v8/test/unittests/compiler/backend/instruction-sequence-unittest.h
Clemens Hammacher ed4b4cd482 Use static RegisterName function instead of RegisterConfiguration
Register names are static, so we do not need to access them via
RegisterConfiguration. This saves a lot of RegisterConfiguration
object creations.

R=mstarzinger@chromium.org

Bug: v8:8238
Change-Id: I295ad4d4b13fe948c70490687b7e3e9b48e70af9
Reviewed-on: https://chromium-review.googlesource.com/c/1342517
Reviewed-by: Jaroslav Sevcik <jarin@chromium.org>
Reviewed-by: Michael Starzinger <mstarzinger@chromium.org>
Commit-Queue: Clemens Hammacher <clemensh@chromium.org>
Cr-Commit-Position: refs/heads/master@{#57668}
2018-11-21 10:24:13 +00:00

300 lines
10 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.
#ifndef V8_UNITTESTS_COMPILER_INSTRUCTION_SEQUENCE_UNITTEST_H_
#define V8_UNITTESTS_COMPILER_INSTRUCTION_SEQUENCE_UNITTEST_H_
#include <memory>
#include "src/compiler/backend/instruction.h"
#include "src/register-configuration.h"
#include "test/unittests/test-utils.h"
#include "testing/gmock/include/gmock/gmock.h"
namespace v8 {
namespace internal {
namespace compiler {
class InstructionSequenceTest : public TestWithIsolateAndZone {
public:
static constexpr int kNoValue = kMinInt;
static constexpr MachineRepresentation kNoRep = MachineRepresentation::kNone;
static constexpr MachineRepresentation kFloat32 =
MachineRepresentation::kFloat32;
static constexpr MachineRepresentation kFloat64 =
MachineRepresentation::kFloat64;
static constexpr MachineRepresentation kSimd128 =
MachineRepresentation::kSimd128;
typedef RpoNumber Rpo;
struct VReg {
VReg() : value_(kNoValue) {}
VReg(PhiInstruction* phi) : value_(phi->virtual_register()) {} // NOLINT
explicit VReg(int value, MachineRepresentation rep = kNoRep)
: value_(value), rep_(rep) {}
int value_;
MachineRepresentation rep_ = kNoRep;
};
typedef std::pair<VReg, VReg> VRegPair;
enum TestOperandType {
kInvalid,
kSameAsFirst,
kRegister,
kFixedRegister,
kSlot,
kFixedSlot,
kExplicit,
kImmediate,
kNone,
kConstant,
kUnique,
kUniqueRegister
};
struct TestOperand {
TestOperand() : type_(kInvalid), vreg_(), value_(kNoValue), rep_(kNoRep) {}
explicit TestOperand(TestOperandType type)
: type_(type), vreg_(), value_(kNoValue), rep_(kNoRep) {}
// For tests that do register allocation.
TestOperand(TestOperandType type, VReg vreg, int value = kNoValue)
: type_(type), vreg_(vreg), value_(value), rep_(vreg.rep_) {}
// For immediates, constants, and tests that don't do register allocation.
TestOperand(TestOperandType type, int value,
MachineRepresentation rep = kNoRep)
: type_(type), vreg_(), value_(value), rep_(rep) {}
TestOperandType type_;
VReg vreg_;
int value_;
MachineRepresentation rep_;
};
static TestOperand Same() { return TestOperand(kSameAsFirst); }
static TestOperand ExplicitReg(int index) {
TestOperandType type = kExplicit;
return TestOperand(type, index);
}
static TestOperand ExplicitFPReg(int index,
MachineRepresentation rep = kFloat64) {
TestOperandType type = kExplicit;
return TestOperand(type, index, rep);
}
static TestOperand Reg(VReg vreg, int index = kNoValue) {
TestOperandType type = (index == kNoValue) ? kRegister : kFixedRegister;
return TestOperand(type, vreg, index);
}
static TestOperand Reg(int index = kNoValue,
MachineRepresentation rep = kNoRep) {
return Reg(VReg(kNoValue, rep), index);
}
static TestOperand FPReg(int index = kNoValue,
MachineRepresentation rep = kFloat64) {
return Reg(index, rep);
}
static TestOperand Slot(VReg vreg, int index = kNoValue) {
TestOperandType type = (index == kNoValue) ? kSlot : kFixedSlot;
return TestOperand(type, vreg, index);
}
static TestOperand Slot(int index = kNoValue,
MachineRepresentation rep = kNoRep) {
return Slot(VReg(kNoValue, rep), index);
}
static TestOperand Const(int index) {
CHECK_NE(kNoValue, index);
return TestOperand(kConstant, index);
}
static TestOperand Use(VReg vreg) { return TestOperand(kNone, vreg); }
static TestOperand Use() { return Use(VReg()); }
static TestOperand Unique(VReg vreg) { return TestOperand(kUnique, vreg); }
static TestOperand UniqueReg(VReg vreg) {
return TestOperand(kUniqueRegister, vreg);
}
enum BlockCompletionType { kBlockEnd, kFallThrough, kBranch, kJump };
struct BlockCompletion {
BlockCompletionType type_;
TestOperand op_;
int offset_0_;
int offset_1_;
};
static BlockCompletion FallThrough() {
BlockCompletion completion = {kFallThrough, TestOperand(), 1, kNoValue};
return completion;
}
static BlockCompletion Jump(int offset) {
BlockCompletion completion = {kJump, TestOperand(), offset, kNoValue};
return completion;
}
static BlockCompletion Branch(TestOperand op, int left_offset,
int right_offset) {
BlockCompletion completion = {kBranch, op, left_offset, right_offset};
return completion;
}
static BlockCompletion Last() {
BlockCompletion completion = {kBlockEnd, TestOperand(), kNoValue, kNoValue};
return completion;
}
InstructionSequenceTest();
void SetNumRegs(int num_general_registers, int num_double_registers);
int GetNumRegs(MachineRepresentation rep);
int GetAllocatableCode(int index, MachineRepresentation rep = kNoRep);
const RegisterConfiguration* config();
InstructionSequence* sequence();
void StartLoop(int loop_blocks);
void EndLoop();
void StartBlock(bool deferred = false);
Instruction* EndBlock(BlockCompletion completion = FallThrough());
TestOperand Imm(int32_t imm = 0);
VReg Define(TestOperand output_op);
VReg Parameter(TestOperand output_op = Reg()) { return Define(output_op); }
VReg FPParameter(MachineRepresentation rep = kFloat64) {
return Parameter(FPReg(kNoValue, rep));
}
MachineRepresentation GetCanonicalRep(TestOperand op) {
return IsFloatingPoint(op.rep_) ? op.rep_
: sequence()->DefaultRepresentation();
}
Instruction* Return(TestOperand input_op_0);
Instruction* Return(VReg vreg) { return Return(Reg(vreg, 0)); }
PhiInstruction* Phi(VReg incoming_vreg_0 = VReg(),
VReg incoming_vreg_1 = VReg(),
VReg incoming_vreg_2 = VReg(),
VReg incoming_vreg_3 = VReg());
PhiInstruction* Phi(VReg incoming_vreg_0, size_t input_count);
void SetInput(PhiInstruction* phi, size_t input, VReg vreg);
VReg DefineConstant(int32_t imm = 0);
Instruction* EmitNop();
Instruction* EmitI(size_t input_size, TestOperand* inputs);
Instruction* EmitI(TestOperand input_op_0 = TestOperand(),
TestOperand input_op_1 = TestOperand(),
TestOperand input_op_2 = TestOperand(),
TestOperand input_op_3 = TestOperand());
VReg EmitOI(TestOperand output_op, size_t input_size, TestOperand* inputs);
VReg EmitOI(TestOperand output_op, TestOperand input_op_0 = TestOperand(),
TestOperand input_op_1 = TestOperand(),
TestOperand input_op_2 = TestOperand(),
TestOperand input_op_3 = TestOperand());
VRegPair EmitOOI(TestOperand output_op_0, TestOperand output_op_1,
size_t input_size, TestOperand* inputs);
VRegPair EmitOOI(TestOperand output_op_0, TestOperand output_op_1,
TestOperand input_op_0 = TestOperand(),
TestOperand input_op_1 = TestOperand(),
TestOperand input_op_2 = TestOperand(),
TestOperand input_op_3 = TestOperand());
VReg EmitCall(TestOperand output_op, size_t input_size, TestOperand* inputs);
VReg EmitCall(TestOperand output_op, TestOperand input_op_0 = TestOperand(),
TestOperand input_op_1 = TestOperand(),
TestOperand input_op_2 = TestOperand(),
TestOperand input_op_3 = TestOperand());
InstructionBlock* current_block() const { return current_block_; }
// Called after all instructions have been inserted.
void WireBlocks();
private:
virtual bool DoesRegisterAllocation() const { return true; }
VReg NewReg(TestOperand op = TestOperand()) {
int vreg = sequence()->NextVirtualRegister();
if (IsFloatingPoint(op.rep_))
sequence()->MarkAsRepresentation(op.rep_, vreg);
return VReg(vreg, op.rep_);
}
static TestOperand Invalid() { return TestOperand(kInvalid); }
Instruction* EmitBranch(TestOperand input_op);
Instruction* EmitFallThrough();
Instruction* EmitJump();
Instruction* NewInstruction(InstructionCode code, size_t outputs_size,
InstructionOperand* outputs,
size_t inputs_size = 0,
InstructionOperand* inputs = nullptr,
size_t temps_size = 0,
InstructionOperand* temps = nullptr);
InstructionOperand Unallocated(TestOperand op,
UnallocatedOperand::ExtendedPolicy policy);
InstructionOperand Unallocated(TestOperand op,
UnallocatedOperand::ExtendedPolicy policy,
UnallocatedOperand::Lifetime lifetime);
InstructionOperand Unallocated(TestOperand op,
UnallocatedOperand::ExtendedPolicy policy,
int index);
InstructionOperand Unallocated(TestOperand op,
UnallocatedOperand::BasicPolicy policy,
int index);
InstructionOperand* ConvertInputs(size_t input_size, TestOperand* inputs);
InstructionOperand ConvertInputOp(TestOperand op);
InstructionOperand ConvertOutputOp(VReg vreg, TestOperand op);
InstructionBlock* NewBlock(bool deferred = false);
void WireBlock(size_t block_offset, int jump_offset);
Instruction* Emit(InstructionCode code, size_t outputs_size = 0,
InstructionOperand* outputs = nullptr,
size_t inputs_size = 0,
InstructionOperand* inputs = nullptr, size_t temps_size = 0,
InstructionOperand* temps = nullptr, bool is_call = false);
Instruction* AddInstruction(Instruction* instruction);
struct LoopData {
Rpo loop_header_;
int expected_blocks_;
};
typedef std::vector<LoopData> LoopBlocks;
typedef std::map<int, const Instruction*> Instructions;
typedef std::vector<BlockCompletion> Completions;
std::unique_ptr<RegisterConfiguration> config_;
InstructionSequence* sequence_;
int num_general_registers_;
int num_double_registers_;
// Block building state.
InstructionBlocks instruction_blocks_;
Instructions instructions_;
Completions completions_;
LoopBlocks loop_blocks_;
InstructionBlock* current_block_;
bool block_returns_;
DISALLOW_COPY_AND_ASSIGN(InstructionSequenceTest);
};
} // namespace compiler
} // namespace internal
} // namespace v8
#endif // V8_UNITTESTS_COMPILER_INSTRUCTION_SEQUENCE_UNITTEST_H_