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// Copyright (c) the JPEG XL Project Authors. All rights reserved.
//
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Misc utilities for SIMD operations
#if defined(LIB_JXL_SIMD_UTIL_INL_H_) == defined(HWY_TARGET_TOGGLE)
#ifdef LIB_JXL_SIMD_UTIL_INL_H_
#undef LIB_JXL_SIMD_UTIL_INL_H_
#else
#define LIB_JXL_SIMD_UTIL_INL_H_
#endif
#include <hwy/highway.h>
#include "lib/jxl/base/compiler_specific.h"
HWY_BEFORE_NAMESPACE();
namespace jxl {
namespace HWY_NAMESPACE {
#if HWY_CAP_GE512
using hwy::HWY_NAMESPACE::Half;
using hwy::HWY_NAMESPACE::Vec;
template <size_t i, class DF, class V>
HWY_INLINE Vec<Half<Half<DF>>> Quarter(const DF df, V v) {
using HF = Half<DF>;
using HHF = Half<HF>;
auto half = i >= 2 ? UpperHalf(HF(), v) : LowerHalf(HF(), v);
return i & 1 ? UpperHalf(HHF(), half) : LowerHalf(HHF(), half);
}
template <class DF, class V>
HWY_INLINE Vec<DF> Concat4(const DF df, V v0, V v1, V v2, V v3) {
using HF = Half<DF>;
return Combine(DF(), Combine(HF(), v3, v2), Combine(HF(), v1, v0));
}
#endif
// Stores v0[0], v1[0], v0[1], v1[1], ... to mem, in this order. Mem must be
// aligned.
template <class DF, class V, typename T>
void StoreInterleaved(const DF df, V v0, V v1, T* mem) {
static_assert(sizeof(T) == 4, "only use StoreInterleaved for 4-byte types");
#if HWY_TARGET == HWY_SCALAR
Store(v0, df, mem);
Store(v1, df, mem + 1);
#elif !HWY_CAP_GE256
Store(InterleaveLower(df, v0, v1), df, mem);
Store(InterleaveUpper(df, v0, v1), df, mem + Lanes(df));
#else
if (!HWY_CAP_GE512 || Lanes(df) == 8) {
auto t0 = InterleaveLower(df, v0, v1);
auto t1 = InterleaveUpper(df, v0, v1);
Store(ConcatLowerLower(df, t1, t0), df, mem);
Store(ConcatUpperUpper(df, t1, t0), df, mem + Lanes(df));
} else {
#if HWY_CAP_GE512
auto t0 = InterleaveLower(df, v0, v1);
auto t1 = InterleaveUpper(df, v0, v1);
Store(Concat4(df, Quarter<0>(df, t0), Quarter<0>(df, t1),
Quarter<1>(df, t0), Quarter<1>(df, t1)),
df, mem);
Store(Concat4(df, Quarter<2>(df, t0), Quarter<2>(df, t1),
Quarter<3>(df, t0), Quarter<3>(df, t1)),
df, mem + Lanes(df));
#endif
}
#endif
}
// Stores v0[0], v1[0], v2[0], v3[0], v0[1] ... to mem, in this order. Mem must
// be aligned.
template <class DF, class V, typename T>
void StoreInterleaved(const DF df, V v0, V v1, V v2, V v3, T* mem) {
static_assert(sizeof(T) == 4, "only use StoreInterleaved for 4-byte types");
#if HWY_TARGET == HWY_SCALAR
Store(v0, df, mem);
Store(v1, df, mem + 1);
Store(v2, df, mem + 2);
Store(v3, df, mem + 3);
#elif !HWY_CAP_GE256
auto t0 = InterleaveLower(df, v0, v2);
auto t1 = InterleaveLower(df, v1, v3);
auto t2 = InterleaveUpper(df, v0, v2);
auto t3 = InterleaveUpper(df, v1, v3);
Store(InterleaveLower(df, t0, t1), df, mem);
Store(InterleaveUpper(df, t0, t1), df, mem + Lanes(df));
Store(InterleaveLower(df, t2, t3), df, mem + 2 * Lanes(df));
Store(InterleaveUpper(df, t2, t3), df, mem + 3 * Lanes(df));
#elif !HWY_CAP_GE512
auto t0 = InterleaveLower(df, v0, v2);
auto t1 = InterleaveLower(df, v1, v3);
auto t2 = InterleaveUpper(df, v0, v2);
auto t3 = InterleaveUpper(df, v1, v3);
auto m0 = InterleaveLower(df, t0, t1);
auto m1 = InterleaveUpper(df, t0, t1);
auto m2 = InterleaveLower(df, t2, t3);
auto m3 = InterleaveUpper(df, t2, t3);
Store(ConcatLowerLower(df, m1, m0), df, mem);
Store(ConcatLowerLower(df, m3, m2), df, mem + Lanes(df));
Store(ConcatUpperUpper(df, m1, m0), df, mem + 2 * Lanes(df));
Store(ConcatUpperUpper(df, m3, m2), df, mem + 3 * Lanes(df));
#else
auto t0 = InterleaveLower(df, v0, v2);
auto t1 = InterleaveLower(df, v1, v3);
auto t2 = InterleaveUpper(df, v0, v2);
auto t3 = InterleaveUpper(df, v1, v3);
auto m0 = InterleaveLower(df, t0, t1);
auto m1 = InterleaveUpper(df, t0, t1);
auto m2 = InterleaveLower(df, t2, t3);
auto m3 = InterleaveUpper(df, t2, t3);
Store(Concat4(df, Quarter<0>(df, m0), Quarter<0>(df, m1), Quarter<0>(df, m2),
Quarter<0>(df, m3)),
df, mem);
Store(Concat4(df, Quarter<1>(df, m0), Quarter<1>(df, m1), Quarter<1>(df, m2),
Quarter<1>(df, m3)),
df, mem + Lanes(df));
Store(Concat4(df, Quarter<2>(df, m0), Quarter<2>(df, m1), Quarter<2>(df, m2),
Quarter<2>(df, m3)),
df, mem + 2 * Lanes(df));
Store(Concat4(df, Quarter<3>(df, m0), Quarter<3>(df, m1), Quarter<3>(df, m2),
Quarter<3>(df, m3)),
df, mem + 3 * Lanes(df));
#endif
}
// Stores v0[0], v1[0], v2[0], v3[0], v4[0], v5[0], v6[0], v7[0], v0[1] ... to
// mem, in this order. Mem must be aligned.
template <class DF, class V>
void StoreInterleaved(const DF df, V v0, V v1, V v2, V v3, V v4, V v5, V v6,
V v7, float* mem) {
#if HWY_TARGET == HWY_SCALAR
Store(v0, df, mem);
Store(v1, df, mem + 1);
Store(v2, df, mem + 2);
Store(v3, df, mem + 3);
Store(v4, df, mem + 4);
Store(v5, df, mem + 5);
Store(v6, df, mem + 6);
Store(v7, df, mem + 7);
#elif !HWY_CAP_GE256
auto t0 = InterleaveLower(df, v0, v4);
auto t1 = InterleaveLower(df, v1, v5);
auto t2 = InterleaveLower(df, v2, v6);
auto t3 = InterleaveLower(df, v3, v7);
auto t4 = InterleaveUpper(df, v0, v4);
auto t5 = InterleaveUpper(df, v1, v5);
auto t6 = InterleaveUpper(df, v2, v6);
auto t7 = InterleaveUpper(df, v3, v7);
auto w0 = InterleaveLower(df, t0, t2);
auto w1 = InterleaveLower(df, t1, t3);
auto w2 = InterleaveUpper(df, t0, t2);
auto w3 = InterleaveUpper(df, t1, t3);
auto w4 = InterleaveLower(df, t4, t6);
auto w5 = InterleaveLower(df, t5, t7);
auto w6 = InterleaveUpper(df, t4, t6);
auto w7 = InterleaveUpper(df, t5, t7);
Store(InterleaveLower(df, w0, w1), df, mem);
Store(InterleaveUpper(df, w0, w1), df, mem + Lanes(df));
Store(InterleaveLower(df, w2, w3), df, mem + 2 * Lanes(df));
Store(InterleaveUpper(df, w2, w3), df, mem + 3 * Lanes(df));
Store(InterleaveLower(df, w4, w5), df, mem + 4 * Lanes(df));
Store(InterleaveUpper(df, w4, w5), df, mem + 5 * Lanes(df));
Store(InterleaveLower(df, w6, w7), df, mem + 6 * Lanes(df));
Store(InterleaveUpper(df, w6, w7), df, mem + 7 * Lanes(df));
#elif !HWY_CAP_GE512
auto t0 = InterleaveLower(df, v0, v4);
auto t1 = InterleaveLower(df, v1, v5);
auto t2 = InterleaveLower(df, v2, v6);
auto t3 = InterleaveLower(df, v3, v7);
auto t4 = InterleaveUpper(df, v0, v4);
auto t5 = InterleaveUpper(df, v1, v5);
auto t6 = InterleaveUpper(df, v2, v6);
auto t7 = InterleaveUpper(df, v3, v7);
auto w0 = InterleaveLower(df, t0, t2);
auto w1 = InterleaveLower(df, t1, t3);
auto w2 = InterleaveUpper(df, t0, t2);
auto w3 = InterleaveUpper(df, t1, t3);
auto w4 = InterleaveLower(df, t4, t6);
auto w5 = InterleaveLower(df, t5, t7);
auto w6 = InterleaveUpper(df, t4, t6);
auto w7 = InterleaveUpper(df, t5, t7);
auto m0 = InterleaveLower(df, w0, w1);
auto m1 = InterleaveUpper(df, w0, w1);
auto m2 = InterleaveLower(df, w2, w3);
auto m3 = InterleaveUpper(df, w2, w3);
auto m4 = InterleaveLower(df, w4, w5);
auto m5 = InterleaveUpper(df, w4, w5);
auto m6 = InterleaveLower(df, w6, w7);
auto m7 = InterleaveUpper(df, w6, w7);
Store(ConcatLowerLower(df, m1, m0), df, mem);
Store(ConcatLowerLower(df, m3, m2), df, mem + Lanes(df));
Store(ConcatLowerLower(df, m5, m4), df, mem + 2 * Lanes(df));
Store(ConcatLowerLower(df, m7, m6), df, mem + 3 * Lanes(df));
Store(ConcatUpperUpper(df, m1, m0), df, mem + 4 * Lanes(df));
Store(ConcatUpperUpper(df, m3, m2), df, mem + 5 * Lanes(df));
Store(ConcatUpperUpper(df, m5, m4), df, mem + 6 * Lanes(df));
Store(ConcatUpperUpper(df, m7, m6), df, mem + 7 * Lanes(df));
#else
auto t0 = InterleaveLower(df, v0, v4);
auto t1 = InterleaveLower(df, v1, v5);
auto t2 = InterleaveLower(df, v2, v6);
auto t3 = InterleaveLower(df, v3, v7);
auto t4 = InterleaveUpper(df, v0, v4);
auto t5 = InterleaveUpper(df, v1, v5);
auto t6 = InterleaveUpper(df, v2, v6);
auto t7 = InterleaveUpper(df, v3, v7);
auto w0 = InterleaveLower(df, t0, t2);
auto w1 = InterleaveLower(df, t1, t3);
auto w2 = InterleaveUpper(df, t0, t2);
auto w3 = InterleaveUpper(df, t1, t3);
auto w4 = InterleaveLower(df, t4, t6);
auto w5 = InterleaveLower(df, t5, t7);
auto w6 = InterleaveUpper(df, t4, t6);
auto w7 = InterleaveUpper(df, t5, t7);
auto m0 = InterleaveLower(df, w0, w1);
auto m1 = InterleaveUpper(df, w0, w1);
auto m2 = InterleaveLower(df, w2, w3);
auto m3 = InterleaveUpper(df, w2, w3);
auto m4 = InterleaveLower(df, w4, w5);
auto m5 = InterleaveUpper(df, w4, w5);
auto m6 = InterleaveLower(df, w6, w7);
auto m7 = InterleaveUpper(df, w6, w7);
Store(Concat4(df, Quarter<0>(df, m0), Quarter<0>(df, m1), Quarter<0>(df, m2),
Quarter<0>(df, m3)),
df, mem);
Store(Concat4(df, Quarter<0>(df, m4), Quarter<0>(df, m5), Quarter<0>(df, m6),
Quarter<0>(df, m7)),
df, mem + Lanes(df));
Store(Concat4(df, Quarter<1>(df, m0), Quarter<1>(df, m1), Quarter<1>(df, m2),
Quarter<1>(df, m3)),
df, mem + 2 * Lanes(df));
Store(Concat4(df, Quarter<1>(df, m4), Quarter<1>(df, m5), Quarter<1>(df, m6),
Quarter<1>(df, m7)),
df, mem + 3 * Lanes(df));
Store(Concat4(df, Quarter<2>(df, m0), Quarter<2>(df, m1), Quarter<2>(df, m2),
Quarter<2>(df, m3)),
df, mem + 4 * Lanes(df));
Store(Concat4(df, Quarter<2>(df, m4), Quarter<2>(df, m5), Quarter<2>(df, m6),
Quarter<2>(df, m7)),
df, mem + 5 * Lanes(df));
Store(Concat4(df, Quarter<3>(df, m0), Quarter<3>(df, m1), Quarter<3>(df, m2),
Quarter<3>(df, m3)),
df, mem + 6 * Lanes(df));
Store(Concat4(df, Quarter<3>(df, m4), Quarter<3>(df, m5), Quarter<3>(df, m6),
Quarter<3>(df, m7)),
df, mem + 7 * Lanes(df));
#endif
}
#if HWY_CAP_GE256
JXL_INLINE void Transpose8x8Block(const int32_t* JXL_RESTRICT from,
int32_t* JXL_RESTRICT to, size_t fromstride) {
const HWY_CAPPED(int32_t, 8) d;
auto i0 = Load(d, from);
auto i1 = Load(d, from + 1 * fromstride);
auto i2 = Load(d, from + 2 * fromstride);
auto i3 = Load(d, from + 3 * fromstride);
auto i4 = Load(d, from + 4 * fromstride);
auto i5 = Load(d, from + 5 * fromstride);
auto i6 = Load(d, from + 6 * fromstride);
auto i7 = Load(d, from + 7 * fromstride);
const auto q0 = InterleaveLower(d, i0, i2);
const auto q1 = InterleaveLower(d, i1, i3);
const auto q2 = InterleaveUpper(d, i0, i2);
const auto q3 = InterleaveUpper(d, i1, i3);
const auto q4 = InterleaveLower(d, i4, i6);
const auto q5 = InterleaveLower(d, i5, i7);
const auto q6 = InterleaveUpper(d, i4, i6);
const auto q7 = InterleaveUpper(d, i5, i7);
const auto r0 = InterleaveLower(d, q0, q1);
const auto r1 = InterleaveUpper(d, q0, q1);
const auto r2 = InterleaveLower(d, q2, q3);
const auto r3 = InterleaveUpper(d, q2, q3);
const auto r4 = InterleaveLower(d, q4, q5);
const auto r5 = InterleaveUpper(d, q4, q5);
const auto r6 = InterleaveLower(d, q6, q7);
const auto r7 = InterleaveUpper(d, q6, q7);
i0 = ConcatLowerLower(d, r4, r0);
i1 = ConcatLowerLower(d, r5, r1);
i2 = ConcatLowerLower(d, r6, r2);
i3 = ConcatLowerLower(d, r7, r3);
i4 = ConcatUpperUpper(d, r4, r0);
i5 = ConcatUpperUpper(d, r5, r1);
i6 = ConcatUpperUpper(d, r6, r2);
i7 = ConcatUpperUpper(d, r7, r3);
Store(i0, d, to);
Store(i1, d, to + 1 * 8);
Store(i2, d, to + 2 * 8);
Store(i3, d, to + 3 * 8);
Store(i4, d, to + 4 * 8);
Store(i5, d, to + 5 * 8);
Store(i6, d, to + 6 * 8);
Store(i7, d, to + 7 * 8);
}
#elif HWY_TARGET != HWY_SCALAR
JXL_INLINE void Transpose8x8Block(const int32_t* JXL_RESTRICT from,
int32_t* JXL_RESTRICT to, size_t fromstride) {
const HWY_CAPPED(int32_t, 4) d;
for (size_t n = 0; n < 8; n += 4) {
for (size_t m = 0; m < 8; m += 4) {
auto p0 = Load(d, from + n * fromstride + m);
auto p1 = Load(d, from + (n + 1) * fromstride + m);
auto p2 = Load(d, from + (n + 2) * fromstride + m);
auto p3 = Load(d, from + (n + 3) * fromstride + m);
const auto q0 = InterleaveLower(d, p0, p2);
const auto q1 = InterleaveLower(d, p1, p3);
const auto q2 = InterleaveUpper(d, p0, p2);
const auto q3 = InterleaveUpper(d, p1, p3);
const auto r0 = InterleaveLower(d, q0, q1);
const auto r1 = InterleaveUpper(d, q0, q1);
const auto r2 = InterleaveLower(d, q2, q3);
const auto r3 = InterleaveUpper(d, q2, q3);
Store(r0, d, to + m * 8 + n);
Store(r1, d, to + (1 + m) * 8 + n);
Store(r2, d, to + (2 + m) * 8 + n);
Store(r3, d, to + (3 + m) * 8 + n);
}
}
}
#endif
// NOLINTNEXTLINE(google-readability-namespace-comments)
} // namespace HWY_NAMESPACE
} // namespace jxl
HWY_AFTER_NAMESPACE();
#endif // LIB_JXL_SIMD_UTIL_INL_H_