v8/test/unittests/compiler/mips/instruction-selector-mips-unittest.cc
ivica.bogosavljevic ee7281f8ff MIPS[64]: Disable fusion multiple-accumulate instructions
MIPS[64]R6 supports only fusion multiply-accumulate instructions, and using
these causes failures of several tests that expect exact floating-point
results. Therefore we disable fusion multiply-accumulate in both emitted and
compiled code on R6.

TEST=cctest/test-run-machops/RunFloat64MulAndFloat64Add1,mjsunit/es6/math-expm1.js
mjsunit/es6/math-fround.js,mjsunit/compiler/multiply-add.js

BUG=

Review-Url: https://codereview.chromium.org/2569683002
Cr-Commit-Position: refs/heads/master@{#41717}
2016-12-15 11:50:12 +00:00

1460 lines
52 KiB
C++

// Copyright 2014 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 "test/unittests/compiler/instruction-selector-unittest.h"
namespace v8 {
namespace internal {
namespace compiler {
namespace {
template <typename T>
struct MachInst {
T constructor;
const char* constructor_name;
ArchOpcode arch_opcode;
MachineType machine_type;
};
template <typename T>
std::ostream& operator<<(std::ostream& os, const MachInst<T>& mi) {
return os << mi.constructor_name;
}
typedef MachInst<Node* (RawMachineAssembler::*)(Node*)> MachInst1;
typedef MachInst<Node* (RawMachineAssembler::*)(Node*, Node*)> MachInst2;
// To avoid duplicated code IntCmp helper structure
// is created. It contains MachInst2 with two nodes and expected_size
// because different cmp instructions have different size.
struct IntCmp {
MachInst2 mi;
uint32_t expected_size;
};
struct FPCmp {
MachInst2 mi;
FlagsCondition cond;
};
const FPCmp kFPCmpInstructions[] = {
{{&RawMachineAssembler::Float64Equal, "Float64Equal", kMipsCmpD,
MachineType::Float64()},
kEqual},
{{&RawMachineAssembler::Float64LessThan, "Float64LessThan", kMipsCmpD,
MachineType::Float64()},
kUnsignedLessThan},
{{&RawMachineAssembler::Float64LessThanOrEqual, "Float64LessThanOrEqual",
kMipsCmpD, MachineType::Float64()},
kUnsignedLessThanOrEqual},
{{&RawMachineAssembler::Float64GreaterThan, "Float64GreaterThan", kMipsCmpD,
MachineType::Float64()},
kUnsignedLessThan},
{{&RawMachineAssembler::Float64GreaterThanOrEqual,
"Float64GreaterThanOrEqual", kMipsCmpD, MachineType::Float64()},
kUnsignedLessThanOrEqual}};
struct Conversion {
// The machine_type field in MachInst1 represents the destination type.
MachInst1 mi;
MachineType src_machine_type;
};
// ----------------------------------------------------------------------------
// Logical instructions.
// ----------------------------------------------------------------------------
const MachInst2 kLogicalInstructions[] = {
{&RawMachineAssembler::WordAnd, "WordAnd", kMipsAnd, MachineType::Int16()},
{&RawMachineAssembler::WordOr, "WordOr", kMipsOr, MachineType::Int16()},
{&RawMachineAssembler::WordXor, "WordXor", kMipsXor, MachineType::Int16()},
{&RawMachineAssembler::Word32And, "Word32And", kMipsAnd,
MachineType::Int32()},
{&RawMachineAssembler::Word32Or, "Word32Or", kMipsOr, MachineType::Int32()},
{&RawMachineAssembler::Word32Xor, "Word32Xor", kMipsXor,
MachineType::Int32()}};
// ----------------------------------------------------------------------------
// Shift instructions.
// ----------------------------------------------------------------------------
const MachInst2 kShiftInstructions[] = {
{&RawMachineAssembler::WordShl, "WordShl", kMipsShl, MachineType::Int16()},
{&RawMachineAssembler::WordShr, "WordShr", kMipsShr, MachineType::Int16()},
{&RawMachineAssembler::WordSar, "WordSar", kMipsSar, MachineType::Int16()},
{&RawMachineAssembler::WordRor, "WordRor", kMipsRor, MachineType::Int16()},
{&RawMachineAssembler::Word32Shl, "Word32Shl", kMipsShl,
MachineType::Int32()},
{&RawMachineAssembler::Word32Shr, "Word32Shr", kMipsShr,
MachineType::Int32()},
{&RawMachineAssembler::Word32Sar, "Word32Sar", kMipsSar,
MachineType::Int32()},
{&RawMachineAssembler::Word32Ror, "Word32Ror", kMipsRor,
MachineType::Int32()}};
// ----------------------------------------------------------------------------
// MUL/DIV instructions.
// ----------------------------------------------------------------------------
const MachInst2 kMulDivInstructions[] = {
{&RawMachineAssembler::Int32Mul, "Int32Mul", kMipsMul,
MachineType::Int32()},
{&RawMachineAssembler::Int32Div, "Int32Div", kMipsDiv,
MachineType::Int32()},
{&RawMachineAssembler::Uint32Div, "Uint32Div", kMipsDivU,
MachineType::Uint32()},
{&RawMachineAssembler::Float64Mul, "Float64Mul", kMipsMulD,
MachineType::Float64()},
{&RawMachineAssembler::Float64Div, "Float64Div", kMipsDivD,
MachineType::Float64()}};
// ----------------------------------------------------------------------------
// MOD instructions.
// ----------------------------------------------------------------------------
const MachInst2 kModInstructions[] = {
{&RawMachineAssembler::Int32Mod, "Int32Mod", kMipsMod,
MachineType::Int32()},
{&RawMachineAssembler::Uint32Mod, "Int32UMod", kMipsModU,
MachineType::Int32()},
{&RawMachineAssembler::Float64Mod, "Float64Mod", kMipsModD,
MachineType::Float64()}};
// ----------------------------------------------------------------------------
// Arithmetic FPU instructions.
// ----------------------------------------------------------------------------
const MachInst2 kFPArithInstructions[] = {
{&RawMachineAssembler::Float64Add, "Float64Add", kMipsAddD,
MachineType::Float64()},
{&RawMachineAssembler::Float64Sub, "Float64Sub", kMipsSubD,
MachineType::Float64()}};
// ----------------------------------------------------------------------------
// IntArithTest instructions, two nodes.
// ----------------------------------------------------------------------------
const MachInst2 kAddSubInstructions[] = {
{&RawMachineAssembler::Int32Add, "Int32Add", kMipsAdd,
MachineType::Int32()},
{&RawMachineAssembler::Int32Sub, "Int32Sub", kMipsSub,
MachineType::Int32()},
{&RawMachineAssembler::Int32AddWithOverflow, "Int32AddWithOverflow",
kMipsAddOvf, MachineType::Int32()},
{&RawMachineAssembler::Int32SubWithOverflow, "Int32SubWithOverflow",
kMipsSubOvf, MachineType::Int32()}};
// ----------------------------------------------------------------------------
// IntArithTest instructions, one node.
// ----------------------------------------------------------------------------
const MachInst1 kAddSubOneInstructions[] = {
{&RawMachineAssembler::Int32Neg, "Int32Neg", kMipsSub,
MachineType::Int32()},
// TODO(dusmil): check this ...
// {&RawMachineAssembler::WordEqual , "WordEqual" , kMipsTst,
// MachineType::Int32()}
};
// ----------------------------------------------------------------------------
// Arithmetic compare instructions.
// ----------------------------------------------------------------------------
const IntCmp kCmpInstructions[] = {
{{&RawMachineAssembler::WordEqual, "WordEqual", kMipsCmp,
MachineType::Int16()},
1U},
{{&RawMachineAssembler::WordNotEqual, "WordNotEqual", kMipsCmp,
MachineType::Int16()},
1U},
{{&RawMachineAssembler::Word32Equal, "Word32Equal", kMipsCmp,
MachineType::Int32()},
1U},
{{&RawMachineAssembler::Word32NotEqual, "Word32NotEqual", kMipsCmp,
MachineType::Int32()},
1U},
{{&RawMachineAssembler::Int32LessThan, "Int32LessThan", kMipsCmp,
MachineType::Int32()},
1U},
{{&RawMachineAssembler::Int32LessThanOrEqual, "Int32LessThanOrEqual",
kMipsCmp, MachineType::Int32()},
1U},
{{&RawMachineAssembler::Int32GreaterThan, "Int32GreaterThan", kMipsCmp,
MachineType::Int32()},
1U},
{{&RawMachineAssembler::Int32GreaterThanOrEqual, "Int32GreaterThanOrEqual",
kMipsCmp, MachineType::Int32()},
1U},
{{&RawMachineAssembler::Uint32LessThan, "Uint32LessThan", kMipsCmp,
MachineType::Uint32()},
1U},
{{&RawMachineAssembler::Uint32LessThanOrEqual, "Uint32LessThanOrEqual",
kMipsCmp, MachineType::Uint32()},
1U}};
// ----------------------------------------------------------------------------
// Conversion instructions.
// ----------------------------------------------------------------------------
const Conversion kConversionInstructions[] = {
// Conversion instructions are related to machine_operator.h:
// FPU conversions:
// Convert representation of integers between float64 and int32/uint32.
// The precise rounding mode and handling of out of range inputs are *not*
// defined for these operators, since they are intended only for use with
// integers.
// mips instruction: cvt_d_w
{{&RawMachineAssembler::ChangeInt32ToFloat64, "ChangeInt32ToFloat64",
kMipsCvtDW, MachineType::Float64()},
MachineType::Int32()},
// mips instruction: cvt_d_uw
{{&RawMachineAssembler::ChangeUint32ToFloat64, "ChangeUint32ToFloat64",
kMipsCvtDUw, MachineType::Float64()},
MachineType::Int32()},
// mips instruction: trunc_w_d
{{&RawMachineAssembler::ChangeFloat64ToInt32, "ChangeFloat64ToInt32",
kMipsTruncWD, MachineType::Float64()},
MachineType::Int32()},
// mips instruction: trunc_uw_d
{{&RawMachineAssembler::ChangeFloat64ToUint32, "ChangeFloat64ToUint32",
kMipsTruncUwD, MachineType::Float64()},
MachineType::Int32()}};
const Conversion kFloat64RoundInstructions[] = {
{{&RawMachineAssembler::Float64RoundUp, "Float64RoundUp", kMipsCeilWD,
MachineType::Int32()},
MachineType::Float64()},
{{&RawMachineAssembler::Float64RoundDown, "Float64RoundDown", kMipsFloorWD,
MachineType::Int32()},
MachineType::Float64()},
{{&RawMachineAssembler::Float64RoundTiesEven, "Float64RoundTiesEven",
kMipsRoundWD, MachineType::Int32()},
MachineType::Float64()},
{{&RawMachineAssembler::Float64RoundTruncate, "Float64RoundTruncate",
kMipsTruncWD, MachineType::Int32()},
MachineType::Float64()}};
const Conversion kFloat32RoundInstructions[] = {
{{&RawMachineAssembler::Float32RoundUp, "Float32RoundUp", kMipsCeilWS,
MachineType::Int32()},
MachineType::Float32()},
{{&RawMachineAssembler::Float32RoundDown, "Float32RoundDown", kMipsFloorWS,
MachineType::Int32()},
MachineType::Float32()},
{{&RawMachineAssembler::Float32RoundTiesEven, "Float32RoundTiesEven",
kMipsRoundWS, MachineType::Int32()},
MachineType::Float32()},
{{&RawMachineAssembler::Float32RoundTruncate, "Float32RoundTruncate",
kMipsTruncWS, MachineType::Int32()},
MachineType::Float32()}};
} // namespace
typedef InstructionSelectorTestWithParam<FPCmp> InstructionSelectorFPCmpTest;
TEST_P(InstructionSelectorFPCmpTest, Parameter) {
const FPCmp cmp = GetParam();
StreamBuilder m(this, MachineType::Int32(), cmp.mi.machine_type,
cmp.mi.machine_type);
m.Return((m.*cmp.mi.constructor)(m.Parameter(0), m.Parameter(1)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(cmp.mi.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(kFlags_set, s[0]->flags_mode());
EXPECT_EQ(cmp.cond, s[0]->flags_condition());
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest, InstructionSelectorFPCmpTest,
::testing::ValuesIn(kFPCmpInstructions));
// ----------------------------------------------------------------------------
// Arithmetic compare instructions integers.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<IntCmp> InstructionSelectorCmpTest;
TEST_P(InstructionSelectorCmpTest, Parameter) {
const IntCmp cmp = GetParam();
const MachineType type = cmp.mi.machine_type;
StreamBuilder m(this, type, type, type);
m.Return((m.*cmp.mi.constructor)(m.Parameter(0), m.Parameter(1)));
Stream s = m.Build();
ASSERT_EQ(cmp.expected_size, s.size());
EXPECT_EQ(cmp.mi.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest, InstructionSelectorCmpTest,
::testing::ValuesIn(kCmpInstructions));
// ----------------------------------------------------------------------------
// Shift instructions.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<MachInst2>
InstructionSelectorShiftTest;
TEST_P(InstructionSelectorShiftTest, Immediate) {
const MachInst2 dpi = GetParam();
const MachineType type = dpi.machine_type;
TRACED_FORRANGE(int32_t, imm, 0,
((1 << ElementSizeLog2Of(type.representation())) * 8) - 1) {
StreamBuilder m(this, type, type);
m.Return((m.*dpi.constructor)(m.Parameter(0), m.Int32Constant(imm)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(dpi.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_TRUE(s[0]->InputAt(1)->IsImmediate());
EXPECT_EQ(imm, s.ToInt32(s[0]->InputAt(1)));
EXPECT_EQ(1U, s[0]->OutputCount());
}
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest, InstructionSelectorShiftTest,
::testing::ValuesIn(kShiftInstructions));
TEST_F(InstructionSelectorTest, Word32ShrWithWord32AndWithImmediate) {
// The available shift operand range is `0 <= imm < 32`, but we also test
// that immediates outside this range are handled properly (modulo-32).
TRACED_FORRANGE(int32_t, shift, -32, 63) {
int32_t lsb = shift & 0x1f;
TRACED_FORRANGE(int32_t, width, 1, 32 - lsb) {
uint32_t jnk = rng()->NextInt();
jnk = (lsb > 0) ? (jnk >> (32 - lsb)) : 0;
uint32_t msk = ((0xffffffffu >> (32 - width)) << lsb) | jnk;
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32Shr(m.Word32And(m.Parameter(0), m.Int32Constant(msk)),
m.Int32Constant(shift)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsExt, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(lsb, s.ToInt32(s[0]->InputAt(1)));
EXPECT_EQ(width, s.ToInt32(s[0]->InputAt(2)));
}
}
TRACED_FORRANGE(int32_t, shift, -32, 63) {
int32_t lsb = shift & 0x1f;
TRACED_FORRANGE(int32_t, width, 1, 32 - lsb) {
uint32_t jnk = rng()->NextInt();
jnk = (lsb > 0) ? (jnk >> (32 - lsb)) : 0;
uint32_t msk = ((0xffffffffu >> (32 - width)) << lsb) | jnk;
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32Shr(m.Word32And(m.Int32Constant(msk), m.Parameter(0)),
m.Int32Constant(shift)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsExt, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(lsb, s.ToInt32(s[0]->InputAt(1)));
EXPECT_EQ(width, s.ToInt32(s[0]->InputAt(2)));
}
}
}
TEST_F(InstructionSelectorTest, Word32ShlWithWord32And) {
TRACED_FORRANGE(int32_t, shift, 0, 30) {
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
Node* const p0 = m.Parameter(0);
Node* const r =
m.Word32Shl(m.Word32And(p0, m.Int32Constant((1 << (31 - shift)) - 1)),
m.Int32Constant(shift + 1));
m.Return(r);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsShl, s[0]->arch_opcode());
ASSERT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(0)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(s.ToVreg(r), s.ToVreg(s[0]->Output()));
}
}
TEST_F(InstructionSelectorTest, Word32SarWithWord32Shl) {
{
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
Node* const p0 = m.Parameter(0);
Node* const r =
m.Word32Sar(m.Word32Shl(p0, m.Int32Constant(24)), m.Int32Constant(24));
m.Return(r);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsSeb, s[0]->arch_opcode());
ASSERT_EQ(1U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(0)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(s.ToVreg(r), s.ToVreg(s[0]->Output()));
}
{
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
Node* const p0 = m.Parameter(0);
Node* const r =
m.Word32Sar(m.Word32Shl(p0, m.Int32Constant(16)), m.Int32Constant(16));
m.Return(r);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsSeh, s[0]->arch_opcode());
ASSERT_EQ(1U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(0)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(s.ToVreg(r), s.ToVreg(s[0]->Output()));
}
}
// ----------------------------------------------------------------------------
// Logical instructions.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<MachInst2>
InstructionSelectorLogicalTest;
TEST_P(InstructionSelectorLogicalTest, Parameter) {
const MachInst2 dpi = GetParam();
const MachineType type = dpi.machine_type;
StreamBuilder m(this, type, type, type);
m.Return((m.*dpi.constructor)(m.Parameter(0), m.Parameter(1)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(dpi.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest, InstructionSelectorLogicalTest,
::testing::ValuesIn(kLogicalInstructions));
TEST_F(InstructionSelectorTest, Word32XorMinusOneWithParameter) {
{
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32Xor(m.Parameter(0), m.Int32Constant(-1)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsNor, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
{
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32Xor(m.Int32Constant(-1), m.Parameter(0)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsNor, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
}
TEST_F(InstructionSelectorTest, Word32XorMinusOneWithWord32Or) {
{
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32Xor(m.Word32Or(m.Parameter(0), m.Parameter(0)),
m.Int32Constant(-1)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsNor, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
{
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32Xor(m.Int32Constant(-1),
m.Word32Or(m.Parameter(0), m.Parameter(0))));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsNor, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
}
TEST_F(InstructionSelectorTest, Word32AndWithImmediateWithWord32Shr) {
// The available shift operand range is `0 <= imm < 32`, but we also test
// that immediates outside this range are handled properly (modulo-32).
TRACED_FORRANGE(int32_t, shift, -32, 63) {
int32_t lsb = shift & 0x1f;
TRACED_FORRANGE(int32_t, width, 1, 31) {
uint32_t msk = (1 << width) - 1;
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32And(m.Word32Shr(m.Parameter(0), m.Int32Constant(shift)),
m.Int32Constant(msk)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsExt, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(lsb, s.ToInt32(s[0]->InputAt(1)));
int32_t actual_width = (lsb + width > 32) ? (32 - lsb) : width;
EXPECT_EQ(actual_width, s.ToInt32(s[0]->InputAt(2)));
}
}
TRACED_FORRANGE(int32_t, shift, -32, 63) {
int32_t lsb = shift & 0x1f;
TRACED_FORRANGE(int32_t, width, 1, 31) {
uint32_t msk = (1 << width) - 1;
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(
m.Word32And(m.Int32Constant(msk),
m.Word32Shr(m.Parameter(0), m.Int32Constant(shift))));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsExt, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(lsb, s.ToInt32(s[0]->InputAt(1)));
int32_t actual_width = (lsb + width > 32) ? (32 - lsb) : width;
EXPECT_EQ(actual_width, s.ToInt32(s[0]->InputAt(2)));
}
}
}
TEST_F(InstructionSelectorTest, Word32AndToClearBits) {
TRACED_FORRANGE(int32_t, shift, 1, 31) {
int32_t mask = ~((1 << shift) - 1);
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32And(m.Parameter(0), m.Int32Constant(mask)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsIns, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(0, s.ToInt32(s[0]->InputAt(1)));
EXPECT_EQ(shift, s.ToInt32(s[0]->InputAt(2)));
}
TRACED_FORRANGE(int32_t, shift, 1, 31) {
int32_t mask = ~((1 << shift) - 1);
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32And(m.Int32Constant(mask), m.Parameter(0)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsIns, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(0, s.ToInt32(s[0]->InputAt(1)));
EXPECT_EQ(shift, s.ToInt32(s[0]->InputAt(2)));
}
}
// ----------------------------------------------------------------------------
// MUL/DIV instructions.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<MachInst2>
InstructionSelectorMulDivTest;
TEST_P(InstructionSelectorMulDivTest, Parameter) {
const MachInst2 dpi = GetParam();
const MachineType type = dpi.machine_type;
StreamBuilder m(this, type, type, type);
m.Return((m.*dpi.constructor)(m.Parameter(0), m.Parameter(1)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(dpi.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest, InstructionSelectorMulDivTest,
::testing::ValuesIn(kMulDivInstructions));
// ----------------------------------------------------------------------------
// MOD instructions.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<MachInst2> InstructionSelectorModTest;
TEST_P(InstructionSelectorModTest, Parameter) {
const MachInst2 dpi = GetParam();
const MachineType type = dpi.machine_type;
StreamBuilder m(this, type, type, type);
m.Return((m.*dpi.constructor)(m.Parameter(0), m.Parameter(1)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(dpi.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest, InstructionSelectorModTest,
::testing::ValuesIn(kModInstructions));
// ----------------------------------------------------------------------------
// Floating point instructions.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<MachInst2>
InstructionSelectorFPArithTest;
TEST_P(InstructionSelectorFPArithTest, Parameter) {
const MachInst2 fpa = GetParam();
StreamBuilder m(this, fpa.machine_type, fpa.machine_type, fpa.machine_type);
m.Return((m.*fpa.constructor)(m.Parameter(0), m.Parameter(1)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(fpa.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest, InstructionSelectorFPArithTest,
::testing::ValuesIn(kFPArithInstructions));
// ----------------------------------------------------------------------------
// Integer arithmetic.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<MachInst2>
InstructionSelectorIntArithTwoTest;
TEST_P(InstructionSelectorIntArithTwoTest, Parameter) {
const MachInst2 intpa = GetParam();
StreamBuilder m(this, intpa.machine_type, intpa.machine_type,
intpa.machine_type);
m.Return((m.*intpa.constructor)(m.Parameter(0), m.Parameter(1)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(intpa.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest,
InstructionSelectorIntArithTwoTest,
::testing::ValuesIn(kAddSubInstructions));
// ----------------------------------------------------------------------------
// One node.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<MachInst1>
InstructionSelectorIntArithOneTest;
TEST_P(InstructionSelectorIntArithOneTest, Parameter) {
const MachInst1 intpa = GetParam();
StreamBuilder m(this, intpa.machine_type, intpa.machine_type,
intpa.machine_type);
m.Return((m.*intpa.constructor)(m.Parameter(0)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(intpa.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest,
InstructionSelectorIntArithOneTest,
::testing::ValuesIn(kAddSubOneInstructions));
// ----------------------------------------------------------------------------
// Conversions.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<Conversion>
InstructionSelectorConversionTest;
TEST_P(InstructionSelectorConversionTest, Parameter) {
const Conversion conv = GetParam();
StreamBuilder m(this, conv.mi.machine_type, conv.src_machine_type);
m.Return((m.*conv.mi.constructor)(m.Parameter(0)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(conv.mi.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(1U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest,
InstructionSelectorConversionTest,
::testing::ValuesIn(kConversionInstructions));
typedef InstructionSelectorTestWithParam<Conversion>
CombineChangeFloat64ToInt32WithRoundFloat64;
TEST_P(CombineChangeFloat64ToInt32WithRoundFloat64, Parameter) {
{
const Conversion conv = GetParam();
StreamBuilder m(this, conv.mi.machine_type, conv.src_machine_type);
m.Return(m.ChangeFloat64ToInt32((m.*conv.mi.constructor)(m.Parameter(0))));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(conv.mi.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(kMode_None, s[0]->addressing_mode());
ASSERT_EQ(1U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest,
CombineChangeFloat64ToInt32WithRoundFloat64,
::testing::ValuesIn(kFloat64RoundInstructions));
typedef InstructionSelectorTestWithParam<Conversion>
CombineChangeFloat32ToInt32WithRoundFloat32;
TEST_P(CombineChangeFloat32ToInt32WithRoundFloat32, Parameter) {
{
const Conversion conv = GetParam();
StreamBuilder m(this, conv.mi.machine_type, conv.src_machine_type);
m.Return(m.ChangeFloat64ToInt32(
m.ChangeFloat32ToFloat64((m.*conv.mi.constructor)(m.Parameter(0)))));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(conv.mi.arch_opcode, s[0]->arch_opcode());
EXPECT_EQ(kMode_None, s[0]->addressing_mode());
ASSERT_EQ(1U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest,
CombineChangeFloat32ToInt32WithRoundFloat32,
::testing::ValuesIn(kFloat32RoundInstructions));
TEST_F(InstructionSelectorTest, ChangeFloat64ToInt32OfChangeFloat32ToFloat64) {
{
StreamBuilder m(this, MachineType::Int32(), MachineType::Float32());
m.Return(m.ChangeFloat64ToInt32(m.ChangeFloat32ToFloat64(m.Parameter(0))));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsTruncWS, s[0]->arch_opcode());
EXPECT_EQ(kMode_None, s[0]->addressing_mode());
ASSERT_EQ(1U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
}
TEST_F(InstructionSelectorTest,
TruncateFloat64ToFloat32OfChangeInt32ToFloat64) {
{
StreamBuilder m(this, MachineType::Float32(), MachineType::Int32());
m.Return(
m.TruncateFloat64ToFloat32(m.ChangeInt32ToFloat64(m.Parameter(0))));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsCvtSW, s[0]->arch_opcode());
EXPECT_EQ(kMode_None, s[0]->addressing_mode());
ASSERT_EQ(1U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
}
// ----------------------------------------------------------------------------
// Loads and stores.
// ----------------------------------------------------------------------------
namespace {
struct MemoryAccess {
MachineType type;
ArchOpcode load_opcode;
ArchOpcode store_opcode;
};
static const MemoryAccess kMemoryAccesses[] = {
{MachineType::Int8(), kMipsLb, kMipsSb},
{MachineType::Uint8(), kMipsLbu, kMipsSb},
{MachineType::Int16(), kMipsLh, kMipsSh},
{MachineType::Uint16(), kMipsLhu, kMipsSh},
{MachineType::Int32(), kMipsLw, kMipsSw},
{MachineType::Float32(), kMipsLwc1, kMipsSwc1},
{MachineType::Float64(), kMipsLdc1, kMipsSdc1}};
struct MemoryAccessImm {
MachineType type;
ArchOpcode load_opcode;
ArchOpcode store_opcode;
bool (InstructionSelectorTest::Stream::*val_predicate)(
const InstructionOperand*) const;
const int32_t immediates[40];
};
std::ostream& operator<<(std::ostream& os, const MemoryAccessImm& acc) {
return os << acc.type;
}
struct MemoryAccessImm1 {
MachineType type;
ArchOpcode load_opcode;
ArchOpcode store_opcode;
bool (InstructionSelectorTest::Stream::*val_predicate)(
const InstructionOperand*) const;
const int32_t immediates[5];
};
std::ostream& operator<<(std::ostream& os, const MemoryAccessImm1& acc) {
return os << acc.type;
}
struct MemoryAccessImm2 {
MachineType type;
ArchOpcode store_opcode;
ArchOpcode store_opcode_unaligned;
bool (InstructionSelectorTest::Stream::*val_predicate)(
const InstructionOperand*) const;
const int32_t immediates[40];
};
std::ostream& operator<<(std::ostream& os, const MemoryAccessImm2& acc) {
return os << acc.type;
}
// ----------------------------------------------------------------------------
// Loads and stores immediate values.
// ----------------------------------------------------------------------------
const MemoryAccessImm kMemoryAccessesImm[] = {
{MachineType::Int8(),
kMipsLb,
kMipsSb,
&InstructionSelectorTest::Stream::IsInteger,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91, -89,
-87, -86, -82, -44, -23, -3, 0, 7, 10, 39, 52, 69, 71, 91, 92, 107, 109,
115, 124, 286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}},
{MachineType::Uint8(),
kMipsLbu,
kMipsSb,
&InstructionSelectorTest::Stream::IsInteger,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91, -89,
-87, -86, -82, -44, -23, -3, 0, 7, 10, 39, 52, 69, 71, 91, 92, 107, 109,
115, 124, 286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}},
{MachineType::Int16(),
kMipsLh,
kMipsSh,
&InstructionSelectorTest::Stream::IsInteger,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91, -89,
-87, -86, -82, -44, -23, -3, 0, 7, 10, 39, 52, 69, 71, 91, 92, 107, 109,
115, 124, 286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}},
{MachineType::Uint16(),
kMipsLhu,
kMipsSh,
&InstructionSelectorTest::Stream::IsInteger,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91, -89,
-87, -86, -82, -44, -23, -3, 0, 7, 10, 39, 52, 69, 71, 91, 92, 107, 109,
115, 124, 286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}},
{MachineType::Int32(),
kMipsLw,
kMipsSw,
&InstructionSelectorTest::Stream::IsInteger,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91, -89,
-87, -86, -82, -44, -23, -3, 0, 7, 10, 39, 52, 69, 71, 91, 92, 107, 109,
115, 124, 286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}},
{MachineType::Float32(),
kMipsLwc1,
kMipsSwc1,
&InstructionSelectorTest::Stream::IsDouble,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91, -89,
-87, -86, -82, -44, -23, -3, 0, 7, 10, 39, 52, 69, 71, 91, 92, 107, 109,
115, 124, 286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}},
{MachineType::Float64(),
kMipsLdc1,
kMipsSdc1,
&InstructionSelectorTest::Stream::IsDouble,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91, -89,
-87, -86, -82, -44, -23, -3, 0, 7, 10, 39, 52, 69, 71, 91, 92, 107, 109,
115, 124, 286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}}};
const MemoryAccessImm1 kMemoryAccessImmMoreThan16bit[] = {
{MachineType::Int8(),
kMipsLb,
kMipsSb,
&InstructionSelectorTest::Stream::IsInteger,
{-65000, -55000, 32777, 55000, 65000}},
{MachineType::Uint8(),
kMipsLbu,
kMipsSb,
&InstructionSelectorTest::Stream::IsInteger,
{-65000, -55000, 32777, 55000, 65000}},
{MachineType::Int16(),
kMipsLh,
kMipsSh,
&InstructionSelectorTest::Stream::IsInteger,
{-65000, -55000, 32777, 55000, 65000}},
{MachineType::Uint16(),
kMipsLhu,
kMipsSh,
&InstructionSelectorTest::Stream::IsInteger,
{-65000, -55000, 32777, 55000, 65000}},
{MachineType::Int32(),
kMipsLw,
kMipsSw,
&InstructionSelectorTest::Stream::IsInteger,
{-65000, -55000, 32777, 55000, 65000}},
{MachineType::Float32(),
kMipsLwc1,
kMipsSwc1,
&InstructionSelectorTest::Stream::IsDouble,
{-65000, -55000, 32777, 55000, 65000}},
{MachineType::Float64(),
kMipsLdc1,
kMipsSdc1,
&InstructionSelectorTest::Stream::IsDouble,
{-65000, -55000, 32777, 55000, 65000}}};
const MemoryAccessImm2 kMemoryAccessesImmUnaligned[] = {
{MachineType::Int16(),
kMipsUsh,
kMipsSh,
&InstructionSelectorTest::Stream::IsInteger,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91,
-89, -87, -86, -82, -44, -23, -3, 0, 7, 10,
39, 52, 69, 71, 91, 92, 107, 109, 115, 124,
286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}},
{MachineType::Int32(),
kMipsUsw,
kMipsSw,
&InstructionSelectorTest::Stream::IsInteger,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91,
-89, -87, -86, -82, -44, -23, -3, 0, 7, 10,
39, 52, 69, 71, 91, 92, 107, 109, 115, 124,
286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}},
{MachineType::Float32(),
kMipsUswc1,
kMipsSwc1,
&InstructionSelectorTest::Stream::IsDouble,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91,
-89, -87, -86, -82, -44, -23, -3, 0, 7, 10,
39, 52, 69, 71, 91, 92, 107, 109, 115, 124,
286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}},
{MachineType::Float64(),
kMipsUsdc1,
kMipsSdc1,
&InstructionSelectorTest::Stream::IsDouble,
{-4095, -3340, -3231, -3224, -3088, -1758, -1203, -123, -117, -91,
-89, -87, -86, -82, -44, -23, -3, 0, 7, 10,
39, 52, 69, 71, 91, 92, 107, 109, 115, 124,
286, 655, 1362, 1569, 2587, 3067, 3096, 3462, 3510, 4095}}};
} // namespace
typedef InstructionSelectorTestWithParam<MemoryAccess>
InstructionSelectorMemoryAccessTest;
TEST_P(InstructionSelectorMemoryAccessTest, LoadWithParameters) {
const MemoryAccess memacc = GetParam();
StreamBuilder m(this, memacc.type, MachineType::Pointer(),
MachineType::Int32());
m.Return(m.Load(memacc.type, m.Parameter(0)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(memacc.load_opcode, s[0]->arch_opcode());
EXPECT_EQ(kMode_MRI, s[0]->addressing_mode());
}
TEST_P(InstructionSelectorMemoryAccessTest, StoreWithParameters) {
const MemoryAccess memacc = GetParam();
StreamBuilder m(this, MachineType::Int32(), MachineType::Pointer(),
MachineType::Int32(), memacc.type);
m.Store(memacc.type.representation(), m.Parameter(0), m.Parameter(1),
kNoWriteBarrier);
m.Return(m.Int32Constant(0));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(memacc.store_opcode, s[0]->arch_opcode());
EXPECT_EQ(kMode_MRI, s[0]->addressing_mode());
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest,
InstructionSelectorMemoryAccessTest,
::testing::ValuesIn(kMemoryAccesses));
// ----------------------------------------------------------------------------
// Load immediate.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<MemoryAccessImm>
InstructionSelectorMemoryAccessImmTest;
TEST_P(InstructionSelectorMemoryAccessImmTest, LoadWithImmediateIndex) {
const MemoryAccessImm memacc = GetParam();
TRACED_FOREACH(int32_t, index, memacc.immediates) {
StreamBuilder m(this, memacc.type, MachineType::Pointer());
m.Return(m.Load(memacc.type, m.Parameter(0), m.Int32Constant(index)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(memacc.load_opcode, s[0]->arch_opcode());
EXPECT_EQ(kMode_MRI, s[0]->addressing_mode());
ASSERT_EQ(2U, s[0]->InputCount());
ASSERT_EQ(InstructionOperand::IMMEDIATE, s[0]->InputAt(1)->kind());
EXPECT_EQ(index, s.ToInt32(s[0]->InputAt(1)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_TRUE((s.*memacc.val_predicate)(s[0]->Output()));
}
}
// ----------------------------------------------------------------------------
// Store immediate.
// ----------------------------------------------------------------------------
TEST_P(InstructionSelectorMemoryAccessImmTest, StoreWithImmediateIndex) {
const MemoryAccessImm memacc = GetParam();
TRACED_FOREACH(int32_t, index, memacc.immediates) {
StreamBuilder m(this, MachineType::Int32(), MachineType::Pointer(),
memacc.type);
m.Store(memacc.type.representation(), m.Parameter(0),
m.Int32Constant(index), m.Parameter(1), kNoWriteBarrier);
m.Return(m.Int32Constant(0));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(memacc.store_opcode, s[0]->arch_opcode());
EXPECT_EQ(kMode_MRI, s[0]->addressing_mode());
ASSERT_EQ(3U, s[0]->InputCount());
ASSERT_EQ(InstructionOperand::IMMEDIATE, s[0]->InputAt(1)->kind());
EXPECT_EQ(index, s.ToInt32(s[0]->InputAt(1)));
EXPECT_EQ(0U, s[0]->OutputCount());
}
}
TEST_P(InstructionSelectorMemoryAccessImmTest, StoreZero) {
const MemoryAccessImm memacc = GetParam();
TRACED_FOREACH(int32_t, index, memacc.immediates) {
StreamBuilder m(this, MachineType::Int32(), MachineType::Pointer());
m.Store(memacc.type.representation(), m.Parameter(0),
m.Int32Constant(index), m.Int32Constant(0), kNoWriteBarrier);
m.Return(m.Int32Constant(0));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(memacc.store_opcode, s[0]->arch_opcode());
EXPECT_EQ(kMode_MRI, s[0]->addressing_mode());
ASSERT_EQ(3U, s[0]->InputCount());
ASSERT_EQ(InstructionOperand::IMMEDIATE, s[0]->InputAt(1)->kind());
EXPECT_EQ(index, s.ToInt32(s[0]->InputAt(1)));
ASSERT_EQ(InstructionOperand::IMMEDIATE, s[0]->InputAt(2)->kind());
EXPECT_EQ(0, s.ToInt64(s[0]->InputAt(2)));
EXPECT_EQ(0U, s[0]->OutputCount());
}
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest,
InstructionSelectorMemoryAccessImmTest,
::testing::ValuesIn(kMemoryAccessesImm));
typedef InstructionSelectorTestWithParam<MemoryAccessImm2>
InstructionSelectorMemoryAccessUnalignedImmTest;
TEST_P(InstructionSelectorMemoryAccessUnalignedImmTest, StoreZero) {
const MemoryAccessImm2 memacc = GetParam();
TRACED_FOREACH(int32_t, index, memacc.immediates) {
StreamBuilder m(this, MachineType::Int32(), MachineType::Pointer());
bool unaligned_store_supported = m.machine()->UnalignedStoreSupported(
MachineType::TypeForRepresentation(memacc.type.representation()), 1);
m.UnalignedStore(memacc.type.representation(), m.Parameter(0),
m.Int32Constant(index), m.Int32Constant(0));
m.Return(m.Int32Constant(0));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(unaligned_store_supported ? memacc.store_opcode_unaligned
: memacc.store_opcode,
s[0]->arch_opcode());
EXPECT_EQ(kMode_MRI, s[0]->addressing_mode());
ASSERT_EQ(3U, s[0]->InputCount());
ASSERT_EQ(InstructionOperand::IMMEDIATE, s[0]->InputAt(1)->kind());
EXPECT_EQ(index, s.ToInt32(s[0]->InputAt(1)));
ASSERT_EQ(InstructionOperand::IMMEDIATE, s[0]->InputAt(2)->kind());
EXPECT_EQ(0, s.ToInt64(s[0]->InputAt(2)));
EXPECT_EQ(0U, s[0]->OutputCount());
}
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest,
InstructionSelectorMemoryAccessUnalignedImmTest,
::testing::ValuesIn(kMemoryAccessesImmUnaligned));
// ----------------------------------------------------------------------------
// Load/store offsets more than 16 bits.
// ----------------------------------------------------------------------------
typedef InstructionSelectorTestWithParam<MemoryAccessImm1>
InstructionSelectorMemoryAccessImmMoreThan16bitTest;
TEST_P(InstructionSelectorMemoryAccessImmMoreThan16bitTest,
LoadWithImmediateIndex) {
const MemoryAccessImm1 memacc = GetParam();
TRACED_FOREACH(int32_t, index, memacc.immediates) {
StreamBuilder m(this, memacc.type, MachineType::Pointer());
m.Return(m.Load(memacc.type, m.Parameter(0), m.Int32Constant(index)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(memacc.load_opcode, s[0]->arch_opcode());
EXPECT_EQ(kMode_MRI, s[0]->addressing_mode());
EXPECT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
}
}
TEST_P(InstructionSelectorMemoryAccessImmMoreThan16bitTest,
StoreWithImmediateIndex) {
const MemoryAccessImm1 memacc = GetParam();
TRACED_FOREACH(int32_t, index, memacc.immediates) {
StreamBuilder m(this, MachineType::Int32(), MachineType::Pointer(),
memacc.type);
m.Store(memacc.type.representation(), m.Parameter(0),
m.Int32Constant(index), m.Parameter(1), kNoWriteBarrier);
m.Return(m.Int32Constant(0));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(memacc.store_opcode, s[0]->arch_opcode());
EXPECT_EQ(kMode_MRI, s[0]->addressing_mode());
EXPECT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(0U, s[0]->OutputCount());
}
}
INSTANTIATE_TEST_CASE_P(InstructionSelectorTest,
InstructionSelectorMemoryAccessImmMoreThan16bitTest,
::testing::ValuesIn(kMemoryAccessImmMoreThan16bit));
// ----------------------------------------------------------------------------
// kMipsTst testing.
// ----------------------------------------------------------------------------
TEST_F(InstructionSelectorTest, Word32EqualWithZero) {
{
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32Equal(m.Parameter(0), m.Int32Constant(0)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsCmp, s[0]->arch_opcode());
EXPECT_EQ(kMode_None, s[0]->addressing_mode());
ASSERT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(kFlags_set, s[0]->flags_mode());
EXPECT_EQ(kEqual, s[0]->flags_condition());
}
{
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Word32Equal(m.Int32Constant(0), m.Parameter(0)));
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsCmp, s[0]->arch_opcode());
EXPECT_EQ(kMode_None, s[0]->addressing_mode());
ASSERT_EQ(2U, s[0]->InputCount());
EXPECT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(kFlags_set, s[0]->flags_mode());
EXPECT_EQ(kEqual, s[0]->flags_condition());
}
}
TEST_F(InstructionSelectorTest, Word32Clz) {
StreamBuilder m(this, MachineType::Uint32(), MachineType::Uint32());
Node* const p0 = m.Parameter(0);
Node* const n = m.Word32Clz(p0);
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsClz, s[0]->arch_opcode());
ASSERT_EQ(1U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(0)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
}
TEST_F(InstructionSelectorTest, Float32Abs) {
StreamBuilder m(this, MachineType::Float32(), MachineType::Float32());
Node* const p0 = m.Parameter(0);
Node* const n = m.Float32Abs(p0);
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsAbsS, s[0]->arch_opcode());
ASSERT_EQ(1U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(0)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
}
TEST_F(InstructionSelectorTest, Float64Abs) {
StreamBuilder m(this, MachineType::Float64(), MachineType::Float64());
Node* const p0 = m.Parameter(0);
Node* const n = m.Float64Abs(p0);
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsAbsD, s[0]->arch_opcode());
ASSERT_EQ(1U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(0)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
}
TEST_F(InstructionSelectorTest, Float32AddWithFloat32Mul) {
if (!IsMipsArchVariant(kMips32r2)) {
return;
}
{
StreamBuilder m(this, MachineType::Float32(), MachineType::Float32(),
MachineType::Float32(), MachineType::Float32());
Node* const p0 = m.Parameter(0);
Node* const p1 = m.Parameter(1);
Node* const p2 = m.Parameter(2);
Node* const n = m.Float32Add(m.Float32Mul(p0, p1), p2);
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsMaddS, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p2), s.ToVreg(s[0]->InputAt(0)));
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(1)));
EXPECT_EQ(s.ToVreg(p1), s.ToVreg(s[0]->InputAt(2)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_FALSE(
UnallocatedOperand::cast(s[0]->Output())->HasSameAsInputPolicy());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
EXPECT_EQ(kFlags_none, s[0]->flags_mode());
}
{
StreamBuilder m(this, MachineType::Float32(), MachineType::Float32(),
MachineType::Float32(), MachineType::Float32());
Node* const p0 = m.Parameter(0);
Node* const p1 = m.Parameter(1);
Node* const p2 = m.Parameter(2);
Node* const n = m.Float32Add(p0, m.Float32Mul(p1, p2));
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsMaddS, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(0)));
EXPECT_EQ(s.ToVreg(p1), s.ToVreg(s[0]->InputAt(1)));
EXPECT_EQ(s.ToVreg(p2), s.ToVreg(s[0]->InputAt(2)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_FALSE(
UnallocatedOperand::cast(s[0]->Output())->HasSameAsInputPolicy());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
EXPECT_EQ(kFlags_none, s[0]->flags_mode());
}
}
TEST_F(InstructionSelectorTest, Float64AddWithFloat64Mul) {
if (!IsMipsArchVariant(kMips32r2)) {
return;
}
{
StreamBuilder m(this, MachineType::Float64(), MachineType::Float64(),
MachineType::Float64(), MachineType::Float64());
Node* const p0 = m.Parameter(0);
Node* const p1 = m.Parameter(1);
Node* const p2 = m.Parameter(2);
Node* const n = m.Float64Add(m.Float64Mul(p0, p1), p2);
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsMaddD, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p2), s.ToVreg(s[0]->InputAt(0)));
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(1)));
EXPECT_EQ(s.ToVreg(p1), s.ToVreg(s[0]->InputAt(2)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_FALSE(
UnallocatedOperand::cast(s[0]->Output())->HasSameAsInputPolicy());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
EXPECT_EQ(kFlags_none, s[0]->flags_mode());
}
{
StreamBuilder m(this, MachineType::Float64(), MachineType::Float64(),
MachineType::Float64(), MachineType::Float64());
Node* const p0 = m.Parameter(0);
Node* const p1 = m.Parameter(1);
Node* const p2 = m.Parameter(2);
Node* const n = m.Float64Add(p0, m.Float64Mul(p1, p2));
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsMaddD, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(0)));
EXPECT_EQ(s.ToVreg(p1), s.ToVreg(s[0]->InputAt(1)));
EXPECT_EQ(s.ToVreg(p2), s.ToVreg(s[0]->InputAt(2)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_FALSE(
UnallocatedOperand::cast(s[0]->Output())->HasSameAsInputPolicy());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
EXPECT_EQ(kFlags_none, s[0]->flags_mode());
}
}
TEST_F(InstructionSelectorTest, Float32SubWithFloat32Mul) {
StreamBuilder m(this, MachineType::Float32(), MachineType::Float32(),
MachineType::Float32(), MachineType::Float32());
if (!IsMipsArchVariant(kMips32r2)) {
return;
}
{
Node* const p0 = m.Parameter(0);
Node* const p1 = m.Parameter(1);
Node* const p2 = m.Parameter(2);
Node* n = nullptr;
n = m.Float32Sub(m.Float32Mul(p1, p2), p0);
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsMsubS, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(0)));
EXPECT_EQ(s.ToVreg(p1), s.ToVreg(s[0]->InputAt(1)));
EXPECT_EQ(s.ToVreg(p2), s.ToVreg(s[0]->InputAt(2)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_FALSE(
UnallocatedOperand::cast(s[0]->Output())->HasSameAsInputPolicy());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
EXPECT_EQ(kFlags_none, s[0]->flags_mode());
}
}
TEST_F(InstructionSelectorTest, Float64SubWithFloat64Mul) {
StreamBuilder m(this, MachineType::Float64(), MachineType::Float64(),
MachineType::Float64(), MachineType::Float64());
if (!IsMipsArchVariant(kMips32r2)) {
return;
}
{
Node* const p0 = m.Parameter(0);
Node* const p1 = m.Parameter(1);
Node* const p2 = m.Parameter(2);
Node* n = nullptr;
n = m.Float64Sub(m.Float64Mul(p1, p2), p0);
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsMsubD, s[0]->arch_opcode());
ASSERT_EQ(3U, s[0]->InputCount());
EXPECT_EQ(s.ToVreg(p0), s.ToVreg(s[0]->InputAt(0)));
EXPECT_EQ(s.ToVreg(p1), s.ToVreg(s[0]->InputAt(1)));
EXPECT_EQ(s.ToVreg(p2), s.ToVreg(s[0]->InputAt(2)));
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_FALSE(
UnallocatedOperand::cast(s[0]->Output())->HasSameAsInputPolicy());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
EXPECT_EQ(kFlags_none, s[0]->flags_mode());
}
}
TEST_F(InstructionSelectorTest, Float64Max) {
StreamBuilder m(this, MachineType::Float64(), MachineType::Float64(),
MachineType::Float64());
Node* const p0 = m.Parameter(0);
Node* const p1 = m.Parameter(1);
Node* const n = m.Float64Max(p0, p1);
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsFloat64Max, s[0]->arch_opcode());
ASSERT_EQ(2U, s[0]->InputCount());
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
}
TEST_F(InstructionSelectorTest, Float64Min) {
StreamBuilder m(this, MachineType::Float64(), MachineType::Float64(),
MachineType::Float64());
Node* const p0 = m.Parameter(0);
Node* const p1 = m.Parameter(1);
Node* const n = m.Float64Min(p0, p1);
m.Return(n);
Stream s = m.Build();
ASSERT_EQ(1U, s.size());
EXPECT_EQ(kMipsFloat64Min, s[0]->arch_opcode());
ASSERT_EQ(2U, s[0]->InputCount());
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(s.ToVreg(n), s.ToVreg(s[0]->Output()));
}
} // namespace compiler
} // namespace internal
} // namespace v8