// 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 IsIntPtrConstant(const intptr_t value) { return kPointerSize == 8 ? IsInt64Constant(static_cast(value)) : IsInt32Constant(static_cast(value)); } Matcher IsIntPtrAdd(const Matcher& lhs_matcher, const Matcher& rhs_matcher) { return kPointerSize == 8 ? IsInt64Add(lhs_matcher, rhs_matcher) : IsInt32Add(lhs_matcher, rhs_matcher); } Matcher IsIntPtrSub(const Matcher& lhs_matcher, const Matcher& rhs_matcher) { return kPointerSize == 8 ? IsInt64Sub(lhs_matcher, rhs_matcher) : IsInt32Sub(lhs_matcher, rhs_matcher); } Matcher IsWordShl(const Matcher& lhs_matcher, const Matcher& rhs_matcher) { return kPointerSize == 8 ? IsWord64Shl(lhs_matcher, rhs_matcher) : IsWord32Shl(lhs_matcher, rhs_matcher); } Matcher IsWordSar(const Matcher& lhs_matcher, const Matcher& rhs_matcher) { return kPointerSize == 8 ? IsWord64Sar(lhs_matcher, rhs_matcher) : IsWord32Sar(lhs_matcher, rhs_matcher); } Matcher IsWordOr(const Matcher& lhs_matcher, const Matcher& rhs_matcher) { return kPointerSize == 8 ? IsWord64Or(lhs_matcher, rhs_matcher) : IsWord32Or(lhs_matcher, rhs_matcher); } Matcher InterpreterAssemblerTest::InterpreterAssemblerForTest::IsLoad( const Matcher& rep_matcher, const Matcher& base_matcher, const Matcher& index_matcher) { return ::i::compiler::IsLoad(rep_matcher, base_matcher, index_matcher, _, _); } Matcher InterpreterAssemblerTest::InterpreterAssemblerForTest::IsStore( const Matcher& rep_matcher, const Matcher& base_matcher, const Matcher& index_matcher, const Matcher& value_matcher) { return ::i::compiler::IsStore(rep_matcher, base_matcher, index_matcher, value_matcher, _, _); } Matcher InterpreterAssemblerTest::InterpreterAssemblerForTest::IsBytecodeOperand( int offset) { return IsLoad( MachineType::Uint8(), IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter), IsIntPtrAdd( IsParameter(InterpreterDispatchDescriptor::kBytecodeOffsetParameter), IsIntPtrConstant(offset))); } Matcher InterpreterAssemblerTest::InterpreterAssemblerForTest:: IsBytecodeOperandSignExtended(int offset) { Matcher 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 InterpreterAssemblerTest::InterpreterAssemblerForTest::IsBytecodeOperandShort( int offset) { if (TargetSupportsUnalignedAccess()) { return IsLoad( MachineType::Uint16(), IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter), IsIntPtrAdd( IsParameter( InterpreterDispatchDescriptor::kBytecodeOffsetParameter), IsIntPtrConstant(offset))); } else { Matcher first_byte = IsLoad( MachineType::Uint8(), IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter), IsIntPtrAdd( IsParameter( InterpreterDispatchDescriptor::kBytecodeOffsetParameter), IsIntPtrConstant(offset))); Matcher second_byte = IsLoad( MachineType::Uint8(), IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter), IsIntPtrAdd( IsParameter( InterpreterDispatchDescriptor::kBytecodeOffsetParameter), IsIntPtrConstant(offset + 1))); #if V8_TARGET_LITTLE_ENDIAN return IsWordOr(IsWordShl(second_byte, IsIntPtrConstant(kBitsPerByte)), first_byte); #elif V8_TARGET_BIG_ENDIAN return IsWordOr(IsWordShl(first_byte, IsIntPtrConstant(kBitsPerByte)), second_byte); #else #error "Unknown Architecture" #endif } } Matcher InterpreterAssemblerTest::InterpreterAssemblerForTest:: IsBytecodeOperandShortSignExtended(int offset) { Matcher load_matcher; if (TargetSupportsUnalignedAccess()) { load_matcher = IsLoad( MachineType::Int16(), IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter), IsIntPtrAdd( IsParameter( InterpreterDispatchDescriptor::kBytecodeOffsetParameter), IsIntPtrConstant(offset))); } else { #if V8_TARGET_LITTLE_ENDIAN int hi_byte_offset = offset + 1; int lo_byte_offset = offset; #elif V8_TARGET_BIG_ENDIAN int hi_byte_offset = offset; int lo_byte_offset = offset + 1; #else #error "Unknown Architecture" #endif Matcher hi_byte = IsLoad( MachineType::Int8(), IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter), IsIntPtrAdd( IsParameter( InterpreterDispatchDescriptor::kBytecodeOffsetParameter), IsIntPtrConstant(hi_byte_offset))); hi_byte = IsWord32Shl(hi_byte, IsInt32Constant(kBitsPerByte)); Matcher lo_byte = IsLoad( MachineType::Uint8(), IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter), IsIntPtrAdd( IsParameter( InterpreterDispatchDescriptor::kBytecodeOffsetParameter), IsIntPtrConstant(lo_byte_offset))); load_matcher = IsWord32Or(hi_byte, lo_byte); } if (kPointerSize == 8) { load_matcher = IsChangeInt32ToInt64(load_matcher); } return load_matcher; } TARGET_TEST_F(InterpreterAssemblerTest, Dispatch) { TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) { InterpreterAssemblerForTest m(this, bytecode); m.Dispatch(); Graph* graph = m.graph(); Node* end = graph->end(); EXPECT_EQ(1, end->InputCount()); Node* tail_call_node = end->InputAt(0); Matcher next_bytecode_offset_matcher = IsIntPtrAdd( IsParameter(InterpreterDispatchDescriptor::kBytecodeOffsetParameter), IsIntPtrConstant(interpreter::Bytecodes::Size(bytecode))); Matcher 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 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), IsParameter(InterpreterDispatchDescriptor::kRegisterFileParameter), next_bytecode_offset_matcher, IsParameter(InterpreterDispatchDescriptor::kBytecodeArrayParameter), IsParameter(InterpreterDispatchDescriptor::kDispatchTableParameter), IsParameter(InterpreterDispatchDescriptor::kContextParameter), _, _)); } } 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); m.Jump(m.IntPtrConstant(jump_offset)); Graph* graph = m.graph(); Node* end = graph->end(); EXPECT_EQ(1, end->InputCount()); Node* tail_call_node = end->InputAt(0); Matcher next_bytecode_offset_matcher = IsIntPtrAdd( IsParameter(InterpreterDispatchDescriptor::kBytecodeOffsetParameter), IsIntPtrConstant(jump_offset)); Matcher target_bytecode_matcher = m.IsLoad(MachineType::Uint8(), _, next_bytecode_offset_matcher); if (kPointerSize == 8) { target_bytecode_matcher = IsChangeUint32ToUint64(target_bytecode_matcher); } Matcher 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), IsParameter( InterpreterDispatchDescriptor::kRegisterFileParameter), next_bytecode_offset_matcher, _, IsParameter( InterpreterDispatchDescriptor::kDispatchTableParameter), IsParameter(InterpreterDispatchDescriptor::kContextParameter), _, _)); } } } TARGET_TEST_F(InterpreterAssemblerTest, JumpIfWordEqual) { static const int kJumpIfTrueOffset = 73; // If debug code is enabled we emit extra code in Jump. if (FLAG_debug_code) return; MachineOperatorBuilder machine(zone()); TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) { InterpreterAssemblerForTest m(this, bytecode); Node* lhs = m.IntPtrConstant(0); Node* rhs = m.IntPtrConstant(1); m.JumpIfWordEqual(lhs, rhs, m.IntPtrConstant(kJumpIfTrueOffset)); Graph* graph = m.graph(); Node* end = graph->end(); EXPECT_EQ(2, end->InputCount()); int jump_offsets[] = {kJumpIfTrueOffset, interpreter::Bytecodes::Size(bytecode)}; for (int i = 0; i < static_cast(arraysize(jump_offsets)); i++) { Matcher next_bytecode_offset_matcher = IsIntPtrAdd( IsParameter(InterpreterDispatchDescriptor::kBytecodeOffsetParameter), IsIntPtrConstant(jump_offsets[i])); Matcher target_bytecode_matcher = m.IsLoad(MachineType::Uint8(), _, next_bytecode_offset_matcher); if (kPointerSize == 8) { target_bytecode_matcher = IsChangeUint32ToUint64(target_bytecode_matcher); } Matcher code_target_matcher = m.IsLoad( MachineType::Pointer(), IsParameter(InterpreterDispatchDescriptor::kDispatchTableParameter), IsWordShl(target_bytecode_matcher, IsIntPtrConstant(kPointerSizeLog2))); EXPECT_THAT( end->InputAt(i), IsTailCall( _, code_target_matcher, IsParameter(InterpreterDispatchDescriptor::kAccumulatorParameter), IsParameter( InterpreterDispatchDescriptor::kRegisterFileParameter), next_bytecode_offset_matcher, _, IsParameter( InterpreterDispatchDescriptor::kDispatchTableParameter), IsParameter(InterpreterDispatchDescriptor::kContextParameter), _, _)); } // TODO(oth): test control flow paths. } } TARGET_TEST_F(InterpreterAssemblerTest, InterpreterReturn) { // If debug code is enabled we emit extra code in InterpreterReturn. if (FLAG_debug_code) return; TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) { InterpreterAssemblerForTest m(this, bytecode); m.InterpreterReturn(); Graph* graph = m.graph(); Node* end = graph->end(); EXPECT_EQ(1, end->InputCount()); Node* tail_call_node = end->InputAt(0); Handle exit_trampoline = isolate()->builtins()->InterpreterExitTrampoline(); EXPECT_THAT( tail_call_node, IsTailCall( _, IsHeapConstant(exit_trampoline), IsParameter(InterpreterDispatchDescriptor::kAccumulatorParameter), IsParameter(InterpreterDispatchDescriptor::kRegisterFileParameter), IsParameter( InterpreterDispatchDescriptor::kBytecodeOffsetParameter), _, IsParameter(InterpreterDispatchDescriptor::kDispatchTableParameter), IsParameter(InterpreterDispatchDescriptor::kContextParameter), _, _)); } } TARGET_TEST_F(InterpreterAssemblerTest, BytecodeOperand) { TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) { InterpreterAssemblerForTest m(this, bytecode); int number_of_operands = interpreter::Bytecodes::NumberOfOperands(bytecode); for (int i = 0; i < number_of_operands; i++) { int offset = interpreter::Bytecodes::GetOperandOffset(bytecode, i); switch (interpreter::Bytecodes::GetOperandType(bytecode, i)) { case interpreter::OperandType::kRegCount8: EXPECT_THAT(m.BytecodeOperandCount(i), m.IsBytecodeOperand(offset)); break; case interpreter::OperandType::kIdx8: EXPECT_THAT(m.BytecodeOperandIdx(i), m.IsBytecodeOperand(offset)); break; case interpreter::OperandType::kImm8: EXPECT_THAT(m.BytecodeOperandImm(i), m.IsBytecodeOperandSignExtended(offset)); break; case interpreter::OperandType::kMaybeReg8: case interpreter::OperandType::kReg8: case interpreter::OperandType::kRegOut8: case interpreter::OperandType::kRegOutPair8: case interpreter::OperandType::kRegOutTriple8: case interpreter::OperandType::kRegPair8: EXPECT_THAT(m.BytecodeOperandReg(i), m.IsBytecodeOperandSignExtended(offset)); break; case interpreter::OperandType::kRegCount16: EXPECT_THAT(m.BytecodeOperandCount(i), m.IsBytecodeOperandShort(offset)); break; case interpreter::OperandType::kIdx16: EXPECT_THAT(m.BytecodeOperandIdx(i), m.IsBytecodeOperandShort(offset)); break; case interpreter::OperandType::kMaybeReg16: case interpreter::OperandType::kReg16: case interpreter::OperandType::kRegOut16: case interpreter::OperandType::kRegOutPair16: case interpreter::OperandType::kRegOutTriple16: case interpreter::OperandType::kRegPair16: EXPECT_THAT(m.BytecodeOperandReg(i), m.IsBytecodeOperandShortSignExtended(offset)); break; case interpreter::OperandType::kNone: UNREACHABLE(); break; } } } } TARGET_TEST_F(InterpreterAssemblerTest, GetSetAccumulator) { TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) { 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. m.Dispatch(); Graph* graph = m.graph(); Node* end = graph->end(); EXPECT_EQ(1, end->InputCount()); Node* tail_call_node = end->InputAt(0); EXPECT_THAT(tail_call_node, IsTailCall(_, _, accumulator_value_2, _, _, _, _, _, _)); } } TARGET_TEST_F(InterpreterAssemblerTest, GetSetContext) { TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) { InterpreterAssemblerForTest m(this, bytecode); Node* context_node = m.Int32Constant(100); m.SetContext(context_node); EXPECT_THAT(m.GetContext(), context_node); } } 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( IsParameter(InterpreterDispatchDescriptor::kRegisterFileParameter), 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(), IsParameter(InterpreterDispatchDescriptor::kRegisterFileParameter), 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), IsParameter(InterpreterDispatchDescriptor::kRegisterFileParameter), 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), IsWordShl(value, IsIntPtrConstant(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 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 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 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.Parameter(InterpreterDispatchDescriptor::kContextParameter); Node* call_runtime = m.CallRuntime(Runtime::kAdd, context, arg1, arg2); EXPECT_THAT( call_runtime, IsCall(_, _, arg1, arg2, _, IsInt32Constant(2), IsParameter(InterpreterDispatchDescriptor::kContextParameter), _, _)); } } 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.Parameter(InterpreterDispatchDescriptor::kContextParameter); Matcher function_table = IsExternalConstant( ExternalReference::runtime_function_table_address(isolate())); Matcher function = IsIntPtrAdd( function_table, IsInt32Mul(function_id, IsInt32Constant(sizeof(Runtime::Function)))); Matcher 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, IsParameter(InterpreterDispatchDescriptor::kContextParameter), _, _)); } } } 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.Parameter(InterpreterDispatchDescriptor::kContextParameter); 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, IsParameter(InterpreterDispatchDescriptor::kContextParameter), _, _)); } } } TARGET_TEST_F(InterpreterAssemblerTest, LoadTypeFeedbackVector) { TRACED_FOREACH(interpreter::Bytecode, bytecode, kBytecodes) { InterpreterAssemblerForTest m(this, bytecode); Node* feedback_vector = m.LoadTypeFeedbackVector(); Matcher load_function_matcher = m.IsLoad( MachineType::AnyTagged(), IsParameter(InterpreterDispatchDescriptor::kRegisterFileParameter), IsIntPtrConstant( InterpreterFrameConstants::kFunctionFromRegisterPointer)); Matcher load_shared_function_info_matcher = m.IsLoad(MachineType::AnyTagged(), load_function_matcher, IsIntPtrConstant(JSFunction::kSharedFunctionInfoOffset - kHeapObjectTag)); EXPECT_THAT( feedback_vector, m.IsLoad(MachineType::AnyTagged(), load_shared_function_info_matcher, IsIntPtrConstant(SharedFunctionInfo::kFeedbackVectorOffset - kHeapObjectTag))); } } } // namespace interpreter } // namespace internal } // namespace v8