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v8/test/unittests/interpreter/interpreter-assembler-unittest.cc
mvstanton 91c88644dc Move of the type feedback vector to the closure. 
We get less "pollution" of type feedback if we have one vector per native
context, rather than one for the whole system. This CL moves the vector
appropriately.

BUG=

Review-Url: https://codereview.chromium.org/1906823002
Cr-Commit-Position: refs/heads/master@{#36539}
2016-05-27 08:10:51 +00:00

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// Copyright 2015 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/interpreter/interpreter-assembler-unittest.h"
#include "src/code-factory.h"
#include "src/compiler/graph.h"
#include "src/compiler/node.h"
#include "src/interface-descriptors.h"
#include "src/isolate.h"
#include "test/unittests/compiler/compiler-test-utils.h"
#include "test/unittests/compiler/node-test-utils.h"
using ::testing::_;
namespace v8 {
namespace internal {
using namespace compiler;
namespace interpreter {
const interpreter::Bytecode kBytecodes[] = {
#define DEFINE_BYTECODE(Name, ...) interpreter::Bytecode::k##Name,
BYTECODE_LIST(DEFINE_BYTECODE)
#undef DEFINE_BYTECODE
};
Matcher<Node*> IsIntPtrConstant(const intptr_t value) {
return kPointerSize == 8 ? IsInt64Constant(static_cast<int64_t>(value))
: IsInt32Constant(static_cast<int32_t>(value));
}
Matcher<Node*> IsIntPtrAdd(const Matcher<Node*>& lhs_matcher,
const Matcher<Node*>& rhs_matcher) {
return kPointerSize == 8 ? IsInt64Add(lhs_matcher, rhs_matcher)
: IsInt32Add(lhs_matcher, rhs_matcher);
}
Matcher<Node*> IsIntPtrSub(const Matcher<Node*>& lhs_matcher,
const Matcher<Node*>& rhs_matcher) {
return kPointerSize == 8 ? IsInt64Sub(lhs_matcher, rhs_matcher)
: IsInt32Sub(lhs_matcher, rhs_matcher);
}
Matcher<Node*> IsWordShl(const Matcher<Node*>& lhs_matcher,
const Matcher<Node*>& rhs_matcher) {
return kPointerSize == 8 ? IsWord64Shl(lhs_matcher, rhs_matcher)
: IsWord32Shl(lhs_matcher, rhs_matcher);
}
Matcher<Node*> IsWordSar(const Matcher<Node*>& lhs_matcher,
const Matcher<Node*>& rhs_matcher) {
return kPointerSize == 8 ? IsWord64Sar(lhs_matcher, rhs_matcher)
: IsWord32Sar(lhs_matcher, rhs_matcher);
}
Matcher<Node*> IsWordOr(const Matcher<Node*>& lhs_matcher,
const Matcher<Node*>& rhs_matcher) {
return kPointerSize == 8 ? IsWord64Or(lhs_matcher, rhs_matcher)
: IsWord32Or(lhs_matcher, rhs_matcher);
}
InterpreterAssemblerTest::InterpreterAssemblerForTest::
~InterpreterAssemblerForTest() {
// Tests don't necessarily read and write accumulator but
// InterpreterAssembler checks accumulator uses.
if (Bytecodes::ReadsAccumulator(bytecode())) {
GetAccumulator();
}
if (Bytecodes::WritesAccumulator(bytecode())) {
SetAccumulator(nullptr);
}
}
Matcher<Node*> InterpreterAssemblerTest::InterpreterAssemblerForTest::IsLoad(
const Matcher<LoadRepresentation>& rep_matcher,
const Matcher<Node*>& base_matcher, const Matcher<Node*>& index_matcher) {
return ::i::compiler::IsLoad(rep_matcher, base_matcher, index_matcher, _, _);
}
Matcher<Node*> InterpreterAssemblerTest::InterpreterAssemblerForTest::IsStore(
const Matcher<StoreRepresentation>& rep_matcher,
const Matcher<Node*>& base_matcher, const Matcher<Node*>& index_matcher,
const Matcher<Node*>& value_matcher) {
return ::i::compiler::IsStore(rep_matcher, base_matcher, index_matcher,
value_matcher, _, _);
}
Matcher<Node*>
InterpreterAssemblerTest::InterpreterAssemblerForTest::IsUnsignedByteOperand(
int offset) {
return IsLoad(
MachineType::Uint8(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrAdd(
IsParameter(InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(offset)));
}
Matcher<Node*>
InterpreterAssemblerTest::InterpreterAssemblerForTest::IsSignedByteOperand(
int offset) {
Matcher<Node*> load_matcher = IsLoad(
MachineType::Int8(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrAdd(
IsParameter(InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(offset)));
if (kPointerSize == 8) {
load_matcher = IsChangeInt32ToInt64(load_matcher);
}
return load_matcher;
}
Matcher<Node*>
InterpreterAssemblerTest::InterpreterAssemblerForTest::IsUnsignedShortOperand(
int offset) {
if (TargetSupportsUnalignedAccess()) {
return IsLoad(
MachineType::Uint16(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrAdd(
IsParameter(
InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(offset)));
} else {
#if V8_TARGET_LITTLE_ENDIAN
const int kStep = -1;
const int kMsbOffset = 1;
#elif V8_TARGET_BIG_ENDIAN
const int kStep = 1;
const int kMsbOffset = 0;
#else
#error "Unknown Architecture"
#endif
Matcher<Node*> bytes[2];
for (int i = 0; i < static_cast<int>(arraysize(bytes)); i++) {
bytes[i] = IsLoad(
MachineType::Uint8(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrAdd(
IsParameter(
InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(offset + kMsbOffset + kStep * i)));
}
return IsWord32Or(IsWord32Shl(bytes[0], IsInt32Constant(kBitsPerByte)),
bytes[1]);
}
}
Matcher<Node*>
InterpreterAssemblerTest::InterpreterAssemblerForTest::IsSignedShortOperand(
int offset) {
Matcher<Node*> load_matcher;
if (TargetSupportsUnalignedAccess()) {
load_matcher = IsLoad(
MachineType::Int16(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrAdd(
IsParameter(
InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(offset)));
} else {
#if V8_TARGET_LITTLE_ENDIAN
const int kStep = -1;
const int kMsbOffset = 1;
#elif V8_TARGET_BIG_ENDIAN
const int kStep = 1;
const int kMsbOffset = 0;
#else
#error "Unknown Architecture"
#endif
Matcher<Node*> bytes[2];
for (int i = 0; i < static_cast<int>(arraysize(bytes)); i++) {
bytes[i] = IsLoad(
(i == 0) ? MachineType::Int8() : MachineType::Uint8(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrAdd(
IsParameter(
InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(offset + kMsbOffset + kStep * i)));
}
load_matcher = IsWord32Or(
IsWord32Shl(bytes[0], IsInt32Constant(kBitsPerByte)), bytes[1]);
}
if (kPointerSize == 8) {
load_matcher = IsChangeInt32ToInt64(load_matcher);
}
return load_matcher;
}
Matcher<Node*>
InterpreterAssemblerTest::InterpreterAssemblerForTest::IsUnsignedQuadOperand(
int offset) {
if (TargetSupportsUnalignedAccess()) {
return IsLoad(
MachineType::Uint32(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrAdd(
IsParameter(
InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(offset)));
} else {
#if V8_TARGET_LITTLE_ENDIAN
const int kStep = -1;
const int kMsbOffset = 3;
#elif V8_TARGET_BIG_ENDIAN
const int kStep = 1;
const int kMsbOffset = 0;
#else
#error "Unknown Architecture"
#endif
Matcher<Node*> bytes[4];
for (int i = 0; i < static_cast<int>(arraysize(bytes)); i++) {
bytes[i] = IsLoad(
MachineType::Uint8(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrAdd(
IsParameter(
InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(offset + kMsbOffset + kStep * i)));
}
return IsWord32Or(
IsWord32Shl(bytes[0], IsInt32Constant(3 * kBitsPerByte)),
IsWord32Or(
IsWord32Shl(bytes[1], IsInt32Constant(2 * kBitsPerByte)),
IsWord32Or(IsWord32Shl(bytes[2], IsInt32Constant(1 * kBitsPerByte)),
bytes[3])));
}
}
Matcher<Node*>
InterpreterAssemblerTest::InterpreterAssemblerForTest::IsSignedQuadOperand(
int offset) {
Matcher<Node*> load_matcher;
if (TargetSupportsUnalignedAccess()) {
load_matcher = IsLoad(
MachineType::Int32(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrAdd(
IsParameter(
InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(offset)));
} else {
#if V8_TARGET_LITTLE_ENDIAN
const int kStep = -1;
int kMsbOffset = 3;
#elif V8_TARGET_BIG_ENDIAN
const int kStep = 1;
int kMsbOffset = 0;
#else
#error "Unknown Architecture"
#endif
Matcher<Node*> bytes[4];
for (int i = 0; i < static_cast<int>(arraysize(bytes)); i++) {
bytes[i] = IsLoad(
(i == 0) ? MachineType::Int8() : MachineType::Uint8(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrAdd(
IsParameter(
InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(offset + kMsbOffset + kStep * i)));
}
load_matcher = IsWord32Or(
IsWord32Shl(bytes[0], IsInt32Constant(3 * kBitsPerByte)),
IsWord32Or(
IsWord32Shl(bytes[1], IsInt32Constant(2 * kBitsPerByte)),
IsWord32Or(IsWord32Shl(bytes[2], IsInt32Constant(1 * kBitsPerByte)),
bytes[3])));
}
if (kPointerSize == 8) {
load_matcher = IsChangeInt32ToInt64(load_matcher);
}
return load_matcher;
}
Matcher<Node*>
InterpreterAssemblerTest::InterpreterAssemblerForTest::IsSignedOperand(
int offset, OperandSize operand_size) {
switch (operand_size) {
case OperandSize::kByte:
return IsSignedByteOperand(offset);
case OperandSize::kShort:
return IsSignedShortOperand(offset);
case OperandSize::kQuad:
return IsSignedQuadOperand(offset);
case OperandSize::kNone:
UNREACHABLE();
}
return nullptr;
}
Matcher<Node*>
InterpreterAssemblerTest::InterpreterAssemblerForTest::IsUnsignedOperand(
int offset, OperandSize operand_size) {
switch (operand_size) {
case OperandSize::kByte:
return IsUnsignedByteOperand(offset);
case OperandSize::kShort:
return IsUnsignedShortOperand(offset);
case OperandSize::kQuad:
return IsUnsignedQuadOperand(offset);
case OperandSize::kNone:
UNREACHABLE();
}
return nullptr;
}
TARGET_TEST_F(InterpreterAssemblerTest, Dispatch) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* tail_call_node = m.Dispatch();
OperandScale operand_scale = OperandScale::kSingle;
Matcher<Node*> next_bytecode_offset_matcher = IsIntPtrAdd(
IsParameter(InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(
interpreter::Bytecodes::Size(bytecode, operand_scale)));
Matcher<Node*> target_bytecode_matcher = m.IsLoad(
MachineType::Uint8(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
next_bytecode_offset_matcher);
if (kPointerSize == 8) {
target_bytecode_matcher = IsChangeUint32ToUint64(target_bytecode_matcher);
}
Matcher<Node*> code_target_matcher = m.IsLoad(
MachineType::Pointer(),
IsParameter(InterpreterDispatchDescriptor::kDispatchTableParameter),
IsWordShl(target_bytecode_matcher, IsIntPtrConstant(kPointerSizeLog2)));
EXPECT_THAT(
tail_call_node,
IsTailCall(
_, code_target_matcher,
IsParameter(InterpreterDispatchDescriptor::kAccumulatorParameter),
next_bytecode_offset_matcher,
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsParameter(InterpreterDispatchDescriptor::kDispatchTableParameter),
_, _));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, Jump) {
// If debug code is enabled we emit extra code in Jump.
if (FLAG_debug_code) return;
int jump_offsets[] = {-9710, -77, 0, +3, +97109};
TRACED_FOREACH(int, jump_offset, jump_offsets) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* tail_call_node = m.Jump(m.IntPtrConstant(jump_offset));
Matcher<Node*> next_bytecode_offset_matcher = IsIntPtrAdd(
IsParameter(InterpreterDispatchDescriptor::kBytecodeOffsetParameter),
IsIntPtrConstant(jump_offset));
Matcher<Node*> target_bytecode_matcher =
m.IsLoad(MachineType::Uint8(), _, next_bytecode_offset_matcher);
if (kPointerSize == 8) {
target_bytecode_matcher =
IsChangeUint32ToUint64(target_bytecode_matcher);
}
Matcher<Node*> code_target_matcher = m.IsLoad(
MachineType::Pointer(),
IsParameter(InterpreterDispatchDescriptor::kDispatchTableParameter),
IsWordShl(target_bytecode_matcher,
IsIntPtrConstant(kPointerSizeLog2)));
EXPECT_THAT(
tail_call_node,
IsTailCall(
_, code_target_matcher,
IsParameter(InterpreterDispatchDescriptor::kAccumulatorParameter),
next_bytecode_offset_matcher, _,
IsParameter(
InterpreterDispatchDescriptor::kDispatchTableParameter),
_, _));
}
}
}
TARGET_TEST_F(InterpreterAssemblerTest, BytecodeOperand) {
static const OperandScale kOperandScales[] = {
OperandScale::kSingle, OperandScale::kDouble, OperandScale::kQuadruple};
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
TRACED_FOREACH(interpreter::OperandScale, operand_scale, kOperandScales) {
InterpreterAssemblerForTest m(this, bytecode, operand_scale);
int number_of_operands =
interpreter::Bytecodes::NumberOfOperands(bytecode);
for (int i = 0; i < number_of_operands; i++) {
int offset = interpreter::Bytecodes::GetOperandOffset(bytecode, i,
operand_scale);
OperandType operand_type =
interpreter::Bytecodes::GetOperandType(bytecode, i);
OperandSize operand_size =
Bytecodes::SizeOfOperand(operand_type, operand_scale);
switch (interpreter::Bytecodes::GetOperandType(bytecode, i)) {
case interpreter::OperandType::kRegCount:
EXPECT_THAT(m.BytecodeOperandCount(i),
m.IsUnsignedOperand(offset, operand_size));
break;
case interpreter::OperandType::kFlag8:
EXPECT_THAT(m.BytecodeOperandFlag(i),
m.IsUnsignedOperand(offset, operand_size));
break;
case interpreter::OperandType::kIdx:
EXPECT_THAT(m.BytecodeOperandIdx(i),
m.IsUnsignedOperand(offset, operand_size));
break;
case interpreter::OperandType::kImm: {
EXPECT_THAT(m.BytecodeOperandImm(i),
m.IsSignedOperand(offset, operand_size));
break;
}
case interpreter::OperandType::kMaybeReg:
case interpreter::OperandType::kReg:
case interpreter::OperandType::kRegOut:
case interpreter::OperandType::kRegOutPair:
case interpreter::OperandType::kRegOutTriple:
case interpreter::OperandType::kRegPair:
EXPECT_THAT(m.BytecodeOperandReg(i),
m.IsSignedOperand(offset, operand_size));
break;
case interpreter::OperandType::kRuntimeId:
EXPECT_THAT(m.BytecodeOperandRuntimeId(i),
m.IsUnsignedOperand(offset, operand_size));
break;
case interpreter::OperandType::kNone:
UNREACHABLE();
break;
}
}
}
}
}
TARGET_TEST_F(InterpreterAssemblerTest, GetSetAccumulator) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
if (!interpreter::Bytecodes::ReadsAccumulator(bytecode) ||
!interpreter::Bytecodes::WritesAccumulator(bytecode)) {
continue;
}
InterpreterAssemblerForTest m(this, bytecode);
// Should be incoming accumulator if not set.
EXPECT_THAT(
m.GetAccumulator(),
IsParameter(InterpreterDispatchDescriptor::kAccumulatorParameter));
// Should be set by SetAccumulator.
Node* accumulator_value_1 = m.Int32Constant(0xdeadbeef);
m.SetAccumulator(accumulator_value_1);
EXPECT_THAT(m.GetAccumulator(), accumulator_value_1);
Node* accumulator_value_2 = m.Int32Constant(42);
m.SetAccumulator(accumulator_value_2);
EXPECT_THAT(m.GetAccumulator(), accumulator_value_2);
// Should be passed to next bytecode handler on dispatch.
Node* tail_call_node = m.Dispatch();
EXPECT_THAT(tail_call_node,
IsTailCall(_, _, accumulator_value_2, _, _, _, _));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, GetContext) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
EXPECT_THAT(
m.GetContext(),
m.IsLoad(MachineType::AnyTagged(), IsLoadParentFramePointer(),
IsIntPtrConstant(Register::current_context().ToOperand()
<< kPointerSizeLog2)));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, RegisterLocation) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* reg_index_node = m.IntPtrConstant(44);
Node* reg_location_node = m.RegisterLocation(reg_index_node);
EXPECT_THAT(reg_location_node,
IsIntPtrAdd(IsLoadParentFramePointer(),
IsWordShl(reg_index_node,
IsIntPtrConstant(kPointerSizeLog2))));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, LoadRegister) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* reg_index_node = m.IntPtrConstant(44);
Node* load_reg_node = m.LoadRegister(reg_index_node);
EXPECT_THAT(load_reg_node,
m.IsLoad(MachineType::AnyTagged(), IsLoadParentFramePointer(),
IsWordShl(reg_index_node,
IsIntPtrConstant(kPointerSizeLog2))));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, StoreRegister) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* store_value = m.Int32Constant(0xdeadbeef);
Node* reg_index_node = m.IntPtrConstant(44);
Node* store_reg_node = m.StoreRegister(store_value, reg_index_node);
EXPECT_THAT(
store_reg_node,
m.IsStore(StoreRepresentation(MachineRepresentation::kTagged,
kNoWriteBarrier),
IsLoadParentFramePointer(),
IsWordShl(reg_index_node, IsIntPtrConstant(kPointerSizeLog2)),
store_value));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, SmiTag) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* value = m.Int32Constant(44);
EXPECT_THAT(m.SmiTag(value),
IsIntPtrConstant(static_cast<intptr_t>(44)
<< (kSmiShiftSize + kSmiTagSize)));
EXPECT_THAT(
m.SmiUntag(value),
IsWordSar(value, IsIntPtrConstant(kSmiShiftSize + kSmiTagSize)));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, IntPtrAdd) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* a = m.Int32Constant(0);
Node* b = m.Int32Constant(1);
Node* add = m.IntPtrAdd(a, b);
EXPECT_THAT(add, IsIntPtrAdd(a, b));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, IntPtrSub) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* a = m.Int32Constant(0);
Node* b = m.Int32Constant(1);
Node* add = m.IntPtrSub(a, b);
EXPECT_THAT(add, IsIntPtrSub(a, b));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, WordShl) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* a = m.IntPtrConstant(0);
Node* add = m.WordShl(a, 10);
EXPECT_THAT(add, IsWordShl(a, IsIntPtrConstant(10)));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, LoadConstantPoolEntry) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* index = m.IntPtrConstant(2);
Node* load_constant = m.LoadConstantPoolEntry(index);
Matcher<Node*> constant_pool_matcher = m.IsLoad(
MachineType::AnyTagged(),
IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter),
IsIntPtrConstant(BytecodeArray::kConstantPoolOffset - kHeapObjectTag));
EXPECT_THAT(
load_constant,
m.IsLoad(MachineType::AnyTagged(), constant_pool_matcher,
IsIntPtrAdd(
IsIntPtrConstant(FixedArray::kHeaderSize - kHeapObjectTag),
IsWordShl(index, IsIntPtrConstant(kPointerSizeLog2)))));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, LoadObjectField) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* object = m.IntPtrConstant(0xdeadbeef);
int offset = 16;
Node* load_field = m.LoadObjectField(object, offset);
EXPECT_THAT(load_field,
m.IsLoad(MachineType::AnyTagged(), object,
IsIntPtrConstant(offset - kHeapObjectTag)));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, LoadContextSlot) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* context = m.IntPtrConstant(1);
Node* slot_index = m.IntPtrConstant(22);
Node* load_context_slot = m.LoadContextSlot(context, slot_index);
Matcher<Node*> offset =
IsIntPtrAdd(IsWordShl(slot_index, IsIntPtrConstant(kPointerSizeLog2)),
IsIntPtrConstant(Context::kHeaderSize - kHeapObjectTag));
EXPECT_THAT(load_context_slot,
m.IsLoad(MachineType::AnyTagged(), context, offset));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, StoreContextSlot) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* context = m.IntPtrConstant(1);
Node* slot_index = m.IntPtrConstant(22);
Node* value = m.SmiConstant(Smi::FromInt(100));
Node* store_context_slot = m.StoreContextSlot(context, slot_index, value);
Matcher<Node*> offset =
IsIntPtrAdd(IsWordShl(slot_index, IsIntPtrConstant(kPointerSizeLog2)),
IsIntPtrConstant(Context::kHeaderSize - kHeapObjectTag));
EXPECT_THAT(store_context_slot,
m.IsStore(StoreRepresentation(MachineRepresentation::kTagged,
kFullWriteBarrier),
context, offset, value));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, CallRuntime2) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* arg1 = m.Int32Constant(2);
Node* arg2 = m.Int32Constant(3);
Node* context = m.Int32Constant(4);
Node* call_runtime = m.CallRuntime(Runtime::kAdd, context, arg1, arg2);
EXPECT_THAT(call_runtime,
IsCall(_, _, arg1, arg2, _, IsInt32Constant(2), context, _, _));
}
}
TARGET_TEST_F(InterpreterAssemblerTest, CallRuntime) {
const int kResultSizes[] = {1, 2};
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
TRACED_FOREACH(int, result_size, kResultSizes) {
InterpreterAssemblerForTest m(this, bytecode);
Callable builtin = CodeFactory::InterpreterCEntry(isolate(), result_size);
Node* function_id = m.Int32Constant(0);
Node* first_arg = m.Int32Constant(1);
Node* arg_count = m.Int32Constant(2);
Node* context = m.Int32Constant(4);
Matcher<Node*> function_table = IsExternalConstant(
ExternalReference::runtime_function_table_address(isolate()));
Matcher<Node*> function = IsIntPtrAdd(
function_table,
IsInt32Mul(function_id, IsInt32Constant(sizeof(Runtime::Function))));
Matcher<Node*> function_entry =
m.IsLoad(MachineType::Pointer(), function,
IsIntPtrConstant(offsetof(Runtime::Function, entry)));
Node* call_runtime = m.CallRuntimeN(function_id, context, first_arg,
arg_count, result_size);
EXPECT_THAT(call_runtime,
IsCall(_, IsHeapConstant(builtin.code()), arg_count,
first_arg, function_entry, context, _, _));
}
}
}
TARGET_TEST_F(InterpreterAssemblerTest, CallJS) {
TailCallMode tail_call_modes[] = {TailCallMode::kDisallow,
TailCallMode::kAllow};
TRACED_FOREACH(TailCallMode, tail_call_mode, tail_call_modes) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Callable builtin =
CodeFactory::InterpreterPushArgsAndCall(isolate(), tail_call_mode);
Node* function = m.Int32Constant(0);
Node* first_arg = m.Int32Constant(1);
Node* arg_count = m.Int32Constant(2);
Node* context = m.Int32Constant(3);
Node* call_js =
m.CallJS(function, context, first_arg, arg_count, tail_call_mode);
EXPECT_THAT(call_js, IsCall(_, IsHeapConstant(builtin.code()), arg_count,
first_arg, function, context, _, _));
}
}
}
TARGET_TEST_F(InterpreterAssemblerTest, LoadTypeFeedbackVector) {
TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) {
InterpreterAssemblerForTest m(this, bytecode);
Node* feedback_vector = m.LoadTypeFeedbackVector();
Matcher<Node*> load_function_matcher =
m.IsLoad(MachineType::AnyTagged(), IsLoadParentFramePointer(),
IsIntPtrConstant(Register::function_closure().ToOperand()
<< kPointerSizeLog2));
Matcher<Node*> load_literals_matcher = m.IsLoad(
MachineType::AnyTagged(), load_function_matcher,
IsIntPtrConstant(JSFunction::kLiteralsOffset - kHeapObjectTag));
EXPECT_THAT(feedback_vector,
m.IsLoad(MachineType::AnyTagged(), load_literals_matcher,
IsIntPtrConstant(LiteralsArray::kFeedbackVectorOffset -
kHeapObjectTag)));
}
}
} // namespace interpreter
} // namespace internal
} // namespace v8
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