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// Copyright 2021 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
//
//
// 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.
// 256-bit WASM vectors and operations. Experimental.
// External include guard in highway.h - see comment there.
// For half-width vectors. Already includes base.h and shared-inl.h.
#include "hwy/ops/wasm_128-inl.h"
HWY_BEFORE_NAMESPACE();
namespace hwy {
namespace HWY_NAMESPACE {
template <typename T>
class Vec256 {
public:
using PrivateT = T; // only for DFromV
static constexpr size_t kPrivateN = 32 / 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 Vec256& operator*=(const Vec256 other) {
return *this = (*this * other);
}
HWY_INLINE Vec256& operator/=(const Vec256 other) {
return *this = (*this / other);
}
HWY_INLINE Vec256& operator+=(const Vec256 other) {
return *this = (*this + other);
}
HWY_INLINE Vec256& operator-=(const Vec256 other) {
return *this = (*this - other);
}
HWY_INLINE Vec256& operator%=(const Vec256 other) {
return *this = (*this % other);
}
HWY_INLINE Vec256& operator&=(const Vec256 other) {
return *this = (*this & other);
}
HWY_INLINE Vec256& operator|=(const Vec256 other) {
return *this = (*this | other);
}
HWY_INLINE Vec256& operator^=(const Vec256 other) {
return *this = (*this ^ other);
}
Vec128<T> v0;
Vec128<T> v1;
};
template <typename T>
struct Mask256 {
Mask128<T> m0;
Mask128<T> m1;
};
// ------------------------------ Zero
// Avoid VFromD here because it is defined in terms of Zero.
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API Vec256<TFromD<D>> Zero(D d) {
const Half<decltype(d)> dh;
Vec256<TFromD<D>> ret;
ret.v0 = ret.v1 = Zero(dh);
return ret;
}
// ------------------------------ BitCast
template <class D, typename TFrom>
HWY_API VFromD<D> BitCast(D d, Vec256<TFrom> v) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = BitCast(dh, v.v0);
ret.v1 = BitCast(dh, v.v1);
return ret;
}
// ------------------------------ ResizeBitCast
// 32-byte vector to 32-byte vector: Same as BitCast
template <class D, typename FromV, HWY_IF_V_SIZE_V(FromV, 32),
HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> ResizeBitCast(D d, FromV v) {
return BitCast(d, v);
}
// <= 16-byte vector to 32-byte vector
template <class D, typename FromV, HWY_IF_V_SIZE_LE_V(FromV, 16),
HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> ResizeBitCast(D d, FromV v) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = ResizeBitCast(dh, v);
ret.v1 = Zero(dh);
return ret;
}
// 32-byte vector to <= 16-byte vector
template <class D, typename FromV, HWY_IF_V_SIZE_V(FromV, 32),
HWY_IF_V_SIZE_LE_D(D, 16)>
HWY_API VFromD<D> ResizeBitCast(D d, FromV v) {
return ResizeBitCast(d, v.v0);
}
// ------------------------------ Set
template <class D, HWY_IF_V_SIZE_D(D, 32), typename T2>
HWY_API VFromD<D> Set(D d, const T2 t) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = ret.v1 = Set(dh, static_cast<TFromD<D>>(t));
return ret;
}
// Undefined, Iota defined in wasm_128.
// ------------------------------ Dup128VecFromValues
template <class D, HWY_IF_T_SIZE_D(D, 1), HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> Dup128VecFromValues(D d, TFromD<D> t0, TFromD<D> t1,
TFromD<D> t2, TFromD<D> t3, TFromD<D> t4,
TFromD<D> t5, TFromD<D> t6, TFromD<D> t7,
TFromD<D> t8, TFromD<D> t9, TFromD<D> t10,
TFromD<D> t11, TFromD<D> t12,
TFromD<D> t13, TFromD<D> t14,
TFromD<D> t15) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = ret.v1 = Dup128VecFromValues(dh, t0, t1, t2, t3, t4, t5, t6, t7, t8,
t9, t10, t11, t12, t13, t14, t15);
return ret;
}
template <class D, HWY_IF_T_SIZE_D(D, 2), HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> Dup128VecFromValues(D d, TFromD<D> t0, TFromD<D> t1,
TFromD<D> t2, TFromD<D> t3, TFromD<D> t4,
TFromD<D> t5, TFromD<D> t6,
TFromD<D> t7) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = ret.v1 = Dup128VecFromValues(dh, t0, t1, t2, t3, t4, t5, t6, t7);
return ret;
}
template <class D, HWY_IF_T_SIZE_D(D, 4), HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> Dup128VecFromValues(D d, TFromD<D> t0, TFromD<D> t1,
TFromD<D> t2, TFromD<D> t3) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = ret.v1 = Dup128VecFromValues(dh, t0, t1, t2, t3);
return ret;
}
template <class D, HWY_IF_T_SIZE_D(D, 8), HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> Dup128VecFromValues(D d, TFromD<D> t0, TFromD<D> t1) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = ret.v1 = Dup128VecFromValues(dh, t0, t1);
return ret;
}
// ================================================== ARITHMETIC
template <typename T>
HWY_API Vec256<T> operator+(Vec256<T> a, const Vec256<T> b) {
a.v0 += b.v0;
a.v1 += b.v1;
return a;
}
template <typename T>
HWY_API Vec256<T> operator-(Vec256<T> a, const Vec256<T> b) {
a.v0 -= b.v0;
a.v1 -= b.v1;
return a;
}
// ------------------------------ SumsOf8
HWY_API Vec256<uint64_t> SumsOf8(const Vec256<uint8_t> v) {
Vec256<uint64_t> ret;
ret.v0 = SumsOf8(v.v0);
ret.v1 = SumsOf8(v.v1);
return ret;
}
HWY_API Vec256<int64_t> SumsOf8(const Vec256<int8_t> v) {
Vec256<int64_t> ret;
ret.v0 = SumsOf8(v.v0);
ret.v1 = SumsOf8(v.v1);
return ret;
}
template <typename T>
HWY_API Vec256<T> SaturatedAdd(Vec256<T> a, const Vec256<T> b) {
a.v0 = SaturatedAdd(a.v0, b.v0);
a.v1 = SaturatedAdd(a.v1, b.v1);
return a;
}
template <typename T>
HWY_API Vec256<T> SaturatedSub(Vec256<T> a, const Vec256<T> b) {
a.v0 = SaturatedSub(a.v0, b.v0);
a.v1 = SaturatedSub(a.v1, b.v1);
return a;
}
template <typename T>
HWY_API Vec256<T> AverageRound(Vec256<T> a, const Vec256<T> b) {
a.v0 = AverageRound(a.v0, b.v0);
a.v1 = AverageRound(a.v1, b.v1);
return a;
}
template <typename T>
HWY_API Vec256<T> Abs(Vec256<T> v) {
v.v0 = Abs(v.v0);
v.v1 = Abs(v.v1);
return v;
}
// ------------------------------ Shift lanes by constant #bits
template <int kBits, typename T>
HWY_API Vec256<T> ShiftLeft(Vec256<T> v) {
v.v0 = ShiftLeft<kBits>(v.v0);
v.v1 = ShiftLeft<kBits>(v.v1);
return v;
}
template <int kBits, typename T>
HWY_API Vec256<T> ShiftRight(Vec256<T> v) {
v.v0 = ShiftRight<kBits>(v.v0);
v.v1 = ShiftRight<kBits>(v.v1);
return v;
}
// ------------------------------ RotateRight (ShiftRight, Or)
template <int kBits, typename T>
HWY_API Vec256<T> RotateRight(const Vec256<T> v) {
constexpr size_t kSizeInBits = sizeof(T) * 8;
static_assert(0 <= kBits && kBits < kSizeInBits, "Invalid shift count");
if (kBits == 0) return v;
return Or(ShiftRight<kBits>(v), ShiftLeft<kSizeInBits - kBits>(v));
}
// ------------------------------ Shift lanes by same variable #bits
template <typename T>
HWY_API Vec256<T> ShiftLeftSame(Vec256<T> v, const int bits) {
v.v0 = ShiftLeftSame(v.v0, bits);
v.v1 = ShiftLeftSame(v.v1, bits);
return v;
}
template <typename T>
HWY_API Vec256<T> ShiftRightSame(Vec256<T> v, const int bits) {
v.v0 = ShiftRightSame(v.v0, bits);
v.v1 = ShiftRightSame(v.v1, bits);
return v;
}
// ------------------------------ Min, Max
template <typename T>
HWY_API Vec256<T> Min(Vec256<T> a, const Vec256<T> b) {
a.v0 = Min(a.v0, b.v0);
a.v1 = Min(a.v1, b.v1);
return a;
}
template <typename T>
HWY_API Vec256<T> Max(Vec256<T> a, const Vec256<T> b) {
a.v0 = Max(a.v0, b.v0);
a.v1 = Max(a.v1, b.v1);
return a;
}
// ------------------------------ Integer multiplication
template <typename T>
HWY_API Vec256<T> operator*(Vec256<T> a, const Vec256<T> b) {
a.v0 *= b.v0;
a.v1 *= b.v1;
return a;
}
template <typename T>
HWY_API Vec256<T> MulHigh(Vec256<T> a, const Vec256<T> b) {
a.v0 = MulHigh(a.v0, b.v0);
a.v1 = MulHigh(a.v1, b.v1);
return a;
}
template <typename T>
HWY_API Vec256<T> MulFixedPoint15(Vec256<T> a, const Vec256<T> b) {
a.v0 = MulFixedPoint15(a.v0, b.v0);
a.v1 = MulFixedPoint15(a.v1, b.v1);
return a;
}
// Cannot use MakeWide because that returns uint128_t for uint64_t, but we want
// uint64_t.
template <class T, HWY_IF_T_SIZE_ONE_OF(T, (1 << 1) | (1 << 2) | (1 << 4)),
HWY_IF_NOT_FLOAT_NOR_SPECIAL(T)>
HWY_API Vec256<MakeWide<T>> MulEven(Vec256<T> a, const Vec256<T> b) {
Vec256<MakeWide<T>> ret;
ret.v0 = MulEven(a.v0, b.v0);
ret.v1 = MulEven(a.v1, b.v1);
return ret;
}
HWY_API Vec256<uint64_t> MulEven(Vec256<uint64_t> a, const Vec256<uint64_t> b) {
Vec256<uint64_t> ret;
ret.v0 = MulEven(a.v0, b.v0);
ret.v1 = MulEven(a.v1, b.v1);
return ret;
}
template <class T, HWY_IF_T_SIZE_ONE_OF(T, (1 << 1) | (1 << 2) | (1 << 4)),
HWY_IF_NOT_FLOAT_NOR_SPECIAL(T)>
HWY_API Vec256<MakeWide<T>> MulOdd(Vec256<T> a, const Vec256<T> b) {
Vec256<MakeWide<T>> ret;
ret.v0 = MulOdd(a.v0, b.v0);
ret.v1 = MulOdd(a.v1, b.v1);
return ret;
}
HWY_API Vec256<uint64_t> MulOdd(Vec256<uint64_t> a, const Vec256<uint64_t> b) {
Vec256<uint64_t> ret;
ret.v0 = MulOdd(a.v0, b.v0);
ret.v1 = MulOdd(a.v1, b.v1);
return ret;
}
// ------------------------------ Negate
template <typename T>
HWY_API Vec256<T> Neg(Vec256<T> v) {
v.v0 = Neg(v.v0);
v.v1 = Neg(v.v1);
return v;
}
// ------------------------------ AbsDiff
// generic_ops takes care of integer T.
template <typename T, HWY_IF_FLOAT(T)>
HWY_API Vec256<T> AbsDiff(const Vec256<T> a, const Vec256<T> b) {
return Abs(a - b);
}
// ------------------------------ Floating-point division
// generic_ops takes care of integer T.
template <typename T, HWY_IF_FLOAT(T)>
HWY_API Vec256<T> operator/(Vec256<T> a, const Vec256<T> b) {
a.v0 /= b.v0;
a.v1 /= b.v1;
return a;
}
// Approximate reciprocal
HWY_API Vec256<float> ApproximateReciprocal(const Vec256<float> v) {
const Vec256<float> one = Set(Full256<float>(), 1.0f);
return one / v;
}
// ------------------------------ Floating-point multiply-add variants
HWY_API Vec256<float> MulAdd(Vec256<float> mul, Vec256<float> x,
Vec256<float> add) {
mul.v0 = MulAdd(mul.v0, x.v0, add.v0);
mul.v1 = MulAdd(mul.v1, x.v1, add.v1);
return mul;
}
HWY_API Vec256<float> NegMulAdd(Vec256<float> mul, Vec256<float> x,
Vec256<float> add) {
mul.v0 = NegMulAdd(mul.v0, x.v0, add.v0);
mul.v1 = NegMulAdd(mul.v1, x.v1, add.v1);
return mul;
}
HWY_API Vec256<float> MulSub(Vec256<float> mul, Vec256<float> x,
Vec256<float> sub) {
mul.v0 = MulSub(mul.v0, x.v0, sub.v0);
mul.v1 = MulSub(mul.v1, x.v1, sub.v1);
return mul;
}
HWY_API Vec256<float> NegMulSub(Vec256<float> mul, Vec256<float> x,
Vec256<float> sub) {
mul.v0 = NegMulSub(mul.v0, x.v0, sub.v0);
mul.v1 = NegMulSub(mul.v1, x.v1, sub.v1);
return mul;
}
// ------------------------------ Floating-point square root
template <typename T>
HWY_API Vec256<T> Sqrt(Vec256<T> v) {
v.v0 = Sqrt(v.v0);
v.v1 = Sqrt(v.v1);
return v;
}
// Approximate reciprocal square root
HWY_API Vec256<float> ApproximateReciprocalSqrt(const Vec256<float> v) {
// TODO(eustas): find cheaper a way to calculate this.
const Vec256<float> one = Set(Full256<float>(), 1.0f);
return one / Sqrt(v);
}
// ------------------------------ Floating-point rounding
// Toward nearest integer, ties to even
HWY_API Vec256<float> Round(Vec256<float> v) {
v.v0 = Round(v.v0);
v.v1 = Round(v.v1);
return v;
}
// Toward zero, aka truncate
HWY_API Vec256<float> Trunc(Vec256<float> v) {
v.v0 = Trunc(v.v0);
v.v1 = Trunc(v.v1);
return v;
}
// Toward +infinity, aka ceiling
HWY_API Vec256<float> Ceil(Vec256<float> v) {
v.v0 = Ceil(v.v0);
v.v1 = Ceil(v.v1);
return v;
}
// Toward -infinity, aka floor
HWY_API Vec256<float> Floor(Vec256<float> v) {
v.v0 = Floor(v.v0);
v.v1 = Floor(v.v1);
return v;
}
// ------------------------------ Floating-point classification
template <typename T>
HWY_API Mask256<T> IsNaN(const Vec256<T> v) {
return v != v;
}
template <typename T, HWY_IF_FLOAT(T)>
HWY_API Mask256<T> IsInf(const Vec256<T> v) {
const DFromV<decltype(v)> d;
const RebindToUnsigned<decltype(d)> du;
const VFromD<decltype(du)> vu = BitCast(du, v);
// 'Shift left' to clear the sign bit, check for exponent=max and mantissa=0.
return RebindMask(d, Eq(Add(vu, vu), Set(du, hwy::MaxExponentTimes2<T>())));
}
// Returns whether normal/subnormal/zero.
template <typename T, HWY_IF_FLOAT(T)>
HWY_API Mask256<T> IsFinite(const Vec256<T> v) {
const DFromV<decltype(v)> d;
const RebindToUnsigned<decltype(d)> du;
const RebindToSigned<decltype(d)> di; // cheaper than unsigned comparison
const VFromD<decltype(du)> vu = BitCast(du, v);
// 'Shift left' to clear the sign bit, then right so we can compare with the
// max exponent (cannot compare with MaxExponentTimes2 directly because it is
// negative and non-negative floats would be greater).
const VFromD<decltype(di)> exp =
BitCast(di, ShiftRight<hwy::MantissaBits<T>() + 1>(Add(vu, vu)));
return RebindMask(d, Lt(exp, Set(di, hwy::MaxExponentField<T>())));
}
// ================================================== COMPARE
// Comparisons fill a lane with 1-bits if the condition is true, else 0.
template <class DTo, typename TFrom, typename TTo = TFromD<DTo>>
HWY_API MFromD<DTo> RebindMask(DTo /*tag*/, Mask256<TFrom> m) {
static_assert(sizeof(TFrom) == sizeof(TTo), "Must have same size");
return MFromD<DTo>{Mask128<TTo>{m.m0.raw}, Mask128<TTo>{m.m1.raw}};
}
template <typename T>
HWY_API Mask256<T> TestBit(Vec256<T> v, Vec256<T> bit) {
static_assert(!hwy::IsFloat<T>(), "Only integer vectors supported");
return (v & bit) == bit;
}
template <typename T>
HWY_API Mask256<T> operator==(Vec256<T> a, const Vec256<T> b) {
Mask256<T> m;
m.m0 = operator==(a.v0, b.v0);
m.m1 = operator==(a.v1, b.v1);
return m;
}
template <typename T>
HWY_API Mask256<T> operator!=(Vec256<T> a, const Vec256<T> b) {
Mask256<T> m;
m.m0 = operator!=(a.v0, b.v0);
m.m1 = operator!=(a.v1, b.v1);
return m;
}
template <typename T>
HWY_API Mask256<T> operator<(Vec256<T> a, const Vec256<T> b) {
Mask256<T> m;
m.m0 = operator<(a.v0, b.v0);
m.m1 = operator<(a.v1, b.v1);
return m;
}
template <typename T>
HWY_API Mask256<T> operator>(Vec256<T> a, const Vec256<T> b) {
Mask256<T> m;
m.m0 = operator>(a.v0, b.v0);
m.m1 = operator>(a.v1, b.v1);
return m;
}
template <typename T>
HWY_API Mask256<T> operator<=(Vec256<T> a, const Vec256<T> b) {
Mask256<T> m;
m.m0 = operator<=(a.v0, b.v0);
m.m1 = operator<=(a.v1, b.v1);
return m;
}
template <typename T>
HWY_API Mask256<T> operator>=(Vec256<T> a, const Vec256<T> b) {
Mask256<T> m;
m.m0 = operator>=(a.v0, b.v0);
m.m1 = operator>=(a.v1, b.v1);
return m;
}
// ------------------------------ FirstN (Iota, Lt)
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API MFromD<D> FirstN(const D d, size_t num) {
const RebindToSigned<decltype(d)> di; // Signed comparisons may be cheaper.
using TI = TFromD<decltype(di)>;
return RebindMask(d, Iota(di, 0) < Set(di, static_cast<TI>(num)));
}
// ================================================== LOGICAL
template <typename T>
HWY_API Vec256<T> Not(Vec256<T> v) {
v.v0 = Not(v.v0);
v.v1 = Not(v.v1);
return v;
}
template <typename T>
HWY_API Vec256<T> And(Vec256<T> a, Vec256<T> b) {
a.v0 = And(a.v0, b.v0);
a.v1 = And(a.v1, b.v1);
return a;
}
template <typename T>
HWY_API Vec256<T> AndNot(Vec256<T> not_mask, Vec256<T> mask) {
not_mask.v0 = AndNot(not_mask.v0, mask.v0);
not_mask.v1 = AndNot(not_mask.v1, mask.v1);
return not_mask;
}
template <typename T>
HWY_API Vec256<T> Or(Vec256<T> a, Vec256<T> b) {
a.v0 = Or(a.v0, b.v0);
a.v1 = Or(a.v1, b.v1);
return a;
}
template <typename T>
HWY_API Vec256<T> Xor(Vec256<T> a, Vec256<T> b) {
a.v0 = Xor(a.v0, b.v0);
a.v1 = Xor(a.v1, b.v1);
return a;
}
template <typename T>
HWY_API Vec256<T> Xor3(Vec256<T> x1, Vec256<T> x2, Vec256<T> x3) {
return Xor(x1, Xor(x2, x3));
}
template <typename T>
HWY_API Vec256<T> Or3(Vec256<T> o1, Vec256<T> o2, Vec256<T> o3) {
return Or(o1, Or(o2, o3));
}
template <typename T>
HWY_API Vec256<T> OrAnd(Vec256<T> o, Vec256<T> a1, Vec256<T> a2) {
return Or(o, And(a1, a2));
}
template <typename T>
HWY_API Vec256<T> IfVecThenElse(Vec256<T> mask, Vec256<T> yes, Vec256<T> no) {
return IfThenElse(MaskFromVec(mask), yes, no);
}
// ------------------------------ Operator overloads (internal-only if float)
template <typename T>
HWY_API Vec256<T> operator&(const Vec256<T> a, const Vec256<T> b) {
return And(a, b);
}
template <typename T>
HWY_API Vec256<T> operator|(const Vec256<T> a, const Vec256<T> b) {
return Or(a, b);
}
template <typename T>
HWY_API Vec256<T> operator^(const Vec256<T> a, const Vec256<T> b) {
return Xor(a, b);
}
// ------------------------------ CopySign
template <typename T>
HWY_API Vec256<T> CopySign(const Vec256<T> magn, const Vec256<T> sign) {
static_assert(IsFloat<T>(), "Only makes sense for floating-point");
const DFromV<decltype(magn)> d;
return BitwiseIfThenElse(SignBit(d), sign, magn);
}
// ------------------------------ CopySignToAbs
template <typename T>
HWY_API Vec256<T> CopySignToAbs(const Vec256<T> abs, const Vec256<T> sign) {
static_assert(IsFloat<T>(), "Only makes sense for floating-point");
const DFromV<decltype(sign)> d;
return OrAnd(abs, SignBit(d), sign);
}
// ------------------------------ Mask
// Mask and Vec are the same (true = FF..FF).
template <typename T>
HWY_API Mask256<T> MaskFromVec(const Vec256<T> v) {
Mask256<T> m;
m.m0 = MaskFromVec(v.v0);
m.m1 = MaskFromVec(v.v1);
return m;
}
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> VecFromMask(D d, Mask256<T> m) {
const Half<decltype(d)> dh;
Vec256<T> v;
v.v0 = VecFromMask(dh, m.m0);
v.v1 = VecFromMask(dh, m.m1);
return v;
}
// mask ? yes : no
template <typename T>
HWY_API Vec256<T> IfThenElse(Mask256<T> mask, Vec256<T> yes, Vec256<T> no) {
yes.v0 = IfThenElse(mask.m0, yes.v0, no.v0);
yes.v1 = IfThenElse(mask.m1, yes.v1, no.v1);
return yes;
}
// mask ? yes : 0
template <typename T>
HWY_API Vec256<T> IfThenElseZero(Mask256<T> mask, Vec256<T> yes) {
return yes & VecFromMask(DFromV<decltype(yes)>(), mask);
}
// mask ? 0 : no
template <typename T>
HWY_API Vec256<T> IfThenZeroElse(Mask256<T> mask, Vec256<T> no) {
return AndNot(VecFromMask(DFromV<decltype(no)>(), mask), no);
}
template <typename T>
HWY_API Vec256<T> IfNegativeThenElse(Vec256<T> v, Vec256<T> yes, Vec256<T> no) {
v.v0 = IfNegativeThenElse(v.v0, yes.v0, no.v0);
v.v1 = IfNegativeThenElse(v.v1, yes.v1, no.v1);
return v;
}
template <typename T, HWY_IF_FLOAT(T)>
HWY_API Vec256<T> ZeroIfNegative(Vec256<T> v) {
return IfThenZeroElse(v < Zero(DFromV<decltype(v)>()), v);
}
// ------------------------------ Mask logical
template <typename T>
HWY_API Mask256<T> Not(const Mask256<T> m) {
return MaskFromVec(Not(VecFromMask(Full256<T>(), m)));
}
template <typename T>
HWY_API Mask256<T> And(const Mask256<T> a, Mask256<T> b) {
const Full256<T> d;
return MaskFromVec(And(VecFromMask(d, a), VecFromMask(d, b)));
}
template <typename T>
HWY_API Mask256<T> AndNot(const Mask256<T> a, Mask256<T> b) {
const Full256<T> d;
return MaskFromVec(AndNot(VecFromMask(d, a), VecFromMask(d, b)));
}
template <typename T>
HWY_API Mask256<T> Or(const Mask256<T> a, Mask256<T> b) {
const Full256<T> d;
return MaskFromVec(Or(VecFromMask(d, a), VecFromMask(d, b)));
}
template <typename T>
HWY_API Mask256<T> Xor(const Mask256<T> a, Mask256<T> b) {
const Full256<T> d;
return MaskFromVec(Xor(VecFromMask(d, a), VecFromMask(d, b)));
}
template <typename T>
HWY_API Mask256<T> ExclusiveNeither(const Mask256<T> a, Mask256<T> b) {
const Full256<T> d;
return MaskFromVec(AndNot(VecFromMask(d, a), Not(VecFromMask(d, b))));
}
// ------------------------------ Shl (BroadcastSignBit, IfThenElse)
template <typename T, HWY_IF_NOT_FLOAT_NOR_SPECIAL(T)>
HWY_API Vec256<T> operator<<(Vec256<T> v, const Vec256<T> bits) {
v.v0 = operator<<(v.v0, bits.v0);
v.v1 = operator<<(v.v1, bits.v1);
return v;
}
// ------------------------------ Shr (BroadcastSignBit, IfThenElse)
template <typename T, HWY_IF_NOT_FLOAT_NOR_SPECIAL(T)>
HWY_API Vec256<T> operator>>(Vec256<T> v, const Vec256<T> bits) {
v.v0 = operator>>(v.v0, bits.v0);
v.v1 = operator>>(v.v1, bits.v1);
return v;
}
// ------------------------------ BroadcastSignBit (compare, VecFromMask)
template <typename T, HWY_IF_NOT_T_SIZE(T, 1)>
HWY_API Vec256<T> BroadcastSignBit(const Vec256<T> v) {
return ShiftRight<sizeof(T) * 8 - 1>(v);
}
HWY_API Vec256<int8_t> BroadcastSignBit(const Vec256<int8_t> v) {
const DFromV<decltype(v)> d;
return VecFromMask(d, v < Zero(d));
}
// ================================================== MEMORY
// ------------------------------ Load
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> Load(D d, const TFromD<D>* HWY_RESTRICT aligned) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = Load(dh, aligned);
ret.v1 = Load(dh, aligned + Lanes(dh));
return ret;
}
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> MaskedLoad(Mask256<T> m, D d, const T* HWY_RESTRICT aligned) {
return IfThenElseZero(m, Load(d, aligned));
}
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> MaskedLoadOr(Vec256<T> v, Mask256<T> m, D d,
const T* HWY_RESTRICT aligned) {
return IfThenElse(m, Load(d, aligned), v);
}
// LoadU == Load.
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> LoadU(D d, const TFromD<D>* HWY_RESTRICT p) {
return Load(d, p);
}
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> LoadDup128(D d, const TFromD<D>* HWY_RESTRICT p) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = ret.v1 = Load(dh, p);
return ret;
}
// ------------------------------ Store
template <class D, typename T = TFromD<D>>
HWY_API void Store(Vec256<T> v, D d, T* HWY_RESTRICT aligned) {
const Half<decltype(d)> dh;
Store(v.v0, dh, aligned);
Store(v.v1, dh, aligned + Lanes(dh));
}
// StoreU == Store.
template <class D, typename T = TFromD<D>>
HWY_API void StoreU(Vec256<T> v, D d, T* HWY_RESTRICT p) {
Store(v, d, p);
}
template <class D, typename T = TFromD<D>>
HWY_API void BlendedStore(Vec256<T> v, Mask256<T> m, D d, T* HWY_RESTRICT p) {
StoreU(IfThenElse(m, v, LoadU(d, p)), d, p);
}
// ------------------------------ Stream
template <class D, typename T = TFromD<D>>
HWY_API void Stream(Vec256<T> v, D d, T* HWY_RESTRICT aligned) {
// Same as aligned stores.
Store(v, d, aligned);
}
// ------------------------------ Scatter, Gather defined in wasm_128
// ================================================== SWIZZLE
// ------------------------------ ExtractLane
template <typename T>
HWY_API T ExtractLane(const Vec256<T> v, size_t i) {
alignas(32) T lanes[32 / sizeof(T)];
Store(v, DFromV<decltype(v)>(), lanes);
return lanes[i];
}
// ------------------------------ InsertLane
template <typename T>
HWY_API Vec256<T> InsertLane(const Vec256<T> v, size_t i, T t) {
DFromV<decltype(v)> d;
alignas(32) T lanes[32 / sizeof(T)];
Store(v, d, lanes);
lanes[i] = t;
return Load(d, lanes);
}
// ------------------------------ ExtractBlock
template <int kBlockIdx, class T>
HWY_API Vec128<T> ExtractBlock(Vec256<T> v) {
static_assert(kBlockIdx == 0 || kBlockIdx == 1, "Invalid block index");
return (kBlockIdx == 0) ? v.v0 : v.v1;
}
// ------------------------------ InsertBlock
template <int kBlockIdx, class T>
HWY_API Vec256<T> InsertBlock(Vec256<T> v, Vec128<T> blk_to_insert) {
static_assert(kBlockIdx == 0 || kBlockIdx == 1, "Invalid block index");
Vec256<T> result;
if (kBlockIdx == 0) {
result.v0 = blk_to_insert;
result.v1 = v.v1;
} else {
result.v0 = v.v0;
result.v1 = blk_to_insert;
}
return result;
}
// ------------------------------ BroadcastBlock
template <int kBlockIdx, class T>
HWY_API Vec256<T> BroadcastBlock(Vec256<T> v) {
static_assert(kBlockIdx == 0 || kBlockIdx == 1, "Invalid block index");
Vec256<T> result;
result.v0 = result.v1 = (kBlockIdx == 0 ? v.v0 : v.v1);
return result;
}
// ------------------------------ LowerHalf
template <class D, typename T = TFromD<D>>
HWY_API Vec128<T> LowerHalf(D /* tag */, Vec256<T> v) {
return v.v0;
}
template <typename T>
HWY_API Vec128<T> LowerHalf(Vec256<T> v) {
return v.v0;
}
// ------------------------------ GetLane (LowerHalf)
template <typename T>
HWY_API T GetLane(const Vec256<T> v) {
return GetLane(LowerHalf(v));
}
// ------------------------------ ShiftLeftBytes
template <int kBytes, class D, typename T = TFromD<D>>
HWY_API Vec256<T> ShiftLeftBytes(D d, Vec256<T> v) {
const Half<decltype(d)> dh;
v.v0 = ShiftLeftBytes<kBytes>(dh, v.v0);
v.v1 = ShiftLeftBytes<kBytes>(dh, v.v1);
return v;
}
template <int kBytes, typename T>
HWY_API Vec256<T> ShiftLeftBytes(Vec256<T> v) {
return ShiftLeftBytes<kBytes>(DFromV<decltype(v)>(), v);
}
// ------------------------------ ShiftLeftLanes
template <int kLanes, class D, typename T = TFromD<D>>
HWY_API Vec256<T> ShiftLeftLanes(D d, const Vec256<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 Vec256<T> ShiftLeftLanes(const Vec256<T> v) {
return ShiftLeftLanes<kLanes>(DFromV<decltype(v)>(), v);
}
// ------------------------------ ShiftRightBytes
template <int kBytes, class D, typename T = TFromD<D>>
HWY_API Vec256<T> ShiftRightBytes(D d, Vec256<T> v) {
const Half<decltype(d)> dh;
v.v0 = ShiftRightBytes<kBytes>(dh, v.v0);
v.v1 = ShiftRightBytes<kBytes>(dh, v.v1);
return v;
}
// ------------------------------ ShiftRightLanes
template <int kLanes, class D, typename T = TFromD<D>>
HWY_API Vec256<T> ShiftRightLanes(D d, const Vec256<T> v) {
const Repartition<uint8_t, decltype(d)> d8;
return BitCast(d, ShiftRightBytes<kLanes * sizeof(T)>(d8, BitCast(d8, v)));
}
// ------------------------------ UpperHalf (ShiftRightBytes)
template <class D, typename T = TFromD<D>>
HWY_API Vec128<T> UpperHalf(D /* tag */, const Vec256<T> v) {
return v.v1;
}
// ------------------------------ CombineShiftRightBytes
template <int kBytes, class D, typename T = TFromD<D>>
HWY_API Vec256<T> CombineShiftRightBytes(D d, Vec256<T> hi, Vec256<T> lo) {
const Half<decltype(d)> dh;
hi.v0 = CombineShiftRightBytes<kBytes>(dh, hi.v0, lo.v0);
hi.v1 = CombineShiftRightBytes<kBytes>(dh, hi.v1, lo.v1);
return hi;
}
// ------------------------------ Broadcast/splat any lane
template <int kLane, typename T>
HWY_API Vec256<T> Broadcast(const Vec256<T> v) {
Vec256<T> ret;
ret.v0 = Broadcast<kLane>(v.v0);
ret.v1 = Broadcast<kLane>(v.v1);
return ret;
}
template <int kLane, typename T>
HWY_API Vec256<T> BroadcastLane(const Vec256<T> v) {
constexpr int kLanesPerBlock = static_cast<int>(16 / sizeof(T));
static_assert(0 <= kLane && kLane < kLanesPerBlock * 2, "Invalid lane");
constexpr int kLaneInBlkIdx = kLane & (kLanesPerBlock - 1);
Vec256<T> ret;
ret.v0 = ret.v1 =
Broadcast<kLaneInBlkIdx>(kLane >= kLanesPerBlock ? v.v1 : v.v0);
return ret;
}
// ------------------------------ TableLookupBytes
// Both full
template <typename T, typename TI>
HWY_API Vec256<TI> TableLookupBytes(const Vec256<T> bytes, Vec256<TI> from) {
from.v0 = TableLookupBytes(bytes.v0, from.v0);
from.v1 = TableLookupBytes(bytes.v1, from.v1);
return from;
}
// Partial index vector
template <typename T, typename TI, size_t NI>
HWY_API Vec128<TI, NI> TableLookupBytes(Vec256<T> bytes,
const Vec128<TI, NI> from) {
// First expand to full 128, then 256.
const auto from_256 = ZeroExtendVector(Full256<TI>(), Vec128<TI>{from.raw});
const auto tbl_full = TableLookupBytes(bytes, from_256);
// Shrink to 128, then partial.
return Vec128<TI, NI>{LowerHalf(Full128<TI>(), tbl_full).raw};
}
// Partial table vector
template <typename T, size_t N, typename TI>
HWY_API Vec256<TI> TableLookupBytes(Vec128<T, N> bytes, const Vec256<TI> from) {
// First expand to full 128, then 256.
const auto bytes_256 = ZeroExtendVector(Full256<T>(), Vec128<T>{bytes.raw});
return TableLookupBytes(bytes_256, from);
}
// Partial both are handled by wasm_128.
template <class V, class VI>
HWY_API VI TableLookupBytesOr0(V bytes, VI from) {
// wasm out-of-bounds policy already zeros, so TableLookupBytes is fine.
return TableLookupBytes(bytes, from);
}
// ------------------------------ Hard-coded shuffles
template <typename T>
HWY_API Vec256<T> Shuffle01(Vec256<T> v) {
v.v0 = Shuffle01(v.v0);
v.v1 = Shuffle01(v.v1);
return v;
}
template <typename T>
HWY_API Vec256<T> Shuffle2301(Vec256<T> v) {
v.v0 = Shuffle2301(v.v0);
v.v1 = Shuffle2301(v.v1);
return v;
}
template <typename T>
HWY_API Vec256<T> Shuffle1032(Vec256<T> v) {
v.v0 = Shuffle1032(v.v0);
v.v1 = Shuffle1032(v.v1);
return v;
}
template <typename T>
HWY_API Vec256<T> Shuffle0321(Vec256<T> v) {
v.v0 = Shuffle0321(v.v0);
v.v1 = Shuffle0321(v.v1);
return v;
}
template <typename T>
HWY_API Vec256<T> Shuffle2103(Vec256<T> v) {
v.v0 = Shuffle2103(v.v0);
v.v1 = Shuffle2103(v.v1);
return v;
}
template <typename T>
HWY_API Vec256<T> Shuffle0123(Vec256<T> v) {
v.v0 = Shuffle0123(v.v0);
v.v1 = Shuffle0123(v.v1);
return v;
}
// Used by generic_ops-inl.h
namespace detail {
template <typename T, HWY_IF_T_SIZE(T, 4)>
HWY_API Vec256<T> ShuffleTwo2301(Vec256<T> a, const Vec256<T> b) {
a.v0 = ShuffleTwo2301(a.v0, b.v0);
a.v1 = ShuffleTwo2301(a.v1, b.v1);
return a;
}
template <typename T, HWY_IF_T_SIZE(T, 4)>
HWY_API Vec256<T> ShuffleTwo1230(Vec256<T> a, const Vec256<T> b) {
a.v0 = ShuffleTwo1230(a.v0, b.v0);
a.v1 = ShuffleTwo1230(a.v1, b.v1);
return a;
}
template <typename T, HWY_IF_T_SIZE(T, 4)>
HWY_API Vec256<T> ShuffleTwo3012(Vec256<T> a, const Vec256<T> b) {
a.v0 = ShuffleTwo3012(a.v0, b.v0);
a.v1 = ShuffleTwo3012(a.v1, b.v1);
return a;
}
} // namespace detail
// ------------------------------ TableLookupLanes
// Returned by SetTableIndices for use by TableLookupLanes.
template <typename T>
struct Indices256 {
__v128_u i0;
__v128_u i1;
};
template <class D, typename T = TFromD<D>, typename TI>
HWY_API Indices256<T> IndicesFromVec(D /* tag */, Vec256<TI> vec) {
static_assert(sizeof(T) == sizeof(TI), "Index size must match lane");
Indices256<T> ret;
ret.i0 = vec.v0.raw;
ret.i1 = vec.v1.raw;
return ret;
}
template <class D, HWY_IF_V_SIZE_D(D, 32), typename TI>
HWY_API Indices256<TFromD<D>> SetTableIndices(D d, const TI* idx) {
const Rebind<TI, decltype(d)> di;
return IndicesFromVec(d, LoadU(di, idx));
}
template <typename T>
HWY_API Vec256<T> TableLookupLanes(const Vec256<T> v, Indices256<T> idx) {
const DFromV<decltype(v)> d;
const Half<decltype(d)> dh;
const auto idx_i0 = IndicesFromVec(dh, Vec128<T>{idx.i0});
const auto idx_i1 = IndicesFromVec(dh, Vec128<T>{idx.i1});
Vec256<T> result;
result.v0 = TwoTablesLookupLanes(v.v0, v.v1, idx_i0);
result.v1 = TwoTablesLookupLanes(v.v0, v.v1, idx_i1);
return result;
}
template <typename T>
HWY_API Vec256<T> TableLookupLanesOr0(Vec256<T> v, Indices256<T> idx) {
// The out of bounds behavior will already zero lanes.
return TableLookupLanesOr0(v, idx);
}
template <typename T>
HWY_API Vec256<T> TwoTablesLookupLanes(const Vec256<T> a, const Vec256<T> b,
Indices256<T> idx) {
const DFromV<decltype(a)> d;
const Half<decltype(d)> dh;
const RebindToUnsigned<decltype(d)> du;
using TU = MakeUnsigned<T>;
constexpr size_t kLanesPerVect = 32 / sizeof(TU);
Vec256<TU> vi;
vi.v0 = Vec128<TU>{idx.i0};
vi.v1 = Vec128<TU>{idx.i1};
const auto vmod = vi & Set(du, TU{kLanesPerVect - 1});
const auto is_lo = RebindMask(d, vi == vmod);
const auto idx_i0 = IndicesFromVec(dh, vmod.v0);
const auto idx_i1 = IndicesFromVec(dh, vmod.v1);
Vec256<T> result_lo;
Vec256<T> result_hi;
result_lo.v0 = TwoTablesLookupLanes(a.v0, a.v1, idx_i0);
result_lo.v1 = TwoTablesLookupLanes(a.v0, a.v1, idx_i1);
result_hi.v0 = TwoTablesLookupLanes(b.v0, b.v1, idx_i0);
result_hi.v1 = TwoTablesLookupLanes(b.v0, b.v1, idx_i1);
return IfThenElse(is_lo, result_lo, result_hi);
}
// ------------------------------ Reverse
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> Reverse(D d, const Vec256<T> v) {
const Half<decltype(d)> dh;
Vec256<T> ret;
ret.v1 = Reverse(dh, v.v0); // note reversed v1 member order
ret.v0 = Reverse(dh, v.v1);
return ret;
}
// ------------------------------ Reverse2
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> Reverse2(D d, Vec256<T> v) {
const Half<decltype(d)> dh;
v.v0 = Reverse2(dh, v.v0);
v.v1 = Reverse2(dh, v.v1);
return v;
}
// ------------------------------ Reverse4
// Each block has only 2 lanes, so swap blocks and their lanes.
template <class D, typename T = TFromD<D>, HWY_IF_T_SIZE(T, 8)>
HWY_API Vec256<T> Reverse4(D d, const Vec256<T> v) {
const Half<decltype(d)> dh;
Vec256<T> ret;
ret.v0 = Reverse2(dh, v.v1); // swapped
ret.v1 = Reverse2(dh, v.v0);
return ret;
}
template <class D, typename T = TFromD<D>, HWY_IF_NOT_T_SIZE(T, 8)>
HWY_API Vec256<T> Reverse4(D d, Vec256<T> v) {
const Half<decltype(d)> dh;
v.v0 = Reverse4(dh, v.v0);
v.v1 = Reverse4(dh, v.v1);
return v;
}
// ------------------------------ Reverse8
template <class D, typename T = TFromD<D>, HWY_IF_T_SIZE(T, 8)>
HWY_API Vec256<T> Reverse8(D /* tag */, Vec256<T> /* v */) {
HWY_ASSERT(0); // don't have 8 u64 lanes
}
// Each block has only 4 lanes, so swap blocks and their lanes.
template <class D, typename T = TFromD<D>, HWY_IF_T_SIZE(T, 4)>
HWY_API Vec256<T> Reverse8(D d, const Vec256<T> v) {
const Half<decltype(d)> dh;
Vec256<T> ret;
ret.v0 = Reverse4(dh, v.v1); // swapped
ret.v1 = Reverse4(dh, v.v0);
return ret;
}
template <class D, typename T = TFromD<D>,
HWY_IF_T_SIZE_ONE_OF(T, (1 << 1) | (1 << 2))>
HWY_API Vec256<T> Reverse8(D d, Vec256<T> v) {
const Half<decltype(d)> dh;
v.v0 = Reverse8(dh, v.v0);
v.v1 = Reverse8(dh, v.v1);
return v;
}
// ------------------------------ InterleaveLower
template <typename T>
HWY_API Vec256<T> InterleaveLower(Vec256<T> a, Vec256<T> b) {
a.v0 = InterleaveLower(a.v0, b.v0);
a.v1 = InterleaveLower(a.v1, b.v1);
return a;
}
// wasm_128 already defines a template with D, V, V args.
// ------------------------------ InterleaveUpper (UpperHalf)
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> InterleaveUpper(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
a.v0 = InterleaveUpper(dh, a.v0, b.v0);
a.v1 = InterleaveUpper(dh, a.v1, b.v1);
return a;
}
// ------------------------------ InterleaveWholeLower
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> InterleaveWholeLower(D d, VFromD<D> a, VFromD<D> b) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = InterleaveLower(a.v0, b.v0);
ret.v1 = InterleaveUpper(dh, a.v0, b.v0);
return ret;
}
// ------------------------------ InterleaveWholeUpper
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> InterleaveWholeUpper(D d, VFromD<D> a, VFromD<D> b) {
const Half<decltype(d)> dh;
VFromD<D> ret;
ret.v0 = InterleaveLower(a.v1, b.v1);
ret.v1 = InterleaveUpper(dh, a.v1, b.v1);
return ret;
}
// ------------------------------ ZipLower/ZipUpper defined in wasm_128
// ================================================== COMBINE
// ------------------------------ Combine (InterleaveLower)
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> Combine(D /* d */, Vec128<T> hi, Vec128<T> lo) {
Vec256<T> ret;
ret.v1 = hi;
ret.v0 = lo;
return ret;
}
// ------------------------------ ZeroExtendVector (Combine)
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> ZeroExtendVector(D d, Vec128<T> lo) {
const Half<decltype(d)> dh;
return Combine(d, Zero(dh), lo);
}
// ------------------------------ ZeroExtendResizeBitCast
namespace detail {
template <size_t kFromVectSize, class DTo, class DFrom,
HWY_IF_LANES_LE(kFromVectSize, 8)>
HWY_INLINE VFromD<DTo> ZeroExtendResizeBitCast(
hwy::SizeTag<kFromVectSize> /* from_size_tag */,
hwy::SizeTag<32> /* to_size_tag */, DTo d_to, DFrom d_from,
VFromD<DFrom> v) {
const Half<decltype(d_to)> dh_to;
return ZeroExtendVector(d_to, ZeroExtendResizeBitCast(dh_to, d_from, v));
}
} // namespace detail
// ------------------------------ ConcatLowerLower
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> ConcatLowerLower(D /* tag */, Vec256<T> hi, Vec256<T> lo) {
Vec256<T> ret;
ret.v1 = hi.v0;
ret.v0 = lo.v0;
return ret;
}
// ------------------------------ ConcatUpperUpper
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> ConcatUpperUpper(D /* tag */, Vec256<T> hi, Vec256<T> lo) {
Vec256<T> ret;
ret.v1 = hi.v1;
ret.v0 = lo.v1;
return ret;
}
// ------------------------------ ConcatLowerUpper
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> ConcatLowerUpper(D /* tag */, Vec256<T> hi, Vec256<T> lo) {
Vec256<T> ret;
ret.v1 = hi.v0;
ret.v0 = lo.v1;
return ret;
}
// ------------------------------ ConcatUpperLower
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> ConcatUpperLower(D /* tag */, Vec256<T> hi, Vec256<T> lo) {
Vec256<T> ret;
ret.v1 = hi.v1;
ret.v0 = lo.v0;
return ret;
}
// ------------------------------ ConcatOdd
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> ConcatOdd(D d, Vec256<T> hi, Vec256<T> lo) {
const Half<decltype(d)> dh;
Vec256<T> ret;
ret.v0 = ConcatOdd(dh, lo.v1, lo.v0);
ret.v1 = ConcatOdd(dh, hi.v1, hi.v0);
return ret;
}
// ------------------------------ ConcatEven
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> ConcatEven(D d, Vec256<T> hi, Vec256<T> lo) {
const Half<decltype(d)> dh;
Vec256<T> ret;
ret.v0 = ConcatEven(dh, lo.v1, lo.v0);
ret.v1 = ConcatEven(dh, hi.v1, hi.v0);
return ret;
}
// ------------------------------ DupEven
template <typename T>
HWY_API Vec256<T> DupEven(Vec256<T> v) {
v.v0 = DupEven(v.v0);
v.v1 = DupEven(v.v1);
return v;
}
// ------------------------------ DupOdd
template <typename T>
HWY_API Vec256<T> DupOdd(Vec256<T> v) {
v.v0 = DupOdd(v.v0);
v.v1 = DupOdd(v.v1);
return v;
}
// ------------------------------ OddEven
template <typename T>
HWY_API Vec256<T> OddEven(Vec256<T> a, const Vec256<T> b) {
a.v0 = OddEven(a.v0, b.v0);
a.v1 = OddEven(a.v1, b.v1);
return a;
}
// ------------------------------ OddEvenBlocks
template <typename T>
HWY_API Vec256<T> OddEvenBlocks(Vec256<T> odd, Vec256<T> even) {
odd.v0 = even.v0;
return odd;
}
// ------------------------------ SwapAdjacentBlocks
template <typename T>
HWY_API Vec256<T> SwapAdjacentBlocks(Vec256<T> v) {
Vec256<T> ret;
ret.v0 = v.v1; // swapped order
ret.v1 = v.v0;
return ret;
}
// ------------------------------ ReverseBlocks
template <class D, typename T = TFromD<D>>
HWY_API Vec256<T> ReverseBlocks(D /* tag */, const Vec256<T> v) {
return SwapAdjacentBlocks(v); // 2 blocks, so Swap = Reverse
}
// ------------------------------ Per4LaneBlockShuffle
namespace detail {
template <size_t kIdx3210, class V>
HWY_INLINE V Per4LaneBlockShuffle(hwy::SizeTag<kIdx3210> /*idx_3210_tag*/,
hwy::SizeTag<1> /*lane_size_tag*/,
hwy::SizeTag<32> /*vect_size_tag*/, V v) {
const DFromV<decltype(v)> d;
const Half<decltype(d)> dh;
using VH = VFromD<decltype(dh)>;
constexpr int kIdx3 = static_cast<int>((kIdx3210 >> 6) & 3);
constexpr int kIdx2 = static_cast<int>((kIdx3210 >> 4) & 3);
constexpr int kIdx1 = static_cast<int>((kIdx3210 >> 2) & 3);
constexpr int kIdx0 = static_cast<int>(kIdx3210 & 3);
V ret;
ret.v0 = VH{wasm_i8x16_shuffle(
v.v0.raw, v.v0.raw, kIdx0, kIdx1, kIdx2, kIdx3, kIdx0 + 4, kIdx1 + 4,
kIdx2 + 4, kIdx3 + 4, kIdx0 + 8, kIdx1 + 8, kIdx2 + 8, kIdx3 + 8,
kIdx0 + 12, kIdx1 + 12, kIdx2 + 12, kIdx3 + 12)};
ret.v1 = VH{wasm_i8x16_shuffle(
v.v1.raw, v.v1.raw, kIdx0, kIdx1, kIdx2, kIdx3, kIdx0 + 4, kIdx1 + 4,
kIdx2 + 4, kIdx3 + 4, kIdx0 + 8, kIdx1 + 8, kIdx2 + 8, kIdx3 + 8,
kIdx0 + 12, kIdx1 + 12, kIdx2 + 12, kIdx3 + 12)};
return ret;
}
template <size_t kIdx3210, class V>
HWY_INLINE V Per4LaneBlockShuffle(hwy::SizeTag<kIdx3210> /*idx_3210_tag*/,
hwy::SizeTag<2> /*lane_size_tag*/,
hwy::SizeTag<32> /*vect_size_tag*/, V v) {
const DFromV<decltype(v)> d;
const Half<decltype(d)> dh;
using VH = VFromD<decltype(dh)>;
constexpr int kIdx3 = static_cast<int>((kIdx3210 >> 6) & 3);
constexpr int kIdx2 = static_cast<int>((kIdx3210 >> 4) & 3);
constexpr int kIdx1 = static_cast<int>((kIdx3210 >> 2) & 3);
constexpr int kIdx0 = static_cast<int>(kIdx3210 & 3);
V ret;
ret.v0 = VH{wasm_i16x8_shuffle(v.v0.raw, v.v0.raw, kIdx0, kIdx1, kIdx2, kIdx3,
kIdx0 + 4, kIdx1 + 4, kIdx2 + 4, kIdx3 + 4)};
ret.v1 = VH{wasm_i16x8_shuffle(v.v1.raw, v.v1.raw, kIdx0, kIdx1, kIdx2, kIdx3,
kIdx0 + 4, kIdx1 + 4, kIdx2 + 4, kIdx3 + 4)};
return ret;
}
template <size_t kIdx3210, class V>
HWY_INLINE V Per4LaneBlockShuffle(hwy::SizeTag<kIdx3210> /*idx_3210_tag*/,
hwy::SizeTag<4> /*lane_size_tag*/,
hwy::SizeTag<32> /*vect_size_tag*/, V v) {
const DFromV<decltype(v)> d;
const Half<decltype(d)> dh;
using VH = VFromD<decltype(dh)>;
constexpr int kIdx3 = static_cast<int>((kIdx3210 >> 6) & 3);
constexpr int kIdx2 = static_cast<int>((kIdx3210 >> 4) & 3);
constexpr int kIdx1 = static_cast<int>((kIdx3210 >> 2) & 3);
constexpr int kIdx0 = static_cast<int>(kIdx3210 & 3);
V ret;
ret.v0 =
VH{wasm_i32x4_shuffle(v.v0.raw, v.v0.raw, kIdx0, kIdx1, kIdx2, kIdx3)};
ret.v1 =
VH{wasm_i32x4_shuffle(v.v1.raw, v.v1.raw, kIdx0, kIdx1, kIdx2, kIdx3)};
return ret;
}
template <size_t kIdx3210, class V>
HWY_INLINE V Per4LaneBlockShuffle(hwy::SizeTag<kIdx3210> /*idx_3210_tag*/,
hwy::SizeTag<8> /*lane_size_tag*/,
hwy::SizeTag<32> /*vect_size_tag*/, V v) {
const DFromV<decltype(v)> d;
const Half<decltype(d)> dh;
using VH = VFromD<decltype(dh)>;
constexpr int kIdx3 = static_cast<int>((kIdx3210 >> 6) & 3);
constexpr int kIdx2 = static_cast<int>((kIdx3210 >> 4) & 3);
constexpr int kIdx1 = static_cast<int>((kIdx3210 >> 2) & 3);
constexpr int kIdx0 = static_cast<int>(kIdx3210 & 3);
V ret;
ret.v0 = VH{wasm_i64x2_shuffle(v.v0.raw, v.v1.raw, kIdx0, kIdx1)};
ret.v1 = VH{wasm_i64x2_shuffle(v.v0.raw, v.v1.raw, kIdx2, kIdx3)};
return ret;
}
} // namespace detail
// ------------------------------ SlideUpBlocks
template <int kBlocks, class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> SlideUpBlocks(D d, VFromD<D> v) {
static_assert(0 <= kBlocks && kBlocks <= 1,
"kBlocks must be between 0 and 1");
return (kBlocks == 1) ? ConcatLowerLower(d, v, Zero(d)) : v;
}
// ------------------------------ SlideDownBlocks
template <int kBlocks, class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> SlideDownBlocks(D d, VFromD<D> v) {
static_assert(0 <= kBlocks && kBlocks <= 1,
"kBlocks must be between 0 and 1");
const Half<decltype(d)> dh;
return (kBlocks == 1) ? ZeroExtendVector(d, UpperHalf(dh, v)) : v;
}
// ------------------------------ SlideUpLanes
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> SlideUpLanes(D d, VFromD<D> v, size_t amt) {
const Half<decltype(d)> dh;
const RebindToUnsigned<decltype(d)> du;
const RebindToUnsigned<decltype(dh)> dh_u;
const auto vu = BitCast(du, v);
VFromD<D> ret;
#if !HWY_IS_DEBUG_BUILD
constexpr size_t kLanesPerBlock = 16 / sizeof(TFromD<D>);
if (__builtin_constant_p(amt) && amt < kLanesPerBlock) {
switch (amt * sizeof(TFromD<D>)) {
case 0:
return v;
case 1:
ret.v0 = BitCast(dh, ShiftLeftBytes<1>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<15>(dh_u, vu.v1, vu.v0));
return ret;
case 2:
ret.v0 = BitCast(dh, ShiftLeftBytes<2>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<14>(dh_u, vu.v1, vu.v0));
return ret;
case 3:
ret.v0 = BitCast(dh, ShiftLeftBytes<3>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<13>(dh_u, vu.v1, vu.v0));
return ret;
case 4:
ret.v0 = BitCast(dh, ShiftLeftBytes<4>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<12>(dh_u, vu.v1, vu.v0));
return ret;
case 5:
ret.v0 = BitCast(dh, ShiftLeftBytes<5>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<11>(dh_u, vu.v1, vu.v0));
return ret;
case 6:
ret.v0 = BitCast(dh, ShiftLeftBytes<6>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<10>(dh_u, vu.v1, vu.v0));
return ret;
case 7:
ret.v0 = BitCast(dh, ShiftLeftBytes<7>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<9>(dh_u, vu.v1, vu.v0));
return ret;
case 8:
ret.v0 = BitCast(dh, ShiftLeftBytes<8>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<8>(dh_u, vu.v1, vu.v0));
return ret;
case 9:
ret.v0 = BitCast(dh, ShiftLeftBytes<9>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<7>(dh_u, vu.v1, vu.v0));
return ret;
case 10:
ret.v0 = BitCast(dh, ShiftLeftBytes<10>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<6>(dh_u, vu.v1, vu.v0));
return ret;
case 11:
ret.v0 = BitCast(dh, ShiftLeftBytes<11>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<5>(dh_u, vu.v1, vu.v0));
return ret;
case 12:
ret.v0 = BitCast(dh, ShiftLeftBytes<12>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<4>(dh_u, vu.v1, vu.v0));
return ret;
case 13:
ret.v0 = BitCast(dh, ShiftLeftBytes<13>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<3>(dh_u, vu.v1, vu.v0));
return ret;
case 14:
ret.v0 = BitCast(dh, ShiftLeftBytes<14>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<2>(dh_u, vu.v1, vu.v0));
return ret;
case 15:
ret.v0 = BitCast(dh, ShiftLeftBytes<15>(dh_u, vu.v0));
ret.v1 = BitCast(dh, CombineShiftRightBytes<1>(dh_u, vu.v1, vu.v0));
return ret;
}
}
if (__builtin_constant_p(amt >= kLanesPerBlock) && amt >= kLanesPerBlock) {
ret.v0 = Zero(dh);
ret.v1 = SlideUpLanes(dh, LowerHalf(dh, v), amt - kLanesPerBlock);
return ret;
}
#endif
const Repartition<uint8_t, decltype(d)> du8;
const RebindToSigned<decltype(du8)> di8;
const Half<decltype(di8)> dh_i8;
const auto lo_byte_idx = BitCast(
di8,
Iota(du8, static_cast<uint8_t>(size_t{0} - amt * sizeof(TFromD<D>))));
const auto hi_byte_idx =
UpperHalf(dh_i8, lo_byte_idx) - Set(dh_i8, int8_t{16});
const auto hi_sel_mask =
UpperHalf(dh_i8, lo_byte_idx) > Set(dh_i8, int8_t{15});
ret = BitCast(d,
TableLookupBytesOr0(ConcatLowerLower(du, vu, vu), lo_byte_idx));
ret.v1 =
BitCast(dh, IfThenElse(hi_sel_mask,
TableLookupBytes(UpperHalf(dh_u, vu), hi_byte_idx),
BitCast(dh_i8, ret.v1)));
return ret;
}
// ------------------------------ Slide1Up
template <typename D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> Slide1Up(D d, VFromD<D> v) {
VFromD<D> ret;
const Half<decltype(d)> dh;
constexpr int kShrByteAmt = static_cast<int>(16 - sizeof(TFromD<D>));
ret.v0 = ShiftLeftLanes<1>(dh, v.v0);
ret.v1 = CombineShiftRightBytes<kShrByteAmt>(dh, v.v1, v.v0);
return ret;
}
// ------------------------------ SlideDownLanes
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> SlideDownLanes(D d, VFromD<D> v, size_t amt) {
const Half<decltype(d)> dh;
const RebindToUnsigned<decltype(d)> du;
const RebindToUnsigned<decltype(dh)> dh_u;
VFromD<D> ret;
const auto vu = BitCast(du, v);
#if !HWY_IS_DEBUG_BUILD
constexpr size_t kLanesPerBlock = 16 / sizeof(TFromD<D>);
if (__builtin_constant_p(amt) && amt < kLanesPerBlock) {
switch (amt * sizeof(TFromD<D>)) {
case 0:
return v;
case 1:
ret.v0 = BitCast(dh, CombineShiftRightBytes<1>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<1>(dh_u, vu.v1));
return ret;
case 2:
ret.v0 = BitCast(dh, CombineShiftRightBytes<2>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<2>(dh_u, vu.v1));
return ret;
case 3:
ret.v0 = BitCast(dh, CombineShiftRightBytes<3>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<3>(dh_u, vu.v1));
return ret;
case 4:
ret.v0 = BitCast(dh, CombineShiftRightBytes<4>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<4>(dh_u, vu.v1));
return ret;
case 5:
ret.v0 = BitCast(dh, CombineShiftRightBytes<5>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<5>(dh_u, vu.v1));
return ret;
case 6:
ret.v0 = BitCast(dh, CombineShiftRightBytes<6>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<6>(dh_u, vu.v1));
return ret;
case 7:
ret.v0 = BitCast(dh, CombineShiftRightBytes<7>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<7>(dh_u, vu.v1));
return ret;
case 8:
ret.v0 = BitCast(dh, CombineShiftRightBytes<8>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<8>(dh_u, vu.v1));
return ret;
case 9:
ret.v0 = BitCast(dh, CombineShiftRightBytes<9>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<9>(dh_u, vu.v1));
return ret;
case 10:
ret.v0 = BitCast(dh, CombineShiftRightBytes<10>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<10>(dh_u, vu.v1));
return ret;
case 11:
ret.v0 = BitCast(dh, CombineShiftRightBytes<11>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<11>(dh_u, vu.v1));
return ret;
case 12:
ret.v0 = BitCast(dh, CombineShiftRightBytes<12>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<12>(dh_u, vu.v1));
return ret;
case 13:
ret.v0 = BitCast(dh, CombineShiftRightBytes<13>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<13>(dh_u, vu.v1));
return ret;
case 14:
ret.v0 = BitCast(dh, CombineShiftRightBytes<14>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<14>(dh_u, vu.v1));
return ret;
case 15:
ret.v0 = BitCast(dh, CombineShiftRightBytes<15>(dh_u, vu.v1, vu.v0));
ret.v1 = BitCast(dh, ShiftRightBytes<15>(dh_u, vu.v1));
return ret;
}
}
if (__builtin_constant_p(amt >= kLanesPerBlock) && amt >= kLanesPerBlock) {
ret.v0 = SlideDownLanes(dh, UpperHalf(dh, v), amt - kLanesPerBlock);
ret.v1 = Zero(dh);
return ret;
}
#endif
const Repartition<uint8_t, decltype(d)> du8;
const Half<decltype(du8)> dh_u8;
const auto lo_byte_idx =
Iota(du8, static_cast<uint8_t>(amt * sizeof(TFromD<D>)));
const auto u8_16 = Set(du8, uint8_t{16});
const auto hi_byte_idx = lo_byte_idx - u8_16;
const auto lo_sel_mask =
LowerHalf(dh_u8, lo_byte_idx) < LowerHalf(dh_u8, u8_16);
ret = BitCast(d, IfThenElseZero(hi_byte_idx < u8_16,
TableLookupBytes(ConcatUpperUpper(du, vu, vu),
hi_byte_idx)));
ret.v0 =
BitCast(dh, IfThenElse(lo_sel_mask,
TableLookupBytes(LowerHalf(dh_u, vu),
LowerHalf(dh_u8, lo_byte_idx)),
BitCast(dh_u8, LowerHalf(dh, ret))));
return ret;
}
// ------------------------------ Slide1Down
template <typename D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> Slide1Down(D d, VFromD<D> v) {
VFromD<D> ret;
const Half<decltype(d)> dh;
constexpr int kShrByteAmt = static_cast<int>(sizeof(TFromD<D>));
ret.v0 = CombineShiftRightBytes<kShrByteAmt>(dh, v.v1, v.v0);
ret.v1 = ShiftRightBytes<kShrByteAmt>(dh, v.v1);
return ret;
}
// ================================================== CONVERT
// ------------------------------ PromoteTo
template <class D, HWY_IF_V_SIZE_D(D, 32), typename TN,
HWY_IF_T_SIZE_D(D, sizeof(TN) * 2)>
HWY_API VFromD<D> PromoteTo(D d, Vec128<TN> v) {
const Half<decltype(d)> dh;
VFromD<D> ret;
// PromoteLowerTo is defined later in generic_ops-inl.h.
ret.v0 = PromoteTo(dh, LowerHalf(v));
ret.v1 = PromoteUpperTo(dh, v);
return ret;
}
// 4x promotion: 8-bit to 32-bit or 16-bit to 64-bit
template <class DW, HWY_IF_V_SIZE_D(DW, 32),
HWY_IF_T_SIZE_ONE_OF_D(DW, (1 << 4) | (1 << 8)),
HWY_IF_NOT_FLOAT_D(DW), typename TN,
HWY_IF_T_SIZE_D(DW, sizeof(TN) * 4), HWY_IF_NOT_FLOAT_NOR_SPECIAL(TN)>
HWY_API Vec256<TFromD<DW>> PromoteTo(DW d, Vec64<TN> v) {
const Half<decltype(d)> dh;
// 16-bit lanes for UI8->UI32, 32-bit lanes for UI16->UI64
const Rebind<MakeWide<TN>, decltype(d)> d2;
const auto v_2x = PromoteTo(d2, v);
Vec256<TFromD<DW>> ret;
// PromoteLowerTo is defined later in generic_ops-inl.h.
ret.v0 = PromoteTo(dh, LowerHalf(v_2x));
ret.v1 = PromoteUpperTo(dh, v_2x);
return ret;
}
// 8x promotion: 8-bit to 64-bit
template <class DW, HWY_IF_V_SIZE_D(DW, 32), HWY_IF_T_SIZE_D(DW, 8),
HWY_IF_NOT_FLOAT_D(DW), typename TN, HWY_IF_T_SIZE(TN, 1)>
HWY_API Vec256<TFromD<DW>> PromoteTo(DW d, Vec32<TN> v) {
const Half<decltype(d)> dh;
const Repartition<MakeWide<MakeWide<TN>>, decltype(dh)> d4; // 32-bit lanes
const auto v32 = PromoteTo(d4, v);
Vec256<TFromD<DW>> ret;
// PromoteLowerTo is defined later in generic_ops-inl.h.
ret.v0 = PromoteTo(dh, LowerHalf(v32));
ret.v1 = PromoteUpperTo(dh, v32);
return ret;
}
// ------------------------------ PromoteUpperTo
// Not native, but still define this here because wasm_128 toggles
// HWY_NATIVE_PROMOTE_UPPER_TO.
template <class D, class T>
HWY_API VFromD<D> PromoteUpperTo(D d, Vec256<T> v) {
// Lanes(d) may differ from Lanes(DFromV<decltype(v)>()). Use the lane type
// from v because it cannot be deduced from D (could be either bf16 or f16).
const Rebind<T, decltype(d)> dh;
return PromoteTo(d, UpperHalf(dh, v));
}
// ------------------------------ DemoteTo
template <class D, HWY_IF_U16_D(D)>
HWY_API Vec128<uint16_t> DemoteTo(D /* tag */, Vec256<int32_t> v) {
return Vec128<uint16_t>{wasm_u16x8_narrow_i32x4(v.v0.raw, v.v1.raw)};
}
template <class D, HWY_IF_I16_D(D)>
HWY_API Vec128<int16_t> DemoteTo(D /* tag */, Vec256<int32_t> v) {
return Vec128<int16_t>{wasm_i16x8_narrow_i32x4(v.v0.raw, v.v1.raw)};
}
template <class D, HWY_IF_U8_D(D)>
HWY_API Vec64<uint8_t> DemoteTo(D /* tag */, Vec256<int32_t> v) {
const auto intermediate = wasm_i16x8_narrow_i32x4(v.v0.raw, v.v1.raw);
return Vec64<uint8_t>{wasm_u8x16_narrow_i16x8(intermediate, intermediate)};
}
template <class D, HWY_IF_U8_D(D)>
HWY_API Vec128<uint8_t> DemoteTo(D /* tag */, Vec256<int16_t> v) {
return Vec128<uint8_t>{wasm_u8x16_narrow_i16x8(v.v0.raw, v.v1.raw)};
}
template <class D, HWY_IF_I8_D(D)>
HWY_API Vec64<int8_t> DemoteTo(D /* tag */, Vec256<int32_t> v) {
const auto intermediate = wasm_i16x8_narrow_i32x4(v.v0.raw, v.v1.raw);
return Vec64<int8_t>{wasm_i8x16_narrow_i16x8(intermediate, intermediate)};
}
template <class D, HWY_IF_I8_D(D)>
HWY_API Vec128<int8_t> DemoteTo(D /* tag */, Vec256<int16_t> v) {
return Vec128<int8_t>{wasm_i8x16_narrow_i16x8(v.v0.raw, v.v1.raw)};
}
template <class D, HWY_IF_I32_D(D)>
HWY_API Vec128<int32_t> DemoteTo(D di, Vec256<double> v) {
const Vec64<int32_t> lo{wasm_i32x4_trunc_sat_f64x2_zero(v.v0.raw)};
const Vec64<int32_t> hi{wasm_i32x4_trunc_sat_f64x2_zero(v.v1.raw)};
return Combine(di, hi, lo);
}
template <class D, HWY_IF_U32_D(D)>
HWY_API Vec128<uint32_t> DemoteTo(D di, Vec256<double> v) {
const Vec64<uint32_t> lo{wasm_u32x4_trunc_sat_f64x2_zero(v.v0.raw)};
const Vec64<uint32_t> hi{wasm_u32x4_trunc_sat_f64x2_zero(v.v1.raw)};
return Combine(di, hi, lo);
}
template <class D, HWY_IF_F32_D(D)>
HWY_API Vec128<float> DemoteTo(D df, Vec256<int64_t> v) {
const Vec64<float> lo = DemoteTo(Full64<float>(), v.v0);
const Vec64<float> hi = DemoteTo(Full64<float>(), v.v1);
return Combine(df, hi, lo);
}
template <class D, HWY_IF_F32_D(D)>
HWY_API Vec128<float> DemoteTo(D df, Vec256<uint64_t> v) {
const Vec64<float> lo = DemoteTo(Full64<float>(), v.v0);
const Vec64<float> hi = DemoteTo(Full64<float>(), v.v1);
return Combine(df, hi, lo);
}
template <class D, HWY_IF_F16_D(D)>
HWY_API Vec128<float16_t> DemoteTo(D d16, Vec256<float> v) {
const Half<decltype(d16)> d16h;
const Vec64<float16_t> lo = DemoteTo(d16h, v.v0);
const Vec64<float16_t> hi = DemoteTo(d16h, v.v1);
return Combine(d16, hi, lo);
}
template <class D, HWY_IF_BF16_D(D)>
HWY_API Vec128<bfloat16_t> DemoteTo(D dbf16, Vec256<float> v) {
const Half<decltype(dbf16)> dbf16h;
const Vec64<bfloat16_t> lo = DemoteTo(dbf16h, v.v0);
const Vec64<bfloat16_t> hi = DemoteTo(dbf16h, v.v1);
return Combine(dbf16, hi, lo);
}
// For already range-limited input [0, 255].
HWY_API Vec64<uint8_t> U8FromU32(Vec256<uint32_t> v) {
const Full64<uint8_t> du8;
const Full256<int32_t> di32; // no unsigned DemoteTo
return DemoteTo(du8, BitCast(di32, v));
}
// ------------------------------ Truncations
template <class D, HWY_IF_U8_D(D)>
HWY_API Vec32<uint8_t> TruncateTo(D /* tag */, Vec256<uint64_t> v) {
return Vec32<uint8_t>{wasm_i8x16_shuffle(v.v0.raw, v.v1.raw, 0, 8, 16, 24, 0,
8, 16, 24, 0, 8, 16, 24, 0, 8, 16,
24)};
}
template <class D, HWY_IF_U16_D(D)>
HWY_API Vec64<uint16_t> TruncateTo(D /* tag */, Vec256<uint64_t> v) {
return Vec64<uint16_t>{wasm_i8x16_shuffle(v.v0.raw, v.v1.raw, 0, 1, 8, 9, 16,
17, 24, 25, 0, 1, 8, 9, 16, 17, 24,
25)};
}
template <class D, HWY_IF_U32_D(D)>
HWY_API Vec128<uint32_t> TruncateTo(D /* tag */, Vec256<uint64_t> v) {
return Vec128<uint32_t>{wasm_i8x16_shuffle(v.v0.raw, v.v1.raw, 0, 1, 2, 3, 8,
9, 10, 11, 16, 17, 18, 19, 24, 25,
26, 27)};
}
template <class D, HWY_IF_U8_D(D)>
HWY_API Vec64<uint8_t> TruncateTo(D /* tag */, Vec256<uint32_t> v) {
return Vec64<uint8_t>{wasm_i8x16_shuffle(v.v0.raw, v.v1.raw, 0, 4, 8, 12, 16,
20, 24, 28, 0, 4, 8, 12, 16, 20, 24,
28)};
}
template <class D, HWY_IF_U16_D(D)>
HWY_API Vec128<uint16_t> TruncateTo(D /* tag */, Vec256<uint32_t> v) {
return Vec128<uint16_t>{wasm_i8x16_shuffle(v.v0.raw, v.v1.raw, 0, 1, 4, 5, 8,
9, 12, 13, 16, 17, 20, 21, 24, 25,
28, 29)};
}
template <class D, HWY_IF_U8_D(D)>
HWY_API Vec128<uint8_t> TruncateTo(D /* tag */, Vec256<uint16_t> v) {
return Vec128<uint8_t>{wasm_i8x16_shuffle(v.v0.raw, v.v1.raw, 0, 2, 4, 6, 8,
10, 12, 14, 16, 18, 20, 22, 24, 26,
28, 30)};
}
// ------------------------------ ReorderDemote2To
template <class DBF16, HWY_IF_BF16_D(DBF16)>
HWY_API Vec256<bfloat16_t> ReorderDemote2To(DBF16 dbf16, Vec256<float> a,
Vec256<float> b) {
const RebindToUnsigned<decltype(dbf16)> du16;
return BitCast(dbf16, ConcatOdd(du16, BitCast(du16, b), BitCast(du16, a)));
}
template <class DN, typename V, HWY_IF_V_SIZE_D(DN, 32),
HWY_IF_NOT_FLOAT_NOR_SPECIAL(TFromD<DN>), HWY_IF_SIGNED_V(V),
HWY_IF_T_SIZE_ONE_OF_D(DN, (1 << 1) | (1 << 2) | (1 << 4)),
HWY_IF_T_SIZE_V(V, sizeof(TFromD<DN>) * 2)>
HWY_API VFromD<DN> ReorderDemote2To(DN dn, V a, V b) {
const Half<decltype(dn)> dnh;
VFromD<DN> demoted;
demoted.v0 = DemoteTo(dnh, a);
demoted.v1 = DemoteTo(dnh, b);
return demoted;
}
template <class DN, typename V, HWY_IF_V_SIZE_D(DN, 32), HWY_IF_UNSIGNED_D(DN),
HWY_IF_UNSIGNED_V(V),
HWY_IF_T_SIZE_ONE_OF_D(DN, (1 << 1) | (1 << 2) | (1 << 4)),
HWY_IF_T_SIZE_V(V, sizeof(TFromD<DN>) * 2)>
HWY_API VFromD<DN> ReorderDemote2To(DN dn, V a, V b) {
const Half<decltype(dn)> dnh;
VFromD<DN> demoted;
demoted.v0 = DemoteTo(dnh, a);
demoted.v1 = DemoteTo(dnh, b);
return demoted;
}
// ------------------------------ Convert i32 <=> f32 (Round)
template <class DTo, typename TFrom, typename TTo = TFromD<DTo>>
HWY_API Vec256<TTo> ConvertTo(DTo d, const Vec256<TFrom> v) {
const Half<decltype(d)> dh;
Vec256<TTo> ret;
ret.v0 = ConvertTo(dh, v.v0);
ret.v1 = ConvertTo(dh, v.v1);
return ret;
}
HWY_API Vec256<int32_t> NearestInt(const Vec256<float> v) {
return ConvertTo(Full256<int32_t>(), Round(v));
}
// ================================================== MISC
// ------------------------------ LoadMaskBits (TestBit)
// `p` points to at least 8 readable bytes, not all of which need be valid.
template <class D, HWY_IF_V_SIZE_D(D, 32),
HWY_IF_T_SIZE_ONE_OF_D(D, (1 << 4) | (1 << 8))>
HWY_API MFromD<D> LoadMaskBits(D d, const uint8_t* HWY_RESTRICT bits) {
const Half<decltype(d)> dh;
MFromD<D> ret;
ret.m0 = LoadMaskBits(dh, bits);
// If size=4, one 128-bit vector has 4 mask bits; otherwise 2 for size=8.
// Both halves fit in one byte's worth of mask bits.
constexpr size_t kBitsPerHalf = 16 / sizeof(TFromD<D>);
const uint8_t bits_upper[8] = {static_cast<uint8_t>(bits[0] >> kBitsPerHalf)};
ret.m1 = LoadMaskBits(dh, bits_upper);
return ret;
}
template <class D, HWY_IF_V_SIZE_D(D, 32),
HWY_IF_T_SIZE_ONE_OF_D(D, (1 << 1) | (1 << 2))>
HWY_API MFromD<D> LoadMaskBits(D d, const uint8_t* HWY_RESTRICT bits) {
const Half<decltype(d)> dh;
MFromD<D> ret;
ret.m0 = LoadMaskBits(dh, bits);
constexpr size_t kLanesPerHalf = 16 / sizeof(TFromD<D>);
constexpr size_t kBytesPerHalf = kLanesPerHalf / 8;
static_assert(kBytesPerHalf != 0, "Lane size <= 16 bits => at least 8 lanes");
ret.m1 = LoadMaskBits(dh, bits + kBytesPerHalf);
return ret;
}
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API MFromD<D> Dup128MaskFromMaskBits(D d, unsigned mask_bits) {
const Half<decltype(d)> dh;
MFromD<D> ret;
ret.m0 = ret.m1 = Dup128MaskFromMaskBits(dh, mask_bits);
return ret;
}
// ------------------------------ Mask
// `p` points to at least 8 writable bytes.
template <class D, typename T = TFromD<D>,
HWY_IF_T_SIZE_ONE_OF(T, (1 << 4) | (1 << 8))>
HWY_API size_t StoreMaskBits(D d, const Mask256<T> mask, uint8_t* bits) {
const Half<decltype(d)> dh;
StoreMaskBits(dh, mask.m0, bits);
const uint8_t lo = bits[0];
StoreMaskBits(dh, mask.m1, bits);
// If size=4, one 128-bit vector has 4 mask bits; otherwise 2 for size=8.
// Both halves fit in one byte's worth of mask bits.
constexpr size_t kBitsPerHalf = 16 / sizeof(T);
bits[0] = static_cast<uint8_t>(lo | (bits[0] << kBitsPerHalf));
return (kBitsPerHalf * 2 + 7) / 8;
}
template <class D, typename T = TFromD<D>,
HWY_IF_T_SIZE_ONE_OF(T, (1 << 1) | (1 << 2))>
HWY_API size_t StoreMaskBits(D d, const Mask256<T> mask, uint8_t* bits) {
const Half<decltype(d)> dh;
constexpr size_t kLanesPerHalf = 16 / sizeof(T);
constexpr size_t kBytesPerHalf = kLanesPerHalf / 8;
static_assert(kBytesPerHalf != 0, "Lane size <= 16 bits => at least 8 lanes");
StoreMaskBits(dh, mask.m0, bits);
StoreMaskBits(dh, mask.m1, bits + kBytesPerHalf);
return kBytesPerHalf * 2;
}
template <class D, typename T = TFromD<D>>
HWY_API size_t CountTrue(D d, const Mask256<T> m) {
const Half<decltype(d)> dh;
return CountTrue(dh, m.m0) + CountTrue(dh, m.m1);
}
template <class D, typename T = TFromD<D>>
HWY_API bool AllFalse(D d, const Mask256<T> m) {
const Half<decltype(d)> dh;
return AllFalse(dh, m.m0) && AllFalse(dh, m.m1);
}
template <class D, typename T = TFromD<D>>
HWY_API bool AllTrue(D d, const Mask256<T> m) {
const Half<decltype(d)> dh;
return AllTrue(dh, m.m0) && AllTrue(dh, m.m1);
}
template <class D, typename T = TFromD<D>>
HWY_API size_t FindKnownFirstTrue(D d, const Mask256<T> mask) {
const Half<decltype(d)> dh;
const intptr_t lo = FindFirstTrue(dh, mask.m0); // not known
constexpr size_t kLanesPerHalf = 16 / sizeof(T);
return lo >= 0 ? static_cast<size_t>(lo)
: kLanesPerHalf + FindKnownFirstTrue(dh, mask.m1);
}
template <class D, typename T = TFromD<D>>
HWY_API intptr_t FindFirstTrue(D d, const Mask256<T> mask) {
const Half<decltype(d)> dh;
const intptr_t lo = FindFirstTrue(dh, mask.m0);
constexpr int kLanesPerHalf = 16 / sizeof(T);
if (lo >= 0) return lo;
const intptr_t hi = FindFirstTrue(dh, mask.m1);
return hi + (hi >= 0 ? kLanesPerHalf : 0);
}
template <class D, typename T = TFromD<D>>
HWY_API size_t FindKnownLastTrue(D d, const Mask256<T> mask) {
const Half<decltype(d)> dh;
const intptr_t hi = FindLastTrue(dh, mask.m1); // not known
constexpr size_t kLanesPerHalf = 16 / sizeof(T);
return hi >= 0 ? kLanesPerHalf + static_cast<size_t>(hi)
: FindKnownLastTrue(dh, mask.m0);
}
template <class D, typename T = TFromD<D>>
HWY_API intptr_t FindLastTrue(D d, const Mask256<T> mask) {
const Half<decltype(d)> dh;
constexpr int kLanesPerHalf = 16 / sizeof(T);
const intptr_t hi = FindLastTrue(dh, mask.m1);
return hi >= 0 ? kLanesPerHalf + hi : FindLastTrue(dh, mask.m0);
}
// ------------------------------ CompressStore
template <class D, typename T = TFromD<D>>
HWY_API size_t CompressStore(Vec256<T> v, const Mask256<T> mask, D d,
T* HWY_RESTRICT unaligned) {
const Half<decltype(d)> dh;
const size_t count = CompressStore(v.v0, mask.m0, dh, unaligned);
const size_t count2 = CompressStore(v.v1, mask.m1, dh, unaligned + count);
return count + count2;
}
// ------------------------------ CompressBlendedStore
template <class D, typename T = TFromD<D>>
HWY_API size_t CompressBlendedStore(Vec256<T> v, const Mask256<T> m, D d,
T* HWY_RESTRICT unaligned) {
const Half<decltype(d)> dh;
const size_t count = CompressBlendedStore(v.v0, m.m0, dh, unaligned);
const size_t count2 = CompressBlendedStore(v.v1, m.m1, dh, unaligned + count);
return count + count2;
}
// ------------------------------ CompressBitsStore
template <class D, typename T = TFromD<D>>
HWY_API size_t CompressBitsStore(Vec256<T> v, const uint8_t* HWY_RESTRICT bits,
D d, T* HWY_RESTRICT unaligned) {
const Mask256<T> m = LoadMaskBits(d, bits);
return CompressStore(v, m, d, unaligned);
}
// ------------------------------ Compress
template <typename T>
HWY_API Vec256<T> Compress(const Vec256<T> v, const Mask256<T> mask) {
const DFromV<decltype(v)> d;
alignas(32) T lanes[32 / sizeof(T)] = {};
(void)CompressStore(v, mask, d, lanes);
return Load(d, lanes);
}
// ------------------------------ CompressNot
template <typename T>
HWY_API Vec256<T> CompressNot(Vec256<T> v, const Mask256<T> mask) {
return Compress(v, Not(mask));
}
// ------------------------------ CompressBlocksNot
HWY_API Vec256<uint64_t> CompressBlocksNot(Vec256<uint64_t> v,
Mask256<uint64_t> mask) {
const Full128<uint64_t> dh;
// Because the non-selected (mask=1) blocks are undefined, we can return the
// input unless mask = 01, in which case we must bring down the upper block.
return AllTrue(dh, AndNot(mask.m1, mask.m0)) ? SwapAdjacentBlocks(v) : v;
}
// ------------------------------ CompressBits
template <typename T>
HWY_API Vec256<T> CompressBits(Vec256<T> v, const uint8_t* HWY_RESTRICT bits) {
const Mask256<T> m = LoadMaskBits(DFromV<decltype(v)>(), bits);
return Compress(v, m);
}
// ------------------------------ Expand
template <typename T>
HWY_API Vec256<T> Expand(const Vec256<T> v, const Mask256<T> mask) {
Vec256<T> ret;
const Full256<T> d;
const Half<decltype(d)> dh;
alignas(32) T lanes[32 / sizeof(T)] = {};
Store(v, d, lanes);
ret.v0 = Expand(v.v0, mask.m0);
ret.v1 = Expand(LoadU(dh, lanes + CountTrue(dh, mask.m0)), mask.m1);
return ret;
}
// ------------------------------ LoadExpand
template <class D, HWY_IF_V_SIZE_D(D, 32)>
HWY_API VFromD<D> LoadExpand(MFromD<D> mask, D d,
const TFromD<D>* HWY_RESTRICT unaligned) {
return Expand(LoadU(d, unaligned), mask);
}
// ------------------------------ LoadInterleaved3/4
// Implemented in generic_ops, we just overload LoadTransposedBlocks3/4.
namespace detail {
// Input:
// 1 0 (<- first block of unaligned)
// 3 2
// 5 4
// Output:
// 3 0
// 4 1
// 5 2
template <class D, typename T = TFromD<D>>
HWY_API void LoadTransposedBlocks3(D d, const T* HWY_RESTRICT unaligned,
Vec256<T>& A, Vec256<T>& B, Vec256<T>& C) {
const Vec256<T> v10 = LoadU(d, unaligned + 0 * MaxLanes(d));
const Vec256<T> v32 = LoadU(d, unaligned + 1 * MaxLanes(d));
const Vec256<T> v54 = LoadU(d, unaligned + 2 * MaxLanes(d));
A = ConcatUpperLower(d, v32, v10);
B = ConcatLowerUpper(d, v54, v10);
C = ConcatUpperLower(d, v54, v32);
}
// Input (128-bit blocks):
// 1 0 (first block of unaligned)
// 3 2
// 5 4
// 7 6
// Output:
// 4 0 (LSB of A)
// 5 1
// 6 2
// 7 3
template <class D, typename T = TFromD<D>>
HWY_API void LoadTransposedBlocks4(D d, const T* HWY_RESTRICT unaligned,
Vec256<T>& vA, Vec256<T>& vB, Vec256<T>& vC,
Vec256<T>& vD) {
const Vec256<T> v10 = LoadU(d, unaligned + 0 * MaxLanes(d));
const Vec256<T> v32 = LoadU(d, unaligned + 1 * MaxLanes(d));
const Vec256<T> v54 = LoadU(d, unaligned + 2 * MaxLanes(d));
const Vec256<T> v76 = LoadU(d, unaligned + 3 * MaxLanes(d));
vA = ConcatLowerLower(d, v54, v10);
vB = ConcatUpperUpper(d, v54, v10);
vC = ConcatLowerLower(d, v76, v32);
vD = ConcatUpperUpper(d, v76, v32);
}
} // namespace detail
// ------------------------------ StoreInterleaved2/3/4 (ConcatUpperLower)
// Implemented in generic_ops, we just overload StoreTransposedBlocks2/3/4.
namespace detail {
// Input (128-bit blocks):
// 2 0 (LSB of i)
// 3 1
// Output:
// 1 0
// 3 2
template <class D, typename T = TFromD<D>>
HWY_API void StoreTransposedBlocks2(Vec256<T> i, Vec256<T> j, D d,
T* HWY_RESTRICT unaligned) {
const Vec256<T> out0 = ConcatLowerLower(d, j, i);
const Vec256<T> out1 = ConcatUpperUpper(d, j, i);
StoreU(out0, d, unaligned + 0 * MaxLanes(d));
StoreU(out1, d, unaligned + 1 * MaxLanes(d));
}
// Input (128-bit blocks):
// 3 0 (LSB of i)
// 4 1
// 5 2
// Output:
// 1 0
// 3 2
// 5 4
template <class D, typename T = TFromD<D>>
HWY_API void StoreTransposedBlocks3(Vec256<T> i, Vec256<T> j, Vec256<T> k, D d,
T* HWY_RESTRICT unaligned) {
const Vec256<T> out0 = ConcatLowerLower(d, j, i);
const Vec256<T> out1 = ConcatUpperLower(d, i, k);
const Vec256<T> out2 = ConcatUpperUpper(d, k, j);
StoreU(out0, d, unaligned + 0 * MaxLanes(d));
StoreU(out1, d, unaligned + 1 * MaxLanes(d));
StoreU(out2, d, unaligned + 2 * MaxLanes(d));
}
// Input (128-bit blocks):
// 4 0 (LSB of i)
// 5 1
// 6 2
// 7 3
// Output:
// 1 0
// 3 2
// 5 4
// 7 6
template <class D, typename T = TFromD<D>>
HWY_API void StoreTransposedBlocks4(Vec256<T> i, Vec256<T> j, Vec256<T> k,
Vec256<T> l, D d,
T* HWY_RESTRICT unaligned) {
// Write lower halves, then upper.
const Vec256<T> out0 = ConcatLowerLower(d, j, i);
const Vec256<T> out1 = ConcatLowerLower(d, l, k);
StoreU(out0, d, unaligned + 0 * MaxLanes(d));
StoreU(out1, d, unaligned + 1 * MaxLanes(d));
const Vec256<T> out2 = ConcatUpperUpper(d, j, i);
const Vec256<T> out3 = ConcatUpperUpper(d, l, k);
StoreU(out2, d, unaligned + 2 * MaxLanes(d));
StoreU(out3, d, unaligned + 3 * MaxLanes(d));
}
} // namespace detail
// ------------------------------ Additional mask logical operations
template <class T>
HWY_API Mask256<T> SetAtOrAfterFirst(Mask256<T> mask) {
const Full256<T> d;
const Half<decltype(d)> dh;
const Repartition<int64_t, decltype(dh)> dh_i64;
Mask256<T> result;
result.m0 = SetAtOrAfterFirst(mask.m0);
result.m1 = SetAtOrAfterFirst(mask.m1);
// Copy the sign bit of the lower 128-bit half to the upper 128-bit half
const auto vmask_lo = BitCast(dh_i64, VecFromMask(dh, result.m0));
result.m1 =
Or(result.m1, MaskFromVec(BitCast(dh, BroadcastSignBit(InterleaveUpper(
dh_i64, vmask_lo, vmask_lo)))));
return result;
}
template <class T>
HWY_API Mask256<T> SetBeforeFirst(Mask256<T> mask) {
return Not(SetAtOrAfterFirst(mask));
}
template <class T>
HWY_API Mask256<T> SetOnlyFirst(Mask256<T> mask) {
const Full256<T> d;
const RebindToSigned<decltype(d)> di;
const Repartition<int64_t, decltype(d)> di64;
const Half<decltype(di64)> dh_i64;
const auto zero = Zero(di64);
const auto vmask = BitCast(di64, VecFromMask(d, mask));
const auto vmask_eq_0 = VecFromMask(di64, vmask == zero);
auto vmask2_lo = LowerHalf(dh_i64, vmask_eq_0);
auto vmask2_hi = UpperHalf(dh_i64, vmask_eq_0);
vmask2_lo = And(vmask2_lo, InterleaveLower(vmask2_lo, vmask2_lo));
vmask2_hi = And(ConcatLowerUpper(dh_i64, vmask2_hi, vmask2_lo),
InterleaveUpper(dh_i64, vmask2_lo, vmask2_lo));
vmask2_lo = InterleaveLower(Set(dh_i64, int64_t{-1}), vmask2_lo);
const auto vmask2 = Combine(di64, vmask2_hi, vmask2_lo);
const auto only_first_vmask = Neg(BitCast(di, And(vmask, Neg(vmask))));
return MaskFromVec(BitCast(d, And(only_first_vmask, BitCast(di, vmask2))));
}
template <class T>
HWY_API Mask256<T> SetAtOrBeforeFirst(Mask256<T> mask) {
const Full256<T> d;
constexpr size_t kLanesPerBlock = MaxLanes(d) / 2;
const auto vmask = VecFromMask(d, mask);
const auto vmask_lo = ConcatLowerLower(d, vmask, Zero(d));
return SetBeforeFirst(
MaskFromVec(CombineShiftRightBytes<(kLanesPerBlock - 1) * sizeof(T)>(
d, vmask, vmask_lo)));
}
// ------------------------------ WidenMulPairwiseAdd
template <class D32, typename T16, typename T32 = TFromD<D32>>
HWY_API Vec256<T32> WidenMulPairwiseAdd(D32 d32, Vec256<T16> a, Vec256<T16> b) {
const Half<decltype(d32)> d32h;
Vec256<T32> result;
result.v0 = WidenMulPairwiseAdd(d32h, a.v0, b.v0);
result.v1 = WidenMulPairwiseAdd(d32h, a.v1, b.v1);
return result;
}
// ------------------------------ ReorderWidenMulAccumulate
template <class D32, typename T16, typename T32 = TFromD<D32>>
HWY_API Vec256<T32> ReorderWidenMulAccumulate(D32 d32, Vec256<T16> a,
Vec256<T16> b, Vec256<T32> sum0,
Vec256<T32>& sum1) {
const Half<decltype(d32)> d32h;
sum0.v0 = ReorderWidenMulAccumulate(d32h, a.v0, b.v0, sum0.v0, sum1.v0);
sum0.v1 = ReorderWidenMulAccumulate(d32h, a.v1, b.v1, sum0.v1, sum1.v1);
return sum0;
}
// ------------------------------ RearrangeToOddPlusEven
template <typename TW>
HWY_API Vec256<TW> RearrangeToOddPlusEven(Vec256<TW> sum0, Vec256<TW> sum1) {
sum0.v0 = RearrangeToOddPlusEven(sum0.v0, sum1.v0);
sum0.v1 = RearrangeToOddPlusEven(sum0.v1, sum1.v1);
return sum0;
}
// ------------------------------ Reductions in generic_ops
// ------------------------------ Lt128
template <class D, typename T = TFromD<D>>
HWY_INLINE Mask256<T> Lt128(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
Mask256<T> ret;
ret.m0 = Lt128(dh, a.v0, b.v0);
ret.m1 = Lt128(dh, a.v1, b.v1);
return ret;
}
template <class D, typename T = TFromD<D>>
HWY_INLINE Mask256<T> Lt128Upper(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
Mask256<T> ret;
ret.m0 = Lt128Upper(dh, a.v0, b.v0);
ret.m1 = Lt128Upper(dh, a.v1, b.v1);
return ret;
}
template <class D, typename T = TFromD<D>>
HWY_INLINE Mask256<T> Eq128(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
Mask256<T> ret;
ret.m0 = Eq128(dh, a.v0, b.v0);
ret.m1 = Eq128(dh, a.v1, b.v1);
return ret;
}
template <class D, typename T = TFromD<D>>
HWY_INLINE Mask256<T> Eq128Upper(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
Mask256<T> ret;
ret.m0 = Eq128Upper(dh, a.v0, b.v0);
ret.m1 = Eq128Upper(dh, a.v1, b.v1);
return ret;
}
template <class D, typename T = TFromD<D>>
HWY_INLINE Mask256<T> Ne128(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
Mask256<T> ret;
ret.m0 = Ne128(dh, a.v0, b.v0);
ret.m1 = Ne128(dh, a.v1, b.v1);
return ret;
}
template <class D, typename T = TFromD<D>>
HWY_INLINE Mask256<T> Ne128Upper(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
Mask256<T> ret;
ret.m0 = Ne128Upper(dh, a.v0, b.v0);
ret.m1 = Ne128Upper(dh, a.v1, b.v1);
return ret;
}
template <class D, typename T = TFromD<D>>
HWY_INLINE Vec256<T> Min128(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
Vec256<T> ret;
ret.v0 = Min128(dh, a.v0, b.v0);
ret.v1 = Min128(dh, a.v1, b.v1);
return ret;
}
template <class D, typename T = TFromD<D>>
HWY_INLINE Vec256<T> Max128(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
Vec256<T> ret;
ret.v0 = Max128(dh, a.v0, b.v0);
ret.v1 = Max128(dh, a.v1, b.v1);
return ret;
}
template <class D, typename T = TFromD<D>>
HWY_INLINE Vec256<T> Min128Upper(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
Vec256<T> ret;
ret.v0 = Min128Upper(dh, a.v0, b.v0);
ret.v1 = Min128Upper(dh, a.v1, b.v1);
return ret;
}
template <class D, typename T = TFromD<D>>
HWY_INLINE Vec256<T> Max128Upper(D d, Vec256<T> a, Vec256<T> b) {
const Half<decltype(d)> dh;
Vec256<T> ret;
ret.v0 = Max128Upper(dh, a.v0, b.v0);
ret.v1 = Max128Upper(dh, a.v1, b.v1);
return ret;
}
// NOLINTNEXTLINE(google-readability-namespace-comments)
} // namespace HWY_NAMESPACE
} // namespace hwy
HWY_AFTER_NAMESPACE();