// Copyright 2019 Google LLC // // 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 #include #include #include #include #undef HWY_TARGET_INCLUDE #define HWY_TARGET_INCLUDE "tests/shift_test.cc" #include "hwy/foreach_target.h" #include "hwy/highway.h" #include "hwy/tests/test_util-inl.h" HWY_BEFORE_NAMESPACE(); namespace hwy { namespace HWY_NAMESPACE { template struct TestLeftShifts { template HWY_NOINLINE void operator()(T t, D d) { if (kSigned) { // Also test positive values TestLeftShifts()(t, d); } using TI = MakeSigned; using TU = MakeUnsigned; const size_t N = Lanes(d); auto expected = AllocateAligned(N); const auto values = Iota(d, kSigned ? -TI(N) : TI(0)); // value to shift constexpr size_t kMaxShift = (sizeof(T) * 8) - 1; // 0 HWY_ASSERT_VEC_EQ(d, values, ShiftLeft<0>(values)); HWY_ASSERT_VEC_EQ(d, values, ShiftLeftSame(values, 0)); // 1 for (size_t i = 0; i < N; ++i) { const T value = kSigned ? T(T(i) - T(N)) : T(i); expected[i] = T(TU(value) << 1); } HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftLeft<1>(values)); HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftLeftSame(values, 1)); // max for (size_t i = 0; i < N; ++i) { const T value = kSigned ? T(T(i) - T(N)) : T(i); expected[i] = T(TU(value) << kMaxShift); } HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftLeft(values)); HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftLeftSame(values, kMaxShift)); } }; template struct TestVariableLeftShifts { template HWY_NOINLINE void operator()(T t, D d) { if (kSigned) { // Also test positive values TestVariableLeftShifts()(t, d); } using TI = MakeSigned; using TU = MakeUnsigned; const size_t N = Lanes(d); auto expected = AllocateAligned(N); const auto v0 = Zero(d); const auto v1 = Set(d, 1); const auto values = Iota(d, kSigned ? -TI(N) : TI(0)); // value to shift constexpr size_t kMaxShift = (sizeof(T) * 8) - 1; const auto max_shift = Set(d, kMaxShift); const auto small_shifts = And(Iota(d, 0), max_shift); const auto large_shifts = max_shift - small_shifts; // Same: 0 HWY_ASSERT_VEC_EQ(d, values, Shl(values, v0)); // Same: 1 for (size_t i = 0; i < N; ++i) { const T value = kSigned ? T(i) - T(N) : T(i); expected[i] = T(TU(value) << 1); } HWY_ASSERT_VEC_EQ(d, expected.get(), Shl(values, v1)); // Same: max for (size_t i = 0; i < N; ++i) { const T value = kSigned ? T(i) - T(N) : T(i); expected[i] = T(TU(value) << kMaxShift); } HWY_ASSERT_VEC_EQ(d, expected.get(), Shl(values, max_shift)); // Variable: small for (size_t i = 0; i < N; ++i) { const T value = kSigned ? T(i) - T(N) : T(i); expected[i] = T(TU(value) << (i & kMaxShift)); } HWY_ASSERT_VEC_EQ(d, expected.get(), Shl(values, small_shifts)); // Variable: large for (size_t i = 0; i < N; ++i) { expected[i] = T(TU(1) << (kMaxShift - (i & kMaxShift))); } HWY_ASSERT_VEC_EQ(d, expected.get(), Shl(v1, large_shifts)); } }; struct TestUnsignedRightShifts { template HWY_NOINLINE void operator()(T /*unused*/, D d) { const size_t N = Lanes(d); auto expected = AllocateAligned(N); const auto values = Iota(d, 0); const T kMax = LimitsMax(); constexpr size_t kMaxShift = (sizeof(T) * 8) - 1; // Shift by 0 HWY_ASSERT_VEC_EQ(d, values, ShiftRight<0>(values)); HWY_ASSERT_VEC_EQ(d, values, ShiftRightSame(values, 0)); // Shift by 1 for (size_t i = 0; i < N; ++i) { expected[i] = T(T(i & kMax) >> 1); } HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftRight<1>(values)); HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftRightSame(values, 1)); // max for (size_t i = 0; i < N; ++i) { expected[i] = T(T(i & kMax) >> kMaxShift); } HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftRight(values)); HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftRightSame(values, kMaxShift)); } }; struct TestRotateRight { template HWY_NOINLINE void operator()(T /*unused*/, D d) { const size_t N = Lanes(d); auto expected = AllocateAligned(N); constexpr size_t kBits = sizeof(T) * 8; const auto mask_shift = Set(d, T{kBits}); // Cover as many bit positions as possible to test shifting out const auto values = Shl(Set(d, T{1}), And(Iota(d, 0), mask_shift)); // Rotate by 0 HWY_ASSERT_VEC_EQ(d, values, RotateRight<0>(values)); // Rotate by 1 Store(values, d, expected.get()); for (size_t i = 0; i < N; ++i) { expected[i] = (expected[i] >> 1) | (expected[i] << (kBits - 1)); } HWY_ASSERT_VEC_EQ(d, expected.get(), RotateRight<1>(values)); // Rotate by half Store(values, d, expected.get()); for (size_t i = 0; i < N; ++i) { expected[i] = (expected[i] >> (kBits / 2)) | (expected[i] << (kBits / 2)); } HWY_ASSERT_VEC_EQ(d, expected.get(), RotateRight(values)); // Rotate by max Store(values, d, expected.get()); for (size_t i = 0; i < N; ++i) { expected[i] = (expected[i] >> (kBits - 1)) | (expected[i] << 1); } HWY_ASSERT_VEC_EQ(d, expected.get(), RotateRight(values)); } }; struct TestVariableUnsignedRightShifts { template HWY_NOINLINE void operator()(T /*unused*/, D d) { const size_t N = Lanes(d); auto expected = AllocateAligned(N); const auto v0 = Zero(d); const auto v1 = Set(d, 1); const auto values = Iota(d, 0); const T kMax = LimitsMax(); const auto max = Set(d, kMax); constexpr size_t kMaxShift = (sizeof(T) * 8) - 1; const auto max_shift = Set(d, kMaxShift); const auto small_shifts = And(Iota(d, 0), max_shift); const auto large_shifts = max_shift - small_shifts; // Same: 0 HWY_ASSERT_VEC_EQ(d, values, Shr(values, v0)); // Same: 1 for (size_t i = 0; i < N; ++i) { expected[i] = T(T(i & kMax) >> 1); } HWY_ASSERT_VEC_EQ(d, expected.get(), Shr(values, v1)); // Same: max HWY_ASSERT_VEC_EQ(d, v0, Shr(values, max_shift)); // Variable: small for (size_t i = 0; i < N; ++i) { expected[i] = T(i) >> (i & kMaxShift); } HWY_ASSERT_VEC_EQ(d, expected.get(), Shr(values, small_shifts)); // Variable: Large for (size_t i = 0; i < N; ++i) { expected[i] = kMax >> (kMaxShift - (i & kMaxShift)); } HWY_ASSERT_VEC_EQ(d, expected.get(), Shr(max, large_shifts)); } }; template T RightShiftNegative(T val) { // C++ shifts are implementation-defined for negative numbers, and we have // seen divisions replaced with shifts, so resort to bit operations. using TU = hwy::MakeUnsigned; TU bits; CopyBytes(&val, &bits); const TU shifted = TU(bits >> kAmount); const TU all = TU(~TU(0)); const size_t num_zero = sizeof(TU) * 8 - 1 - kAmount; const TU sign_extended = static_cast((all << num_zero) & LimitsMax()); bits = shifted | sign_extended; CopyBytes(&bits, &val); return val; } class TestSignedRightShifts { public: template HWY_NOINLINE void operator()(T /*unused*/, D d) { const size_t N = Lanes(d); auto expected = AllocateAligned(N); constexpr T kMin = LimitsMin(); constexpr T kMax = LimitsMax(); constexpr size_t kMaxShift = (sizeof(T) * 8) - 1; // First test positive values, negative are checked below. const auto v0 = Zero(d); const auto values = And(Iota(d, 0), Set(d, kMax)); // Shift by 0 HWY_ASSERT_VEC_EQ(d, values, ShiftRight<0>(values)); HWY_ASSERT_VEC_EQ(d, values, ShiftRightSame(values, 0)); // Shift by 1 for (size_t i = 0; i < N; ++i) { expected[i] = T(T(i & kMax) >> 1); } HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftRight<1>(values)); HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftRightSame(values, 1)); // max HWY_ASSERT_VEC_EQ(d, v0, ShiftRight(values)); HWY_ASSERT_VEC_EQ(d, v0, ShiftRightSame(values, kMaxShift)); // Even negative value Test<0>(kMin, d, __LINE__); Test<1>(kMin, d, __LINE__); Test<2>(kMin, d, __LINE__); Test(kMin, d, __LINE__); const T odd = static_cast(kMin + 1); Test<0>(odd, d, __LINE__); Test<1>(odd, d, __LINE__); Test<2>(odd, d, __LINE__); Test(odd, d, __LINE__); } private: template void Test(T val, D d, int line) { const auto expected = Set(d, RightShiftNegative(val)); const auto in = Set(d, val); const char* file = __FILE__; AssertVecEqual(d, expected, ShiftRight(in), file, line); AssertVecEqual(d, expected, ShiftRightSame(in, kAmount), file, line); } }; struct TestVariableSignedRightShifts { template HWY_NOINLINE void operator()(T /*unused*/, D d) { using TU = MakeUnsigned; const size_t N = Lanes(d); auto expected = AllocateAligned(N); constexpr T kMin = LimitsMin(); constexpr T kMax = LimitsMax(); constexpr size_t kMaxShift = (sizeof(T) * 8) - 1; // First test positive values, negative are checked below. const auto v0 = Zero(d); const auto positive = Iota(d, 0) & Set(d, kMax); // Shift by 0 HWY_ASSERT_VEC_EQ(d, positive, ShiftRight<0>(positive)); HWY_ASSERT_VEC_EQ(d, positive, ShiftRightSame(positive, 0)); // Shift by 1 for (size_t i = 0; i < N; ++i) { expected[i] = T(T(i & kMax) >> 1); } HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftRight<1>(positive)); HWY_ASSERT_VEC_EQ(d, expected.get(), ShiftRightSame(positive, 1)); // max HWY_ASSERT_VEC_EQ(d, v0, ShiftRight(positive)); HWY_ASSERT_VEC_EQ(d, v0, ShiftRightSame(positive, kMaxShift)); const auto max_shift = Set(d, kMaxShift); const auto small_shifts = And(Iota(d, 0), max_shift); const auto large_shifts = max_shift - small_shifts; const auto negative = Iota(d, kMin); // Test varying negative to shift for (size_t i = 0; i < N; ++i) { expected[i] = RightShiftNegative<1>(static_cast(kMin + i)); } HWY_ASSERT_VEC_EQ(d, expected.get(), Shr(negative, Set(d, 1))); // Shift MSB right by small amounts for (size_t i = 0; i < N; ++i) { const size_t amount = i & kMaxShift; const TU shifted = ~((1ull << (kMaxShift - amount)) - 1); CopyBytes(&shifted, &expected[i]); } HWY_ASSERT_VEC_EQ(d, expected.get(), Shr(Set(d, kMin), small_shifts)); // Shift MSB right by large amounts for (size_t i = 0; i < N; ++i) { const size_t amount = kMaxShift - (i & kMaxShift); const TU shifted = ~((1ull << (kMaxShift - amount)) - 1); CopyBytes(&shifted, &expected[i]); } HWY_ASSERT_VEC_EQ(d, expected.get(), Shr(Set(d, kMin), large_shifts)); } }; HWY_NOINLINE void TestAllShifts() { ForUnsignedTypes(ForPartialVectors>()); ForSignedTypes(ForPartialVectors>()); ForUnsignedTypes(ForPartialVectors()); ForSignedTypes(ForPartialVectors()); } HWY_NOINLINE void TestAllVariableShifts() { const ForPartialVectors> shl_u; const ForPartialVectors> shl_s; const ForPartialVectors shr_u; const ForPartialVectors shr_s; shl_u(uint16_t()); shr_u(uint16_t()); shl_u(uint32_t()); shr_u(uint32_t()); shl_s(int16_t()); shr_s(int16_t()); shl_s(int32_t()); shr_s(int32_t()); #if HWY_HAVE_INTEGER64 shl_u(uint64_t()); shr_u(uint64_t()); shl_s(int64_t()); shr_s(int64_t()); #endif } HWY_NOINLINE void TestAllRotateRight() { const ForPartialVectors test; test(uint32_t()); #if HWY_HAVE_INTEGER64 test(uint64_t()); #endif } // NOLINTNEXTLINE(google-readability-namespace-comments) } // namespace HWY_NAMESPACE } // namespace hwy HWY_AFTER_NAMESPACE(); #if HWY_ONCE namespace hwy { HWY_BEFORE_TEST(HwyShiftTest); HWY_EXPORT_AND_TEST_P(HwyShiftTest, TestAllShifts); HWY_EXPORT_AND_TEST_P(HwyShiftTest, TestAllVariableShifts); HWY_EXPORT_AND_TEST_P(HwyShiftTest, TestAllRotateRight); } // namespace hwy // Ought not to be necessary, but without this, no tests run on RVV. int main(int argc, char** argv) { ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); } #endif