// Copyright 2019 Google LLC
// SPDX-License-Identifier: Apache-2.0
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include <stddef.h>
#undef HWY_TARGET_INCLUDE
#define HWY_TARGET_INCLUDE
"tests/swizzle_block_test.cc"
#include "hwy/foreach_target.h" // IWYU pragma: keep
#include "hwy/highway.h"
#include "hwy/tests/test_util-inl.h"
HWY_BEFORE_NAMESPACE();
namespace hwy {
namespace HWY_NAMESPACE {
struct TestOddEvenBlocks {
template <
class T,
class D>
HWY_NOINLINE
void operator()(T
/*unused*/, D d) {
const size_t N = Lanes(d);
const auto even = Iota(d, 1);
const auto odd = Iota(d, 1 + N);
auto expected = AllocateAligned<T>(N);
HWY_ASSERT(expected);
for (size_t i = 0; i < N; ++i) {
const size_t idx_block = i / (16 /
sizeof(T));
expected[i] = ConvertScalarTo<T>(1 + i + ((idx_block & 1) ? N : 0));
}
HWY_ASSERT_VEC_EQ(d, expected.get(), OddEvenBlocks(odd, even));
}
};
HWY_NOINLINE
void TestAllOddEvenBlocks() {
ForAllTypes(ForGEVectors<128, TestOddEvenBlocks>());
}
struct TestSwapAdjacentBlocks {
template <
class T,
class D>
HWY_NOINLINE
void operator()(T
/*unused*/, D d) {
const size_t N = Lanes(d);
constexpr size_t kLanesPerBlock = 16 /
sizeof(T);
if (N < 2 * kLanesPerBlock)
return;
const auto vi = Iota(d, 1);
auto expected = AllocateAligned<T>(N);
HWY_ASSERT(expected);
for (size_t i = 0; i < N; ++i) {
const size_t idx_block = i / kLanesPerBlock;
const size_t base = (idx_block ^ 1) * kLanesPerBlock;
const size_t mod = i % kLanesPerBlock;
expected[i] = ConvertScalarTo<T>(1 + base + mod);
}
HWY_ASSERT_VEC_EQ(d, expected.get(), SwapAdjacentBlocks(vi));
}
};
HWY_NOINLINE
void TestAllSwapAdjacentBlocks() {
ForAllTypes(ForGEVectors<128, TestSwapAdjacentBlocks>());
}
class TestInsertBlock {
private:
template <
int kBlock,
class D,
HWY_IF_V_SIZE_GT_D(D,
static_cast<size_t>(kBlock) * 16)>
static HWY_INLINE
void DoTestInsertBlock(D d,
const size_t N,
TFromD<D>* HWY_RESTRICT expected) {
// kBlock * 16 < D.MaxBytes() is true
using T = TFromD<D>;
using TI = MakeSigned<T>;
using TU = MakeUnsigned<T>;
const RebindToUnsigned<decltype(d)> du;
const BlockDFromD<decltype(d)> d_block;
const RebindToUnsigned<decltype(d_block)> du_block;
using V = Vec<D>;
using VB = Vec<decltype(d_block)>;
constexpr TU kPositiveMask =
static_cast<TU>(LimitsMax<TI>());
constexpr TU kSignBit =
static_cast<TU>(~kPositiveMask);
for (size_t i = 0; i < N; i++) {
const T val = ConvertScalarTo<T>(i);
TU val_bits;
CopySameSize(&val, &val_bits);
val_bits &= kPositiveMask;
CopySameSize(&val_bits, &expected[i]);
}
constexpr size_t kLanesPer16ByteBlk = 16 /
sizeof(T);
constexpr size_t kBlkLaneOffset =
static_cast<size_t>(kBlock) * kLanesPer16ByteBlk;
if (kBlkLaneOffset < N) {
const size_t num_of_lanes_in_blk =
HWY_MIN(N - kBlkLaneOffset, kLanesPer16ByteBlk);
for (size_t i = 0; i < num_of_lanes_in_blk; i++) {
const T val =
ConvertScalarTo<T>(
static_cast<TU>(i) +
static_cast<TU>(kBlock));
TU val_bits;
CopySameSize(&val, &val_bits);
val_bits |= kSignBit;
CopySameSize(&val_bits, &expected[kBlkLaneOffset + i]);
}
}
const V v =
And(Iota(d, 0), BitCast(d, Set(du, kPositiveMask)));
const VB blk_to_insert =
Or(Iota(d_block, kBlock), BitCast(d_block, Set(du_block, kSignBit)));
const V actual = InsertBlock<kBlock>(v, blk_to_insert);
HWY_ASSERT_VEC_EQ(d, expected, actual);
}
template <
int kBlock,
class D,
HWY_IF_V_SIZE_LE_D(D,
static_cast<size_t>(kBlock) * 16)>
static HWY_INLINE
void DoTestInsertBlock(
D
/*d*/, const size_t /*N*/, TFromD<D>* HWY_RESTRICT /*expected*/) {
// If kBlock * 16 >= D.MaxBytes() is true, do nothing
}
public:
template <
class T,
class D>
HWY_NOINLINE
void operator()(T
/*unused*/, D d) {
const size_t N = Lanes(d);
auto expected = AllocateAligned<T>(N);
HWY_ASSERT(expected);
DoTestInsertBlock<0>(d, N, expected.get());
DoTestInsertBlock<1>(d, N, expected.get());
DoTestInsertBlock<2>(d, N, expected.get());
DoTestInsertBlock<3>(d, N, expected.get());
}
};
HWY_NOINLINE
void TestAllInsertBlock() {
ForAllTypes(ForPartialFixedOrFullScalableVectors<TestInsertBlock>());
}
class TestExtractBlock {
private:
template <
int kBlock,
class D,
HWY_IF_V_SIZE_GT_D(D,
static_cast<size_t>(kBlock) * 16)>
static HWY_INLINE
void DoTestExtractBlock(D d,
const size_t N,
TFromD<D>* HWY_RESTRICT expected) {
// kBlock * 16 < D.MaxBytes() is true
using T = TFromD<D>;
constexpr size_t kLanesPer16ByteBlk = 16 /
sizeof(T);
constexpr size_t kBlkLaneOffset =
static_cast<size_t>(kBlock) * kLanesPer16ByteBlk;
if (kBlkLaneOffset >= N)
return;
const BlockDFromD<decltype(d)> d_block;
static_assert(d_block.MaxLanes() <= kLanesPer16ByteBlk,
"d_block.MaxLanes() <= kLanesPer16ByteBlk must be true");
for (size_t i = 0; i < kLanesPer16ByteBlk; i++) {
expected[i] = ConvertScalarTo<T>(kBlkLaneOffset + i);
}
const auto v = Iota(d, 0);
const Vec<BlockDFromD<decltype(d_block)>> actual = ExtractBlock<kBlock>(v);
HWY_ASSERT_VEC_EQ(d_block, expected, actual);
}
template <
int kBlock,
class D,
HWY_IF_V_SIZE_LE_D(D,
static_cast<size_t>(kBlock) * 16)>
static HWY_INLINE
void DoTestExtractBlock(
D
/*d*/, const size_t /*N*/, TFromD<D>* HWY_RESTRICT /*expected*/) {
// If kBlock * 16 >= D.MaxBytes() is true, do nothing
}
public:
template <
class T,
class D>
HWY_NOINLINE
void operator()(T
/*unused*/, D d) {
constexpr size_t kLanesPer16ByteBlk = 16 /
sizeof(T);
const size_t N = Lanes(d);
auto expected = AllocateAligned<T>(kLanesPer16ByteBlk);
HWY_ASSERT(expected);
DoTestExtractBlock<0>(d, N, expected.get());
DoTestExtractBlock<1>(d, N, expected.get());
DoTestExtractBlock<2>(d, N, expected.get());
DoTestExtractBlock<3>(d, N, expected.get());
}
};
HWY_NOINLINE
void TestAllExtractBlock() {
ForAllTypes(ForPartialFixedOrFullScalableVectors<TestExtractBlock>());
}
class TestBroadcastBlock {
private:
template <
int kBlock,
class D,
HWY_IF_V_SIZE_GT_D(D,
static_cast<size_t>(kBlock) * 16)>
static HWY_INLINE
void DoTestBroadcastBlock(
D d,
const size_t N, TFromD<D>* HWY_RESTRICT expected) {
// kBlock * 16 < D.MaxBytes() is true
using T = TFromD<D>;
constexpr size_t kLanesPer16ByteBlk = 16 /
sizeof(T);
constexpr size_t kBlkLaneOffset =
static_cast<size_t>(kBlock) * kLanesPer16ByteBlk;
if (kBlkLaneOffset >= N)
return;
for (size_t i = 0; i < N; i++) {
const size_t idx_in_blk = i & (kLanesPer16ByteBlk - 1);
expected[i] =
ConvertScalarTo<T>(kBlkLaneOffset + kLanesPer16ByteBlk + idx_in_blk);
}
const auto v = Iota(d, kLanesPer16ByteBlk);
const auto actual = BroadcastBlock<kBlock>(v);
HWY_ASSERT_VEC_EQ(d, expected, actual);
}
template <
int kBlock,
class D,
HWY_IF_V_SIZE_LE_D(D,
static_cast<size_t>(kBlock) * 16)>
static HWY_INLINE
void DoTestBroadcastBlock(
D
/*d*/, const size_t /*N*/, TFromD<D>* HWY_RESTRICT /*expected*/) {
// If kBlock * 16 >= D.MaxBytes() is true, do nothing
}
public:
template <
class T,
class D>
HWY_NOINLINE
void operator()(T
/*unused*/, D d) {
const size_t N = Lanes(d);
auto expected = AllocateAligned<T>(N);
HWY_ASSERT(expected);
DoTestBroadcastBlock<0>(d, N, expected.get());
DoTestBroadcastBlock<1>(d, N, expected.get());
DoTestBroadcastBlock<2>(d, N, expected.get());
DoTestBroadcastBlock<3>(d, N, expected.get());
}
};
HWY_NOINLINE
void TestAllBroadcastBlock() {
ForAllTypes(ForPartialFixedOrFullScalableVectors<TestBroadcastBlock>());
}
// NOLINTNEXTLINE(google-readability-namespace-comments)
}
// namespace HWY_NAMESPACE
}
// namespace hwy
HWY_AFTER_NAMESPACE();
#if HWY_ONCE
namespace hwy {
HWY_BEFORE_TEST(HwySwizzleBlockTest);
HWY_EXPORT_AND_TEST_P(HwySwizzleBlockTest, TestAllOddEvenBlocks);
HWY_EXPORT_AND_TEST_P(HwySwizzleBlockTest, TestAllSwapAdjacentBlocks);
HWY_EXPORT_AND_TEST_P(HwySwizzleBlockTest, TestAllInsertBlock);
HWY_EXPORT_AND_TEST_P(HwySwizzleBlockTest, TestAllExtractBlock);
HWY_EXPORT_AND_TEST_P(HwySwizzleBlockTest, TestAllBroadcastBlock);
}
// namespace hwy
#endif
