// 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. #ifndef V8_UNITTESTS_COMPILER_INSTRUCTION_SELECTOR_UNITTEST_H_ #define V8_UNITTESTS_COMPILER_INSTRUCTION_SELECTOR_UNITTEST_H_ #include #include #include "src/base/utils/random-number-generator.h" #include "src/compiler/instruction-selector.h" #include "src/compiler/raw-machine-assembler.h" #include "src/macro-assembler.h" #include "test/unittests/test-utils.h" namespace v8 { namespace internal { namespace compiler { class InstructionSelectorTest : public TestWithContext, public TestWithIsolateAndZone { public: InstructionSelectorTest(); ~InstructionSelectorTest() override; base::RandomNumberGenerator* rng() { return &rng_; } class Stream; enum StreamBuilderMode { kAllInstructions, kTargetInstructions, kAllExceptNopInstructions }; class StreamBuilder final : public RawMachineAssembler { public: StreamBuilder(InstructionSelectorTest* test, MachineType return_type) : RawMachineAssembler(test->isolate(), new (test->zone()) Graph(test->zone()), MakeCallDescriptor(test->zone(), return_type), MachineType::PointerRepresentation(), MachineOperatorBuilder::kAllOptionalOps), test_(test) {} StreamBuilder(InstructionSelectorTest* test, MachineType return_type, MachineType parameter0_type) : RawMachineAssembler( test->isolate(), new (test->zone()) Graph(test->zone()), MakeCallDescriptor(test->zone(), return_type, parameter0_type), MachineType::PointerRepresentation(), MachineOperatorBuilder::kAllOptionalOps), test_(test) {} StreamBuilder(InstructionSelectorTest* test, MachineType return_type, MachineType parameter0_type, MachineType parameter1_type) : RawMachineAssembler( test->isolate(), new (test->zone()) Graph(test->zone()), MakeCallDescriptor(test->zone(), return_type, parameter0_type, parameter1_type), MachineType::PointerRepresentation(), MachineOperatorBuilder::kAllOptionalOps), test_(test) {} StreamBuilder(InstructionSelectorTest* test, MachineType return_type, MachineType parameter0_type, MachineType parameter1_type, MachineType parameter2_type) : RawMachineAssembler( test->isolate(), new (test->zone()) Graph(test->zone()), MakeCallDescriptor(test->zone(), return_type, parameter0_type, parameter1_type, parameter2_type), MachineType::PointerRepresentation(), MachineOperatorBuilder::kAllOptionalOps), test_(test) {} Stream Build(CpuFeature feature) { return Build(InstructionSelector::Features(feature)); } Stream Build(CpuFeature feature1, CpuFeature feature2) { return Build(InstructionSelector::Features(feature1, feature2)); } Stream Build(StreamBuilderMode mode = kTargetInstructions) { return Build(InstructionSelector::Features(), mode); } Stream Build(InstructionSelector::Features features, StreamBuilderMode mode = kTargetInstructions, InstructionSelector::SourcePositionMode source_position_mode = InstructionSelector::kAllSourcePositions); const FrameStateFunctionInfo* GetFrameStateFunctionInfo(int parameter_count, int local_count); private: CallDescriptor* MakeCallDescriptor(Zone* zone, MachineType return_type) { MachineSignature::Builder builder(zone, 1, 0); builder.AddReturn(return_type); return MakeSimpleCallDescriptor(zone, builder.Build()); } CallDescriptor* MakeCallDescriptor(Zone* zone, MachineType return_type, MachineType parameter0_type) { MachineSignature::Builder builder(zone, 1, 1); builder.AddReturn(return_type); builder.AddParam(parameter0_type); return MakeSimpleCallDescriptor(zone, builder.Build()); } CallDescriptor* MakeCallDescriptor(Zone* zone, MachineType return_type, MachineType parameter0_type, MachineType parameter1_type) { MachineSignature::Builder builder(zone, 1, 2); builder.AddReturn(return_type); builder.AddParam(parameter0_type); builder.AddParam(parameter1_type); return MakeSimpleCallDescriptor(zone, builder.Build()); } CallDescriptor* MakeCallDescriptor(Zone* zone, MachineType return_type, MachineType parameter0_type, MachineType parameter1_type, MachineType parameter2_type) { MachineSignature::Builder builder(zone, 1, 3); builder.AddReturn(return_type); builder.AddParam(parameter0_type); builder.AddParam(parameter1_type); builder.AddParam(parameter2_type); return MakeSimpleCallDescriptor(zone, builder.Build()); } private: InstructionSelectorTest* test_; // Create a simple call descriptor for testing. CallDescriptor* MakeSimpleCallDescriptor(Zone* zone, MachineSignature* msig) { LocationSignature::Builder locations(zone, msig->return_count(), msig->parameter_count()); // Add return location(s). const int return_count = static_cast(msig->return_count()); for (int i = 0; i < return_count; i++) { locations.AddReturn( LinkageLocation::ForCallerFrameSlot(-1 - i, msig->GetReturn(i))); } // Just put all parameters on the stack. const int parameter_count = static_cast(msig->parameter_count()); for (int i = 0; i < parameter_count; i++) { locations.AddParam( LinkageLocation::ForCallerFrameSlot(-1 - i, msig->GetParam(i))); } const RegList kCalleeSaveRegisters = 0; const RegList kCalleeSaveFPRegisters = 0; MachineType target_type = MachineType::Pointer(); LinkageLocation target_loc = LinkageLocation::ForAnyRegister(); return new (zone) CallDescriptor( // -- CallDescriptor::kCallAddress, // kind target_type, // target MachineType target_loc, // target location locations.Build(), // location_sig 0, // stack_parameter_count Operator::kNoProperties, // properties kCalleeSaveRegisters, // callee-saved registers kCalleeSaveFPRegisters, // callee-saved fp regs CallDescriptor::kNoFlags, // flags "iselect-test-call"); } }; class Stream final { public: size_t size() const { return instructions_.size(); } const Instruction* operator[](size_t index) const { EXPECT_LT(index, size()); return instructions_[index]; } bool IsDouble(const InstructionOperand* operand) const { return IsDouble(ToVreg(operand)); } bool IsDouble(const Node* node) const { return IsDouble(ToVreg(node)); } bool IsInteger(const InstructionOperand* operand) const { return IsInteger(ToVreg(operand)); } bool IsInteger(const Node* node) const { return IsInteger(ToVreg(node)); } bool IsReference(const InstructionOperand* operand) const { return IsReference(ToVreg(operand)); } bool IsReference(const Node* node) const { return IsReference(ToVreg(node)); } float ToFloat32(const InstructionOperand* operand) const { return ToConstant(operand).ToFloat32(); } double ToFloat64(const InstructionOperand* operand) const { return ToConstant(operand).ToFloat64(); } int32_t ToInt32(const InstructionOperand* operand) const { return ToConstant(operand).ToInt32(); } int64_t ToInt64(const InstructionOperand* operand) const { return ToConstant(operand).ToInt64(); } Handle ToHeapObject(const InstructionOperand* operand) const { return ToConstant(operand).ToHeapObject(); } int ToVreg(const InstructionOperand* operand) const { if (operand->IsConstant()) { return ConstantOperand::cast(operand)->virtual_register(); } EXPECT_EQ(InstructionOperand::UNALLOCATED, operand->kind()); return UnallocatedOperand::cast(operand)->virtual_register(); } int ToVreg(const Node* node) const; bool IsFixed(const InstructionOperand* operand, Register reg) const; bool IsSameAsFirst(const InstructionOperand* operand) const; bool IsUsedAtStart(const InstructionOperand* operand) const; FrameStateDescriptor* GetFrameStateDescriptor(int deoptimization_id) { EXPECT_LT(deoptimization_id, GetFrameStateDescriptorCount()); return deoptimization_entries_[deoptimization_id]; } int GetFrameStateDescriptorCount() { return static_cast(deoptimization_entries_.size()); } private: bool IsDouble(int virtual_register) const { return doubles_.find(virtual_register) != doubles_.end(); } bool IsInteger(int virtual_register) const { return !IsDouble(virtual_register) && !IsReference(virtual_register); } bool IsReference(int virtual_register) const { return references_.find(virtual_register) != references_.end(); } Constant ToConstant(const InstructionOperand* operand) const { ConstantMap::const_iterator i; if (operand->IsConstant()) { i = constants_.find(ConstantOperand::cast(operand)->virtual_register()); EXPECT_EQ(ConstantOperand::cast(operand)->virtual_register(), i->first); EXPECT_FALSE(constants_.end() == i); } else { EXPECT_EQ(InstructionOperand::IMMEDIATE, operand->kind()); auto imm = ImmediateOperand::cast(operand); if (imm->type() == ImmediateOperand::INLINE) { return Constant(imm->inline_value()); } i = immediates_.find(imm->indexed_value()); EXPECT_EQ(imm->indexed_value(), i->first); EXPECT_FALSE(immediates_.end() == i); } return i->second; } friend class StreamBuilder; typedef std::map ConstantMap; typedef std::map VirtualRegisters; ConstantMap constants_; ConstantMap immediates_; std::deque instructions_; std::set doubles_; std::set references_; VirtualRegisters virtual_registers_; std::deque deoptimization_entries_; }; base::RandomNumberGenerator rng_; }; template class InstructionSelectorTestWithParam : public InstructionSelectorTest, public ::testing::WithParamInterface {}; } // namespace compiler } // namespace internal } // namespace v8 #endif // V8_UNITTESTS_COMPILER_INSTRUCTION_SELECTOR_UNITTEST_H_