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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-21 11:44:51 +0000
committerDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-21 11:44:51 +0000
commit9e3c08db40b8916968b9f30096c7be3f00ce9647 (patch)
treea68f146d7fa01f0134297619fbe7e33db084e0aa /gfx/2d/SIMD.h
parentInitial commit. (diff)
downloadthunderbird-9e3c08db40b8916968b9f30096c7be3f00ce9647.tar.xz
thunderbird-9e3c08db40b8916968b9f30096c7be3f00ce9647.zip
Adding upstream version 1:115.7.0.upstream/1%115.7.0upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'gfx/2d/SIMD.h')
-rw-r--r--gfx/2d/SIMD.h1039
1 files changed, 1039 insertions, 0 deletions
diff --git a/gfx/2d/SIMD.h b/gfx/2d/SIMD.h
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+/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
+/* vim: set ts=8 sts=2 et sw=2 tw=80: */
+/* This Source Code Form is subject to the terms of the Mozilla Public
+ * License, v. 2.0. If a copy of the MPL was not distributed with this
+ * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
+
+#ifndef _MOZILLA_GFX_SIMD_H_
+#define _MOZILLA_GFX_SIMD_H_
+
+/**
+ * Consumers of this file need to #define SIMD_COMPILE_SSE2 before including it
+ * if they want access to the SSE2 functions.
+ */
+
+#ifdef SIMD_COMPILE_SSE2
+# include <xmmintrin.h>
+#endif
+
+namespace mozilla {
+namespace gfx {
+
+namespace simd {
+
+template <typename u8x16_t>
+u8x16_t Load8(const uint8_t* aSource);
+
+template <typename u8x16_t>
+u8x16_t From8(uint8_t a, uint8_t b, uint8_t c, uint8_t d, uint8_t e, uint8_t f,
+ uint8_t g, uint8_t h, uint8_t i, uint8_t j, uint8_t k, uint8_t l,
+ uint8_t m, uint8_t n, uint8_t o, uint8_t p);
+
+template <typename u8x16_t>
+u8x16_t FromZero8();
+
+template <typename i16x8_t>
+i16x8_t FromI16(int16_t a, int16_t b, int16_t c, int16_t d, int16_t e,
+ int16_t f, int16_t g, int16_t h);
+
+template <typename u16x8_t>
+u16x8_t FromU16(uint16_t a, uint16_t b, uint16_t c, uint16_t d, uint16_t e,
+ uint16_t f, uint16_t g, uint16_t h);
+
+template <typename i16x8_t>
+i16x8_t FromI16(int16_t a);
+
+template <typename u16x8_t>
+u16x8_t FromU16(uint16_t a);
+
+template <typename i32x4_t>
+i32x4_t From32(int32_t a, int32_t b, int32_t c, int32_t d);
+
+template <typename i32x4_t>
+i32x4_t From32(int32_t a);
+
+template <typename f32x4_t>
+f32x4_t FromF32(float a, float b, float c, float d);
+
+template <typename f32x4_t>
+f32x4_t FromF32(float a);
+
+// All SIMD backends overload these functions for their SIMD types:
+
+#if 0
+
+// Store 16 bytes to a 16-byte aligned address
+void Store8(uint8_t* aTarget, u8x16_t aM);
+
+// Fixed shifts
+template<int32_t aNumberOfBits> i16x8_t ShiftRight16(i16x8_t aM);
+template<int32_t aNumberOfBits> i32x4_t ShiftRight32(i32x4_t aM);
+
+i16x8_t Add16(i16x8_t aM1, i16x8_t aM2);
+i32x4_t Add32(i32x4_t aM1, i32x4_t aM2);
+i16x8_t Sub16(i16x8_t aM1, i16x8_t aM2);
+i32x4_t Sub32(i32x4_t aM1, i32x4_t aM2);
+u8x16_t Min8(u8x16_t aM1, iu8x16_t aM2);
+u8x16_t Max8(u8x16_t aM1, iu8x16_t aM2);
+i32x4_t Min32(i32x4_t aM1, i32x4_t aM2);
+i32x4_t Max32(i32x4_t aM1, i32x4_t aM2);
+
+// Truncating i16 -> i16 multiplication
+i16x8_t Mul16(i16x8_t aM1, i16x8_t aM2);
+
+// Long multiplication i16 -> i32
+// aFactorsA1B1 = (a1[4] b1[4])
+// aFactorsA2B2 = (a2[4] b2[4])
+// aProductA = a1 * a2, aProductB = b1 * b2
+void Mul16x4x2x2To32x4x2(i16x8_t aFactorsA1B1, i16x8_t aFactorsA2B2,
+ i32x4_t& aProductA, i32x4_t& aProductB);
+
+// Long multiplication + pairwise addition i16 -> i32
+// See the scalar implementation for specifics.
+i32x4_t MulAdd16x8x2To32x4(i16x8_t aFactorsA, i16x8_t aFactorsB);
+i32x4_t MulAdd16x8x2To32x4(u16x8_t aFactorsA, u16x8_t aFactorsB);
+
+// Set all four 32-bit components to the value of the component at aIndex.
+template<int8_t aIndex>
+i32x4_t Splat32(i32x4_t aM);
+
+// Interpret the input as four 32-bit values, apply Splat32<aIndex> on them,
+// re-interpret the result as sixteen 8-bit values.
+template<int8_t aIndex>
+u8x16_t Splat32On8(u8x16_t aM);
+
+template<int8_t i0, int8_t i1, int8_t i2, int8_t i3> i32x4 Shuffle32(i32x4 aM);
+template<int8_t i0, int8_t i1, int8_t i2, int8_t i3> i16x8 ShuffleLo16(i16x8 aM);
+template<int8_t i0, int8_t i1, int8_t i2, int8_t i3> i16x8 ShuffleHi16(i16x8 aM);
+
+u8x16_t InterleaveLo8(u8x16_t m1, u8x16_t m2);
+u8x16_t InterleaveHi8(u8x16_t m1, u8x16_t m2);
+i16x8_t InterleaveLo16(i16x8_t m1, i16x8_t m2);
+i16x8_t InterleaveHi16(i16x8_t m1, i16x8_t m2);
+i32x4_t InterleaveLo32(i32x4_t m1, i32x4_t m2);
+
+i16x8_t UnpackLo8x8ToI16x8(u8x16_t m);
+i16x8_t UnpackHi8x8ToI16x8(u8x16_t m);
+u16x8_t UnpackLo8x8ToU16x8(u8x16_t m);
+u16x8_t UnpackHi8x8ToU16x8(u8x16_t m);
+
+i16x8_t PackAndSaturate32To16(i32x4_t m1, i32x4_t m2);
+u8x16_t PackAndSaturate16To8(i16x8_t m1, i16x8_t m2);
+u8x16_t PackAndSaturate32To8(i32x4_t m1, i32x4_t m2, i32x4_t m3, const i32x4_t& m4);
+
+i32x4 FastDivideBy255(i32x4 m);
+i16x8 FastDivideBy255_16(i16x8 m);
+
+#endif
+
+// Scalar
+
+struct Scalaru8x16_t {
+ uint8_t u8[16];
+};
+
+union Scalari16x8_t {
+ int16_t i16[8];
+ uint16_t u16[8];
+};
+
+typedef Scalari16x8_t Scalaru16x8_t;
+
+struct Scalari32x4_t {
+ int32_t i32[4];
+};
+
+struct Scalarf32x4_t {
+ float f32[4];
+};
+
+template <>
+inline Scalaru8x16_t Load8<Scalaru8x16_t>(const uint8_t* aSource) {
+ return *(Scalaru8x16_t*)aSource;
+}
+
+inline void Store8(uint8_t* aTarget, Scalaru8x16_t aM) {
+ *(Scalaru8x16_t*)aTarget = aM;
+}
+
+template <>
+inline Scalaru8x16_t From8<Scalaru8x16_t>(uint8_t a, uint8_t b, uint8_t c,
+ uint8_t d, uint8_t e, uint8_t f,
+ uint8_t g, uint8_t h, uint8_t i,
+ uint8_t j, uint8_t k, uint8_t l,
+ uint8_t m, uint8_t n, uint8_t o,
+ uint8_t p) {
+ Scalaru8x16_t _m;
+ _m.u8[0] = a;
+ _m.u8[1] = b;
+ _m.u8[2] = c;
+ _m.u8[3] = d;
+ _m.u8[4] = e;
+ _m.u8[5] = f;
+ _m.u8[6] = g;
+ _m.u8[7] = h;
+ _m.u8[8 + 0] = i;
+ _m.u8[8 + 1] = j;
+ _m.u8[8 + 2] = k;
+ _m.u8[8 + 3] = l;
+ _m.u8[8 + 4] = m;
+ _m.u8[8 + 5] = n;
+ _m.u8[8 + 6] = o;
+ _m.u8[8 + 7] = p;
+ return _m;
+}
+
+template <>
+inline Scalaru8x16_t FromZero8<Scalaru8x16_t>() {
+ return From8<Scalaru8x16_t>(0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0);
+}
+
+template <>
+inline Scalari16x8_t FromI16<Scalari16x8_t>(int16_t a, int16_t b, int16_t c,
+ int16_t d, int16_t e, int16_t f,
+ int16_t g, int16_t h) {
+ Scalari16x8_t m;
+ m.i16[0] = a;
+ m.i16[1] = b;
+ m.i16[2] = c;
+ m.i16[3] = d;
+ m.i16[4] = e;
+ m.i16[5] = f;
+ m.i16[6] = g;
+ m.i16[7] = h;
+ return m;
+}
+
+template <>
+inline Scalaru16x8_t FromU16<Scalaru16x8_t>(uint16_t a, uint16_t b, uint16_t c,
+ uint16_t d, uint16_t e, uint16_t f,
+ uint16_t g, uint16_t h) {
+ Scalaru16x8_t m;
+ m.u16[0] = a;
+ m.u16[1] = b;
+ m.u16[2] = c;
+ m.u16[3] = d;
+ m.u16[4] = e;
+ m.u16[5] = f;
+ m.u16[6] = g;
+ m.u16[7] = h;
+ return m;
+}
+
+template <>
+inline Scalari16x8_t FromI16<Scalari16x8_t>(int16_t a) {
+ return FromI16<Scalari16x8_t>(a, a, a, a, a, a, a, a);
+}
+
+template <>
+inline Scalaru16x8_t FromU16<Scalaru16x8_t>(uint16_t a) {
+ return FromU16<Scalaru16x8_t>(a, a, a, a, a, a, a, a);
+}
+
+template <>
+inline Scalari32x4_t From32<Scalari32x4_t>(int32_t a, int32_t b, int32_t c,
+ int32_t d) {
+ Scalari32x4_t m;
+ m.i32[0] = a;
+ m.i32[1] = b;
+ m.i32[2] = c;
+ m.i32[3] = d;
+ return m;
+}
+
+template <>
+inline Scalarf32x4_t FromF32<Scalarf32x4_t>(float a, float b, float c,
+ float d) {
+ Scalarf32x4_t m;
+ m.f32[0] = a;
+ m.f32[1] = b;
+ m.f32[2] = c;
+ m.f32[3] = d;
+ return m;
+}
+
+template <>
+inline Scalarf32x4_t FromF32<Scalarf32x4_t>(float a) {
+ return FromF32<Scalarf32x4_t>(a, a, a, a);
+}
+
+template <>
+inline Scalari32x4_t From32<Scalari32x4_t>(int32_t a) {
+ return From32<Scalari32x4_t>(a, a, a, a);
+}
+
+template <int32_t aNumberOfBits>
+inline Scalari16x8_t ShiftRight16(Scalari16x8_t aM) {
+ return FromI16<Scalari16x8_t>(uint16_t(aM.i16[0]) >> aNumberOfBits,
+ uint16_t(aM.i16[1]) >> aNumberOfBits,
+ uint16_t(aM.i16[2]) >> aNumberOfBits,
+ uint16_t(aM.i16[3]) >> aNumberOfBits,
+ uint16_t(aM.i16[4]) >> aNumberOfBits,
+ uint16_t(aM.i16[5]) >> aNumberOfBits,
+ uint16_t(aM.i16[6]) >> aNumberOfBits,
+ uint16_t(aM.i16[7]) >> aNumberOfBits);
+}
+
+template <int32_t aNumberOfBits>
+inline Scalari32x4_t ShiftRight32(Scalari32x4_t aM) {
+ return From32<Scalari32x4_t>(
+ aM.i32[0] >> aNumberOfBits, aM.i32[1] >> aNumberOfBits,
+ aM.i32[2] >> aNumberOfBits, aM.i32[3] >> aNumberOfBits);
+}
+
+inline Scalaru16x8_t Add16(Scalaru16x8_t aM1, Scalaru16x8_t aM2) {
+ return FromU16<Scalaru16x8_t>(
+ aM1.u16[0] + aM2.u16[0], aM1.u16[1] + aM2.u16[1], aM1.u16[2] + aM2.u16[2],
+ aM1.u16[3] + aM2.u16[3], aM1.u16[4] + aM2.u16[4], aM1.u16[5] + aM2.u16[5],
+ aM1.u16[6] + aM2.u16[6], aM1.u16[7] + aM2.u16[7]);
+}
+
+inline Scalari32x4_t Add32(Scalari32x4_t aM1, Scalari32x4_t aM2) {
+ return From32<Scalari32x4_t>(aM1.i32[0] + aM2.i32[0], aM1.i32[1] + aM2.i32[1],
+ aM1.i32[2] + aM2.i32[2],
+ aM1.i32[3] + aM2.i32[3]);
+}
+
+inline Scalaru16x8_t Sub16(Scalaru16x8_t aM1, Scalaru16x8_t aM2) {
+ return FromU16<Scalaru16x8_t>(
+ aM1.u16[0] - aM2.u16[0], aM1.u16[1] - aM2.u16[1], aM1.u16[2] - aM2.u16[2],
+ aM1.u16[3] - aM2.u16[3], aM1.u16[4] - aM2.u16[4], aM1.u16[5] - aM2.u16[5],
+ aM1.u16[6] - aM2.u16[6], aM1.u16[7] - aM2.u16[7]);
+}
+
+inline Scalari32x4_t Sub32(Scalari32x4_t aM1, Scalari32x4_t aM2) {
+ return From32<Scalari32x4_t>(aM1.i32[0] - aM2.i32[0], aM1.i32[1] - aM2.i32[1],
+ aM1.i32[2] - aM2.i32[2],
+ aM1.i32[3] - aM2.i32[3]);
+}
+
+inline int32_t umin(int32_t a, int32_t b) { return a - ((a - b) & -(a > b)); }
+
+inline int32_t umax(int32_t a, int32_t b) { return a - ((a - b) & -(a < b)); }
+
+inline Scalaru8x16_t Min8(Scalaru8x16_t aM1, Scalaru8x16_t aM2) {
+ return From8<Scalaru8x16_t>(
+ umin(aM1.u8[0], aM2.u8[0]), umin(aM1.u8[1], aM2.u8[1]),
+ umin(aM1.u8[2], aM2.u8[2]), umin(aM1.u8[3], aM2.u8[3]),
+ umin(aM1.u8[4], aM2.u8[4]), umin(aM1.u8[5], aM2.u8[5]),
+ umin(aM1.u8[6], aM2.u8[6]), umin(aM1.u8[7], aM2.u8[7]),
+ umin(aM1.u8[8 + 0], aM2.u8[8 + 0]), umin(aM1.u8[8 + 1], aM2.u8[8 + 1]),
+ umin(aM1.u8[8 + 2], aM2.u8[8 + 2]), umin(aM1.u8[8 + 3], aM2.u8[8 + 3]),
+ umin(aM1.u8[8 + 4], aM2.u8[8 + 4]), umin(aM1.u8[8 + 5], aM2.u8[8 + 5]),
+ umin(aM1.u8[8 + 6], aM2.u8[8 + 6]), umin(aM1.u8[8 + 7], aM2.u8[8 + 7]));
+}
+
+inline Scalaru8x16_t Max8(Scalaru8x16_t aM1, Scalaru8x16_t aM2) {
+ return From8<Scalaru8x16_t>(
+ umax(aM1.u8[0], aM2.u8[0]), umax(aM1.u8[1], aM2.u8[1]),
+ umax(aM1.u8[2], aM2.u8[2]), umax(aM1.u8[3], aM2.u8[3]),
+ umax(aM1.u8[4], aM2.u8[4]), umax(aM1.u8[5], aM2.u8[5]),
+ umax(aM1.u8[6], aM2.u8[6]), umax(aM1.u8[7], aM2.u8[7]),
+ umax(aM1.u8[8 + 0], aM2.u8[8 + 0]), umax(aM1.u8[8 + 1], aM2.u8[8 + 1]),
+ umax(aM1.u8[8 + 2], aM2.u8[8 + 2]), umax(aM1.u8[8 + 3], aM2.u8[8 + 3]),
+ umax(aM1.u8[8 + 4], aM2.u8[8 + 4]), umax(aM1.u8[8 + 5], aM2.u8[8 + 5]),
+ umax(aM1.u8[8 + 6], aM2.u8[8 + 6]), umax(aM1.u8[8 + 7], aM2.u8[8 + 7]));
+}
+
+inline Scalari32x4_t Min32(Scalari32x4_t aM1, Scalari32x4_t aM2) {
+ return From32<Scalari32x4_t>(
+ umin(aM1.i32[0], aM2.i32[0]), umin(aM1.i32[1], aM2.i32[1]),
+ umin(aM1.i32[2], aM2.i32[2]), umin(aM1.i32[3], aM2.i32[3]));
+}
+
+inline Scalari32x4_t Max32(Scalari32x4_t aM1, Scalari32x4_t aM2) {
+ return From32<Scalari32x4_t>(
+ umax(aM1.i32[0], aM2.i32[0]), umax(aM1.i32[1], aM2.i32[1]),
+ umax(aM1.i32[2], aM2.i32[2]), umax(aM1.i32[3], aM2.i32[3]));
+}
+
+inline Scalaru16x8_t Mul16(Scalaru16x8_t aM1, Scalaru16x8_t aM2) {
+ return FromU16<Scalaru16x8_t>(
+ uint16_t(int32_t(aM1.u16[0]) * int32_t(aM2.u16[0])),
+ uint16_t(int32_t(aM1.u16[1]) * int32_t(aM2.u16[1])),
+ uint16_t(int32_t(aM1.u16[2]) * int32_t(aM2.u16[2])),
+ uint16_t(int32_t(aM1.u16[3]) * int32_t(aM2.u16[3])),
+ uint16_t(int32_t(aM1.u16[4]) * int32_t(aM2.u16[4])),
+ uint16_t(int32_t(aM1.u16[5]) * int32_t(aM2.u16[5])),
+ uint16_t(int32_t(aM1.u16[6]) * int32_t(aM2.u16[6])),
+ uint16_t(int32_t(aM1.u16[7]) * int32_t(aM2.u16[7])));
+}
+
+inline void Mul16x4x2x2To32x4x2(Scalari16x8_t aFactorsA1B1,
+ Scalari16x8_t aFactorsA2B2,
+ Scalari32x4_t& aProductA,
+ Scalari32x4_t& aProductB) {
+ aProductA = From32<Scalari32x4_t>(aFactorsA1B1.i16[0] * aFactorsA2B2.i16[0],
+ aFactorsA1B1.i16[1] * aFactorsA2B2.i16[1],
+ aFactorsA1B1.i16[2] * aFactorsA2B2.i16[2],
+ aFactorsA1B1.i16[3] * aFactorsA2B2.i16[3]);
+ aProductB = From32<Scalari32x4_t>(aFactorsA1B1.i16[4] * aFactorsA2B2.i16[4],
+ aFactorsA1B1.i16[5] * aFactorsA2B2.i16[5],
+ aFactorsA1B1.i16[6] * aFactorsA2B2.i16[6],
+ aFactorsA1B1.i16[7] * aFactorsA2B2.i16[7]);
+}
+
+inline Scalari32x4_t MulAdd16x8x2To32x4(Scalari16x8_t aFactorsA,
+ Scalari16x8_t aFactorsB) {
+ return From32<Scalari32x4_t>(
+ aFactorsA.i16[0] * aFactorsB.i16[0] + aFactorsA.i16[1] * aFactorsB.i16[1],
+ aFactorsA.i16[2] * aFactorsB.i16[2] + aFactorsA.i16[3] * aFactorsB.i16[3],
+ aFactorsA.i16[4] * aFactorsB.i16[4] + aFactorsA.i16[5] * aFactorsB.i16[5],
+ aFactorsA.i16[6] * aFactorsB.i16[6] +
+ aFactorsA.i16[7] * aFactorsB.i16[7]);
+}
+
+template <int8_t aIndex>
+inline void AssertIndex() {
+ static_assert(aIndex == 0 || aIndex == 1 || aIndex == 2 || aIndex == 3,
+ "Invalid splat index");
+}
+
+template <int8_t aIndex>
+inline Scalari32x4_t Splat32(Scalari32x4_t aM) {
+ AssertIndex<aIndex>();
+ return From32<Scalari32x4_t>(aM.i32[aIndex], aM.i32[aIndex], aM.i32[aIndex],
+ aM.i32[aIndex]);
+}
+
+template <int8_t i>
+inline Scalaru8x16_t Splat32On8(Scalaru8x16_t aM) {
+ AssertIndex<i>();
+ return From8<Scalaru8x16_t>(
+ aM.u8[i * 4], aM.u8[i * 4 + 1], aM.u8[i * 4 + 2], aM.u8[i * 4 + 3],
+ aM.u8[i * 4], aM.u8[i * 4 + 1], aM.u8[i * 4 + 2], aM.u8[i * 4 + 3],
+ aM.u8[i * 4], aM.u8[i * 4 + 1], aM.u8[i * 4 + 2], aM.u8[i * 4 + 3],
+ aM.u8[i * 4], aM.u8[i * 4 + 1], aM.u8[i * 4 + 2], aM.u8[i * 4 + 3]);
+}
+
+template <int8_t i0, int8_t i1, int8_t i2, int8_t i3>
+inline Scalari32x4_t Shuffle32(Scalari32x4_t aM) {
+ AssertIndex<i0>();
+ AssertIndex<i1>();
+ AssertIndex<i2>();
+ AssertIndex<i3>();
+ Scalari32x4_t m = aM;
+ m.i32[0] = aM.i32[i3];
+ m.i32[1] = aM.i32[i2];
+ m.i32[2] = aM.i32[i1];
+ m.i32[3] = aM.i32[i0];
+ return m;
+}
+
+template <int8_t i0, int8_t i1, int8_t i2, int8_t i3>
+inline Scalari16x8_t ShuffleLo16(Scalari16x8_t aM) {
+ AssertIndex<i0>();
+ AssertIndex<i1>();
+ AssertIndex<i2>();
+ AssertIndex<i3>();
+ Scalari16x8_t m = aM;
+ m.i16[0] = aM.i16[i3];
+ m.i16[1] = aM.i16[i2];
+ m.i16[2] = aM.i16[i1];
+ m.i16[3] = aM.i16[i0];
+ return m;
+}
+
+template <int8_t i0, int8_t i1, int8_t i2, int8_t i3>
+inline Scalari16x8_t ShuffleHi16(Scalari16x8_t aM) {
+ AssertIndex<i0>();
+ AssertIndex<i1>();
+ AssertIndex<i2>();
+ AssertIndex<i3>();
+ Scalari16x8_t m = aM;
+ m.i16[4 + 0] = aM.i16[4 + i3];
+ m.i16[4 + 1] = aM.i16[4 + i2];
+ m.i16[4 + 2] = aM.i16[4 + i1];
+ m.i16[4 + 3] = aM.i16[4 + i0];
+ return m;
+}
+
+template <int8_t aIndexLo, int8_t aIndexHi>
+inline Scalaru16x8_t Splat16(Scalaru16x8_t aM) {
+ AssertIndex<aIndexLo>();
+ AssertIndex<aIndexHi>();
+ Scalaru16x8_t m;
+ int16_t chosenValueLo = aM.u16[aIndexLo];
+ m.u16[0] = chosenValueLo;
+ m.u16[1] = chosenValueLo;
+ m.u16[2] = chosenValueLo;
+ m.u16[3] = chosenValueLo;
+ int16_t chosenValueHi = aM.u16[4 + aIndexHi];
+ m.u16[4] = chosenValueHi;
+ m.u16[5] = chosenValueHi;
+ m.u16[6] = chosenValueHi;
+ m.u16[7] = chosenValueHi;
+ return m;
+}
+
+inline Scalaru8x16_t InterleaveLo8(Scalaru8x16_t m1, Scalaru8x16_t m2) {
+ return From8<Scalaru8x16_t>(m1.u8[0], m2.u8[0], m1.u8[1], m2.u8[1], m1.u8[2],
+ m2.u8[2], m1.u8[3], m2.u8[3], m1.u8[4], m2.u8[4],
+ m1.u8[5], m2.u8[5], m1.u8[6], m2.u8[6], m1.u8[7],
+ m2.u8[7]);
+}
+
+inline Scalaru8x16_t InterleaveHi8(Scalaru8x16_t m1, Scalaru8x16_t m2) {
+ return From8<Scalaru8x16_t>(
+ m1.u8[8 + 0], m2.u8[8 + 0], m1.u8[8 + 1], m2.u8[8 + 1], m1.u8[8 + 2],
+ m2.u8[8 + 2], m1.u8[8 + 3], m2.u8[8 + 3], m1.u8[8 + 4], m2.u8[8 + 4],
+ m1.u8[8 + 5], m2.u8[8 + 5], m1.u8[8 + 6], m2.u8[8 + 6], m1.u8[8 + 7],
+ m2.u8[8 + 7]);
+}
+
+inline Scalaru16x8_t InterleaveLo16(Scalaru16x8_t m1, Scalaru16x8_t m2) {
+ return FromU16<Scalaru16x8_t>(m1.u16[0], m2.u16[0], m1.u16[1], m2.u16[1],
+ m1.u16[2], m2.u16[2], m1.u16[3], m2.u16[3]);
+}
+
+inline Scalaru16x8_t InterleaveHi16(Scalaru16x8_t m1, Scalaru16x8_t m2) {
+ return FromU16<Scalaru16x8_t>(m1.u16[4], m2.u16[4], m1.u16[5], m2.u16[5],
+ m1.u16[6], m2.u16[6], m1.u16[7], m2.u16[7]);
+}
+
+inline Scalari32x4_t InterleaveLo32(Scalari32x4_t m1, Scalari32x4_t m2) {
+ return From32<Scalari32x4_t>(m1.i32[0], m2.i32[0], m1.i32[1], m2.i32[1]);
+}
+
+inline Scalari16x8_t UnpackLo8x8ToI16x8(Scalaru8x16_t aM) {
+ Scalari16x8_t m;
+ m.i16[0] = aM.u8[0];
+ m.i16[1] = aM.u8[1];
+ m.i16[2] = aM.u8[2];
+ m.i16[3] = aM.u8[3];
+ m.i16[4] = aM.u8[4];
+ m.i16[5] = aM.u8[5];
+ m.i16[6] = aM.u8[6];
+ m.i16[7] = aM.u8[7];
+ return m;
+}
+
+inline Scalari16x8_t UnpackHi8x8ToI16x8(Scalaru8x16_t aM) {
+ Scalari16x8_t m;
+ m.i16[0] = aM.u8[8 + 0];
+ m.i16[1] = aM.u8[8 + 1];
+ m.i16[2] = aM.u8[8 + 2];
+ m.i16[3] = aM.u8[8 + 3];
+ m.i16[4] = aM.u8[8 + 4];
+ m.i16[5] = aM.u8[8 + 5];
+ m.i16[6] = aM.u8[8 + 6];
+ m.i16[7] = aM.u8[8 + 7];
+ return m;
+}
+
+inline Scalaru16x8_t UnpackLo8x8ToU16x8(Scalaru8x16_t aM) {
+ return FromU16<Scalaru16x8_t>(uint16_t(aM.u8[0]), uint16_t(aM.u8[1]),
+ uint16_t(aM.u8[2]), uint16_t(aM.u8[3]),
+ uint16_t(aM.u8[4]), uint16_t(aM.u8[5]),
+ uint16_t(aM.u8[6]), uint16_t(aM.u8[7]));
+}
+
+inline Scalaru16x8_t UnpackHi8x8ToU16x8(Scalaru8x16_t aM) {
+ return FromU16<Scalaru16x8_t>(aM.u8[8 + 0], aM.u8[8 + 1], aM.u8[8 + 2],
+ aM.u8[8 + 3], aM.u8[8 + 4], aM.u8[8 + 5],
+ aM.u8[8 + 6], aM.u8[8 + 7]);
+}
+
+template <uint8_t aNumBytes>
+inline Scalaru8x16_t Rotate8(Scalaru8x16_t a1234, Scalaru8x16_t a5678) {
+ Scalaru8x16_t m;
+ for (uint8_t i = 0; i < 16; i++) {
+ uint8_t sourceByte = i + aNumBytes;
+ m.u8[i] =
+ sourceByte < 16 ? a1234.u8[sourceByte] : a5678.u8[sourceByte - 16];
+ }
+ return m;
+}
+
+template <typename T>
+inline int16_t SaturateTo16(T a) {
+ return int16_t(a >= INT16_MIN ? (a <= INT16_MAX ? a : INT16_MAX) : INT16_MIN);
+}
+
+inline Scalari16x8_t PackAndSaturate32To16(Scalari32x4_t m1, Scalari32x4_t m2) {
+ Scalari16x8_t m;
+ m.i16[0] = SaturateTo16(m1.i32[0]);
+ m.i16[1] = SaturateTo16(m1.i32[1]);
+ m.i16[2] = SaturateTo16(m1.i32[2]);
+ m.i16[3] = SaturateTo16(m1.i32[3]);
+ m.i16[4] = SaturateTo16(m2.i32[0]);
+ m.i16[5] = SaturateTo16(m2.i32[1]);
+ m.i16[6] = SaturateTo16(m2.i32[2]);
+ m.i16[7] = SaturateTo16(m2.i32[3]);
+ return m;
+}
+
+template <typename T>
+inline uint16_t SaturateToU16(T a) {
+ return uint16_t(umin(a & -(a >= 0), INT16_MAX));
+}
+
+inline Scalaru16x8_t PackAndSaturate32ToU16(Scalari32x4_t m1,
+ Scalari32x4_t m2) {
+ Scalaru16x8_t m;
+ m.u16[0] = SaturateToU16(m1.i32[0]);
+ m.u16[1] = SaturateToU16(m1.i32[1]);
+ m.u16[2] = SaturateToU16(m1.i32[2]);
+ m.u16[3] = SaturateToU16(m1.i32[3]);
+ m.u16[4] = SaturateToU16(m2.i32[0]);
+ m.u16[5] = SaturateToU16(m2.i32[1]);
+ m.u16[6] = SaturateToU16(m2.i32[2]);
+ m.u16[7] = SaturateToU16(m2.i32[3]);
+ return m;
+}
+
+template <typename T>
+inline uint8_t SaturateTo8(T a) {
+ return uint8_t(umin(a & -(a >= 0), 255));
+}
+
+inline Scalaru8x16_t PackAndSaturate32To8(Scalari32x4_t m1, Scalari32x4_t m2,
+ Scalari32x4_t m3,
+ const Scalari32x4_t& m4) {
+ Scalaru8x16_t m;
+ m.u8[0] = SaturateTo8(m1.i32[0]);
+ m.u8[1] = SaturateTo8(m1.i32[1]);
+ m.u8[2] = SaturateTo8(m1.i32[2]);
+ m.u8[3] = SaturateTo8(m1.i32[3]);
+ m.u8[4] = SaturateTo8(m2.i32[0]);
+ m.u8[5] = SaturateTo8(m2.i32[1]);
+ m.u8[6] = SaturateTo8(m2.i32[2]);
+ m.u8[7] = SaturateTo8(m2.i32[3]);
+ m.u8[8] = SaturateTo8(m3.i32[0]);
+ m.u8[9] = SaturateTo8(m3.i32[1]);
+ m.u8[10] = SaturateTo8(m3.i32[2]);
+ m.u8[11] = SaturateTo8(m3.i32[3]);
+ m.u8[12] = SaturateTo8(m4.i32[0]);
+ m.u8[13] = SaturateTo8(m4.i32[1]);
+ m.u8[14] = SaturateTo8(m4.i32[2]);
+ m.u8[15] = SaturateTo8(m4.i32[3]);
+ return m;
+}
+
+inline Scalaru8x16_t PackAndSaturate16To8(Scalari16x8_t m1, Scalari16x8_t m2) {
+ Scalaru8x16_t m;
+ m.u8[0] = SaturateTo8(m1.i16[0]);
+ m.u8[1] = SaturateTo8(m1.i16[1]);
+ m.u8[2] = SaturateTo8(m1.i16[2]);
+ m.u8[3] = SaturateTo8(m1.i16[3]);
+ m.u8[4] = SaturateTo8(m1.i16[4]);
+ m.u8[5] = SaturateTo8(m1.i16[5]);
+ m.u8[6] = SaturateTo8(m1.i16[6]);
+ m.u8[7] = SaturateTo8(m1.i16[7]);
+ m.u8[8] = SaturateTo8(m2.i16[0]);
+ m.u8[9] = SaturateTo8(m2.i16[1]);
+ m.u8[10] = SaturateTo8(m2.i16[2]);
+ m.u8[11] = SaturateTo8(m2.i16[3]);
+ m.u8[12] = SaturateTo8(m2.i16[4]);
+ m.u8[13] = SaturateTo8(m2.i16[5]);
+ m.u8[14] = SaturateTo8(m2.i16[6]);
+ m.u8[15] = SaturateTo8(m2.i16[7]);
+ return m;
+}
+
+// Fast approximate division by 255. It has the property that
+// for all 0 <= n <= 255*255, FAST_DIVIDE_BY_255(n) == n/255.
+// But it only uses two adds and two shifts instead of an
+// integer division (which is expensive on many processors).
+//
+// equivalent to v/255
+template <class B, class A>
+inline B FastDivideBy255(A v) {
+ return ((v << 8) + v + 255) >> 16;
+}
+
+inline Scalaru16x8_t FastDivideBy255_16(Scalaru16x8_t m) {
+ return FromU16<Scalaru16x8_t>(FastDivideBy255<uint16_t>(int32_t(m.u16[0])),
+ FastDivideBy255<uint16_t>(int32_t(m.u16[1])),
+ FastDivideBy255<uint16_t>(int32_t(m.u16[2])),
+ FastDivideBy255<uint16_t>(int32_t(m.u16[3])),
+ FastDivideBy255<uint16_t>(int32_t(m.u16[4])),
+ FastDivideBy255<uint16_t>(int32_t(m.u16[5])),
+ FastDivideBy255<uint16_t>(int32_t(m.u16[6])),
+ FastDivideBy255<uint16_t>(int32_t(m.u16[7])));
+}
+
+inline Scalari32x4_t FastDivideBy255(Scalari32x4_t m) {
+ return From32<Scalari32x4_t>(
+ FastDivideBy255<int32_t>(m.i32[0]), FastDivideBy255<int32_t>(m.i32[1]),
+ FastDivideBy255<int32_t>(m.i32[2]), FastDivideBy255<int32_t>(m.i32[3]));
+}
+
+inline Scalaru8x16_t Pick(Scalaru8x16_t mask, Scalaru8x16_t a,
+ Scalaru8x16_t b) {
+ return From8<Scalaru8x16_t>(
+ (a.u8[0] & (~mask.u8[0])) | (b.u8[0] & mask.u8[0]),
+ (a.u8[1] & (~mask.u8[1])) | (b.u8[1] & mask.u8[1]),
+ (a.u8[2] & (~mask.u8[2])) | (b.u8[2] & mask.u8[2]),
+ (a.u8[3] & (~mask.u8[3])) | (b.u8[3] & mask.u8[3]),
+ (a.u8[4] & (~mask.u8[4])) | (b.u8[4] & mask.u8[4]),
+ (a.u8[5] & (~mask.u8[5])) | (b.u8[5] & mask.u8[5]),
+ (a.u8[6] & (~mask.u8[6])) | (b.u8[6] & mask.u8[6]),
+ (a.u8[7] & (~mask.u8[7])) | (b.u8[7] & mask.u8[7]),
+ (a.u8[8 + 0] & (~mask.u8[8 + 0])) | (b.u8[8 + 0] & mask.u8[8 + 0]),
+ (a.u8[8 + 1] & (~mask.u8[8 + 1])) | (b.u8[8 + 1] & mask.u8[8 + 1]),
+ (a.u8[8 + 2] & (~mask.u8[8 + 2])) | (b.u8[8 + 2] & mask.u8[8 + 2]),
+ (a.u8[8 + 3] & (~mask.u8[8 + 3])) | (b.u8[8 + 3] & mask.u8[8 + 3]),
+ (a.u8[8 + 4] & (~mask.u8[8 + 4])) | (b.u8[8 + 4] & mask.u8[8 + 4]),
+ (a.u8[8 + 5] & (~mask.u8[8 + 5])) | (b.u8[8 + 5] & mask.u8[8 + 5]),
+ (a.u8[8 + 6] & (~mask.u8[8 + 6])) | (b.u8[8 + 6] & mask.u8[8 + 6]),
+ (a.u8[8 + 7] & (~mask.u8[8 + 7])) | (b.u8[8 + 7] & mask.u8[8 + 7]));
+}
+
+inline Scalari32x4_t Pick(Scalari32x4_t mask, Scalari32x4_t a,
+ Scalari32x4_t b) {
+ return From32<Scalari32x4_t>(
+ (a.i32[0] & (~mask.i32[0])) | (b.i32[0] & mask.i32[0]),
+ (a.i32[1] & (~mask.i32[1])) | (b.i32[1] & mask.i32[1]),
+ (a.i32[2] & (~mask.i32[2])) | (b.i32[2] & mask.i32[2]),
+ (a.i32[3] & (~mask.i32[3])) | (b.i32[3] & mask.i32[3]));
+}
+
+inline Scalarf32x4_t MixF32(Scalarf32x4_t a, Scalarf32x4_t b, float t) {
+ return FromF32<Scalarf32x4_t>(a.f32[0] + (b.f32[0] - a.f32[0]) * t,
+ a.f32[1] + (b.f32[1] - a.f32[1]) * t,
+ a.f32[2] + (b.f32[2] - a.f32[2]) * t,
+ a.f32[3] + (b.f32[3] - a.f32[3]) * t);
+}
+
+inline Scalarf32x4_t WSumF32(Scalarf32x4_t a, Scalarf32x4_t b, float wa,
+ float wb) {
+ return FromF32<Scalarf32x4_t>(
+ a.f32[0] * wa + b.f32[0] * wb, a.f32[1] * wa + b.f32[1] * wb,
+ a.f32[2] * wa + b.f32[2] * wb, a.f32[3] * wa + b.f32[3] * wb);
+}
+
+inline Scalarf32x4_t AbsF32(Scalarf32x4_t a) {
+ return FromF32<Scalarf32x4_t>(fabs(a.f32[0]), fabs(a.f32[1]), fabs(a.f32[2]),
+ fabs(a.f32[3]));
+}
+
+inline Scalarf32x4_t AddF32(Scalarf32x4_t a, Scalarf32x4_t b) {
+ return FromF32<Scalarf32x4_t>(a.f32[0] + b.f32[0], a.f32[1] + b.f32[1],
+ a.f32[2] + b.f32[2], a.f32[3] + b.f32[3]);
+}
+
+inline Scalarf32x4_t MulF32(Scalarf32x4_t a, Scalarf32x4_t b) {
+ return FromF32<Scalarf32x4_t>(a.f32[0] * b.f32[0], a.f32[1] * b.f32[1],
+ a.f32[2] * b.f32[2], a.f32[3] * b.f32[3]);
+}
+
+inline Scalarf32x4_t DivF32(Scalarf32x4_t a, Scalarf32x4_t b) {
+ return FromF32<Scalarf32x4_t>(a.f32[0] / b.f32[0], a.f32[1] / b.f32[1],
+ a.f32[2] / b.f32[2], a.f32[3] / b.f32[3]);
+}
+
+template <uint8_t aIndex>
+inline Scalarf32x4_t SplatF32(Scalarf32x4_t m) {
+ AssertIndex<aIndex>();
+ return FromF32<Scalarf32x4_t>(m.f32[aIndex], m.f32[aIndex], m.f32[aIndex],
+ m.f32[aIndex]);
+}
+
+inline Scalari32x4_t F32ToI32(Scalarf32x4_t m) {
+ return From32<Scalari32x4_t>(
+ int32_t(floor(m.f32[0] + 0.5f)), int32_t(floor(m.f32[1] + 0.5f)),
+ int32_t(floor(m.f32[2] + 0.5f)), int32_t(floor(m.f32[3] + 0.5f)));
+}
+
+#ifdef SIMD_COMPILE_SSE2
+
+// SSE2
+
+template <>
+inline __m128i Load8<__m128i>(const uint8_t* aSource) {
+ return _mm_load_si128((const __m128i*)aSource);
+}
+
+inline void Store8(uint8_t* aTarget, __m128i aM) {
+ _mm_store_si128((__m128i*)aTarget, aM);
+}
+
+template <>
+inline __m128i FromZero8<__m128i>() {
+ return _mm_setzero_si128();
+}
+
+template <>
+inline __m128i From8<__m128i>(uint8_t a, uint8_t b, uint8_t c, uint8_t d,
+ uint8_t e, uint8_t f, uint8_t g, uint8_t h,
+ uint8_t i, uint8_t j, uint8_t k, uint8_t l,
+ uint8_t m, uint8_t n, uint8_t o, uint8_t p) {
+ return _mm_setr_epi16((b << 8) + a, (d << 8) + c, (e << 8) + f, (h << 8) + g,
+ (j << 8) + i, (l << 8) + k, (m << 8) + n, (p << 8) + o);
+}
+
+template <>
+inline __m128i FromI16<__m128i>(int16_t a, int16_t b, int16_t c, int16_t d,
+ int16_t e, int16_t f, int16_t g, int16_t h) {
+ return _mm_setr_epi16(a, b, c, d, e, f, g, h);
+}
+
+template <>
+inline __m128i FromU16<__m128i>(uint16_t a, uint16_t b, uint16_t c, uint16_t d,
+ uint16_t e, uint16_t f, uint16_t g,
+ uint16_t h) {
+ return _mm_setr_epi16(a, b, c, d, e, f, g, h);
+}
+
+template <>
+inline __m128i FromI16<__m128i>(int16_t a) {
+ return _mm_set1_epi16(a);
+}
+
+template <>
+inline __m128i FromU16<__m128i>(uint16_t a) {
+ return _mm_set1_epi16((int16_t)a);
+}
+
+template <>
+inline __m128i From32<__m128i>(int32_t a, int32_t b, int32_t c, int32_t d) {
+ return _mm_setr_epi32(a, b, c, d);
+}
+
+template <>
+inline __m128i From32<__m128i>(int32_t a) {
+ return _mm_set1_epi32(a);
+}
+
+template <>
+inline __m128 FromF32<__m128>(float a, float b, float c, float d) {
+ return _mm_setr_ps(a, b, c, d);
+}
+
+template <>
+inline __m128 FromF32<__m128>(float a) {
+ return _mm_set1_ps(a);
+}
+
+template <int32_t aNumberOfBits>
+inline __m128i ShiftRight16(__m128i aM) {
+ return _mm_srli_epi16(aM, aNumberOfBits);
+}
+
+template <int32_t aNumberOfBits>
+inline __m128i ShiftRight32(__m128i aM) {
+ return _mm_srai_epi32(aM, aNumberOfBits);
+}
+
+inline __m128i Add16(__m128i aM1, __m128i aM2) {
+ return _mm_add_epi16(aM1, aM2);
+}
+
+inline __m128i Add32(__m128i aM1, __m128i aM2) {
+ return _mm_add_epi32(aM1, aM2);
+}
+
+inline __m128i Sub16(__m128i aM1, __m128i aM2) {
+ return _mm_sub_epi16(aM1, aM2);
+}
+
+inline __m128i Sub32(__m128i aM1, __m128i aM2) {
+ return _mm_sub_epi32(aM1, aM2);
+}
+
+inline __m128i Min8(__m128i aM1, __m128i aM2) { return _mm_min_epu8(aM1, aM2); }
+
+inline __m128i Max8(__m128i aM1, __m128i aM2) { return _mm_max_epu8(aM1, aM2); }
+
+inline __m128i Min32(__m128i aM1, __m128i aM2) {
+ __m128i m1_minus_m2 = _mm_sub_epi32(aM1, aM2);
+ __m128i m1_greater_than_m2 = _mm_cmpgt_epi32(aM1, aM2);
+ return _mm_sub_epi32(aM1, _mm_and_si128(m1_minus_m2, m1_greater_than_m2));
+}
+
+inline __m128i Max32(__m128i aM1, __m128i aM2) {
+ __m128i m1_minus_m2 = _mm_sub_epi32(aM1, aM2);
+ __m128i m2_greater_than_m1 = _mm_cmpgt_epi32(aM2, aM1);
+ return _mm_sub_epi32(aM1, _mm_and_si128(m1_minus_m2, m2_greater_than_m1));
+}
+
+inline __m128i Mul16(__m128i aM1, __m128i aM2) {
+ return _mm_mullo_epi16(aM1, aM2);
+}
+
+inline __m128i MulU16(__m128i aM1, __m128i aM2) {
+ return _mm_mullo_epi16(aM1, aM2);
+}
+
+inline void Mul16x4x2x2To32x4x2(__m128i aFactorsA1B1, __m128i aFactorsA2B2,
+ __m128i& aProductA, __m128i& aProductB) {
+ __m128i prodAB_lo = _mm_mullo_epi16(aFactorsA1B1, aFactorsA2B2);
+ __m128i prodAB_hi = _mm_mulhi_epi16(aFactorsA1B1, aFactorsA2B2);
+ aProductA = _mm_unpacklo_epi16(prodAB_lo, prodAB_hi);
+ aProductB = _mm_unpackhi_epi16(prodAB_lo, prodAB_hi);
+}
+
+inline __m128i MulAdd16x8x2To32x4(__m128i aFactorsA, __m128i aFactorsB) {
+ return _mm_madd_epi16(aFactorsA, aFactorsB);
+}
+
+template <int8_t i0, int8_t i1, int8_t i2, int8_t i3>
+inline __m128i Shuffle32(__m128i aM) {
+ AssertIndex<i0>();
+ AssertIndex<i1>();
+ AssertIndex<i2>();
+ AssertIndex<i3>();
+ return _mm_shuffle_epi32(aM, _MM_SHUFFLE(i0, i1, i2, i3));
+}
+
+template <int8_t i0, int8_t i1, int8_t i2, int8_t i3>
+inline __m128i ShuffleLo16(__m128i aM) {
+ AssertIndex<i0>();
+ AssertIndex<i1>();
+ AssertIndex<i2>();
+ AssertIndex<i3>();
+ return _mm_shufflelo_epi16(aM, _MM_SHUFFLE(i0, i1, i2, i3));
+}
+
+template <int8_t i0, int8_t i1, int8_t i2, int8_t i3>
+inline __m128i ShuffleHi16(__m128i aM) {
+ AssertIndex<i0>();
+ AssertIndex<i1>();
+ AssertIndex<i2>();
+ AssertIndex<i3>();
+ return _mm_shufflehi_epi16(aM, _MM_SHUFFLE(i0, i1, i2, i3));
+}
+
+template <int8_t aIndex>
+inline __m128i Splat32(__m128i aM) {
+ return Shuffle32<aIndex, aIndex, aIndex, aIndex>(aM);
+}
+
+template <int8_t aIndex>
+inline __m128i Splat32On8(__m128i aM) {
+ return Shuffle32<aIndex, aIndex, aIndex, aIndex>(aM);
+}
+
+template <int8_t aIndexLo, int8_t aIndexHi>
+inline __m128i Splat16(__m128i aM) {
+ AssertIndex<aIndexLo>();
+ AssertIndex<aIndexHi>();
+ return ShuffleHi16<aIndexHi, aIndexHi, aIndexHi, aIndexHi>(
+ ShuffleLo16<aIndexLo, aIndexLo, aIndexLo, aIndexLo>(aM));
+}
+
+inline __m128i UnpackLo8x8ToI16x8(__m128i m) {
+ __m128i zero = _mm_set1_epi8(0);
+ return _mm_unpacklo_epi8(m, zero);
+}
+
+inline __m128i UnpackHi8x8ToI16x8(__m128i m) {
+ __m128i zero = _mm_set1_epi8(0);
+ return _mm_unpackhi_epi8(m, zero);
+}
+
+inline __m128i UnpackLo8x8ToU16x8(__m128i m) {
+ __m128i zero = _mm_set1_epi8(0);
+ return _mm_unpacklo_epi8(m, zero);
+}
+
+inline __m128i UnpackHi8x8ToU16x8(__m128i m) {
+ __m128i zero = _mm_set1_epi8(0);
+ return _mm_unpackhi_epi8(m, zero);
+}
+
+inline __m128i InterleaveLo8(__m128i m1, __m128i m2) {
+ return _mm_unpacklo_epi8(m1, m2);
+}
+
+inline __m128i InterleaveHi8(__m128i m1, __m128i m2) {
+ return _mm_unpackhi_epi8(m1, m2);
+}
+
+inline __m128i InterleaveLo16(__m128i m1, __m128i m2) {
+ return _mm_unpacklo_epi16(m1, m2);
+}
+
+inline __m128i InterleaveHi16(__m128i m1, __m128i m2) {
+ return _mm_unpackhi_epi16(m1, m2);
+}
+
+inline __m128i InterleaveLo32(__m128i m1, __m128i m2) {
+ return _mm_unpacklo_epi32(m1, m2);
+}
+
+template <uint8_t aNumBytes>
+inline __m128i Rotate8(__m128i a1234, __m128i a5678) {
+ return _mm_or_si128(_mm_srli_si128(a1234, aNumBytes),
+ _mm_slli_si128(a5678, 16 - aNumBytes));
+}
+
+inline __m128i PackAndSaturate32To16(__m128i m1, __m128i m2) {
+ return _mm_packs_epi32(m1, m2);
+}
+
+inline __m128i PackAndSaturate32ToU16(__m128i m1, __m128i m2) {
+ return _mm_packs_epi32(m1, m2);
+}
+
+inline __m128i PackAndSaturate32To8(__m128i m1, __m128i m2, __m128i m3,
+ const __m128i& m4) {
+ // Pack into 8 16bit signed integers (saturating).
+ __m128i m12 = _mm_packs_epi32(m1, m2);
+ __m128i m34 = _mm_packs_epi32(m3, m4);
+
+ // Pack into 16 8bit unsigned integers (saturating).
+ return _mm_packus_epi16(m12, m34);
+}
+
+inline __m128i PackAndSaturate16To8(__m128i m1, __m128i m2) {
+ // Pack into 16 8bit unsigned integers (saturating).
+ return _mm_packus_epi16(m1, m2);
+}
+
+inline __m128i FastDivideBy255(__m128i m) {
+ // v = m << 8
+ __m128i v = _mm_slli_epi32(m, 8);
+ // v = v + (m + (255,255,255,255))
+ v = _mm_add_epi32(v, _mm_add_epi32(m, _mm_set1_epi32(255)));
+ // v = v >> 16
+ return _mm_srai_epi32(v, 16);
+}
+
+inline __m128i FastDivideBy255_16(__m128i m) {
+ __m128i zero = _mm_set1_epi16(0);
+ __m128i lo = _mm_unpacklo_epi16(m, zero);
+ __m128i hi = _mm_unpackhi_epi16(m, zero);
+ return _mm_packs_epi32(FastDivideBy255(lo), FastDivideBy255(hi));
+}
+
+inline __m128i Pick(__m128i mask, __m128i a, __m128i b) {
+ return _mm_or_si128(_mm_andnot_si128(mask, a), _mm_and_si128(mask, b));
+}
+
+inline __m128 MixF32(__m128 a, __m128 b, float t) {
+ return _mm_add_ps(a, _mm_mul_ps(_mm_sub_ps(b, a), _mm_set1_ps(t)));
+}
+
+inline __m128 WSumF32(__m128 a, __m128 b, float wa, float wb) {
+ return _mm_add_ps(_mm_mul_ps(a, _mm_set1_ps(wa)),
+ _mm_mul_ps(b, _mm_set1_ps(wb)));
+}
+
+inline __m128 AbsF32(__m128 a) {
+ return _mm_max_ps(_mm_sub_ps(_mm_setzero_ps(), a), a);
+}
+
+inline __m128 AddF32(__m128 a, __m128 b) { return _mm_add_ps(a, b); }
+
+inline __m128 MulF32(__m128 a, __m128 b) { return _mm_mul_ps(a, b); }
+
+inline __m128 DivF32(__m128 a, __m128 b) { return _mm_div_ps(a, b); }
+
+template <uint8_t aIndex>
+inline __m128 SplatF32(__m128 m) {
+ AssertIndex<aIndex>();
+ return _mm_shuffle_ps(m, m, _MM_SHUFFLE(aIndex, aIndex, aIndex, aIndex));
+}
+
+inline __m128i F32ToI32(__m128 m) { return _mm_cvtps_epi32(m); }
+
+#endif // SIMD_COMPILE_SSE2
+
+} // namespace simd
+
+} // namespace gfx
+} // namespace mozilla
+
+#endif // _MOZILLA_GFX_SIMD_H_