64 will ignore the upper bits. + const Full512<T> d; + const RebindToUnsigned<decltype(d)> du64; + const auto packed = Set(du64, packed_array[mask.raw]); + alignas(64) constexpr uint64_t shifts[8] = {0, 4, 8, 12, 16, 20, 24, 28}; + const auto indices = Indices512<T>{(packed >> Load(du64, shifts)).raw}; + return TableLookupLanes(v, indices); +} + +// uint64_t lanes. Only implement for 256 and 512-bit vectors because this is a +// no-op for 128-bit. +template <class V, class M, hwy::EnableIf<(sizeof(V) > 16)>* = nullptr> +HWY_API V CompressBlocksNot(V v, M mask) { + return CompressNot(v, mask); +} + +// ------------------------------ CompressBits +template <class V> +HWY_API V CompressBits(V v, const uint8_t* HWY_RESTRICT bits) { + return Compress(v, LoadMaskBits(DFromV<V>(), bits)); +} + +// ------------------------------ CompressStore + +template <class V, class D, HWY_IF_LANE_SIZE_ONE_OF_V(V, 0x6)> // 1 or 2 bytes +HWY_API size_t CompressStore(V v, MFromD<D> mask, D d, + TFromD<D>* HWY_RESTRICT unaligned) { + const RebindToUnsigned<decltype(d)> du; + const auto mu = RebindMask(du, mask); + auto pu = reinterpret_cast<TFromD<decltype(du)> * HWY_RESTRICT>(unaligned); +#if HWY_TARGET == HWY_AVX3_DL // VBMI2 + detail::NativeCompressStore(BitCast(du, v), mu, du, pu); +#else + detail::EmuCompressStore(BitCast(du, v), mu, du, pu); +#endif + const size_t count = CountTrue(d, mask); + detail::MaybeUnpoison(pu, count); + return count; +} + +template <class V, class D, HWY_IF_LANE_SIZE_ONE_OF_V(V, 0x110)> // 4 or 8 +HWY_API size_t CompressStore(V v, MFromD<D> mask, D d, + TFromD<D>* HWY_RESTRICT unaligned) { + const RebindToUnsigned<decltype(d)> du; + const auto mu = RebindMask(du, mask); + using TU = TFromD<decltype(du)>; + TU* HWY_RESTRICT pu = reinterpret_cast<TU*>(unaligned); + detail::NativeCompressStore(BitCast(du, v), mu, du, pu); + const size_t count = CountTrue(d, mask); + detail::MaybeUnpoison(pu, count); + return count; +} + +// Additional overloads to avoid casting to uint32_t (delay?). +HWY_API size_t CompressStore(Vec512<float> v, Mask512<float> mask, + Full512<float> /* tag */, + float* HWY_RESTRICT unaligned) { + _mm512_mask_compressstoreu_ps(unaligned, mask.raw, v.raw); + const size_t count = PopCount(uint64_t{mask.raw}); + detail::MaybeUnpoison(unaligned, count); + return count; +} + +HWY_API size_t CompressStore(Vec512<double> v, Mask512<double> mask, + Full512<double> /* tag */, + double* HWY_RESTRICT unaligned) { + _mm512_mask_compressstoreu_pd(unaligned, mask.raw, v.raw); + const size_t count = PopCount(uint64_t{mask.raw}); + detail::MaybeUnpoison(unaligned, count); + return count; +} + +// ------------------------------ CompressBlendedStore +template <class D, typename T = TFromD<D>> +HWY_API size_t CompressBlendedStore(VFromD<D> v, MFromD<D> m, D d, + T* HWY_RESTRICT unaligned) { + // Native CompressStore already does the blending at no extra cost (latency + // 11, rthroughput 2 - same as compress plus store). + if (HWY_TARGET == HWY_AVX3_DL || sizeof(T) > 2) { + return CompressStore(v, m, d, unaligned); + } else { + const size_t count = CountTrue(d, m); + BlendedStore(Compress(v, m), FirstN(d, count), d, unaligned); + detail::MaybeUnpoison(unaligned, count); + return count; + } +} + +// ------------------------------ CompressBitsStore +template <class D> +HWY_API size_t CompressBitsStore(VFromD<D> v, const uint8_t* HWY_RESTRICT bits, + D d, TFromD<D>* HWY_RESTRICT unaligned) { + return CompressStore(v, LoadMaskBits(d, bits), d, unaligned); +} + +// ------------------------------ LoadInterleaved4 + +// Actually implemented in generic_ops, we just overload LoadTransposedBlocks4. +namespace detail { + +// Type-safe wrapper. +template <_MM_PERM_ENUM kPerm, typename T> +Vec512<T> Shuffle128(const Vec512<T> lo, const Vec512<T> hi) { + return Vec512<T>{_mm512_shuffle_i64x2(lo.raw, hi.raw, kPerm)}; +} +template <_MM_PERM_ENUM kPerm> +Vec512<float> Shuffle128(const Vec512<float> lo, const Vec512<float> hi) { + return Vec512<float>{_mm512_shuffle_f32x4(lo.raw, hi.raw, kPerm)}; +} +template <_MM_PERM_ENUM kPerm> +Vec512<double> Shuffle128(const Vec512<double> lo, const Vec512<double> hi) { + return Vec512<double>{_mm512_shuffle_f64x2(lo.raw, hi.raw, kPerm)}; +} + +// Input (128-bit blocks): +// 3 2 1 0 (<- first block in unaligned) +// 7 6 5 4 +// b a 9 8 +// Output: +// 9 6 3 0 (LSB of A) +// a 7 4 1 +// b 8 5 2 +template <typename T> +HWY_API void LoadTransposedBlocks3(Full512<T> d, + const T* HWY_RESTRICT unaligned, + Vec512<T>& A, Vec512<T>& B, Vec512<T>& C) { + constexpr size_t N = 64 / sizeof(T); + const Vec512<T> v3210 = LoadU(d, unaligned + 0 * N); + const Vec512<T> v7654 = LoadU(d, unaligned + 1 * N); + const Vec512<T> vba98 = LoadU(d, unaligned + 2 * N); + + const Vec512<T> v5421 = detail::Shuffle128<_MM_PERM_BACB>(v3210, v7654); + const Vec512<T> va976 = detail::Shuffle128<_MM_PERM_CBDC>(v7654, vba98); + + A = detail::Shuffle128<_MM_PERM_CADA>(v3210, va976); + B = detail::Shuffle128<_MM_PERM_DBCA>(v5421, va976); + C = detail::Shuffle128<_MM_PERM_DADB>(v5421, vba98); +} + +// Input (128-bit blocks): +// 3 2 1 0 (<- first block in unaligned) +// 7 6 5 4 +// b a 9 8 +// f e d c +// Output: +// c 8 4 0 (LSB of A) +// d 9 5 1 +// e a 6 2 +// f b 7 3 +template <typename T> +HWY_API void LoadTransposedBlocks4(Full512<T> d, + const T* HWY_RESTRICT unaligned, + Vec512<T>& A, Vec512<T>& B, Vec512<T>& C, + Vec512<T>& D) { + constexpr size_t N = 64 / sizeof(T); + const Vec512<T> v3210 = LoadU(d, unaligned + 0 * N); + const Vec512<T> v7654 = LoadU(d, unaligned + 1 * N); + const Vec512<T> vba98 = LoadU(d, unaligned + 2 * N); + const Vec512<T> vfedc = LoadU(d, unaligned + 3 * N); + + const Vec512<T> v5410 = detail::Shuffle128<_MM_PERM_BABA>(v3210, v7654); + const Vec512<T> vdc98 = detail::Shuffle128<_MM_PERM_BABA>(vba98, vfedc); + const Vec512<T> v7632 = detail::Shuffle128<_MM_PERM_DCDC>(v3210, v7654); + const Vec512<T> vfeba = detail::Shuffle128<_MM_PERM_DCDC>(vba98, vfedc); + A = detail::Shuffle128<_MM_PERM_CACA>(v5410, vdc98); + B = detail::Shuffle128<_MM_PERM_DBDB>(v5410, vdc98); + C = detail::Shuffle128<_MM_PERM_CACA>(v7632, vfeba); + D = detail::Shuffle128<_MM_PERM_DBDB>(v7632, vfeba); +} + +} // namespace detail + +// ------------------------------ StoreInterleaved2 + +// Implemented in generic_ops, we just overload StoreTransposedBlocks2/3/4. + +namespace detail { + +// Input (128-bit blocks): +// 6 4 2 0 (LSB of i) +// 7 5 3 1 +// Output: +// 3 2 1 0 +// 7 6 5 4 +template <typename T> +HWY_API void StoreTransposedBlocks2(const Vec512<T> i, const Vec512<T> j, + const Full512<T> d, + T* HWY_RESTRICT unaligned) { + constexpr size_t N = 64 / sizeof(T); + const auto j1_j0_i1_i0 = detail::Shuffle128<_MM_PERM_BABA>(i, j); + const auto j3_j2_i3_i2 = detail::Shuffle128<_MM_PERM_DCDC>(i, j); + const auto j1_i1_j0_i0 = + detail::Shuffle128<_MM_PERM_DBCA>(j1_j0_i1_i0, j1_j0_i1_i0); + const auto j3_i3_j2_i2 = + detail::Shuffle128<_MM_PERM_DBCA>(j3_j2_i3_i2, j3_j2_i3_i2); + StoreU(j1_i1_j0_i0, d, unaligned + 0 * N); + StoreU(j3_i3_j2_i2, d, unaligned + 1 * N); +} + +// Input (128-bit blocks): +// 9 6 3 0 (LSB of i) +// a 7 4 1 +// b 8 5 2 +// Output: +// 3 2 1 0 +// 7 6 5 4 +// b a 9 8 +template <typename T> +HWY_API void StoreTransposedBlocks3(const Vec512<T> i, const Vec512<T> j, + const Vec512<T> k, Full512<T> d, + T* HWY_RESTRICT unaligned) { + constexpr size_t N = 64 / sizeof(T); + const Vec512<T> j2_j0_i2_i0 = detail::Shuffle128<_MM_PERM_CACA>(i, j); + const Vec512<T> i3_i1_k2_k0 = detail::Shuffle128<_MM_PERM_DBCA>(k, i); + const Vec512<T> j3_j1_k3_k1 = detail::Shuffle128<_MM_PERM_DBDB>(k, j); + + const Vec512<T> out0 = // i1 k0 j0 i0 + detail::Shuffle128<_MM_PERM_CACA>(j2_j0_i2_i0, i3_i1_k2_k0); + const Vec512<T> out1 = // j2 i2 k1 j1 + detail::Shuffle128<_MM_PERM_DBAC>(j3_j1_k3_k1, j2_j0_i2_i0); + const Vec512<T> out2 = // k3 j3 i3 k2 + detail::Shuffle128<_MM_PERM_BDDB>(i3_i1_k2_k0, j3_j1_k3_k1); + + StoreU(out0, d, unaligned + 0 * N); + StoreU(out1, d, unaligned + 1 * N); + StoreU(out2, d, unaligned + 2 * N); +} + +// Input (128-bit blocks): +// c 8 4 0 (LSB of i) +// d 9 5 1 +// e a 6 2 +// f b 7 3 +// Output: +// 3 2 1 0 +// 7 6 5 4 +// b a 9 8 +// f e d c +template <typename T> +HWY_API void StoreTransposedBlocks4(const Vec512<T> i, const Vec512<T> j, + const Vec512<T> k, const Vec512<T> l, + Full512<T> d, T* HWY_RESTRICT unaligned) { + constexpr size_t N = 64 / sizeof(T); + const Vec512<T> j1_j0_i1_i0 = detail::Shuffle128<_MM_PERM_BABA>(i, j); + const Vec512<T> l1_l0_k1_k0 = detail::Shuffle128<_MM_PERM_BABA>(k, l); + const Vec512<T> j3_j2_i3_i2 = detail::Shuffle128<_MM_PERM_DCDC>(i, j); + const Vec512<T> l3_l2_k3_k2 = detail::Shuffle128<_MM_PERM_DCDC>(k, l); + const Vec512<T> out0 = + detail::Shuffle128<_MM_PERM_CACA>(j1_j0_i1_i0, l1_l0_k1_k0); + const Vec512<T> out1 = + detail::Shuffle128<_MM_PERM_DBDB>(j1_j0_i1_i0, l1_l0_k1_k0); + const Vec512<T> out2 = + detail::Shuffle128<_MM_PERM_CACA>(j3_j2_i3_i2, l3_l2_k3_k2); + const Vec512<T> out3 = + detail::Shuffle128<_MM_PERM_DBDB>(j3_j2_i3_i2, l3_l2_k3_k2); + StoreU(out0, d, unaligned + 0 * N); + StoreU(out1, d, unaligned + 1 * N); + StoreU(out2, d, unaligned + 2 * N); + StoreU(out3, d, unaligned + 3 * N); +} + +} // namespace detail + +// ------------------------------ MulEven/Odd (Shuffle2301, InterleaveLower) + +HWY_INLINE Vec512<uint64_t> MulEven(const Vec512<uint64_t> a, + const Vec512<uint64_t> b) { + const Full512<uint64_t> du64; + const RepartitionToNarrow<decltype(du64)> du32; + const auto maskL = Set(du64, 0xFFFFFFFFULL); + const auto a32 = BitCast(du32, a); + const auto b32 = BitCast(du32, b); + // Inputs for MulEven: we only need the lower 32 bits + const auto aH = Shuffle2301(a32); + const auto bH = Shuffle2301(b32); + + // Knuth double-word multiplication. We use 32x32 = 64 MulEven and only need + // the even (lower 64 bits of every 128-bit block) results. See + // https://github.com/hcs0/Hackers-Delight/blob/master/muldwu.c.tat + const auto aLbL = MulEven(a32, b32); + const auto w3 = aLbL & maskL; + + const auto t2 = MulEven(aH, b32) + ShiftRight<32>(aLbL); + const auto w2 = t2 & maskL; + const auto w1 = ShiftRight<32>(t2); + + const auto t = MulEven(a32, bH) + w2; + const auto k = ShiftRight<32>(t); + + const auto mulH = MulEven(aH, bH) + w1 + k; + const auto mulL = ShiftLeft<32>(t) + w3; + return InterleaveLower(mulL, mulH); +} + +HWY_INLINE Vec512<uint64_t> MulOdd(const Vec512<uint64_t> a, + const Vec512<uint64_t> b) { + const Full512<uint64_t> du64; + const RepartitionToNarrow<decltype(du64)> du32; + const auto maskL = Set(du64, 0xFFFFFFFFULL); + const auto a32 = BitCast(du32, a); + const auto b32 = BitCast(du32, b); + // Inputs for MulEven: we only need bits [95:64] (= upper half of input) + const auto aH = Shuffle2301(a32); + const auto bH = Shuffle2301(b32); + + // Same as above, but we're using the odd results (upper 64 bits per block). + const auto aLbL = MulEven(a32, b32); + const auto w3 = aLbL & maskL; + + const auto t2 = MulEven(aH, b32) + ShiftRight<32>(aLbL); + const auto w2 = t2 & maskL; + const auto w1 = ShiftRight<32>(t2); + + const auto t = MulEven(a32, bH) + w2; + const auto k = ShiftRight<32>(t); + + const auto mulH = MulEven(aH, bH) + w1 + k; + const auto mulL = ShiftLeft<32>(t) + w3; + return InterleaveUpper(du64, mulL, mulH); +} + +// ------------------------------ ReorderWidenMulAccumulate +HWY_API Vec512<int32_t> ReorderWidenMulAccumulate(Full512<int32_t> /*d32*/, + Vec512<int16_t> a, + Vec512<int16_t> b, + const Vec512<int32_t> sum0, + Vec512<int32_t>& /*sum1*/) { + return sum0 + Vec512<int32_t>{_mm512_madd_epi16(a.raw, b.raw)}; +} + +HWY_API Vec512<int32_t> RearrangeToOddPlusEven(const Vec512<int32_t> sum0, + Vec512<int32_t> /*sum1*/) { + return sum0; // invariant already holds +} + +// ------------------------------ Reductions + +// Returns the sum in each lane. +HWY_API Vec512<int32_t> SumOfLanes(Full512<int32_t> d, Vec512<int32_t> v) { + return Set(d, _mm512_reduce_add_epi32(v.raw)); +} +HWY_API Vec512<int64_t> SumOfLanes(Full512<int64_t> d, Vec512<int64_t> v) { + return Set(d, _mm512_reduce_add_epi64(v.raw)); +} +HWY_API Vec512<uint32_t> SumOfLanes(Full512<uint32_t> d, Vec512<uint32_t> v) { + return Set(d, static_cast<uint32_t>(_mm512_reduce_add_epi32(v.raw))); +} +HWY_API Vec512<uint64_t> SumOfLanes(Full512<uint64_t> d, Vec512<uint64_t> v) { + return Set(d, static_cast<uint64_t>(_mm512_reduce_add_epi64(v.raw))); +} +HWY_API Vec512<float> SumOfLanes(Full512<float> d, Vec512<float> v) { + return Set(d, _mm512_reduce_add_ps(v.raw)); +} +HWY_API Vec512<double> SumOfLanes(Full512<double> d, Vec512<double> v) { + return Set(d, _mm512_reduce_add_pd(v.raw)); +} +HWY_API Vec512<uint16_t> SumOfLanes(Full512<uint16_t> d, Vec512<uint16_t> v) { + const RepartitionToWide<decltype(d)> d32; + const auto even = And(BitCast(d32, v), Set(d32, 0xFFFF)); + const auto odd = ShiftRight<16>(BitCast(d32, v)); + const auto sum = SumOfLanes(d32, even + odd); + // Also broadcast into odd lanes. + return OddEven(BitCast(d, ShiftLeft<16>(sum)), BitCast(d, sum)); +} +HWY_API Vec512<int16_t> SumOfLanes(Full512<int16_t> d, Vec512<int16_t> v) { + const RepartitionToWide<decltype(d)> d32; + // Sign-extend + const auto even = ShiftRight<16>(ShiftLeft<16>(BitCast(d32, v))); + const auto odd = ShiftRight<16>(BitCast(d32, v)); + const auto sum = SumOfLanes(d32, even + odd); + // Also broadcast into odd lanes. + return OddEven(BitCast(d, ShiftLeft<16>(sum)), BitCast(d, sum)); +} + +// Returns the minimum in each lane. +HWY_API Vec512<int32_t> MinOfLanes(Full512<int32_t> d, Vec512<int32_t> v) { + return Set(d, _mm512_reduce_min_epi32(v.raw)); +} +HWY_API Vec512<int64_t> MinOfLanes(Full512<int64_t> d, Vec512<int64_t> v) { + return Set(d, _mm512_reduce_min_epi64(v.raw)); +} +HWY_API Vec512<uint32_t> MinOfLanes(Full512<uint32_t> d, Vec512<uint32_t> v) { + return Set(d, _mm512_reduce_min_epu32(v.raw)); +} +HWY_API Vec512<uint64_t> MinOfLanes(Full512<uint64_t> d, Vec512<uint64_t> v) { + return Set(d, _mm512_reduce_min_epu64(v.raw)); +} +HWY_API Vec512<float> MinOfLanes(Full512<float> d, Vec512<float> v) { + return Set(d, _mm512_reduce_min_ps(v.raw)); +} +HWY_API Vec512<double> MinOfLanes(Full512<double> d, Vec512<double> v) { + return Set(d, _mm512_reduce_min_pd(v.raw)); +} +HWY_API Vec512<uint16_t> MinOfLanes(Full512<uint16_t> d, Vec512<uint16_t> v) { + const RepartitionToWide<decltype(d)> d32; + const auto even = And(BitCast(d32, v), Set(d32, 0xFFFF)); + const auto odd = ShiftRight<16>(BitCast(d32, v)); + const auto min = MinOfLanes(d32, Min(even, odd)); + // Also broadcast into odd lanes. + return OddEven(BitCast(d, ShiftLeft<16>(min)), BitCast(d, min)); +} +HWY_API Vec512<int16_t> MinOfLanes(Full512<int16_t> d, Vec512<int16_t> v) { + const RepartitionToWide<decltype(d)> d32; + // Sign-extend + const auto even = ShiftRight<16>(ShiftLeft<16>(BitCast(d32, v))); + const auto odd = ShiftRight<16>(BitCast(d32, v)); + const auto min = MinOfLanes(d32, Min(even, odd)); + // Also broadcast into odd lanes. + return OddEven(BitCast(d, ShiftLeft<16>(min)), BitCast(d, min)); +} + +// Returns the maximum in each lane. +HWY_API Vec512<int32_t> MaxOfLanes(Full512<int32_t> d, Vec512<int32_t> v) { + return Set(d, _mm512_reduce_max_epi32(v.raw)); +} +HWY_API Vec512<int64_t> MaxOfLanes(Full512<int64_t> d, Vec512<int64_t> v) { + return Set(d, _mm512_reduce_max_epi64(v.raw)); +} +HWY_API Vec512<uint32_t> MaxOfLanes(Full512<uint32_t> d, Vec512<uint32_t> v) { + return Set(d, _mm512_reduce_max_epu32(v.raw)); +} +HWY_API Vec512<uint64_t> MaxOfLanes(Full512<uint64_t> d, Vec512<uint64_t> v) { + return Set(d, _mm512_reduce_max_epu64(v.raw)); +} +HWY_API Vec512<float> MaxOfLanes(Full512<float> d, Vec512<float> v) { + return Set(d, _mm512_reduce_max_ps(v.raw)); +} +HWY_API Vec512<double> MaxOfLanes(Full512<double> d, Vec512<double> v) { + return Set(d, _mm512_reduce_max_pd(v.raw)); +} +HWY_API Vec512<uint16_t> MaxOfLanes(Full512<uint16_t> d, Vec512<uint16_t> v) { + const RepartitionToWide<decltype(d)> d32; + const auto even = And(BitCast(d32, v), Set(d32, 0xFFFF)); + const auto odd = ShiftRight<16>(BitCast(d32, v)); + const auto min = MaxOfLanes(d32, Max(even, odd)); + // Also broadcast into odd lanes. + return OddEven(BitCast(d, ShiftLeft<16>(min)), BitCast(d, min)); +} +HWY_API Vec512<int16_t> MaxOfLanes(Full512<int16_t> d, Vec512<int16_t> v) { + const RepartitionToWide<decltype(d)> d32; + // Sign-extend + const auto even = ShiftRight<16>(ShiftLeft<16>(BitCast(d32, v))); + const auto odd = ShiftRight<16>(BitCast(d32, v)); + const auto min = MaxOfLanes(d32, Max(even, odd)); + // Also broadcast into odd lanes. + return OddEven(BitCast(d, ShiftLeft<16>(min)), BitCast(d, min)); +} + +// NOLINTNEXTLINE(google-readability-namespace-comments) +} // namespace HWY_NAMESPACE +} // namespace hwy +HWY_AFTER_NAMESPACE(); + +// Note that the GCC warnings are not suppressed if we only wrap the *intrin.h - +// the warning seems to be issued at the call site of intrinsics, i.e. our code. +HWY_DIAGNOSTICS(pop) |