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v8/test/cctest/wasm/test-run-wasm-simd.cc
Clemens Backes 1876767992 [wasm] Rename {Get,Set}Global to Global{Get,Set} 
This brings our constants back in line with the changed spec text. We
already use kExprTableGet and kExprTableSet, but for locals and globals
we still use the old wording.

This renaming is mostly mechanical.

PS1 was created using:
ag -l 'kExpr(Get|Set)Global' src test | \
  xargs -L1 sed -E 's/kExpr(Get|Set)Global\b/kExprGlobal\1/g' -i

PS2 contains manual fixes.

R=mstarzinger@chromium.org

Bug: v8:9810
Change-Id: I064a6448cd95bc24d31a5931b5b4ef2464ea88b1
Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/1847355
Commit-Queue: Clemens Backes <clemensb@chromium.org>
Reviewed-by: Michael Starzinger <mstarzinger@chromium.org>
Cr-Commit-Position: refs/heads/master@{#64163}
2019-10-08 14:27:50 +00:00

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// Copyright 2016 the V8 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.
#include <type_traits>
#include "src/base/bits.h"
#include "src/base/overflowing-math.h"
#include "src/codegen/assembler-inl.h"
#include "test/cctest/cctest.h"
#include "test/cctest/compiler/value-helper.h"
#include "test/cctest/wasm/wasm-run-utils.h"
#include "test/common/wasm/wasm-macro-gen.h"
namespace v8 {
namespace internal {
namespace wasm {
namespace test_run_wasm_simd {
namespace {
using DoubleUnOp = double (*)(double);
using DoubleBinOp = double (*)(double, double);
using DoubleCompareOp = int64_t (*)(double, double);
using FloatUnOp = float (*)(float);
using FloatBinOp = float (*)(float, float);
using FloatCompareOp = int (*)(float, float);
using Int64UnOp = int64_t (*)(int64_t);
using Int64BinOp = int64_t (*)(int64_t, int64_t);
using Int64ShiftOp = int64_t (*)(int64_t, int);
using Int32UnOp = int32_t (*)(int32_t);
using Int32BinOp = int32_t (*)(int32_t, int32_t);
using Int32CompareOp = int (*)(int32_t, int32_t);
using Int32ShiftOp = int32_t (*)(int32_t, int);
using Int16UnOp = int16_t (*)(int16_t);
using Int16BinOp = int16_t (*)(int16_t, int16_t);
using Int16CompareOp = int (*)(int16_t, int16_t);
using Int16ShiftOp = int16_t (*)(int16_t, int);
using Int8UnOp = int8_t (*)(int8_t);
using Int8BinOp = int8_t (*)(int8_t, int8_t);
using Int8CompareOp = int (*)(int8_t, int8_t);
using Int8ShiftOp = int8_t (*)(int8_t, int);
#define WASM_SIMD_TEST(name) \
void RunWasm_##name##_Impl(LowerSimd lower_simd, \
ExecutionTier execution_tier); \
TEST(RunWasm_##name##_turbofan) { \
EXPERIMENTAL_FLAG_SCOPE(simd); \
RunWasm_##name##_Impl(kNoLowerSimd, ExecutionTier::kTurbofan); \
} \
TEST(RunWasm_##name##_interpreter) { \
EXPERIMENTAL_FLAG_SCOPE(simd); \
RunWasm_##name##_Impl(kNoLowerSimd, ExecutionTier::kInterpreter); \
} \
TEST(RunWasm_##name##_simd_lowered) { \
EXPERIMENTAL_FLAG_SCOPE(simd); \
RunWasm_##name##_Impl(kLowerSimd, ExecutionTier::kTurbofan); \
} \
void RunWasm_##name##_Impl(LowerSimd lower_simd, ExecutionTier execution_tier)
// Generic expected value functions.
template <typename T, typename = typename std::enable_if<
std::is_floating_point<T>::value>::type>
T Negate(T a) {
return -a;
}
// For signed integral types, use base::AddWithWraparound.
template <typename T, typename = typename std::enable_if<
std::is_floating_point<T>::value>::type>
T Add(T a, T b) {
return a + b;
}
// For signed integral types, use base::SubWithWraparound.
template <typename T, typename = typename std::enable_if<
std::is_floating_point<T>::value>::type>
T Sub(T a, T b) {
return a - b;
}
// For signed integral types, use base::MulWithWraparound.
template <typename T, typename = typename std::enable_if<
std::is_floating_point<T>::value>::type>
T Mul(T a, T b) {
return a * b;
}
template <typename T, typename = typename std::enable_if<
std::is_floating_point<T>::value>::type>
T Div(T a, T b) {
// Workaround C++ undefined behavior when b is 0.
return base::Divide(a, b);
}
template <typename T>
T Minimum(T a, T b) {
return a <= b ? a : b;
}
template <typename T>
T Maximum(T a, T b) {
return a >= b ? a : b;
}
template <typename T>
T UnsignedMinimum(T a, T b) {
using UnsignedT = typename std::make_unsigned<T>::type;
return static_cast<UnsignedT>(a) <= static_cast<UnsignedT>(b) ? a : b;
}
template <typename T>
T UnsignedMaximum(T a, T b) {
using UnsignedT = typename std::make_unsigned<T>::type;
return static_cast<UnsignedT>(a) >= static_cast<UnsignedT>(b) ? a : b;
}
int Equal(float a, float b) { return a == b ? -1 : 0; }
template <typename T>
T Equal(T a, T b) {
return a == b ? -1 : 0;
}
int NotEqual(float a, float b) { return a != b ? -1 : 0; }
template <typename T>
T NotEqual(T a, T b) {
return a != b ? -1 : 0;
}
int Less(float a, float b) { return a < b ? -1 : 0; }
template <typename T>
T Less(T a, T b) {
return a < b ? -1 : 0;
}
int LessEqual(float a, float b) { return a <= b ? -1 : 0; }
template <typename T>
T LessEqual(T a, T b) {
return a <= b ? -1 : 0;
}
int Greater(float a, float b) { return a > b ? -1 : 0; }
template <typename T>
T Greater(T a, T b) {
return a > b ? -1 : 0;
}
int GreaterEqual(float a, float b) { return a >= b ? -1 : 0; }
template <typename T>
T GreaterEqual(T a, T b) {
return a >= b ? -1 : 0;
}
template <typename T>
T UnsignedLess(T a, T b) {
using UnsignedT = typename std::make_unsigned<T>::type;
return static_cast<UnsignedT>(a) < static_cast<UnsignedT>(b) ? -1 : 0;
}
template <typename T>
T UnsignedLessEqual(T a, T b) {
using UnsignedT = typename std::make_unsigned<T>::type;
return static_cast<UnsignedT>(a) <= static_cast<UnsignedT>(b) ? -1 : 0;
}
template <typename T>
T UnsignedGreater(T a, T b) {
using UnsignedT = typename std::make_unsigned<T>::type;
return static_cast<UnsignedT>(a) > static_cast<UnsignedT>(b) ? -1 : 0;
}
template <typename T>
T UnsignedGreaterEqual(T a, T b) {
using UnsignedT = typename std::make_unsigned<T>::type;
return static_cast<UnsignedT>(a) >= static_cast<UnsignedT>(b) ? -1 : 0;
}
template <typename T>
T LogicalShiftLeft(T a, int shift) {
using UnsignedT = typename std::make_unsigned<T>::type;
return static_cast<UnsignedT>(a) << (shift % (sizeof(T) * 8));
}
template <typename T>
T LogicalShiftRight(T a, int shift) {
using UnsignedT = typename std::make_unsigned<T>::type;
return static_cast<UnsignedT>(a) >> (shift % (sizeof(T) * 8));
}
// Define our own ArithmeticShiftRight instead of using the one from utils.h
// because the shift amount needs to be taken modulo lane width.
template <typename T>
T ArithmeticShiftRight(T a, int shift) {
return a >> (shift % (sizeof(T) * 8));
}
template <typename T>
T Clamp(int64_t value) {
static_assert(sizeof(int64_t) > sizeof(T), "T must be int32_t or smaller");
int64_t min = static_cast<int64_t>(std::numeric_limits<T>::min());
int64_t max = static_cast<int64_t>(std::numeric_limits<T>::max());
int64_t clamped = std::max(min, std::min(max, value));
return static_cast<T>(clamped);
}
template <typename T>
int64_t Widen(T value) {
static_assert(sizeof(int64_t) > sizeof(T), "T must be int32_t or smaller");
return static_cast<int64_t>(value);
}
template <typename T>
int64_t UnsignedWiden(T value) {
static_assert(sizeof(int64_t) > sizeof(T), "T must be int32_t or smaller");
using UnsignedT = typename std::make_unsigned<T>::type;
return static_cast<int64_t>(static_cast<UnsignedT>(value));
}
template <typename T>
T Narrow(int64_t value) {
return Clamp<T>(value);
}
template <typename T>
T UnsignedNarrow(int64_t value) {
static_assert(sizeof(int64_t) > sizeof(T), "T must be int32_t or smaller");
using UnsignedT = typename std::make_unsigned<T>::type;
return static_cast<T>(Clamp<UnsignedT>(value & 0xFFFFFFFFu));
}
template <typename T>
T AddSaturate(T a, T b) {
return Clamp<T>(Widen(a) + Widen(b));
}
template <typename T>
T SubSaturate(T a, T b) {
return Clamp<T>(Widen(a) - Widen(b));
}
template <typename T>
T UnsignedAddSaturate(T a, T b) {
using UnsignedT = typename std::make_unsigned<T>::type;
return Clamp<UnsignedT>(UnsignedWiden(a) + UnsignedWiden(b));
}
template <typename T>
T UnsignedSubSaturate(T a, T b) {
using UnsignedT = typename std::make_unsigned<T>::type;
return Clamp<UnsignedT>(UnsignedWiden(a) - UnsignedWiden(b));
}
template <typename T>
T And(T a, T b) {
return a & b;
}
template <typename T>
T Or(T a, T b) {
return a | b;
}
template <typename T>
T Xor(T a, T b) {
return a ^ b;
}
template <typename T>
T Not(T a) {
return ~a;
}
template <typename T>
T LogicalNot(T a) {
return a == 0 ? -1 : 0;
}
template <typename T>
T Sqrt(T a) {
return std::sqrt(a);
}
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
// only used for F64x2 tests below
int64_t Equal(double a, double b) { return a == b ? -1 : 0; }
int64_t NotEqual(double a, double b) { return a != b ? -1 : 0; }
int64_t Greater(double a, double b) { return a > b ? -1 : 0; }
int64_t GreaterEqual(double a, double b) { return a >= b ? -1 : 0; }
int64_t Less(double a, double b) { return a < b ? -1 : 0; }
int64_t LessEqual(double a, double b) { return a <= b ? -1 : 0; }
// Only used for qfma and qfms tests below.
// FMOperation holds the params (a, b, c) for a Multiply-Add or
// Multiply-Subtract operation, and the expected result if the operation was
// fused, rounded only once for the entire operation, or unfused, rounded after
// multiply and again after add/subtract.
template <typename T>
struct FMOperation {
const T a;
const T b;
const T c;
const T fused_result;
const T unfused_result;
};
// large_n is large number that overflows T when multiplied by itself, this is a
// useful constant to test fused/unfused behavior.
template <typename T>
constexpr T large_n = T(0);
template <>
constexpr double large_n<double> = 1e200;
template <>
constexpr float large_n<float> = 1e20;
// Fused Multiply-Add performs a + b * c.
template <typename T>
static constexpr FMOperation<T> qfma_array[] = {
{1.0f, 2.0f, 3.0f, 7.0f, 7.0f},
// fused: a + b * c = -inf + (positive overflow) = -inf
// unfused: a + b * c = -inf + inf = NaN
{-std::numeric_limits<T>::infinity(), large_n<T>, large_n<T>,
-std::numeric_limits<T>::infinity(), std::numeric_limits<T>::quiet_NaN()},
// fused: a + b * c = inf + (negative overflow) = inf
// unfused: a + b * c = inf + -inf = NaN
{std::numeric_limits<T>::infinity(), -large_n<T>, large_n<T>,
std::numeric_limits<T>::infinity(), std::numeric_limits<T>::quiet_NaN()},
// NaN
{std::numeric_limits<T>::quiet_NaN(), 2.0f, 3.0f,
std::numeric_limits<T>::quiet_NaN(), std::numeric_limits<T>::quiet_NaN()},
// -NaN
{-std::numeric_limits<T>::quiet_NaN(), 2.0f, 3.0f,
std::numeric_limits<T>::quiet_NaN(), std::numeric_limits<T>::quiet_NaN()}};
template <typename T>
static constexpr Vector<const FMOperation<T>> qfma_vector() {
return ArrayVector(qfma_array<T>);
}
// Fused Multiply-Subtract performs a - b * c.
template <typename T>
static constexpr FMOperation<T> qfms_array[]{
{1.0f, 2.0f, 3.0f, -5.0f, -5.0f},
// fused: a - b * c = inf - (positive overflow) = inf
// unfused: a - b * c = inf - inf = NaN
{std::numeric_limits<T>::infinity(), large_n<T>, large_n<T>,
std::numeric_limits<T>::infinity(), std::numeric_limits<T>::quiet_NaN()},
// fused: a - b * c = -inf - (negative overflow) = -inf
// unfused: a - b * c = -inf - -inf = NaN
{-std::numeric_limits<T>::infinity(), -large_n<T>, large_n<T>,
-std::numeric_limits<T>::infinity(), std::numeric_limits<T>::quiet_NaN()},
// NaN
{std::numeric_limits<T>::quiet_NaN(), 2.0f, 3.0f,
std::numeric_limits<T>::quiet_NaN(), std::numeric_limits<T>::quiet_NaN()},
// -NaN
{-std::numeric_limits<T>::quiet_NaN(), 2.0f, 3.0f,
std::numeric_limits<T>::quiet_NaN(), std::numeric_limits<T>::quiet_NaN()}};
template <typename T>
static constexpr Vector<const FMOperation<T>> qfms_vector() {
return ArrayVector(qfms_array<T>);
}
// Fused results only when fma3 feature is enabled, and running on TurboFan.
bool ExpectFused(ExecutionTier tier) {
#ifdef V8_TARGET_ARCH_X64
return CpuFeatures::IsSupported(FMA3) && (tier == ExecutionTier::kTurbofan);
#else
return (tier == ExecutionTier::kTurbofan);
#endif
}
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
} // namespace
#define WASM_SIMD_CHECK_LANE(TYPE, value, LANE_TYPE, lane_value, lane_index) \
WASM_IF(WASM_##LANE_TYPE##_NE(WASM_GET_LOCAL(lane_value), \
WASM_SIMD_##TYPE##_EXTRACT_LANE( \
lane_index, WASM_GET_LOCAL(value))), \
WASM_RETURN1(WASM_ZERO))
#define TO_BYTE(val) static_cast<byte>(val)
#define WASM_SIMD_OP(op) kSimdPrefix, TO_BYTE(op)
#define WASM_SIMD_SPLAT(Type, ...) __VA_ARGS__, WASM_SIMD_OP(kExpr##Type##Splat)
#define WASM_SIMD_UNOP(op, x) x, WASM_SIMD_OP(op)
#define WASM_SIMD_BINOP(op, x, y) x, y, WASM_SIMD_OP(op)
#define WASM_SIMD_SHIFT_OP(op, x, y) x, y, WASM_SIMD_OP(op)
#define WASM_SIMD_CONCAT_OP(op, bytes, x, y) \
x, y, WASM_SIMD_OP(op), TO_BYTE(bytes)
#define WASM_SIMD_SELECT(format, x, y, z) x, y, z, WASM_SIMD_OP(kExprS128Select)
#define WASM_SIMD_F64x2_SPLAT(x) WASM_SIMD_SPLAT(F64x2, x)
#define WASM_SIMD_F64x2_EXTRACT_LANE(lane, x) \
x, WASM_SIMD_OP(kExprF64x2ExtractLane), TO_BYTE(lane)
#define WASM_SIMD_F64x2_REPLACE_LANE(lane, x, y) \
x, y, WASM_SIMD_OP(kExprF64x2ReplaceLane), TO_BYTE(lane)
#define WASM_SIMD_F32x4_SPLAT(x) WASM_SIMD_SPLAT(F32x4, x)
#define WASM_SIMD_F32x4_EXTRACT_LANE(lane, x) \
x, WASM_SIMD_OP(kExprF32x4ExtractLane), TO_BYTE(lane)
#define WASM_SIMD_F32x4_REPLACE_LANE(lane, x, y) \
x, y, WASM_SIMD_OP(kExprF32x4ReplaceLane), TO_BYTE(lane)
#define WASM_SIMD_I64x2_SPLAT(x) WASM_SIMD_SPLAT(I64x2, x)
#define WASM_SIMD_I64x2_EXTRACT_LANE(lane, x) \
x, WASM_SIMD_OP(kExprI64x2ExtractLane), TO_BYTE(lane)
#define WASM_SIMD_I64x2_REPLACE_LANE(lane, x, y) \
x, y, WASM_SIMD_OP(kExprI64x2ReplaceLane), TO_BYTE(lane)
#define WASM_SIMD_I32x4_SPLAT(x) WASM_SIMD_SPLAT(I32x4, x)
#define WASM_SIMD_I32x4_EXTRACT_LANE(lane, x) \
x, WASM_SIMD_OP(kExprI32x4ExtractLane), TO_BYTE(lane)
#define WASM_SIMD_I32x4_REPLACE_LANE(lane, x, y) \
x, y, WASM_SIMD_OP(kExprI32x4ReplaceLane), TO_BYTE(lane)
#define WASM_SIMD_I16x8_SPLAT(x) WASM_SIMD_SPLAT(I16x8, x)
#define WASM_SIMD_I16x8_EXTRACT_LANE(lane, x) \
x, WASM_SIMD_OP(kExprI16x8ExtractLane), TO_BYTE(lane)
#define WASM_SIMD_I16x8_REPLACE_LANE(lane, x, y) \
x, y, WASM_SIMD_OP(kExprI16x8ReplaceLane), TO_BYTE(lane)
#define WASM_SIMD_I8x16_SPLAT(x) WASM_SIMD_SPLAT(I8x16, x)
#define WASM_SIMD_I8x16_EXTRACT_LANE(lane, x) \
x, WASM_SIMD_OP(kExprI8x16ExtractLane), TO_BYTE(lane)
#define WASM_SIMD_I8x16_REPLACE_LANE(lane, x, y) \
x, y, WASM_SIMD_OP(kExprI8x16ReplaceLane), TO_BYTE(lane)
#define WASM_SIMD_S8x16_SHUFFLE_OP(opcode, m, x, y) \
x, y, WASM_SIMD_OP(opcode), TO_BYTE(m[0]), TO_BYTE(m[1]), TO_BYTE(m[2]), \
TO_BYTE(m[3]), TO_BYTE(m[4]), TO_BYTE(m[5]), TO_BYTE(m[6]), \
TO_BYTE(m[7]), TO_BYTE(m[8]), TO_BYTE(m[9]), TO_BYTE(m[10]), \
TO_BYTE(m[11]), TO_BYTE(m[12]), TO_BYTE(m[13]), TO_BYTE(m[14]), \
TO_BYTE(m[15])
#define WASM_SIMD_LOAD_MEM(index) \
index, WASM_SIMD_OP(kExprS128LoadMem), ZERO_ALIGNMENT, ZERO_OFFSET
#define WASM_SIMD_LOAD_MEM_OFFSET(offset, index) \
index, WASM_SIMD_OP(kExprS128LoadMem), ZERO_ALIGNMENT, offset
#define WASM_SIMD_STORE_MEM(index, val) \
index, val, WASM_SIMD_OP(kExprS128StoreMem), ZERO_ALIGNMENT, ZERO_OFFSET
#define WASM_SIMD_STORE_MEM_OFFSET(offset, index, val) \
index, val, WASM_SIMD_OP(kExprS128StoreMem), ZERO_ALIGNMENT, offset
#define WASM_SIMD_F64x2_QFMA(a, b, c) a, b, c, WASM_SIMD_OP(kExprF64x2Qfma)
#define WASM_SIMD_F64x2_QFMS(a, b, c) a, b, c, WASM_SIMD_OP(kExprF64x2Qfms)
#define WASM_SIMD_F32x4_QFMA(a, b, c) a, b, c, WASM_SIMD_OP(kExprF32x4Qfma)
#define WASM_SIMD_F32x4_QFMS(a, b, c) a, b, c, WASM_SIMD_OP(kExprF32x4Qfms)
// Runs tests of compiled code, using the interpreter as a reference.
#define WASM_SIMD_COMPILED_TEST(name) \
void RunWasm_##name##_Impl(LowerSimd lower_simd, \
ExecutionTier execution_tier); \
TEST(RunWasm_##name##_turbofan) { \
EXPERIMENTAL_FLAG_SCOPE(simd); \
RunWasm_##name##_Impl(kNoLowerSimd, ExecutionTier::kTurbofan); \
} \
TEST(RunWasm_##name##_simd_lowered) { \
EXPERIMENTAL_FLAG_SCOPE(simd); \
RunWasm_##name##_Impl(kLowerSimd, ExecutionTier::kTurbofan); \
} \
void RunWasm_##name##_Impl(LowerSimd lower_simd, ExecutionTier execution_tier)
// The macro below disables tests lowering for certain nodes where the simd
// lowering doesn't work correctly. Early return here if the CPU does not
// support SIMD as the graph will be implicitly lowered in that case.
#define WASM_SIMD_TEST_NO_LOWERING(name) \
void RunWasm_##name##_Impl(LowerSimd lower_simd, \
ExecutionTier execution_tier); \
TEST(RunWasm_##name##_turbofan) { \
if (!CpuFeatures::SupportsWasmSimd128()) return; \
EXPERIMENTAL_FLAG_SCOPE(simd); \
RunWasm_##name##_Impl(kNoLowerSimd, ExecutionTier::kTurbofan); \
} \
TEST(RunWasm_##name##_interpreter) { \
EXPERIMENTAL_FLAG_SCOPE(simd); \
RunWasm_##name##_Impl(kNoLowerSimd, ExecutionTier::kInterpreter); \
} \
void RunWasm_##name##_Impl(LowerSimd lower_simd, ExecutionTier execution_tier)
// Returns true if the platform can represent the result.
template <typename T>
bool PlatformCanRepresent(T x) {
#if V8_TARGET_ARCH_ARM
return std::fpclassify(x) != FP_SUBNORMAL;
#else
return true;
#endif
}
// Returns true for very small and very large numbers. We skip these test
// values for the approximation instructions, which don't work at the extremes.
bool IsExtreme(float x) {
float abs_x = std::fabs(x);
const float kSmallFloatThreshold = 1.0e-32f;
const float kLargeFloatThreshold = 1.0e32f;
return abs_x != 0.0f && // 0 or -0 are fine.
(abs_x < kSmallFloatThreshold || abs_x > kLargeFloatThreshold);
}
WASM_SIMD_TEST(F32x4Splat) {
WasmRunner<int32_t, float> r(execution_tier, lower_simd);
// Set up a global to hold output vector.
float* g = r.builder().AddGlobal<float>(kWasmS128);
byte param1 = 0;
BUILD(r, WASM_SET_GLOBAL(0, WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(param1))),
WASM_ONE);
FOR_FLOAT32_INPUTS(x) {
r.Call(x);
float expected = x;
for (int i = 0; i < 4; i++) {
float actual = ReadLittleEndianValue<float>(&g[i]);
if (std::isnan(expected)) {
CHECK(std::isnan(actual));
} else {
CHECK_EQ(actual, expected);
}
}
}
}
WASM_SIMD_TEST(F32x4ReplaceLane) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
// Set up a global to hold input/output vector.
float* g = r.builder().AddGlobal<float>(kWasmS128);
// Build function to replace each lane with its (FP) index.
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_F32x4_SPLAT(WASM_F32(3.14159f))),
WASM_SET_LOCAL(temp1, WASM_SIMD_F32x4_REPLACE_LANE(
0, WASM_GET_LOCAL(temp1), WASM_F32(0.0f))),
WASM_SET_LOCAL(temp1, WASM_SIMD_F32x4_REPLACE_LANE(
1, WASM_GET_LOCAL(temp1), WASM_F32(1.0f))),
WASM_SET_LOCAL(temp1, WASM_SIMD_F32x4_REPLACE_LANE(
2, WASM_GET_LOCAL(temp1), WASM_F32(2.0f))),
WASM_SET_GLOBAL(0, WASM_SIMD_F32x4_REPLACE_LANE(
3, WASM_GET_LOCAL(temp1), WASM_F32(3.0f))),
WASM_ONE);
r.Call();
for (int i = 0; i < 4; i++) {
CHECK_EQ(static_cast<float>(i), ReadLittleEndianValue<float>(&g[i]));
}
}
// Tests both signed and unsigned conversion.
// v8:8425 tracks this test being enabled in the interpreter.
WASM_SIMD_COMPILED_TEST(F32x4ConvertI32x4) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Create two output vectors to hold signed and unsigned results.
float* g0 = r.builder().AddGlobal<float>(kWasmS128);
float* g1 = r.builder().AddGlobal<float>(kWasmS128);
// Build fn to splat test value, perform conversions, and write the results.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I32x4_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(
0, WASM_SIMD_UNOP(kExprF32x4SConvertI32x4, WASM_GET_LOCAL(temp1))),
WASM_SET_GLOBAL(
1, WASM_SIMD_UNOP(kExprF32x4UConvertI32x4, WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_INT32_INPUTS(x) {
r.Call(x);
float expected_signed = static_cast<float>(x);
float expected_unsigned = static_cast<float>(static_cast<uint32_t>(x));
for (int i = 0; i < 4; i++) {
CHECK_EQ(expected_signed, ReadLittleEndianValue<float>(&g0[i]));
CHECK_EQ(expected_unsigned, ReadLittleEndianValue<float>(&g1[i]));
}
}
}
bool IsSameNan(float expected, float actual) {
// Sign is non-deterministic.
uint32_t expected_bits = bit_cast<uint32_t>(expected) & ~0x80000000;
uint32_t actual_bits = bit_cast<uint32_t>(actual) & ~0x80000000;
// Some implementations convert signaling NaNs to quiet NaNs.
return (expected_bits == actual_bits) ||
((expected_bits | 0x00400000) == actual_bits);
}
bool IsCanonical(float actual) {
uint32_t actual_bits = bit_cast<uint32_t>(actual);
// Canonical NaN has quiet bit and no payload.
return (actual_bits & 0xFFC00000) == actual_bits;
}
void CheckFloatResult(float x, float y, float expected, float actual,
bool exact = true) {
if (std::isnan(expected)) {
CHECK(std::isnan(actual));
if (std::isnan(x) && IsSameNan(x, actual)) return;
if (std::isnan(y) && IsSameNan(y, actual)) return;
if (IsSameNan(expected, actual)) return;
if (IsCanonical(actual)) return;
// This is expected to assert; it's useful for debugging.
CHECK_EQ(bit_cast<uint32_t>(expected), bit_cast<uint32_t>(actual));
} else {
if (exact) {
CHECK_EQ(expected, actual);
// The sign of 0's must match.
CHECK_EQ(std::signbit(expected), std::signbit(actual));
return;
}
// Otherwise, perform an approximate equality test. First check for
// equality to handle +/-Infinity where approximate equality doesn't work.
if (expected == actual) return;
// 1% error allows all platforms to pass easily.
constexpr float kApproximationError = 0.01f;
float abs_error = std::abs(expected) * kApproximationError,
min = expected - abs_error, max = expected + abs_error;
CHECK_LE(min, actual);
CHECK_GE(max, actual);
}
}
// Test some values not included in the float inputs from value_helper. These
// tests are useful for opcodes that are synthesized during code gen, like Min
// and Max on ia32 and x64.
static constexpr uint32_t nan_test_array[] = {
// Bit patterns of quiet NaNs and signaling NaNs, with or without
// additional payload.
0x7FC00000, 0xFFC00000, 0x7FFFFFFF, 0x7F800000, 0xFF800000, 0x7F876543,
0xFF876543,
// Both Infinities.
0x7F800000, 0xFF800000,
// Some "normal" numbers, 1 and -1.
0x3F800000, 0xBF800000};
#define FOR_FLOAT32_NAN_INPUTS(i) \
for (size_t i = 0; i < arraysize(nan_test_array); ++i)
void RunF32x4UnOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, FloatUnOp expected_op,
bool exact = true) {
WasmRunner<int32_t, float> r(execution_tier, lower_simd);
// Global to hold output.
float* g = r.builder().AddGlobal<float>(kWasmS128);
// Build fn to splat test value, perform unop, and write the result.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(0, WASM_SIMD_UNOP(opcode, WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_FLOAT32_INPUTS(x) {
if (!PlatformCanRepresent(x)) continue;
// Extreme values have larger errors so skip them for approximation tests.
if (!exact && IsExtreme(x)) continue;
float expected = expected_op(x);
if (!PlatformCanRepresent(expected)) continue;
r.Call(x);
for (int i = 0; i < 4; i++) {
float actual = ReadLittleEndianValue<float>(&g[i]);
CheckFloatResult(x, x, expected, actual, exact);
}
}
FOR_FLOAT32_NAN_INPUTS(i) {
float x = bit_cast<float>(nan_test_array[i]);
if (!PlatformCanRepresent(x)) continue;
// Extreme values have larger errors so skip them for approximation tests.
if (!exact && IsExtreme(x)) continue;
float expected = expected_op(x);
if (!PlatformCanRepresent(expected)) continue;
r.Call(x);
for (int i = 0; i < 4; i++) {
float actual = ReadLittleEndianValue<float>(&g[i]);
CheckFloatResult(x, x, expected, actual, exact);
}
}
}
WASM_SIMD_TEST(F32x4Abs) {
RunF32x4UnOpTest(execution_tier, lower_simd, kExprF32x4Abs, std::abs);
}
WASM_SIMD_TEST(F32x4Neg) {
RunF32x4UnOpTest(execution_tier, lower_simd, kExprF32x4Neg, Negate);
}
WASM_SIMD_TEST(F32x4Sqrt) {
RunF32x4UnOpTest(execution_tier, lower_simd, kExprF32x4Sqrt, Sqrt);
}
WASM_SIMD_TEST(F32x4RecipApprox) {
RunF32x4UnOpTest(execution_tier, lower_simd, kExprF32x4RecipApprox,
base::Recip, false /* !exact */);
}
WASM_SIMD_TEST(F32x4RecipSqrtApprox) {
RunF32x4UnOpTest(execution_tier, lower_simd, kExprF32x4RecipSqrtApprox,
base::RecipSqrt, false /* !exact */);
}
void RunF32x4BinOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, FloatBinOp expected_op) {
WasmRunner<int32_t, float, float> r(execution_tier, lower_simd);
// Global to hold output.
float* g = r.builder().AddGlobal<float>(kWasmS128);
// Build fn to splat test values, perform binop, and write the result.
byte value1 = 0, value2 = 1;
byte temp1 = r.AllocateLocal(kWasmS128);
byte temp2 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value1))),
WASM_SET_LOCAL(temp2, WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value2))),
WASM_SET_GLOBAL(0, WASM_SIMD_BINOP(opcode, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp2))),
WASM_ONE);
FOR_FLOAT32_INPUTS(x) {
if (!PlatformCanRepresent(x)) continue;
FOR_FLOAT32_INPUTS(y) {
if (!PlatformCanRepresent(y)) continue;
float expected = expected_op(x, y);
if (!PlatformCanRepresent(expected)) continue;
r.Call(x, y);
for (int i = 0; i < 4; i++) {
float actual = ReadLittleEndianValue<float>(&g[i]);
CheckFloatResult(x, y, expected, actual, true /* exact */);
}
}
}
FOR_FLOAT32_NAN_INPUTS(i) {
float x = bit_cast<float>(nan_test_array[i]);
if (!PlatformCanRepresent(x)) continue;
FOR_FLOAT32_NAN_INPUTS(j) {
float y = bit_cast<float>(nan_test_array[j]);
if (!PlatformCanRepresent(y)) continue;
float expected = expected_op(x, y);
if (!PlatformCanRepresent(expected)) continue;
r.Call(x, y);
for (int i = 0; i < 4; i++) {
float actual = ReadLittleEndianValue<float>(&g[i]);
CheckFloatResult(x, y, expected, actual, true /* exact */);
}
}
}
}
#undef FOR_FLOAT32_NAN_INPUTS
WASM_SIMD_TEST(F32x4Add) {
RunF32x4BinOpTest(execution_tier, lower_simd, kExprF32x4Add, Add);
}
WASM_SIMD_TEST(F32x4Sub) {
RunF32x4BinOpTest(execution_tier, lower_simd, kExprF32x4Sub, Sub);
}
WASM_SIMD_TEST(F32x4Mul) {
RunF32x4BinOpTest(execution_tier, lower_simd, kExprF32x4Mul, Mul);
}
WASM_SIMD_TEST(F32x4Div) {
RunF32x4BinOpTest(execution_tier, lower_simd, kExprF32x4Div, Div);
}
WASM_SIMD_TEST(F32x4Min) {
RunF32x4BinOpTest(execution_tier, lower_simd, kExprF32x4Min, JSMin);
}
WASM_SIMD_TEST(F32x4Max) {
RunF32x4BinOpTest(execution_tier, lower_simd, kExprF32x4Max, JSMax);
}
void RunF32x4CompareOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, FloatCompareOp expected_op) {
WasmRunner<int32_t, float, float> r(execution_tier, lower_simd);
// Set up global to hold mask output.
int32_t* g = r.builder().AddGlobal<int32_t>(kWasmS128);
// Build fn to splat test values, perform compare op, and write the result.
byte value1 = 0, value2 = 1;
byte temp1 = r.AllocateLocal(kWasmS128);
byte temp2 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value1))),
WASM_SET_LOCAL(temp2, WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value2))),
WASM_SET_GLOBAL(0, WASM_SIMD_BINOP(opcode, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp2))),
WASM_ONE);
FOR_FLOAT32_INPUTS(x) {
if (!PlatformCanRepresent(x)) continue;
FOR_FLOAT32_INPUTS(y) {
if (!PlatformCanRepresent(y)) continue;
float diff = x - y; // Model comparison as subtraction.
if (!PlatformCanRepresent(diff)) continue;
r.Call(x, y);
int32_t expected = expected_op(x, y);
for (int i = 0; i < 4; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int32_t>(&g[i]));
}
}
}
}
WASM_SIMD_TEST(F32x4Eq) {
RunF32x4CompareOpTest(execution_tier, lower_simd, kExprF32x4Eq, Equal);
}
WASM_SIMD_TEST(F32x4Ne) {
RunF32x4CompareOpTest(execution_tier, lower_simd, kExprF32x4Ne, NotEqual);
}
WASM_SIMD_TEST(F32x4Gt) {
RunF32x4CompareOpTest(execution_tier, lower_simd, kExprF32x4Gt, Greater);
}
WASM_SIMD_TEST(F32x4Ge) {
RunF32x4CompareOpTest(execution_tier, lower_simd, kExprF32x4Ge, GreaterEqual);
}
WASM_SIMD_TEST(F32x4Lt) {
RunF32x4CompareOpTest(execution_tier, lower_simd, kExprF32x4Lt, Less);
}
WASM_SIMD_TEST(F32x4Le) {
RunF32x4CompareOpTest(execution_tier, lower_simd, kExprF32x4Le, LessEqual);
}
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_TEST_NO_LOWERING(F32x4Qfma) {
WasmRunner<int32_t, float, float, float> r(execution_tier, lower_simd);
// Set up global to hold mask output.
float* g = r.builder().AddGlobal<float>(kWasmS128);
// Build fn to splat test values, perform compare op, and write the result.
byte value1 = 0, value2 = 1, value3 = 2;
BUILD(r,
WASM_SET_GLOBAL(0, WASM_SIMD_F32x4_QFMA(
WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value1)),
WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value2)),
WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value3)))),
WASM_ONE);
for (FMOperation<float> x : qfma_vector<float>()) {
r.Call(x.a, x.b, x.c);
float expected =
ExpectFused(execution_tier) ? x.fused_result : x.unfused_result;
for (int i = 0; i < 4; i++) {
float actual = ReadLittleEndianValue<float>(&g[i]);
CheckFloatResult(x.a, x.b, expected, actual, true /* exact */);
}
}
}
WASM_SIMD_TEST_NO_LOWERING(F32x4Qfms) {
WasmRunner<int32_t, float, float, float> r(execution_tier, lower_simd);
// Set up global to hold mask output.
float* g = r.builder().AddGlobal<float>(kWasmS128);
// Build fn to splat test values, perform compare op, and write the result.
byte value1 = 0, value2 = 1, value3 = 2;
BUILD(r,
WASM_SET_GLOBAL(0, WASM_SIMD_F32x4_QFMS(
WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value1)),
WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value2)),
WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value3)))),
WASM_ONE);
for (FMOperation<float> x : qfms_vector<float>()) {
r.Call(x.a, x.b, x.c);
float expected =
ExpectFused(execution_tier) ? x.fused_result : x.unfused_result;
for (int i = 0; i < 4; i++) {
float actual = ReadLittleEndianValue<float>(&g[i]);
CheckFloatResult(x.a, x.b, expected, actual, true /* exact */);
}
}
}
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64 || V8_TARGET_ARCH_IA32
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_TEST_NO_LOWERING(I64x2Splat) {
WasmRunner<int32_t, int64_t> r(execution_tier, lower_simd);
// Set up a global to hold output vector.
int64_t* g = r.builder().AddGlobal<int64_t>(kWasmS128);
byte param1 = 0;
BUILD(r, WASM_SET_GLOBAL(0, WASM_SIMD_I64x2_SPLAT(WASM_GET_LOCAL(param1))),
WASM_ONE);
FOR_INT64_INPUTS(x) {
r.Call(x);
int64_t expected = x;
for (int i = 0; i < 2; i++) {
int64_t actual = ReadLittleEndianValue<int64_t>(&g[i]);
CHECK_EQ(actual, expected);
}
}
}
WASM_SIMD_TEST_NO_LOWERING(I64x2ExtractLane) {
WasmRunner<int64_t> r(execution_tier, lower_simd);
r.AllocateLocal(kWasmI64);
r.AllocateLocal(kWasmS128);
BUILD(
r,
WASM_SET_LOCAL(0, WASM_SIMD_I64x2_EXTRACT_LANE(
0, WASM_SIMD_I64x2_SPLAT(WASM_I64V(0xFFFFFFFFFF)))),
WASM_SET_LOCAL(1, WASM_SIMD_I64x2_SPLAT(WASM_GET_LOCAL(0))),
WASM_SIMD_I64x2_EXTRACT_LANE(1, WASM_GET_LOCAL(1)));
CHECK_EQ(0xFFFFFFFFFF, r.Call());
}
WASM_SIMD_TEST_NO_LOWERING(I64x2ReplaceLane) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
// Set up a global to hold input/output vector.
int64_t* g = r.builder().AddGlobal<int64_t>(kWasmS128);
// Build function to replace each lane with its index.
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I64x2_SPLAT(WASM_I64V(-1))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I64x2_REPLACE_LANE(
0, WASM_GET_LOCAL(temp1), WASM_I64V(0))),
WASM_SET_GLOBAL(0, WASM_SIMD_I64x2_REPLACE_LANE(
1, WASM_GET_LOCAL(temp1), WASM_I64V(1))),
WASM_ONE);
r.Call();
for (int64_t i = 0; i < 2; i++) {
CHECK_EQ(i, ReadLittleEndianValue<int64_t>(&g[i]));
}
}
void RunI64x2UnOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int64UnOp expected_op) {
WasmRunner<int32_t, int64_t> r(execution_tier, lower_simd);
// Global to hold output.
int64_t* g = r.builder().AddGlobal<int64_t>(kWasmS128);
// Build fn to splat test value, perform unop, and write the result.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I64x2_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(0, WASM_SIMD_UNOP(opcode, WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_INT64_INPUTS(x) {
r.Call(x);
int64_t expected = expected_op(x);
for (int i = 0; i < 2; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int64_t>(&g[i]));
}
}
}
WASM_SIMD_TEST_NO_LOWERING(I64x2Neg) {
RunI64x2UnOpTest(execution_tier, lower_simd, kExprI64x2Neg,
base::NegateWithWraparound);
}
void RunI64x2ShiftOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int64ShiftOp expected_op) {
// Intentionally shift by 64, should be no-op.
for (int shift = 1; shift <= 64; shift++) {
WasmRunner<int32_t, int64_t> r(execution_tier, lower_simd);
int64_t* g = r.builder().AddGlobal<int64_t>(kWasmS128);
byte value = 0;
byte shift_index = r.AllocateLocal(kWasmI32);
byte simd1 = r.AllocateLocal(kWasmS128);
BUILD(r,
WASM_SET_LOCAL(simd1, WASM_SIMD_I64x2_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_LOCAL(shift_index, WASM_I32V(shift)),
WASM_SET_GLOBAL(0, WASM_SIMD_SHIFT_OP(opcode, WASM_GET_LOCAL(simd1),
WASM_GET_LOCAL(shift_index))),
WASM_ONE);
FOR_INT64_INPUTS(x) {
r.Call(x);
int64_t expected = expected_op(x, shift);
for (int i = 0; i < 2; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int64_t>(&g[i]));
}
}
}
}
WASM_SIMD_TEST_NO_LOWERING(I64x2Shl) {
RunI64x2ShiftOpTest(execution_tier, lower_simd, kExprI64x2Shl,
LogicalShiftLeft);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2ShrS) {
RunI64x2ShiftOpTest(execution_tier, lower_simd, kExprI64x2ShrS,
ArithmeticShiftRight);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2ShrU) {
RunI64x2ShiftOpTest(execution_tier, lower_simd, kExprI64x2ShrU,
LogicalShiftRight);
}
void RunI64x2BinOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int64BinOp expected_op) {
WasmRunner<int32_t, int64_t, int64_t> r(execution_tier, lower_simd);
// Global to hold output.
int64_t* g = r.builder().AddGlobal<int64_t>(kWasmS128);
// Build fn to splat test values, perform binop, and write the result.
byte value1 = 0, value2 = 1;
byte temp1 = r.AllocateLocal(kWasmS128);
byte temp2 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I64x2_SPLAT(WASM_GET_LOCAL(value1))),
WASM_SET_LOCAL(temp2, WASM_SIMD_I64x2_SPLAT(WASM_GET_LOCAL(value2))),
WASM_SET_GLOBAL(0, WASM_SIMD_BINOP(opcode, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp2))),
WASM_ONE);
FOR_INT64_INPUTS(x) {
FOR_INT64_INPUTS(y) {
r.Call(x, y);
int64_t expected = expected_op(x, y);
for (int i = 0; i < 2; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int64_t>(&g[i]));
}
}
}
}
WASM_SIMD_TEST_NO_LOWERING(I64x2Add) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2Add,
base::AddWithWraparound);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2Sub) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2Sub,
base::SubWithWraparound);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2Eq) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2Eq, Equal);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2Ne) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2Ne, NotEqual);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2LtS) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2LtS, Less);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2LeS) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2LeS, LessEqual);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2GtS) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2GtS, Greater);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2GeS) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2GeS, GreaterEqual);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2LtU) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2LtU, UnsignedLess);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2LeU) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2LeU,
UnsignedLessEqual);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2GtU) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2GtU, UnsignedGreater);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2GeU) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2GeU,
UnsignedGreaterEqual);
}
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_TEST_NO_LOWERING(F64x2Splat) {
WasmRunner<int32_t, double> r(execution_tier, lower_simd);
// Set up a global to hold output vector.
double* g = r.builder().AddGlobal<double>(kWasmS128);
byte param1 = 0;
BUILD(r, WASM_SET_GLOBAL(0, WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(param1))),
WASM_ONE);
FOR_FLOAT64_INPUTS(x) {
r.Call(x);
double expected = x;
for (int i = 0; i < 2; i++) {
double actual = ReadLittleEndianValue<double>(&g[i]);
if (std::isnan(expected)) {
CHECK(std::isnan(actual));
} else {
CHECK_EQ(actual, expected);
}
}
}
}
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_TEST_NO_LOWERING(F64x2ExtractLaneWithI64x2) {
WasmRunner<int64_t> r(execution_tier, lower_simd);
BUILD(r, WASM_IF_ELSE_L(
WASM_F64_EQ(WASM_SIMD_F64x2_EXTRACT_LANE(
0, WASM_SIMD_I64x2_SPLAT(WASM_I64V(1e15))),
WASM_F64_REINTERPRET_I64(WASM_I64V(1e15))),
WASM_I64V(1), WASM_I64V(0)));
CHECK_EQ(1, r.Call());
}
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_TEST_NO_LOWERING(F64x2ExtractLane) {
WasmRunner<double, double> r(execution_tier, lower_simd);
byte param1 = 0;
byte temp1 = r.AllocateLocal(kWasmF64);
byte temp2 = r.AllocateLocal(kWasmS128);
BUILD(r,
WASM_SET_LOCAL(temp1,
WASM_SIMD_F64x2_EXTRACT_LANE(
0, WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(param1)))),
WASM_SET_LOCAL(temp2, WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(temp1))),
WASM_SIMD_F64x2_EXTRACT_LANE(1, WASM_GET_LOCAL(temp2)));
FOR_FLOAT64_INPUTS(x) {
double actual = r.Call(x);
double expected = x;
if (std::isnan(expected)) {
CHECK(std::isnan(actual));
} else {
CHECK_EQ(actual, expected);
}
}
}
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_TEST_NO_LOWERING(I64x2ExtractWithF64x2) {
WasmRunner<int64_t> r(execution_tier, lower_simd);
BUILD(r, WASM_IF_ELSE_L(
WASM_I64_EQ(WASM_SIMD_I64x2_EXTRACT_LANE(
0, WASM_SIMD_F64x2_SPLAT(WASM_F64(1e15))),
WASM_I64_REINTERPRET_F64(WASM_F64(1e15))),
WASM_I64V(1), WASM_I64V(0)));
CHECK_EQ(1, r.Call());
}
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_TEST_NO_LOWERING(F64x2ReplaceLane) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
// Set up a global to hold input/output vector.
double* g = r.builder().AddGlobal<double>(kWasmS128);
// Build function to replace each lane with its (FP) index.
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_F64x2_SPLAT(WASM_F64(1e100))),
WASM_SET_LOCAL(temp1, WASM_SIMD_F64x2_REPLACE_LANE(
0, WASM_GET_LOCAL(temp1), WASM_F64(0.0f))),
WASM_SET_GLOBAL(0, WASM_SIMD_F64x2_REPLACE_LANE(
1, WASM_GET_LOCAL(temp1), WASM_F64(1.0f))),
WASM_ONE);
r.Call();
for (int i = 0; i < 2; i++) {
CHECK_EQ(static_cast<double>(i), ReadLittleEndianValue<double>(&g[i]));
}
}
bool IsExtreme(double x) {
double abs_x = std::fabs(x);
const double kSmallFloatThreshold = 1.0e-298;
const double kLargeFloatThreshold = 1.0e298;
return abs_x != 0.0f && // 0 or -0 are fine.
(abs_x < kSmallFloatThreshold || abs_x > kLargeFloatThreshold);
}
bool IsSameNan(double expected, double actual) {
// Sign is non-deterministic.
uint64_t expected_bits = bit_cast<uint64_t>(expected) & ~0x8000000000000000;
uint64_t actual_bits = bit_cast<uint64_t>(actual) & ~0x8000000000000000;
// Some implementations convert signaling NaNs to quiet NaNs.
return (expected_bits == actual_bits) ||
((expected_bits | 0x0008000000000000) == actual_bits);
}
bool IsCanonical(double actual) {
uint64_t actual_bits = bit_cast<uint64_t>(actual);
// Canonical NaN has quiet bit and no payload.
return (actual_bits & 0xFFF8000000000000) == actual_bits;
}
void CheckDoubleResult(double x, double y, double expected, double actual,
bool exact = true) {
if (std::isnan(expected)) {
CHECK(std::isnan(actual));
if (std::isnan(x) && IsSameNan(x, actual)) return;
if (std::isnan(y) && IsSameNan(y, actual)) return;
if (IsSameNan(expected, actual)) return;
if (IsCanonical(actual)) return;
// This is expected to assert; it's useful for debugging.
CHECK_EQ(bit_cast<uint64_t>(expected), bit_cast<uint64_t>(actual));
} else {
if (exact) {
CHECK_EQ(expected, actual);
// The sign of 0's must match.
CHECK_EQ(std::signbit(expected), std::signbit(actual));
return;
}
// Otherwise, perform an approximate equality test. First check for
// equality to handle +/-Infinity where approximate equality doesn't work.
if (expected == actual) return;
// 1% error allows all platforms to pass easily.
constexpr double kApproximationError = 0.01f;
double abs_error = std::abs(expected) * kApproximationError,
min = expected - abs_error, max = expected + abs_error;
CHECK_LE(min, actual);
CHECK_GE(max, actual);
}
}
// Test some values not included in the double inputs from value_helper. These
// tests are useful for opcodes that are synthesized during code gen, like Min
// and Max on ia32 and x64.
static constexpr uint64_t double_nan_test_array[] = {
// quiet NaNs, + and -
0x7FF8000000000001, 0xFFF8000000000001,
// with payload
0x7FF8000000000011, 0xFFF8000000000011,
// signaling NaNs, + and -
0x7FF0000000000001, 0xFFF0000000000001,
// with payload
0x7FF0000000000011, 0xFFF0000000000011,
// Both Infinities.
0x7FF0000000000000, 0xFFF0000000000000,
// Some "normal" numbers, 1 and -1.
0x3FF0000000000000, 0xBFF0000000000000};
#define FOR_FLOAT64_NAN_INPUTS(i) \
for (size_t i = 0; i < arraysize(double_nan_test_array); ++i)
void RunF64x2UnOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, DoubleUnOp expected_op,
bool exact = true) {
WasmRunner<int32_t, double> r(execution_tier, lower_simd);
// Global to hold output.
double* g = r.builder().AddGlobal<double>(kWasmS128);
// Build fn to splat test value, perform unop, and write the result.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(0, WASM_SIMD_UNOP(opcode, WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_FLOAT64_INPUTS(x) {
if (!PlatformCanRepresent(x)) continue;
// Extreme values have larger errors so skip them for approximation tests.
if (!exact && IsExtreme(x)) continue;
double expected = expected_op(x);
if (!PlatformCanRepresent(expected)) continue;
r.Call(x);
for (int i = 0; i < 2; i++) {
double actual = ReadLittleEndianValue<double>(&g[i]);
CheckDoubleResult(x, x, expected, actual, exact);
}
}
FOR_FLOAT64_NAN_INPUTS(i) {
double x = bit_cast<double>(double_nan_test_array[i]);
if (!PlatformCanRepresent(x)) continue;
// Extreme values have larger errors so skip them for approximation tests.
if (!exact && IsExtreme(x)) continue;
double expected = expected_op(x);
if (!PlatformCanRepresent(expected)) continue;
r.Call(x);
for (int i = 0; i < 2; i++) {
double actual = ReadLittleEndianValue<double>(&g[i]);
CheckDoubleResult(x, x, expected, actual, exact);
}
}
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Abs) {
RunF64x2UnOpTest(execution_tier, lower_simd, kExprF64x2Abs, std::abs);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Neg) {
RunF64x2UnOpTest(execution_tier, lower_simd, kExprF64x2Neg, Negate);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Sqrt) {
RunF64x2UnOpTest(execution_tier, lower_simd, kExprF64x2Sqrt, Sqrt);
}
void RunF64x2BinOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, DoubleBinOp expected_op) {
WasmRunner<int32_t, double, double> r(execution_tier, lower_simd);
// Global to hold output.
double* g = r.builder().AddGlobal<double>(kWasmS128);
// Build fn to splat test value, perform binop, and write the result.
byte value1 = 0, value2 = 1;
byte temp1 = r.AllocateLocal(kWasmS128);
byte temp2 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value1))),
WASM_SET_LOCAL(temp2, WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value2))),
WASM_SET_GLOBAL(0, WASM_SIMD_BINOP(opcode, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp2))),
WASM_ONE);
FOR_FLOAT64_INPUTS(x) {
if (!PlatformCanRepresent(x)) continue;
FOR_FLOAT64_INPUTS(y) {
if (!PlatformCanRepresent(x)) continue;
double expected = expected_op(x, y);
if (!PlatformCanRepresent(expected)) continue;
r.Call(x, y);
for (int i = 0; i < 2; i++) {
double actual = ReadLittleEndianValue<double>(&g[i]);
CheckDoubleResult(x, y, expected, actual, true /* exact */);
}
}
}
FOR_FLOAT64_NAN_INPUTS(i) {
double x = bit_cast<double>(double_nan_test_array[i]);
if (!PlatformCanRepresent(x)) continue;
FOR_FLOAT64_NAN_INPUTS(j) {
double y = bit_cast<double>(double_nan_test_array[j]);
double expected = expected_op(x, y);
if (!PlatformCanRepresent(expected)) continue;
r.Call(x, y);
for (int i = 0; i < 2; i++) {
double actual = ReadLittleEndianValue<double>(&g[i]);
CheckDoubleResult(x, y, expected, actual, true /* exact */);
}
}
}
}
#undef FOR_FLOAT64_NAN_INPUTS
WASM_SIMD_TEST_NO_LOWERING(F64x2Add) {
RunF64x2BinOpTest(execution_tier, lower_simd, kExprF64x2Add, Add);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Sub) {
RunF64x2BinOpTest(execution_tier, lower_simd, kExprF64x2Sub, Sub);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Mul) {
RunF64x2BinOpTest(execution_tier, lower_simd, kExprF64x2Mul, Mul);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Div) {
RunF64x2BinOpTest(execution_tier, lower_simd, kExprF64x2Div, Div);
}
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
void RunF64x2CompareOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, DoubleCompareOp expected_op) {
WasmRunner<int32_t, double, double> r(execution_tier, lower_simd);
// Set up global to hold mask output.
int64_t* g = r.builder().AddGlobal<int64_t>(kWasmS128);
// Build fn to splat test values, perform compare op, and write the result.
byte value1 = 0, value2 = 1;
byte temp1 = r.AllocateLocal(kWasmS128);
byte temp2 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value1))),
WASM_SET_LOCAL(temp2, WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value2))),
WASM_SET_GLOBAL(0, WASM_SIMD_BINOP(opcode, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp2))),
WASM_ONE);
FOR_FLOAT64_INPUTS(x) {
if (!PlatformCanRepresent(x)) continue;
FOR_FLOAT64_INPUTS(y) {
if (!PlatformCanRepresent(y)) continue;
double diff = x - y; // Model comparison as subtraction.
if (!PlatformCanRepresent(diff)) continue;
r.Call(x, y);
int64_t expected = expected_op(x, y);
for (int i = 0; i < 2; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int64_t>(&g[i]));
}
}
}
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Eq) {
RunF64x2CompareOpTest(execution_tier, lower_simd, kExprF64x2Eq, Equal);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Ne) {
RunF64x2CompareOpTest(execution_tier, lower_simd, kExprF64x2Ne, NotEqual);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Gt) {
RunF64x2CompareOpTest(execution_tier, lower_simd, kExprF64x2Gt, Greater);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Ge) {
RunF64x2CompareOpTest(execution_tier, lower_simd, kExprF64x2Ge, GreaterEqual);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Lt) {
RunF64x2CompareOpTest(execution_tier, lower_simd, kExprF64x2Lt, Less);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Le) {
RunF64x2CompareOpTest(execution_tier, lower_simd, kExprF64x2Le, LessEqual);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Min) {
RunF64x2BinOpTest(execution_tier, lower_simd, kExprF64x2Min, JSMin);
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Max) {
RunF64x2BinOpTest(execution_tier, lower_simd, kExprF64x2Max, JSMax);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2Mul) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2Mul,
base::MulWithWraparound);
}
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
#if V8_TARGET_ARCH_X64
WASM_SIMD_TEST_NO_LOWERING(I64x2MinS) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2MinS, Minimum);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2MaxS) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2MaxS, Maximum);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2MinU) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2MinU,
UnsignedMinimum);
}
WASM_SIMD_TEST_NO_LOWERING(I64x2MaxU) {
RunI64x2BinOpTest(execution_tier, lower_simd, kExprI64x2MaxU,
UnsignedMaximum);
}
#endif // V8_TARGET_ARCH_X64
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_TEST_NO_LOWERING(F64x2Qfma) {
WasmRunner<int32_t, double, double, double> r(execution_tier, lower_simd);
// Set up global to hold mask output.
double* g = r.builder().AddGlobal<double>(kWasmS128);
// Build fn to splat test values, perform compare op, and write the result.
byte value1 = 0, value2 = 1, value3 = 2;
BUILD(r,
WASM_SET_GLOBAL(0, WASM_SIMD_F64x2_QFMA(
WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value1)),
WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value2)),
WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value3)))),
WASM_ONE);
for (FMOperation<double> x : qfma_vector<double>()) {
r.Call(x.a, x.b, x.c);
double expected =
ExpectFused(execution_tier) ? x.fused_result : x.unfused_result;
for (int i = 0; i < 2; i++) {
double actual = ReadLittleEndianValue<double>(&g[i]);
CheckDoubleResult(x.a, x.b, expected, actual, true /* exact */);
}
}
}
WASM_SIMD_TEST_NO_LOWERING(F64x2Qfms) {
WasmRunner<int32_t, double, double, double> r(execution_tier, lower_simd);
// Set up global to hold mask output.
double* g = r.builder().AddGlobal<double>(kWasmS128);
// Build fn to splat test values, perform compare op, and write the result.
byte value1 = 0, value2 = 1, value3 = 2;
BUILD(r,
WASM_SET_GLOBAL(0, WASM_SIMD_F64x2_QFMS(
WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value1)),
WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value2)),
WASM_SIMD_F64x2_SPLAT(WASM_GET_LOCAL(value3)))),
WASM_ONE);
for (FMOperation<double> x : qfms_vector<double>()) {
r.Call(x.a, x.b, x.c);
double expected =
ExpectFused(execution_tier) ? x.fused_result : x.unfused_result;
for (int i = 0; i < 2; i++) {
double actual = ReadLittleEndianValue<double>(&g[i]);
CheckDoubleResult(x.a, x.b, expected, actual, true /* exact */);
}
}
}
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64 || V8_TARGET_ARCH_IA32
WASM_SIMD_TEST(I32x4Splat) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Set up a global to hold output vector.
int32_t* g = r.builder().AddGlobal<int32_t>(kWasmS128);
byte param1 = 0;
BUILD(r, WASM_SET_GLOBAL(0, WASM_SIMD_I32x4_SPLAT(WASM_GET_LOCAL(param1))),
WASM_ONE);
FOR_INT32_INPUTS(x) {
r.Call(x);
int32_t expected = x;
for (int i = 0; i < 4; i++) {
int32_t actual = ReadLittleEndianValue<int32_t>(&g[i]);
CHECK_EQ(actual, expected);
}
}
}
WASM_SIMD_TEST(I32x4ReplaceLane) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
// Set up a global to hold input/output vector.
int32_t* g = r.builder().AddGlobal<int32_t>(kWasmS128);
// Build function to replace each lane with its index.
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I32x4_SPLAT(WASM_I32V(-1))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I32x4_REPLACE_LANE(
0, WASM_GET_LOCAL(temp1), WASM_I32V(0))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I32x4_REPLACE_LANE(
1, WASM_GET_LOCAL(temp1), WASM_I32V(1))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I32x4_REPLACE_LANE(
2, WASM_GET_LOCAL(temp1), WASM_I32V(2))),
WASM_SET_GLOBAL(0, WASM_SIMD_I32x4_REPLACE_LANE(
3, WASM_GET_LOCAL(temp1), WASM_I32V(3))),
WASM_ONE);
r.Call();
for (int32_t i = 0; i < 4; i++) {
CHECK_EQ(i, ReadLittleEndianValue<int32_t>(&g[i]));
}
}
WASM_SIMD_TEST(I16x8Splat) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Set up a global to hold output vector.
int16_t* g = r.builder().AddGlobal<int16_t>(kWasmS128);
byte param1 = 0;
BUILD(r, WASM_SET_GLOBAL(0, WASM_SIMD_I16x8_SPLAT(WASM_GET_LOCAL(param1))),
WASM_ONE);
FOR_INT16_INPUTS(x) {
r.Call(x);
int16_t expected = x;
for (int i = 0; i < 8; i++) {
int16_t actual = ReadLittleEndianValue<int16_t>(&g[i]);
CHECK_EQ(actual, expected);
}
}
}
WASM_SIMD_TEST(I16x8ReplaceLane) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
// Set up a global to hold input/output vector.
int16_t* g = r.builder().AddGlobal<int16_t>(kWasmS128);
// Build function to replace each lane with its index.
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_SPLAT(WASM_I32V(-1))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_REPLACE_LANE(
0, WASM_GET_LOCAL(temp1), WASM_I32V(0))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_REPLACE_LANE(
1, WASM_GET_LOCAL(temp1), WASM_I32V(1))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_REPLACE_LANE(
2, WASM_GET_LOCAL(temp1), WASM_I32V(2))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_REPLACE_LANE(
3, WASM_GET_LOCAL(temp1), WASM_I32V(3))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_REPLACE_LANE(
4, WASM_GET_LOCAL(temp1), WASM_I32V(4))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_REPLACE_LANE(
5, WASM_GET_LOCAL(temp1), WASM_I32V(5))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_REPLACE_LANE(
6, WASM_GET_LOCAL(temp1), WASM_I32V(6))),
WASM_SET_GLOBAL(0, WASM_SIMD_I16x8_REPLACE_LANE(
7, WASM_GET_LOCAL(temp1), WASM_I32V(7))),
WASM_ONE);
r.Call();
for (int16_t i = 0; i < 8; i++) {
CHECK_EQ(i, ReadLittleEndianValue<int16_t>(&g[i]));
}
}
WASM_SIMD_TEST(I8x16Splat) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Set up a global to hold output vector.
int8_t* g = r.builder().AddGlobal<int8_t>(kWasmS128);
byte param1 = 0;
BUILD(r, WASM_SET_GLOBAL(0, WASM_SIMD_I8x16_SPLAT(WASM_GET_LOCAL(param1))),
WASM_ONE);
FOR_INT8_INPUTS(x) {
r.Call(x);
int8_t expected = x;
for (int i = 0; i < 16; i++) {
int8_t actual = ReadLittleEndianValue<int8_t>(&g[i]);
CHECK_EQ(actual, expected);
}
}
}
WASM_SIMD_TEST(I8x16ReplaceLane) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
// Set up a global to hold input/output vector.
int8_t* g = r.builder().AddGlobal<int8_t>(kWasmS128);
// Build function to replace each lane with its index.
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_SPLAT(WASM_I32V(-1))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
0, WASM_GET_LOCAL(temp1), WASM_I32V(0))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
1, WASM_GET_LOCAL(temp1), WASM_I32V(1))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
2, WASM_GET_LOCAL(temp1), WASM_I32V(2))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
3, WASM_GET_LOCAL(temp1), WASM_I32V(3))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
4, WASM_GET_LOCAL(temp1), WASM_I32V(4))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
5, WASM_GET_LOCAL(temp1), WASM_I32V(5))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
6, WASM_GET_LOCAL(temp1), WASM_I32V(6))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
7, WASM_GET_LOCAL(temp1), WASM_I32V(7))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
8, WASM_GET_LOCAL(temp1), WASM_I32V(8))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
9, WASM_GET_LOCAL(temp1), WASM_I32V(9))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
10, WASM_GET_LOCAL(temp1), WASM_I32V(10))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
11, WASM_GET_LOCAL(temp1), WASM_I32V(11))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
12, WASM_GET_LOCAL(temp1), WASM_I32V(12))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
13, WASM_GET_LOCAL(temp1), WASM_I32V(13))),
WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_REPLACE_LANE(
14, WASM_GET_LOCAL(temp1), WASM_I32V(14))),
WASM_SET_GLOBAL(0, WASM_SIMD_I8x16_REPLACE_LANE(
15, WASM_GET_LOCAL(temp1), WASM_I32V(15))),
WASM_ONE);
r.Call();
for (int8_t i = 0; i < 16; i++) {
CHECK_EQ(i, ReadLittleEndianValue<int8_t>(&g[i]));
}
}
// Use doubles to ensure exact conversion.
int32_t ConvertToInt(double val, bool unsigned_integer) {
if (std::isnan(val)) return 0;
if (unsigned_integer) {
if (val < 0) return 0;
if (val > kMaxUInt32) return kMaxUInt32;
return static_cast<uint32_t>(val);
} else {
if (val < kMinInt) return kMinInt;
if (val > kMaxInt) return kMaxInt;
return static_cast<int>(val);
}
}
// Tests both signed and unsigned conversion.
WASM_SIMD_TEST(I32x4ConvertF32x4) {
WasmRunner<int32_t, float> r(execution_tier, lower_simd);
// Create two output vectors to hold signed and unsigned results.
int32_t* g0 = r.builder().AddGlobal<int32_t>(kWasmS128);
int32_t* g1 = r.builder().AddGlobal<int32_t>(kWasmS128);
// Build fn to splat test value, perform conversions, and write the results.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(
0, WASM_SIMD_UNOP(kExprI32x4SConvertF32x4, WASM_GET_LOCAL(temp1))),
WASM_SET_GLOBAL(
1, WASM_SIMD_UNOP(kExprI32x4UConvertF32x4, WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_FLOAT32_INPUTS(x) {
if (!PlatformCanRepresent(x)) continue;
r.Call(x);
int32_t expected_signed = ConvertToInt(x, false);
int32_t expected_unsigned = ConvertToInt(x, true);
for (int i = 0; i < 4; i++) {
CHECK_EQ(expected_signed, ReadLittleEndianValue<int32_t>(&g0[i]));
CHECK_EQ(expected_unsigned, ReadLittleEndianValue<int32_t>(&g1[i]));
}
}
}
// Tests both signed and unsigned conversion from I16x8 (unpacking).
WASM_SIMD_TEST(I32x4ConvertI16x8) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Create four output vectors to hold signed and unsigned results.
int32_t* g0 = r.builder().AddGlobal<int32_t>(kWasmS128);
int32_t* g1 = r.builder().AddGlobal<int32_t>(kWasmS128);
int32_t* g2 = r.builder().AddGlobal<int32_t>(kWasmS128);
int32_t* g3 = r.builder().AddGlobal<int32_t>(kWasmS128);
// Build fn to splat test value, perform conversions, and write the results.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(0, WASM_SIMD_UNOP(kExprI32x4SConvertI16x8High,
WASM_GET_LOCAL(temp1))),
WASM_SET_GLOBAL(1, WASM_SIMD_UNOP(kExprI32x4SConvertI16x8Low,
WASM_GET_LOCAL(temp1))),
WASM_SET_GLOBAL(2, WASM_SIMD_UNOP(kExprI32x4UConvertI16x8High,
WASM_GET_LOCAL(temp1))),
WASM_SET_GLOBAL(3, WASM_SIMD_UNOP(kExprI32x4UConvertI16x8Low,
WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_INT16_INPUTS(x) {
r.Call(x);
int32_t expected_signed = static_cast<int32_t>(Widen<int16_t>(x));
int32_t expected_unsigned = static_cast<int32_t>(UnsignedWiden<int16_t>(x));
for (int i = 0; i < 4; i++) {
CHECK_EQ(expected_signed, ReadLittleEndianValue<int32_t>(&g0[i]));
CHECK_EQ(expected_signed, ReadLittleEndianValue<int32_t>(&g1[i]));
CHECK_EQ(expected_unsigned, ReadLittleEndianValue<int32_t>(&g2[i]));
CHECK_EQ(expected_unsigned, ReadLittleEndianValue<int32_t>(&g3[i]));
}
}
}
void RunI32x4UnOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int32UnOp expected_op) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Global to hold output.
int32_t* g = r.builder().AddGlobal<int32_t>(kWasmS128);
// Build fn to splat test value, perform unop, and write the result.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I32x4_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(0, WASM_SIMD_UNOP(opcode, WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_INT32_INPUTS(x) {
r.Call(x);
int32_t expected = expected_op(x);
for (int i = 0; i < 4; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int32_t>(&g[i]));
}
}
}
WASM_SIMD_TEST(I32x4Neg) {
RunI32x4UnOpTest(execution_tier, lower_simd, kExprI32x4Neg,
base::NegateWithWraparound);
}
WASM_SIMD_TEST(S128Not) {
RunI32x4UnOpTest(execution_tier, lower_simd, kExprS128Not, Not);
}
void RunI32x4BinOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int32BinOp expected_op) {
WasmRunner<int32_t, int32_t, int32_t> r(execution_tier, lower_simd);
// Global to hold output.
int32_t* g = r.builder().AddGlobal<int32_t>(kWasmS128);
// Build fn to splat test values, perform binop, and write the result.
byte value1 = 0, value2 = 1;
byte temp1 = r.AllocateLocal(kWasmS128);
byte temp2 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I32x4_SPLAT(WASM_GET_LOCAL(value1))),
WASM_SET_LOCAL(temp2, WASM_SIMD_I32x4_SPLAT(WASM_GET_LOCAL(value2))),
WASM_SET_GLOBAL(0, WASM_SIMD_BINOP(opcode, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp2))),
WASM_ONE);
FOR_INT32_INPUTS(x) {
FOR_INT32_INPUTS(y) {
r.Call(x, y);
int32_t expected = expected_op(x, y);
for (int i = 0; i < 4; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int32_t>(&g[i]));
}
}
}
}
WASM_SIMD_TEST(I32x4Add) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4Add,
base::AddWithWraparound);
}
WASM_SIMD_TEST(I32x4Sub) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4Sub,
base::SubWithWraparound);
}
WASM_SIMD_TEST(I32x4Mul) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4Mul,
base::MulWithWraparound);
}
WASM_SIMD_TEST(I32x4MinS) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4MinS, Minimum);
}
WASM_SIMD_TEST(I32x4MaxS) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4MaxS, Maximum);
}
WASM_SIMD_TEST(I32x4MinU) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4MinU,
UnsignedMinimum);
}
WASM_SIMD_TEST(I32x4MaxU) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4MaxU,
UnsignedMaximum);
}
WASM_SIMD_TEST(S128And) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprS128And, And);
}
WASM_SIMD_TEST(S128Or) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprS128Or, Or);
}
WASM_SIMD_TEST(S128Xor) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprS128Xor, Xor);
}
WASM_SIMD_TEST(I32x4Eq) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4Eq, Equal);
}
WASM_SIMD_TEST(I32x4Ne) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4Ne, NotEqual);
}
WASM_SIMD_TEST(I32x4LtS) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4LtS, Less);
}
WASM_SIMD_TEST(I32x4LeS) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4LeS, LessEqual);
}
WASM_SIMD_TEST(I32x4GtS) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4GtS, Greater);
}
WASM_SIMD_TEST(I32x4GeS) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4GeS, GreaterEqual);
}
WASM_SIMD_TEST(I32x4LtU) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4LtU, UnsignedLess);
}
WASM_SIMD_TEST(I32x4LeU) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4LeU,
UnsignedLessEqual);
}
WASM_SIMD_TEST(I32x4GtU) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4GtU, UnsignedGreater);
}
WASM_SIMD_TEST(I32x4GeU) {
RunI32x4BinOpTest(execution_tier, lower_simd, kExprI32x4GeU,
UnsignedGreaterEqual);
}
void RunI32x4ShiftOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int32ShiftOp expected_op) {
// Intentionally shift by 32, should be no-op.
for (int shift = 1; shift <= 32; shift++) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
int32_t* g = r.builder().AddGlobal<int32_t>(kWasmS128);
byte value = 0;
byte shift_index = r.AllocateLocal(kWasmI32);
byte simd1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(shift_index, WASM_I32V(shift)),
WASM_SET_LOCAL(simd1, WASM_SIMD_I32x4_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(0, WASM_SIMD_SHIFT_OP(opcode, WASM_GET_LOCAL(simd1),
WASM_GET_LOCAL(shift_index))),
WASM_ONE);
FOR_INT32_INPUTS(x) {
r.Call(x);
int32_t expected = expected_op(x, shift);
for (int i = 0; i < 4; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int32_t>(&g[i]));
}
}
}
}
WASM_SIMD_TEST_NO_LOWERING(I32x4Shl) {
RunI32x4ShiftOpTest(execution_tier, lower_simd, kExprI32x4Shl,
LogicalShiftLeft);
}
WASM_SIMD_TEST_NO_LOWERING(I32x4ShrS) {
RunI32x4ShiftOpTest(execution_tier, lower_simd, kExprI32x4ShrS,
ArithmeticShiftRight);
}
WASM_SIMD_TEST_NO_LOWERING(I32x4ShrU) {
RunI32x4ShiftOpTest(execution_tier, lower_simd, kExprI32x4ShrU,
LogicalShiftRight);
}
// Tests both signed and unsigned conversion from I8x16 (unpacking).
WASM_SIMD_TEST(I16x8ConvertI8x16) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Create four output vectors to hold signed and unsigned results.
int16_t* g0 = r.builder().AddGlobal<int16_t>(kWasmS128);
int16_t* g1 = r.builder().AddGlobal<int16_t>(kWasmS128);
int16_t* g2 = r.builder().AddGlobal<int16_t>(kWasmS128);
int16_t* g3 = r.builder().AddGlobal<int16_t>(kWasmS128);
// Build fn to splat test value, perform conversions, and write the results.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(0, WASM_SIMD_UNOP(kExprI16x8SConvertI8x16High,
WASM_GET_LOCAL(temp1))),
WASM_SET_GLOBAL(1, WASM_SIMD_UNOP(kExprI16x8SConvertI8x16Low,
WASM_GET_LOCAL(temp1))),
WASM_SET_GLOBAL(2, WASM_SIMD_UNOP(kExprI16x8UConvertI8x16High,
WASM_GET_LOCAL(temp1))),
WASM_SET_GLOBAL(3, WASM_SIMD_UNOP(kExprI16x8UConvertI8x16Low,
WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_INT8_INPUTS(x) {
r.Call(x);
int16_t expected_signed = static_cast<int16_t>(Widen<int8_t>(x));
int16_t expected_unsigned = static_cast<int16_t>(UnsignedWiden<int8_t>(x));
for (int i = 0; i < 8; i++) {
CHECK_EQ(expected_signed, ReadLittleEndianValue<int16_t>(&g0[i]));
CHECK_EQ(expected_signed, ReadLittleEndianValue<int16_t>(&g1[i]));
CHECK_EQ(expected_unsigned, ReadLittleEndianValue<int16_t>(&g2[i]));
CHECK_EQ(expected_unsigned, ReadLittleEndianValue<int16_t>(&g3[i]));
}
}
}
// Tests both signed and unsigned conversion from I32x4 (packing).
WASM_SIMD_TEST(I16x8ConvertI32x4) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Create output vectors to hold signed and unsigned results.
int16_t* g0 = r.builder().AddGlobal<int16_t>(kWasmS128);
int16_t* g1 = r.builder().AddGlobal<int16_t>(kWasmS128);
// Build fn to splat test value, perform conversions, and write the results.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I32x4_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(
0, WASM_SIMD_BINOP(kExprI16x8SConvertI32x4, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp1))),
WASM_SET_GLOBAL(
1, WASM_SIMD_BINOP(kExprI16x8UConvertI32x4, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_INT32_INPUTS(x) {
r.Call(x);
int16_t expected_signed = Narrow<int16_t>(x);
int16_t expected_unsigned = UnsignedNarrow<int16_t>(x);
for (int i = 0; i < 8; i++) {
CHECK_EQ(expected_signed, ReadLittleEndianValue<int16_t>(&g0[i]));
CHECK_EQ(expected_unsigned, ReadLittleEndianValue<int16_t>(&g1[i]));
}
}
}
void RunI16x8UnOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int16UnOp expected_op) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Global to hold output.
int16_t* g = r.builder().AddGlobal<int16_t>(kWasmS128);
// Build fn to splat test value, perform unop, and write the result.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(0, WASM_SIMD_UNOP(opcode, WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_INT16_INPUTS(x) {
r.Call(x);
int16_t expected = expected_op(x);
for (int i = 0; i < 8; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int16_t>(&g[i]));
}
}
}
WASM_SIMD_TEST(I16x8Neg) {
RunI16x8UnOpTest(execution_tier, lower_simd, kExprI16x8Neg,
base::NegateWithWraparound);
}
void RunI16x8BinOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int16BinOp expected_op) {
WasmRunner<int32_t, int32_t, int32_t> r(execution_tier, lower_simd);
// Global to hold output.
int16_t* g = r.builder().AddGlobal<int16_t>(kWasmS128);
// Build fn to splat test values, perform binop, and write the result.
byte value1 = 0, value2 = 1;
byte temp1 = r.AllocateLocal(kWasmS128);
byte temp2 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_SPLAT(WASM_GET_LOCAL(value1))),
WASM_SET_LOCAL(temp2, WASM_SIMD_I16x8_SPLAT(WASM_GET_LOCAL(value2))),
WASM_SET_GLOBAL(0, WASM_SIMD_BINOP(opcode, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp2))),
WASM_ONE);
FOR_INT16_INPUTS(x) {
FOR_INT16_INPUTS(y) {
r.Call(x, y);
int16_t expected = expected_op(x, y);
for (int i = 0; i < 8; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int16_t>(&g[i]));
}
}
}
}
WASM_SIMD_TEST(I16x8Add) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8Add,
base::AddWithWraparound);
}
WASM_SIMD_TEST(I16x8AddSaturateS) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8AddSaturateS,
AddSaturate);
}
WASM_SIMD_TEST(I16x8Sub) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8Sub,
base::SubWithWraparound);
}
WASM_SIMD_TEST(I16x8SubSaturateS) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8SubSaturateS,
SubSaturate);
}
WASM_SIMD_TEST(I16x8Mul) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8Mul,
base::MulWithWraparound);
}
WASM_SIMD_TEST(I16x8MinS) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8MinS, Minimum);
}
WASM_SIMD_TEST(I16x8MaxS) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8MaxS, Maximum);
}
WASM_SIMD_TEST(I16x8AddSaturateU) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8AddSaturateU,
UnsignedAddSaturate);
}
WASM_SIMD_TEST(I16x8SubSaturateU) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8SubSaturateU,
UnsignedSubSaturate);
}
WASM_SIMD_TEST(I16x8MinU) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8MinU,
UnsignedMinimum);
}
WASM_SIMD_TEST(I16x8MaxU) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8MaxU,
UnsignedMaximum);
}
WASM_SIMD_TEST(I16x8Eq) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8Eq, Equal);
}
WASM_SIMD_TEST(I16x8Ne) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8Ne, NotEqual);
}
WASM_SIMD_TEST(I16x8LtS) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8LtS, Less);
}
WASM_SIMD_TEST(I16x8LeS) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8LeS, LessEqual);
}
WASM_SIMD_TEST(I16x8GtS) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8GtS, Greater);
}
WASM_SIMD_TEST(I16x8GeS) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8GeS, GreaterEqual);
}
WASM_SIMD_TEST(I16x8GtU) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8GtU, UnsignedGreater);
}
WASM_SIMD_TEST(I16x8GeU) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8GeU,
UnsignedGreaterEqual);
}
WASM_SIMD_TEST(I16x8LtU) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8LtU, UnsignedLess);
}
WASM_SIMD_TEST(I16x8LeU) {
RunI16x8BinOpTest(execution_tier, lower_simd, kExprI16x8LeU,
UnsignedLessEqual);
}
void RunI16x8ShiftOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int16ShiftOp expected_op) {
// Intentionally shift by 16, should be no-op.
for (int shift = 1; shift <= 16; shift++) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
int16_t* g = r.builder().AddGlobal<int16_t>(kWasmS128);
byte value = 0;
byte simd1 = r.AllocateLocal(kWasmS128);
byte shift_index = r.AllocateLocal(kWasmI32);
BUILD(r,
WASM_SET_LOCAL(simd1, WASM_SIMD_I16x8_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_LOCAL(shift_index, WASM_I32V(shift)),
WASM_SET_GLOBAL(0, WASM_SIMD_SHIFT_OP(opcode, WASM_GET_LOCAL(simd1),
WASM_GET_LOCAL(shift_index))),
WASM_ONE);
FOR_INT16_INPUTS(x) {
r.Call(x);
int16_t expected = expected_op(x, shift);
for (int i = 0; i < 8; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int16_t>(&g[i]));
}
}
}
}
WASM_SIMD_TEST_NO_LOWERING(I16x8Shl) {
RunI16x8ShiftOpTest(execution_tier, lower_simd, kExprI16x8Shl,
LogicalShiftLeft);
}
WASM_SIMD_TEST_NO_LOWERING(I16x8ShrS) {
RunI16x8ShiftOpTest(execution_tier, lower_simd, kExprI16x8ShrS,
ArithmeticShiftRight);
}
WASM_SIMD_TEST_NO_LOWERING(I16x8ShrU) {
RunI16x8ShiftOpTest(execution_tier, lower_simd, kExprI16x8ShrU,
LogicalShiftRight);
}
void RunI8x16UnOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int8UnOp expected_op) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Global to hold output.
int8_t* g = r.builder().AddGlobal<int8_t>(kWasmS128);
// Build fn to splat test value, perform unop, and write the result.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(0, WASM_SIMD_UNOP(opcode, WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_INT8_INPUTS(x) {
r.Call(x);
int8_t expected = expected_op(x);
for (int i = 0; i < 16; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int8_t>(&g[i]));
}
}
}
WASM_SIMD_TEST(I8x16Neg) {
RunI8x16UnOpTest(execution_tier, lower_simd, kExprI8x16Neg,
base::NegateWithWraparound);
}
// Tests both signed and unsigned conversion from I16x8 (packing).
WASM_SIMD_TEST(I8x16ConvertI16x8) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Create output vectors to hold signed and unsigned results.
int8_t* g0 = r.builder().AddGlobal<int8_t>(kWasmS128);
int8_t* g1 = r.builder().AddGlobal<int8_t>(kWasmS128);
// Build fn to splat test value, perform conversions, and write the results.
byte value = 0;
byte temp1 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_GLOBAL(
0, WASM_SIMD_BINOP(kExprI8x16SConvertI16x8, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp1))),
WASM_SET_GLOBAL(
1, WASM_SIMD_BINOP(kExprI8x16UConvertI16x8, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp1))),
WASM_ONE);
FOR_INT16_INPUTS(x) {
r.Call(x);
int8_t expected_signed = Narrow<int8_t>(x);
int8_t expected_unsigned = UnsignedNarrow<int8_t>(x);
for (int i = 0; i < 16; i++) {
CHECK_EQ(expected_signed, ReadLittleEndianValue<int8_t>(&g0[i]));
CHECK_EQ(expected_unsigned, ReadLittleEndianValue<int8_t>(&g1[i]));
}
}
}
void RunI8x16BinOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int8BinOp expected_op) {
WasmRunner<int32_t, int32_t, int32_t> r(execution_tier, lower_simd);
// Global to hold output.
int8_t* g = r.builder().AddGlobal<int8_t>(kWasmS128);
// Build fn to splat test values, perform binop, and write the result.
byte value1 = 0, value2 = 1;
byte temp1 = r.AllocateLocal(kWasmS128);
byte temp2 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_SPLAT(WASM_GET_LOCAL(value1))),
WASM_SET_LOCAL(temp2, WASM_SIMD_I8x16_SPLAT(WASM_GET_LOCAL(value2))),
WASM_SET_GLOBAL(0, WASM_SIMD_BINOP(opcode, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp2))),
WASM_ONE);
FOR_INT8_INPUTS(x) {
FOR_INT8_INPUTS(y) {
r.Call(x, y);
int8_t expected = expected_op(x, y);
for (int i = 0; i < 16; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int8_t>(&g[i]));
}
}
}
}
WASM_SIMD_TEST(I8x16Add) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16Add,
base::AddWithWraparound);
}
WASM_SIMD_TEST(I8x16AddSaturateS) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16AddSaturateS,
AddSaturate);
}
WASM_SIMD_TEST(I8x16Sub) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16Sub,
base::SubWithWraparound);
}
WASM_SIMD_TEST(I8x16SubSaturateS) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16SubSaturateS,
SubSaturate);
}
WASM_SIMD_TEST(I8x16MinS) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16MinS, Minimum);
}
WASM_SIMD_TEST(I8x16MaxS) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16MaxS, Maximum);
}
WASM_SIMD_TEST(I8x16AddSaturateU) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16AddSaturateU,
UnsignedAddSaturate);
}
WASM_SIMD_TEST(I8x16SubSaturateU) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16SubSaturateU,
UnsignedSubSaturate);
}
WASM_SIMD_TEST(I8x16MinU) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16MinU,
UnsignedMinimum);
}
WASM_SIMD_TEST(I8x16MaxU) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16MaxU,
UnsignedMaximum);
}
WASM_SIMD_TEST(I8x16Eq) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16Eq, Equal);
}
WASM_SIMD_TEST(I8x16Ne) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16Ne, NotEqual);
}
WASM_SIMD_TEST(I8x16GtS) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16GtS, Greater);
}
WASM_SIMD_TEST(I8x16GeS) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16GeS, GreaterEqual);
}
WASM_SIMD_TEST(I8x16LtS) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16LtS, Less);
}
WASM_SIMD_TEST(I8x16LeS) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16LeS, LessEqual);
}
WASM_SIMD_TEST(I8x16GtU) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16GtU, UnsignedGreater);
}
WASM_SIMD_TEST(I8x16GeU) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16GeU,
UnsignedGreaterEqual);
}
WASM_SIMD_TEST(I8x16LtU) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16LtU, UnsignedLess);
}
WASM_SIMD_TEST(I8x16LeU) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16LeU,
UnsignedLessEqual);
}
WASM_SIMD_TEST(I8x16Mul) {
RunI8x16BinOpTest(execution_tier, lower_simd, kExprI8x16Mul,
base::MulWithWraparound);
}
void RunI8x16ShiftOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode opcode, Int8ShiftOp expected_op) {
// Intentionally shift by 8, should be no-op.
for (int shift = 1; shift <= 8; shift++) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
int8_t* g = r.builder().AddGlobal<int8_t>(kWasmS128);
byte value = 0;
byte simd1 = r.AllocateLocal(kWasmS128);
byte shift_index = r.AllocateLocal(kWasmI32);
BUILD(r,
WASM_SET_LOCAL(simd1, WASM_SIMD_I8x16_SPLAT(WASM_GET_LOCAL(value))),
WASM_SET_LOCAL(shift_index, WASM_I32V(shift)),
WASM_SET_GLOBAL(0, WASM_SIMD_SHIFT_OP(opcode, WASM_GET_LOCAL(simd1),
WASM_GET_LOCAL(shift_index))),
WASM_ONE);
FOR_INT8_INPUTS(x) {
r.Call(x);
int8_t expected = expected_op(x, shift);
for (int i = 0; i < 16; i++) {
CHECK_EQ(expected, ReadLittleEndianValue<int8_t>(&g[i]));
}
}
}
}
WASM_SIMD_TEST_NO_LOWERING(I8x16Shl) {
RunI8x16ShiftOpTest(execution_tier, lower_simd, kExprI8x16Shl,
LogicalShiftLeft);
}
WASM_SIMD_TEST_NO_LOWERING(I8x16ShrS) {
RunI8x16ShiftOpTest(execution_tier, lower_simd, kExprI8x16ShrS,
ArithmeticShiftRight);
}
WASM_SIMD_TEST_NO_LOWERING(I8x16ShrU) {
RunI8x16ShiftOpTest(execution_tier, lower_simd, kExprI8x16ShrU,
LogicalShiftRight);
}
// Test Select by making a mask where the 0th and 3rd lanes are true and the
// rest false, and comparing for non-equality with zero to convert to a boolean
// vector.
#define WASM_SIMD_SELECT_TEST(format) \
WASM_SIMD_TEST(S##format##Select) { \
WasmRunner<int32_t, int32_t, int32_t> r(execution_tier, lower_simd); \
byte val1 = 0; \
byte val2 = 1; \
byte src1 = r.AllocateLocal(kWasmS128); \
byte src2 = r.AllocateLocal(kWasmS128); \
byte zero = r.AllocateLocal(kWasmS128); \
byte mask = r.AllocateLocal(kWasmS128); \
BUILD(r, \
WASM_SET_LOCAL(src1, \
WASM_SIMD_I##format##_SPLAT(WASM_GET_LOCAL(val1))), \
WASM_SET_LOCAL(src2, \
WASM_SIMD_I##format##_SPLAT(WASM_GET_LOCAL(val2))), \
WASM_SET_LOCAL(zero, WASM_SIMD_I##format##_SPLAT(WASM_ZERO)), \
WASM_SET_LOCAL(mask, WASM_SIMD_I##format##_REPLACE_LANE( \
1, WASM_GET_LOCAL(zero), WASM_I32V(-1))), \
WASM_SET_LOCAL(mask, WASM_SIMD_I##format##_REPLACE_LANE( \
2, WASM_GET_LOCAL(mask), WASM_I32V(-1))), \
WASM_SET_LOCAL( \
mask, \
WASM_SIMD_SELECT( \
format, WASM_GET_LOCAL(src1), WASM_GET_LOCAL(src2), \
WASM_SIMD_BINOP(kExprI##format##Ne, WASM_GET_LOCAL(mask), \
WASM_GET_LOCAL(zero)))), \
WASM_SIMD_CHECK_LANE(I##format, mask, I32, val2, 0), \
WASM_SIMD_CHECK_LANE(I##format, mask, I32, val1, 1), \
WASM_SIMD_CHECK_LANE(I##format, mask, I32, val1, 2), \
WASM_SIMD_CHECK_LANE(I##format, mask, I32, val2, 3), WASM_ONE); \
\
CHECK_EQ(1, r.Call(0x12, 0x34)); \
}
WASM_SIMD_SELECT_TEST(32x4)
WASM_SIMD_SELECT_TEST(16x8)
WASM_SIMD_SELECT_TEST(8x16)
// Test Select by making a mask where the 0th and 3rd lanes are non-zero and the
// rest 0. The mask is not the result of a comparison op.
#define WASM_SIMD_NON_CANONICAL_SELECT_TEST(format) \
WASM_SIMD_TEST_NO_LOWERING(S##format##NonCanonicalSelect) { \
WasmRunner<int32_t, int32_t, int32_t, int32_t> r(execution_tier, \
lower_simd); \
byte val1 = 0; \
byte val2 = 1; \
byte combined = 2; \
byte src1 = r.AllocateLocal(kWasmS128); \
byte src2 = r.AllocateLocal(kWasmS128); \
byte zero = r.AllocateLocal(kWasmS128); \
byte mask = r.AllocateLocal(kWasmS128); \
BUILD(r, \
WASM_SET_LOCAL(src1, \
WASM_SIMD_I##format##_SPLAT(WASM_GET_LOCAL(val1))), \
WASM_SET_LOCAL(src2, \
WASM_SIMD_I##format##_SPLAT(WASM_GET_LOCAL(val2))), \
WASM_SET_LOCAL(zero, WASM_SIMD_I##format##_SPLAT(WASM_ZERO)), \
WASM_SET_LOCAL(mask, WASM_SIMD_I##format##_REPLACE_LANE( \
1, WASM_GET_LOCAL(zero), WASM_I32V(0xF))), \
WASM_SET_LOCAL(mask, WASM_SIMD_I##format##_REPLACE_LANE( \
2, WASM_GET_LOCAL(mask), WASM_I32V(0xF))), \
WASM_SET_LOCAL(mask, WASM_SIMD_SELECT(format, WASM_GET_LOCAL(src1), \
WASM_GET_LOCAL(src2), \
WASM_GET_LOCAL(mask))), \
WASM_SIMD_CHECK_LANE(I##format, mask, I32, val2, 0), \
WASM_SIMD_CHECK_LANE(I##format, mask, I32, combined, 1), \
WASM_SIMD_CHECK_LANE(I##format, mask, I32, combined, 2), \
WASM_SIMD_CHECK_LANE(I##format, mask, I32, val2, 3), WASM_ONE); \
\
CHECK_EQ(1, r.Call(0x12, 0x34, 0x32)); \
}
WASM_SIMD_NON_CANONICAL_SELECT_TEST(32x4)
WASM_SIMD_NON_CANONICAL_SELECT_TEST(16x8)
WASM_SIMD_NON_CANONICAL_SELECT_TEST(8x16)
// Test binary ops with two lane test patterns, all lanes distinct.
template <typename T>
void RunBinaryLaneOpTest(
ExecutionTier execution_tier, LowerSimd lower_simd, WasmOpcode simd_op,
const std::array<T, kSimd128Size / sizeof(T)>& expected) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
// Set up two test patterns as globals, e.g. [0, 1, 2, 3] and [4, 5, 6, 7].
T* src0 = r.builder().AddGlobal<T>(kWasmS128);
T* src1 = r.builder().AddGlobal<T>(kWasmS128);
static const int kElems = kSimd128Size / sizeof(T);
for (int i = 0; i < kElems; i++) {
WriteLittleEndianValue<T>(&src0[i], i);
WriteLittleEndianValue<T>(&src1[i], kElems + i);
}
if (simd_op == kExprS8x16Shuffle) {
BUILD(r,
WASM_SET_GLOBAL(0, WASM_SIMD_S8x16_SHUFFLE_OP(simd_op, expected,
WASM_GET_GLOBAL(0),
WASM_GET_GLOBAL(1))),
WASM_ONE);
} else {
BUILD(r,
WASM_SET_GLOBAL(0, WASM_SIMD_BINOP(simd_op, WASM_GET_GLOBAL(0),
WASM_GET_GLOBAL(1))),
WASM_ONE);
}
CHECK_EQ(1, r.Call());
for (size_t i = 0; i < expected.size(); i++) {
CHECK_EQ(ReadLittleEndianValue<T>(&src0[i]), expected[i]);
}
}
WASM_SIMD_TEST(I32x4AddHoriz) {
// Inputs are [0 1 2 3] and [4 5 6 7].
RunBinaryLaneOpTest<int32_t>(execution_tier, lower_simd, kExprI32x4AddHoriz,
{{1, 5, 9, 13}});
}
WASM_SIMD_TEST(I16x8AddHoriz) {
// Inputs are [0 1 2 3 4 5 6 7] and [8 9 10 11 12 13 14 15].
RunBinaryLaneOpTest<int16_t>(execution_tier, lower_simd, kExprI16x8AddHoriz,
{{1, 5, 9, 13, 17, 21, 25, 29}});
}
WASM_SIMD_TEST(F32x4AddHoriz) {
// Inputs are [0.0f 1.0f 2.0f 3.0f] and [4.0f 5.0f 6.0f 7.0f].
RunBinaryLaneOpTest<float>(execution_tier, lower_simd, kExprF32x4AddHoriz,
{{1.0f, 5.0f, 9.0f, 13.0f}});
}
// Test shuffle ops.
void RunShuffleOpTest(ExecutionTier execution_tier, LowerSimd lower_simd,
WasmOpcode simd_op,
const std::array<int8_t, kSimd128Size>& shuffle) {
// Test the original shuffle.
RunBinaryLaneOpTest<int8_t>(execution_tier, lower_simd, simd_op, shuffle);
// Test a non-canonical (inputs reversed) version of the shuffle.
std::array<int8_t, kSimd128Size> other_shuffle(shuffle);
for (size_t i = 0; i < shuffle.size(); ++i) other_shuffle[i] ^= kSimd128Size;
RunBinaryLaneOpTest<int8_t>(execution_tier, lower_simd, simd_op,
other_shuffle);
// Test the swizzle (one-operand) version of the shuffle.
std::array<int8_t, kSimd128Size> swizzle(shuffle);
for (size_t i = 0; i < shuffle.size(); ++i) swizzle[i] &= (kSimd128Size - 1);
RunBinaryLaneOpTest<int8_t>(execution_tier, lower_simd, simd_op, swizzle);
// Test the non-canonical swizzle (one-operand) version of the shuffle.
std::array<int8_t, kSimd128Size> other_swizzle(shuffle);
for (size_t i = 0; i < shuffle.size(); ++i) other_swizzle[i] |= kSimd128Size;
RunBinaryLaneOpTest<int8_t>(execution_tier, lower_simd, simd_op,
other_swizzle);
}
#define SHUFFLE_LIST(V) \
V(S128Identity) \
V(S32x4Dup) \
V(S32x4ZipLeft) \
V(S32x4ZipRight) \
V(S32x4UnzipLeft) \
V(S32x4UnzipRight) \
V(S32x4TransposeLeft) \
V(S32x4TransposeRight) \
V(S32x2Reverse) \
V(S32x4Irregular) \
V(S16x8Dup) \
V(S16x8ZipLeft) \
V(S16x8ZipRight) \
V(S16x8UnzipLeft) \
V(S16x8UnzipRight) \
V(S16x8TransposeLeft) \
V(S16x8TransposeRight) \
V(S16x4Reverse) \
V(S16x2Reverse) \
V(S16x8Irregular) \
V(S8x16Dup) \
V(S8x16ZipLeft) \
V(S8x16ZipRight) \
V(S8x16UnzipLeft) \
V(S8x16UnzipRight) \
V(S8x16TransposeLeft) \
V(S8x16TransposeRight) \
V(S8x8Reverse) \
V(S8x4Reverse) \
V(S8x2Reverse) \
V(S8x16Irregular)
enum ShuffleKey {
#define SHUFFLE_ENUM_VALUE(Name) k##Name,
SHUFFLE_LIST(SHUFFLE_ENUM_VALUE)
#undef SHUFFLE_ENUM_VALUE
kNumShuffleKeys
};
using Shuffle = std::array<int8_t, kSimd128Size>;
using ShuffleMap = std::map<ShuffleKey, const Shuffle>;
ShuffleMap test_shuffles = {
{kS128Identity,
{{16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31}}},
{kS32x4Dup,
{{16, 17, 18, 19, 16, 17, 18, 19, 16, 17, 18, 19, 16, 17, 18, 19}}},
{kS32x4ZipLeft, {{0, 1, 2, 3, 16, 17, 18, 19, 4, 5, 6, 7, 20, 21, 22, 23}}},
{kS32x4ZipRight,
{{8, 9, 10, 11, 24, 25, 26, 27, 12, 13, 14, 15, 28, 29, 30, 31}}},
{kS32x4UnzipLeft,
{{0, 1, 2, 3, 8, 9, 10, 11, 16, 17, 18, 19, 24, 25, 26, 27}}},
{kS32x4UnzipRight,
{{4, 5, 6, 7, 12, 13, 14, 15, 20, 21, 22, 23, 28, 29, 30, 31}}},
{kS32x4TransposeLeft,
{{0, 1, 2, 3, 16, 17, 18, 19, 8, 9, 10, 11, 24, 25, 26, 27}}},
{kS32x4TransposeRight,
{{4, 5, 6, 7, 20, 21, 22, 23, 12, 13, 14, 15, 28, 29, 30, 31}}},
{kS32x2Reverse, // swizzle only
{{4, 5, 6, 7, 0, 1, 2, 3, 12, 13, 14, 15, 8, 9, 10, 11}}},
{kS32x4Irregular,
{{0, 1, 2, 3, 16, 17, 18, 19, 16, 17, 18, 19, 20, 21, 22, 23}}},
{kS16x8Dup,
{{18, 19, 18, 19, 18, 19, 18, 19, 18, 19, 18, 19, 18, 19, 18, 19}}},
{kS16x8ZipLeft, {{0, 1, 16, 17, 2, 3, 18, 19, 4, 5, 20, 21, 6, 7, 22, 23}}},
{kS16x8ZipRight,
{{8, 9, 24, 25, 10, 11, 26, 27, 12, 13, 28, 29, 14, 15, 30, 31}}},
{kS16x8UnzipLeft,
{{0, 1, 4, 5, 8, 9, 12, 13, 16, 17, 20, 21, 24, 25, 28, 29}}},
{kS16x8UnzipRight,
{{2, 3, 6, 7, 10, 11, 14, 15, 18, 19, 22, 23, 26, 27, 30, 31}}},
{kS16x8TransposeLeft,
{{0, 1, 16, 17, 4, 5, 20, 21, 8, 9, 24, 25, 12, 13, 28, 29}}},
{kS16x8TransposeRight,
{{2, 3, 18, 19, 6, 7, 22, 23, 10, 11, 26, 27, 14, 15, 30, 31}}},
{kS16x4Reverse, // swizzle only
{{6, 7, 4, 5, 2, 3, 0, 1, 14, 15, 12, 13, 10, 11, 8, 9}}},
{kS16x2Reverse, // swizzle only
{{2, 3, 0, 1, 6, 7, 4, 5, 10, 11, 8, 9, 14, 15, 12, 13}}},
{kS16x8Irregular,
{{0, 1, 16, 17, 16, 17, 0, 1, 4, 5, 20, 21, 6, 7, 22, 23}}},
{kS8x16Dup,
{{19, 19, 19, 19, 19, 19, 19, 19, 19, 19, 19, 19, 19, 19, 19, 19}}},
{kS8x16ZipLeft, {{0, 16, 1, 17, 2, 18, 3, 19, 4, 20, 5, 21, 6, 22, 7, 23}}},
{kS8x16ZipRight,
{{8, 24, 9, 25, 10, 26, 11, 27, 12, 28, 13, 29, 14, 30, 15, 31}}},
{kS8x16UnzipLeft,
{{0, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28, 30}}},
{kS8x16UnzipRight,
{{1, 3, 5, 7, 9, 11, 13, 15, 17, 19, 21, 23, 25, 27, 29, 31}}},
{kS8x16TransposeLeft,
{{0, 16, 2, 18, 4, 20, 6, 22, 8, 24, 10, 26, 12, 28, 14, 30}}},
{kS8x16TransposeRight,
{{1, 17, 3, 19, 5, 21, 7, 23, 9, 25, 11, 27, 13, 29, 15, 31}}},
{kS8x8Reverse, // swizzle only
{{7, 6, 5, 4, 3, 2, 1, 0, 15, 14, 13, 12, 11, 10, 9, 8}}},
{kS8x4Reverse, // swizzle only
{{3, 2, 1, 0, 7, 6, 5, 4, 11, 10, 9, 8, 15, 14, 13, 12}}},
{kS8x2Reverse, // swizzle only
{{1, 0, 3, 2, 5, 4, 7, 6, 9, 8, 11, 10, 13, 12, 15, 14}}},
{kS8x16Irregular,
{{0, 16, 0, 16, 2, 18, 3, 19, 4, 20, 5, 21, 6, 22, 7, 23}}},
};
#define SHUFFLE_TEST(Name) \
WASM_SIMD_TEST(Name) { \
ShuffleMap::const_iterator it = test_shuffles.find(k##Name); \
DCHECK_NE(it, test_shuffles.end()); \
RunShuffleOpTest(execution_tier, lower_simd, kExprS8x16Shuffle, \
it->second); \
}
SHUFFLE_LIST(SHUFFLE_TEST)
#undef SHUFFLE_TEST
#undef SHUFFLE_LIST
// Test shuffles that blend the two vectors (elements remain in their lanes.)
WASM_SIMD_TEST(S8x16Blend) {
std::array<int8_t, kSimd128Size> expected;
for (int bias = 1; bias < kSimd128Size; bias++) {
for (int i = 0; i < bias; i++) expected[i] = i;
for (int i = bias; i < kSimd128Size; i++) expected[i] = i + kSimd128Size;
RunShuffleOpTest(execution_tier, lower_simd, kExprS8x16Shuffle, expected);
}
}
// Test shuffles that concatenate the two vectors.
WASM_SIMD_TEST(S8x16Concat) {
std::array<int8_t, kSimd128Size> expected;
// n is offset or bias of concatenation.
for (int n = 1; n < kSimd128Size; ++n) {
int i = 0;
// last kLanes - n bytes of first vector.
for (int j = n; j < kSimd128Size; ++j) {
expected[i++] = j;
}
// first n bytes of second vector
for (int j = 0; j < n; ++j) {
expected[i++] = j + kSimd128Size;
}
RunShuffleOpTest(execution_tier, lower_simd, kExprS8x16Shuffle, expected);
}
}
// Combine 3 shuffles a, b, and c by applying both a and b and then applying c
// to those two results.
Shuffle Combine(const Shuffle& a, const Shuffle& b, const Shuffle& c) {
Shuffle result;
for (int i = 0; i < kSimd128Size; ++i) {
result[i] = c[i] < kSimd128Size ? a[c[i]] : b[c[i] - kSimd128Size];
}
return result;
}
const Shuffle& GetRandomTestShuffle(v8::base::RandomNumberGenerator* rng) {
return test_shuffles[static_cast<ShuffleKey>(rng->NextInt(kNumShuffleKeys))];
}
// Test shuffles that are random combinations of 3 test shuffles. Completely
// random shuffles almost always generate the slow general shuffle code, so
// don't exercise as many code paths.
WASM_SIMD_TEST(S8x16ShuffleFuzz) {
v8::base::RandomNumberGenerator* rng = CcTest::random_number_generator();
static const int kTests = 100;
for (int i = 0; i < kTests; ++i) {
auto shuffle = Combine(GetRandomTestShuffle(rng), GetRandomTestShuffle(rng),
GetRandomTestShuffle(rng));
RunShuffleOpTest(execution_tier, lower_simd, kExprS8x16Shuffle, shuffle);
}
}
void AppendShuffle(const Shuffle& shuffle, std::vector<byte>* buffer) {
byte opcode[] = {WASM_SIMD_OP(kExprS8x16Shuffle)};
for (size_t i = 0; i < arraysize(opcode); ++i) buffer->push_back(opcode[i]);
for (size_t i = 0; i < kSimd128Size; ++i) buffer->push_back((shuffle[i]));
}
void BuildShuffle(const std::vector<Shuffle>& shuffles,
std::vector<byte>* buffer) {
// Perform the leaf shuffles on globals 0 and 1.
size_t row_index = (shuffles.size() - 1) / 2;
for (size_t i = row_index; i < shuffles.size(); ++i) {
byte operands[] = {WASM_GET_GLOBAL(0), WASM_GET_GLOBAL(1)};
for (size_t j = 0; j < arraysize(operands); ++j)
buffer->push_back(operands[j]);
AppendShuffle(shuffles[i], buffer);
}
// Now perform inner shuffles in the correct order on operands on the stack.
do {
for (size_t i = row_index / 2; i < row_index; ++i) {
AppendShuffle(shuffles[i], buffer);
}
row_index /= 2;
} while (row_index != 0);
byte epilog[] = {kExprGlobalSet, static_cast<byte>(0), WASM_ONE};
for (size_t j = 0; j < arraysize(epilog); ++j) buffer->push_back(epilog[j]);
}
void RunWasmCode(ExecutionTier execution_tier, LowerSimd lower_simd,
const std::vector<byte>& code,
std::array<int8_t, kSimd128Size>* result) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
// Set up two test patterns as globals, e.g. [0, 1, 2, 3] and [4, 5, 6, 7].
int8_t* src0 = r.builder().AddGlobal<int8_t>(kWasmS128);
int8_t* src1 = r.builder().AddGlobal<int8_t>(kWasmS128);
for (int i = 0; i < kSimd128Size; ++i) {
WriteLittleEndianValue<int8_t>(&src0[i], i);
WriteLittleEndianValue<int8_t>(&src1[i], kSimd128Size + i);
}
r.Build(code.data(), code.data() + code.size());
CHECK_EQ(1, r.Call());
for (size_t i = 0; i < kSimd128Size; i++) {
(*result)[i] = ReadLittleEndianValue<int8_t>(&src0[i]);
}
}
// Test multiple shuffles executed in sequence.
WASM_SIMD_COMPILED_TEST(S8x16MultiShuffleFuzz) {
v8::base::RandomNumberGenerator* rng = CcTest::random_number_generator();
static const int kShuffles = 100;
for (int i = 0; i < kShuffles; ++i) {
// Create an odd number in [3..23] of random test shuffles so we can build
// a complete binary tree (stored as a heap) of shuffle operations. The leaf
// shuffles operate on the test pattern inputs, while the interior shuffles
// operate on the results of the two child shuffles.
int num_shuffles = rng->NextInt(10) * 2 + 3;
std::vector<Shuffle> shuffles;
for (int j = 0; j < num_shuffles; ++j) {
shuffles.push_back(GetRandomTestShuffle(rng));
}
// Generate the code for the shuffle expression.
std::vector<byte> buffer;
BuildShuffle(shuffles, &buffer);
// Run the code using the interpreter to get the expected result.
std::array<int8_t, kSimd128Size> expected;
RunWasmCode(ExecutionTier::kInterpreter, kNoLowerSimd, buffer, &expected);
// Run the SIMD or scalar lowered compiled code and compare results.
std::array<int8_t, kSimd128Size> result;
RunWasmCode(execution_tier, lower_simd, buffer, &result);
for (size_t i = 0; i < kSimd128Size; ++i) {
CHECK_EQ(result[i], expected[i]);
}
}
}
// Boolean unary operations are 'AllTrue' and 'AnyTrue', which return an integer
// result. Use relational ops on numeric vectors to create the boolean vector
// test inputs. Test inputs with all true, all false, one true, and one false.
#define WASM_SIMD_BOOL_REDUCTION_TEST(format, lanes, int_type) \
WASM_SIMD_TEST(ReductionTest##lanes) { \
WasmRunner<int32_t> r(execution_tier, lower_simd); \
if (lanes == 2 && lower_simd == kLowerSimd) return; \
byte zero = r.AllocateLocal(kWasmS128); \
byte one_one = r.AllocateLocal(kWasmS128); \
byte reduced = r.AllocateLocal(kWasmI32); \
BUILD(r, WASM_SET_LOCAL(zero, WASM_SIMD_I##format##_SPLAT(int_type(0))), \
WASM_SET_LOCAL( \
reduced, WASM_SIMD_UNOP(kExprS1x##lanes##AnyTrue, \
WASM_SIMD_BINOP(kExprI##format##Eq, \
WASM_GET_LOCAL(zero), \
WASM_GET_LOCAL(zero)))), \
WASM_IF(WASM_I32_EQ(WASM_GET_LOCAL(reduced), WASM_ZERO), \
WASM_RETURN1(WASM_ZERO)), \
WASM_SET_LOCAL( \
reduced, WASM_SIMD_UNOP(kExprS1x##lanes##AnyTrue, \
WASM_SIMD_BINOP(kExprI##format##Ne, \
WASM_GET_LOCAL(zero), \
WASM_GET_LOCAL(zero)))), \
WASM_IF(WASM_I32_NE(WASM_GET_LOCAL(reduced), WASM_ZERO), \
WASM_RETURN1(WASM_ZERO)), \
WASM_SET_LOCAL( \
reduced, WASM_SIMD_UNOP(kExprS1x##lanes##AllTrue, \
WASM_SIMD_BINOP(kExprI##format##Eq, \
WASM_GET_LOCAL(zero), \
WASM_GET_LOCAL(zero)))), \
WASM_IF(WASM_I32_EQ(WASM_GET_LOCAL(reduced), WASM_ZERO), \
WASM_RETURN1(WASM_ZERO)), \
WASM_SET_LOCAL( \
reduced, WASM_SIMD_UNOP(kExprS1x##lanes##AllTrue, \
WASM_SIMD_BINOP(kExprI##format##Ne, \
WASM_GET_LOCAL(zero), \
WASM_GET_LOCAL(zero)))), \
WASM_IF(WASM_I32_NE(WASM_GET_LOCAL(reduced), WASM_ZERO), \
WASM_RETURN1(WASM_ZERO)), \
WASM_SET_LOCAL(one_one, \
WASM_SIMD_I##format##_REPLACE_LANE( \
lanes - 1, WASM_GET_LOCAL(zero), int_type(1))), \
WASM_SET_LOCAL( \
reduced, WASM_SIMD_UNOP(kExprS1x##lanes##AnyTrue, \
WASM_SIMD_BINOP(kExprI##format##Eq, \
WASM_GET_LOCAL(one_one), \
WASM_GET_LOCAL(zero)))), \
WASM_IF(WASM_I32_EQ(WASM_GET_LOCAL(reduced), WASM_ZERO), \
WASM_RETURN1(WASM_ZERO)), \
WASM_SET_LOCAL( \
reduced, WASM_SIMD_UNOP(kExprS1x##lanes##AnyTrue, \
WASM_SIMD_BINOP(kExprI##format##Ne, \
WASM_GET_LOCAL(one_one), \
WASM_GET_LOCAL(zero)))), \
WASM_IF(WASM_I32_EQ(WASM_GET_LOCAL(reduced), WASM_ZERO), \
WASM_RETURN1(WASM_ZERO)), \
WASM_SET_LOCAL( \
reduced, WASM_SIMD_UNOP(kExprS1x##lanes##AllTrue, \
WASM_SIMD_BINOP(kExprI##format##Eq, \
WASM_GET_LOCAL(one_one), \
WASM_GET_LOCAL(zero)))), \
WASM_IF(WASM_I32_NE(WASM_GET_LOCAL(reduced), WASM_ZERO), \
WASM_RETURN1(WASM_ZERO)), \
WASM_SET_LOCAL( \
reduced, WASM_SIMD_UNOP(kExprS1x##lanes##AllTrue, \
WASM_SIMD_BINOP(kExprI##format##Ne, \
WASM_GET_LOCAL(one_one), \
WASM_GET_LOCAL(zero)))), \
WASM_IF(WASM_I32_NE(WASM_GET_LOCAL(reduced), WASM_ZERO), \
WASM_RETURN1(WASM_ZERO)), \
WASM_ONE); \
CHECK_EQ(1, r.Call()); \
}
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_BOOL_REDUCTION_TEST(64x2, 2, WASM_I64V)
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_BOOL_REDUCTION_TEST(32x4, 4, WASM_I32V)
WASM_SIMD_BOOL_REDUCTION_TEST(16x8, 8, WASM_I32V)
WASM_SIMD_BOOL_REDUCTION_TEST(8x16, 16, WASM_I32V)
WASM_SIMD_TEST(SimdI32x4ExtractWithF32x4) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
BUILD(r, WASM_IF_ELSE_I(
WASM_I32_EQ(WASM_SIMD_I32x4_EXTRACT_LANE(
0, WASM_SIMD_F32x4_SPLAT(WASM_F32(30.5))),
WASM_I32_REINTERPRET_F32(WASM_F32(30.5))),
WASM_I32V(1), WASM_I32V(0)));
CHECK_EQ(1, r.Call());
}
WASM_SIMD_TEST(SimdF32x4ExtractWithI32x4) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
BUILD(r,
WASM_IF_ELSE_I(WASM_F32_EQ(WASM_SIMD_F32x4_EXTRACT_LANE(
0, WASM_SIMD_I32x4_SPLAT(WASM_I32V(15))),
WASM_F32_REINTERPRET_I32(WASM_I32V(15))),
WASM_I32V(1), WASM_I32V(0)));
CHECK_EQ(1, r.Call());
}
WASM_SIMD_TEST(SimdF32x4ExtractLane) {
WasmRunner<float> r(execution_tier, lower_simd);
r.AllocateLocal(kWasmF32);
r.AllocateLocal(kWasmS128);
BUILD(r,
WASM_SET_LOCAL(0, WASM_SIMD_F32x4_EXTRACT_LANE(
0, WASM_SIMD_F32x4_SPLAT(WASM_F32(30.5)))),
WASM_SET_LOCAL(1, WASM_SIMD_F32x4_SPLAT(WASM_GET_LOCAL(0))),
WASM_SIMD_F32x4_EXTRACT_LANE(1, WASM_GET_LOCAL(1)));
CHECK_EQ(30.5, r.Call());
}
WASM_SIMD_TEST(SimdF32x4AddWithI32x4) {
// Choose two floating point values whose sum is normal and exactly
// representable as a float.
const int kOne = 0x3F800000;
const int kTwo = 0x40000000;
WasmRunner<int32_t> r(execution_tier, lower_simd);
BUILD(r,
WASM_IF_ELSE_I(
WASM_F32_EQ(
WASM_SIMD_F32x4_EXTRACT_LANE(
0, WASM_SIMD_BINOP(kExprF32x4Add,
WASM_SIMD_I32x4_SPLAT(WASM_I32V(kOne)),
WASM_SIMD_I32x4_SPLAT(WASM_I32V(kTwo)))),
WASM_F32_ADD(WASM_F32_REINTERPRET_I32(WASM_I32V(kOne)),
WASM_F32_REINTERPRET_I32(WASM_I32V(kTwo)))),
WASM_I32V(1), WASM_I32V(0)));
CHECK_EQ(1, r.Call());
}
WASM_SIMD_TEST(SimdI32x4AddWithF32x4) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
BUILD(r,
WASM_IF_ELSE_I(
WASM_I32_EQ(
WASM_SIMD_I32x4_EXTRACT_LANE(
0, WASM_SIMD_BINOP(kExprI32x4Add,
WASM_SIMD_F32x4_SPLAT(WASM_F32(21.25)),
WASM_SIMD_F32x4_SPLAT(WASM_F32(31.5)))),
WASM_I32_ADD(WASM_I32_REINTERPRET_F32(WASM_F32(21.25)),
WASM_I32_REINTERPRET_F32(WASM_F32(31.5)))),
WASM_I32V(1), WASM_I32V(0)));
CHECK_EQ(1, r.Call());
}
WASM_SIMD_TEST(SimdI32x4Local) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(0, WASM_SIMD_I32x4_SPLAT(WASM_I32V(31))),
WASM_SIMD_I32x4_EXTRACT_LANE(0, WASM_GET_LOCAL(0)));
CHECK_EQ(31, r.Call());
}
WASM_SIMD_TEST(SimdI32x4SplatFromExtract) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
r.AllocateLocal(kWasmI32);
r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(0, WASM_SIMD_I32x4_EXTRACT_LANE(
0, WASM_SIMD_I32x4_SPLAT(WASM_I32V(76)))),
WASM_SET_LOCAL(1, WASM_SIMD_I32x4_SPLAT(WASM_GET_LOCAL(0))),
WASM_SIMD_I32x4_EXTRACT_LANE(1, WASM_GET_LOCAL(1)));
CHECK_EQ(76, r.Call());
}
WASM_SIMD_TEST(SimdI32x4For) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
r.AllocateLocal(kWasmI32);
r.AllocateLocal(kWasmS128);
BUILD(r,
WASM_SET_LOCAL(1, WASM_SIMD_I32x4_SPLAT(WASM_I32V(31))),
WASM_SET_LOCAL(1, WASM_SIMD_I32x4_REPLACE_LANE(1, WASM_GET_LOCAL(1),
WASM_I32V(53))),
WASM_SET_LOCAL(1, WASM_SIMD_I32x4_REPLACE_LANE(2, WASM_GET_LOCAL(1),
WASM_I32V(23))),
WASM_SET_LOCAL(0, WASM_I32V(0)),
WASM_LOOP(
WASM_SET_LOCAL(
1, WASM_SIMD_BINOP(kExprI32x4Add, WASM_GET_LOCAL(1),
WASM_SIMD_I32x4_SPLAT(WASM_I32V(1)))),
WASM_IF(WASM_I32_NE(WASM_INC_LOCAL(0), WASM_I32V(5)), WASM_BR(1))),
WASM_SET_LOCAL(0, WASM_I32V(1)),
WASM_IF(WASM_I32_NE(WASM_SIMD_I32x4_EXTRACT_LANE(0, WASM_GET_LOCAL(1)),
WASM_I32V(36)),
WASM_SET_LOCAL(0, WASM_I32V(0))),
WASM_IF(WASM_I32_NE(WASM_SIMD_I32x4_EXTRACT_LANE(1, WASM_GET_LOCAL(1)),
WASM_I32V(58)),
WASM_SET_LOCAL(0, WASM_I32V(0))),
WASM_IF(WASM_I32_NE(WASM_SIMD_I32x4_EXTRACT_LANE(2, WASM_GET_LOCAL(1)),
WASM_I32V(28)),
WASM_SET_LOCAL(0, WASM_I32V(0))),
WASM_IF(WASM_I32_NE(WASM_SIMD_I32x4_EXTRACT_LANE(3, WASM_GET_LOCAL(1)),
WASM_I32V(36)),
WASM_SET_LOCAL(0, WASM_I32V(0))),
WASM_GET_LOCAL(0));
CHECK_EQ(1, r.Call());
}
WASM_SIMD_TEST(SimdF32x4For) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
r.AllocateLocal(kWasmI32);
r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(1, WASM_SIMD_F32x4_SPLAT(WASM_F32(21.25))),
WASM_SET_LOCAL(1, WASM_SIMD_F32x4_REPLACE_LANE(3, WASM_GET_LOCAL(1),
WASM_F32(19.5))),
WASM_SET_LOCAL(0, WASM_I32V(0)),
WASM_LOOP(
WASM_SET_LOCAL(
1, WASM_SIMD_BINOP(kExprF32x4Add, WASM_GET_LOCAL(1),
WASM_SIMD_F32x4_SPLAT(WASM_F32(2.0)))),
WASM_IF(WASM_I32_NE(WASM_INC_LOCAL(0), WASM_I32V(3)), WASM_BR(1))),
WASM_SET_LOCAL(0, WASM_I32V(1)),
WASM_IF(WASM_F32_NE(WASM_SIMD_F32x4_EXTRACT_LANE(0, WASM_GET_LOCAL(1)),
WASM_F32(27.25)),
WASM_SET_LOCAL(0, WASM_I32V(0))),
WASM_IF(WASM_F32_NE(WASM_SIMD_F32x4_EXTRACT_LANE(3, WASM_GET_LOCAL(1)),
WASM_F32(25.5)),
WASM_SET_LOCAL(0, WASM_I32V(0))),
WASM_GET_LOCAL(0));
CHECK_EQ(1, r.Call());
}
template <typename T, int numLanes = 4>
void SetVectorByLanes(T* v, const std::array<T, numLanes>& arr) {
for (int lane = 0; lane < numLanes; lane++) {
WriteLittleEndianValue<T>(&v[lane], arr[lane]);
}
}
template <typename T>
const T GetScalar(T* v, int lane) {
constexpr int kElems = kSimd128Size / sizeof(T);
const int index = lane;
USE(kElems);
DCHECK(index >= 0 && index < kElems);
return ReadLittleEndianValue<T>(&v[index]);
}
WASM_SIMD_TEST(SimdI32x4GetGlobal) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Pad the globals with a few unused slots to get a non-zero offset.
r.builder().AddGlobal<int32_t>(kWasmI32); // purposefully unused
r.builder().AddGlobal<int32_t>(kWasmI32); // purposefully unused
r.builder().AddGlobal<int32_t>(kWasmI32); // purposefully unused
r.builder().AddGlobal<int32_t>(kWasmI32); // purposefully unused
int32_t* global = r.builder().AddGlobal<int32_t>(kWasmS128);
SetVectorByLanes(global, {{0, 1, 2, 3}});
r.AllocateLocal(kWasmI32);
BUILD(
r, WASM_SET_LOCAL(1, WASM_I32V(1)),
WASM_IF(WASM_I32_NE(WASM_I32V(0),
WASM_SIMD_I32x4_EXTRACT_LANE(0, WASM_GET_GLOBAL(4))),
WASM_SET_LOCAL(1, WASM_I32V(0))),
WASM_IF(WASM_I32_NE(WASM_I32V(1),
WASM_SIMD_I32x4_EXTRACT_LANE(1, WASM_GET_GLOBAL(4))),
WASM_SET_LOCAL(1, WASM_I32V(0))),
WASM_IF(WASM_I32_NE(WASM_I32V(2),
WASM_SIMD_I32x4_EXTRACT_LANE(2, WASM_GET_GLOBAL(4))),
WASM_SET_LOCAL(1, WASM_I32V(0))),
WASM_IF(WASM_I32_NE(WASM_I32V(3),
WASM_SIMD_I32x4_EXTRACT_LANE(3, WASM_GET_GLOBAL(4))),
WASM_SET_LOCAL(1, WASM_I32V(0))),
WASM_GET_LOCAL(1));
CHECK_EQ(1, r.Call(0));
}
WASM_SIMD_TEST(SimdI32x4SetGlobal) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
// Pad the globals with a few unused slots to get a non-zero offset.
r.builder().AddGlobal<int32_t>(kWasmI32); // purposefully unused
r.builder().AddGlobal<int32_t>(kWasmI32); // purposefully unused
r.builder().AddGlobal<int32_t>(kWasmI32); // purposefully unused
r.builder().AddGlobal<int32_t>(kWasmI32); // purposefully unused
int32_t* global = r.builder().AddGlobal<int32_t>(kWasmS128);
BUILD(r, WASM_SET_GLOBAL(4, WASM_SIMD_I32x4_SPLAT(WASM_I32V(23))),
WASM_SET_GLOBAL(4, WASM_SIMD_I32x4_REPLACE_LANE(1, WASM_GET_GLOBAL(4),
WASM_I32V(34))),
WASM_SET_GLOBAL(4, WASM_SIMD_I32x4_REPLACE_LANE(2, WASM_GET_GLOBAL(4),
WASM_I32V(45))),
WASM_SET_GLOBAL(4, WASM_SIMD_I32x4_REPLACE_LANE(3, WASM_GET_GLOBAL(4),
WASM_I32V(56))),
WASM_I32V(1));
CHECK_EQ(1, r.Call(0));
CHECK_EQ(GetScalar(global, 0), 23);
CHECK_EQ(GetScalar(global, 1), 34);
CHECK_EQ(GetScalar(global, 2), 45);
CHECK_EQ(GetScalar(global, 3), 56);
}
WASM_SIMD_TEST(SimdF32x4GetGlobal) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
float* global = r.builder().AddGlobal<float>(kWasmS128);
SetVectorByLanes<float>(global, {{0.0, 1.5, 2.25, 3.5}});
r.AllocateLocal(kWasmI32);
BUILD(
r, WASM_SET_LOCAL(1, WASM_I32V(1)),
WASM_IF(WASM_F32_NE(WASM_F32(0.0),
WASM_SIMD_F32x4_EXTRACT_LANE(0, WASM_GET_GLOBAL(0))),
WASM_SET_LOCAL(1, WASM_I32V(0))),
WASM_IF(WASM_F32_NE(WASM_F32(1.5),
WASM_SIMD_F32x4_EXTRACT_LANE(1, WASM_GET_GLOBAL(0))),
WASM_SET_LOCAL(1, WASM_I32V(0))),
WASM_IF(WASM_F32_NE(WASM_F32(2.25),
WASM_SIMD_F32x4_EXTRACT_LANE(2, WASM_GET_GLOBAL(0))),
WASM_SET_LOCAL(1, WASM_I32V(0))),
WASM_IF(WASM_F32_NE(WASM_F32(3.5),
WASM_SIMD_F32x4_EXTRACT_LANE(3, WASM_GET_GLOBAL(0))),
WASM_SET_LOCAL(1, WASM_I32V(0))),
WASM_GET_LOCAL(1));
CHECK_EQ(1, r.Call(0));
}
WASM_SIMD_TEST(SimdF32x4SetGlobal) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
float* global = r.builder().AddGlobal<float>(kWasmS128);
BUILD(r, WASM_SET_GLOBAL(0, WASM_SIMD_F32x4_SPLAT(WASM_F32(13.5))),
WASM_SET_GLOBAL(0, WASM_SIMD_F32x4_REPLACE_LANE(1, WASM_GET_GLOBAL(0),
WASM_F32(45.5))),
WASM_SET_GLOBAL(0, WASM_SIMD_F32x4_REPLACE_LANE(2, WASM_GET_GLOBAL(0),
WASM_F32(32.25))),
WASM_SET_GLOBAL(0, WASM_SIMD_F32x4_REPLACE_LANE(3, WASM_GET_GLOBAL(0),
WASM_F32(65.0))),
WASM_I32V(1));
CHECK_EQ(1, r.Call(0));
CHECK_EQ(GetScalar(global, 0), 13.5f);
CHECK_EQ(GetScalar(global, 1), 45.5f);
CHECK_EQ(GetScalar(global, 2), 32.25f);
CHECK_EQ(GetScalar(global, 3), 65.0f);
}
WASM_SIMD_TEST(SimdLoadStoreLoad) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
int32_t* memory =
r.builder().AddMemoryElems<int32_t>(kWasmPageSize / sizeof(int32_t));
// Load memory, store it, then reload it and extract the first lane. Use a
// non-zero offset into the memory of 1 lane (4 bytes) to test indexing.
BUILD(r, WASM_SIMD_STORE_MEM(WASM_I32V(4), WASM_SIMD_LOAD_MEM(WASM_I32V(4))),
WASM_SIMD_I32x4_EXTRACT_LANE(0, WASM_SIMD_LOAD_MEM(WASM_I32V(4))));
FOR_INT32_INPUTS(i) {
int32_t expected = i;
r.builder().WriteMemory(&memory[1], expected);
CHECK_EQ(expected, r.Call());
}
}
WASM_SIMD_TEST(SimdLoadStoreLoadMemargOffset) {
WasmRunner<int32_t> r(execution_tier, lower_simd);
int32_t* memory =
r.builder().AddMemoryElems<int32_t>(kWasmPageSize / sizeof(int32_t));
constexpr byte offset_1 = 4;
constexpr byte offset_2 = 8;
// Load from memory at offset_1, store to offset_2, load from offset_2, and
// extract first lane. We use non-zero memarg offsets to test offset decoding.
BUILD(
r,
WASM_SIMD_STORE_MEM_OFFSET(
offset_2, WASM_ZERO, WASM_SIMD_LOAD_MEM_OFFSET(offset_1, WASM_ZERO)),
WASM_SIMD_I32x4_EXTRACT_LANE(
0, WASM_SIMD_LOAD_MEM_OFFSET(offset_2, WASM_ZERO)));
FOR_INT32_INPUTS(i) {
int32_t expected = i;
// Index 1 of memory (int32_t) will be bytes 4 to 8.
r.builder().WriteMemory(&memory[1], expected);
CHECK_EQ(expected, r.Call());
}
}
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_IA32 || V8_TARGET_ARCH_ARM64 || \
V8_TARGET_ARCH_ARM
#define WASM_SIMD_ANYTRUE_TEST(format, lanes, max, param_type) \
WASM_SIMD_TEST(S##format##AnyTrue) { \
WasmRunner<int32_t, param_type> r(execution_tier, lower_simd); \
if (lanes == 2 && lower_simd == kLowerSimd) return; \
byte simd = r.AllocateLocal(kWasmS128); \
BUILD( \
r, \
WASM_SET_LOCAL(simd, WASM_SIMD_I##format##_SPLAT(WASM_GET_LOCAL(0))), \
WASM_SIMD_UNOP(kExprS1x##lanes##AnyTrue, WASM_GET_LOCAL(simd))); \
DCHECK_EQ(1, r.Call(max)); \
DCHECK_EQ(1, r.Call(5)); \
DCHECK_EQ(0, r.Call(0)); \
}
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_ANYTRUE_TEST(64x2, 2, 0xffffffffffffffff, int64_t)
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_ANYTRUE_TEST(32x4, 4, 0xffffffff, int32_t)
WASM_SIMD_ANYTRUE_TEST(16x8, 8, 0xffff, int32_t)
WASM_SIMD_ANYTRUE_TEST(8x16, 16, 0xff, int32_t)
#define WASM_SIMD_ALLTRUE_TEST(format, lanes, max, param_type) \
WASM_SIMD_TEST(S##format##AllTrue) { \
WasmRunner<int32_t, param_type> r(execution_tier, lower_simd); \
if (lanes == 2 && lower_simd == kLowerSimd) return; \
byte simd = r.AllocateLocal(kWasmS128); \
BUILD( \
r, \
WASM_SET_LOCAL(simd, WASM_SIMD_I##format##_SPLAT(WASM_GET_LOCAL(0))), \
WASM_SIMD_UNOP(kExprS1x##lanes##AllTrue, WASM_GET_LOCAL(simd))); \
DCHECK_EQ(1, r.Call(max)); \
DCHECK_EQ(1, r.Call(0x1)); \
DCHECK_EQ(0, r.Call(0)); \
}
#if V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_ALLTRUE_TEST(64x2, 2, 0xffffffffffffffff, int64_t)
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_ARM64
WASM_SIMD_ALLTRUE_TEST(32x4, 4, 0xffffffff, int32_t)
WASM_SIMD_ALLTRUE_TEST(16x8, 8, 0xffff, int32_t)
WASM_SIMD_ALLTRUE_TEST(8x16, 16, 0xff, int32_t)
#endif // V8_TARGET_ARCH_X64 || V8_TARGET_ARCH_IA32 || V8_TARGET_ARCH_ARM64 ||
// V8_TARGET_ARCH_ARM
WASM_SIMD_TEST(BitSelect) {
WasmRunner<int32_t, int32_t> r(execution_tier, lower_simd);
byte simd = r.AllocateLocal(kWasmS128);
BUILD(r,
WASM_SET_LOCAL(
simd,
WASM_SIMD_SELECT(32x4, WASM_SIMD_I32x4_SPLAT(WASM_I32V(0x01020304)),
WASM_SIMD_I32x4_SPLAT(WASM_I32V(0)),
WASM_SIMD_I32x4_SPLAT(WASM_GET_LOCAL(0)))),
WASM_SIMD_I32x4_EXTRACT_LANE(0, WASM_GET_LOCAL(simd)));
DCHECK_EQ(0x01020304, r.Call(0xFFFFFFFF));
}
void RunI8x16MixedRelationalOpTest(ExecutionTier execution_tier,
LowerSimd lower_simd, WasmOpcode opcode,
Int8BinOp expected_op) {
WasmRunner<int32_t, int32_t, int32_t> r(execution_tier, lower_simd);
byte value1 = 0, value2 = 1;
byte temp1 = r.AllocateLocal(kWasmS128);
byte temp2 = r.AllocateLocal(kWasmS128);
byte temp3 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I8x16_SPLAT(WASM_GET_LOCAL(value1))),
WASM_SET_LOCAL(temp2, WASM_SIMD_I16x8_SPLAT(WASM_GET_LOCAL(value2))),
WASM_SET_LOCAL(temp3, WASM_SIMD_BINOP(opcode, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp2))),
WASM_SIMD_I8x16_EXTRACT_LANE(0, WASM_GET_LOCAL(temp3)));
DCHECK_EQ(expected_op(0xff, static_cast<uint8_t>(0x7fff)),
r.Call(0xff, 0x7fff));
DCHECK_EQ(expected_op(0xfe, static_cast<uint8_t>(0x7fff)),
r.Call(0xfe, 0x7fff));
DCHECK_EQ(expected_op(0xff, static_cast<uint8_t>(0x7ffe)),
r.Call(0xff, 0x7ffe));
}
WASM_SIMD_TEST_NO_LOWERING(I8x16LeUMixed) {
RunI8x16MixedRelationalOpTest(execution_tier, lower_simd, kExprI8x16LeU,
UnsignedLessEqual);
}
WASM_SIMD_TEST_NO_LOWERING(I8x16LtUMixed) {
RunI8x16MixedRelationalOpTest(execution_tier, lower_simd, kExprI8x16LtU,
UnsignedLess);
}
WASM_SIMD_TEST_NO_LOWERING(I8x16GeUMixed) {
RunI8x16MixedRelationalOpTest(execution_tier, lower_simd, kExprI8x16GeU,
UnsignedGreaterEqual);
}
WASM_SIMD_TEST_NO_LOWERING(I8x16GtUMixed) {
RunI8x16MixedRelationalOpTest(execution_tier, lower_simd, kExprI8x16GtU,
UnsignedGreater);
}
void RunI16x8MixedRelationalOpTest(ExecutionTier execution_tier,
LowerSimd lower_simd, WasmOpcode opcode,
Int16BinOp expected_op) {
WasmRunner<int32_t, int32_t, int32_t> r(execution_tier, lower_simd);
byte value1 = 0, value2 = 1;
byte temp1 = r.AllocateLocal(kWasmS128);
byte temp2 = r.AllocateLocal(kWasmS128);
byte temp3 = r.AllocateLocal(kWasmS128);
BUILD(r, WASM_SET_LOCAL(temp1, WASM_SIMD_I16x8_SPLAT(WASM_GET_LOCAL(value1))),
WASM_SET_LOCAL(temp2, WASM_SIMD_I32x4_SPLAT(WASM_GET_LOCAL(value2))),
WASM_SET_LOCAL(temp3, WASM_SIMD_BINOP(opcode, WASM_GET_LOCAL(temp1),
WASM_GET_LOCAL(temp2))),
WASM_SIMD_I16x8_EXTRACT_LANE(0, WASM_GET_LOCAL(temp3)));
DCHECK_EQ(expected_op(0xffff, static_cast<uint16_t>(0x7fffffff)),
r.Call(0xffff, 0x7fffffff));
DCHECK_EQ(expected_op(0xfeff, static_cast<uint16_t>(0x7fffffff)),
r.Call(0xfeff, 0x7fffffff));
DCHECK_EQ(expected_op(0xffff, static_cast<uint16_t>(0x7ffffeff)),
r.Call(0xffff, 0x7ffffeff));
}
WASM_SIMD_TEST_NO_LOWERING(I16x8LeUMixed) {
RunI16x8MixedRelationalOpTest(execution_tier, lower_simd, kExprI16x8LeU,
UnsignedLessEqual);
}
WASM_SIMD_TEST_NO_LOWERING(I16x8LtUMixed) {
RunI16x8MixedRelationalOpTest(execution_tier, lower_simd, kExprI16x8LtU,
UnsignedLess);
}
WASM_SIMD_TEST_NO_LOWERING(I16x8GeUMixed) {
RunI16x8MixedRelationalOpTest(execution_tier, lower_simd, kExprI16x8GeU,
UnsignedGreaterEqual);
}
WASM_SIMD_TEST_NO_LOWERING(I16x8GtUMixed) {
RunI16x8MixedRelationalOpTest(execution_tier, lower_simd, kExprI16x8GtU,
UnsignedGreater);
}
#undef WASM_SIMD_TEST
#undef WASM_SIMD_CHECK_LANE
#undef TO_BYTE
#undef WASM_SIMD_OP
#undef WASM_SIMD_SPLAT
#undef WASM_SIMD_UNOP
#undef WASM_SIMD_BINOP
#undef WASM_SIMD_SHIFT_OP
#undef WASM_SIMD_CONCAT_OP
#undef WASM_SIMD_SELECT
#undef WASM_SIMD_F64x2_SPLAT
#undef WASM_SIMD_F64x2_EXTRACT_LANE
#undef WASM_SIMD_F64x2_REPLACE_LANE
#undef WASM_SIMD_F32x4_SPLAT
#undef WASM_SIMD_F32x4_EXTRACT_LANE
#undef WASM_SIMD_F32x4_REPLACE_LANE
#undef WASM_SIMD_I64x2_SPLAT
#undef WASM_SIMD_I64x2_EXTRACT_LANE
#undef WASM_SIMD_I64x2_REPLACE_LANE
#undef WASM_SIMD_I32x4_SPLAT
#undef WASM_SIMD_I32x4_EXTRACT_LANE
#undef WASM_SIMD_I32x4_REPLACE_LANE
#undef WASM_SIMD_I16x8_SPLAT
#undef WASM_SIMD_I16x8_EXTRACT_LANE
#undef WASM_SIMD_I16x8_REPLACE_LANE
#undef WASM_SIMD_I8x16_SPLAT
#undef WASM_SIMD_I8x16_EXTRACT_LANE
#undef WASM_SIMD_I8x16_REPLACE_LANE
#undef WASM_SIMD_S8x16_SHUFFLE_OP
#undef WASM_SIMD_LOAD_MEM
#undef WASM_SIMD_LOAD_MEM_OFFSET
#undef WASM_SIMD_STORE_MEM
#undef WASM_SIMD_STORE_MEM_OFFSET
#undef WASM_SIMD_SELECT_TEST
#undef WASM_SIMD_NON_CANONICAL_SELECT_TEST
#undef WASM_SIMD_COMPILED_TEST
#undef WASM_SIMD_BOOL_REDUCTION_TEST
#undef WASM_SIMD_TEST_NO_LOWERING
#undef WASM_SIMD_ANYTRUE_TEST
#undef WASM_SIMD_ALLTRUE_TEST
#undef WASM_SIMD_F64x2_QFMA
#undef WASM_SIMD_F64x2_QFMS
#undef WASM_SIMD_F32x4_QFMA
#undef WASM_SIMD_F32x4_QFMS
} // namespace test_run_wasm_simd
} // namespace wasm
} // namespace internal
} // namespace v8
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