ed4b4cd482
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}
511 lines
19 KiB
C++
511 lines
19 KiB
C++
// Copyright 2014 the V8 project authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include "test/unittests/compiler/backend/instruction-sequence-unittest.h"
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#include "src/base/utils/random-number-generator.h"
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#include "src/compiler/pipeline.h"
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#include "test/unittests/test-utils.h"
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#include "testing/gmock/include/gmock/gmock.h"
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namespace v8 {
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namespace internal {
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namespace compiler {
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namespace {
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constexpr int kMaxNumAllocatable =
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Max(Register::kNumRegisters, DoubleRegister::kNumRegisters);
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static std::array<int, kMaxNumAllocatable> kAllocatableCodes =
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base::make_array<kMaxNumAllocatable>(
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[](size_t i) { return static_cast<int>(i); });
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}
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InstructionSequenceTest::InstructionSequenceTest()
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: sequence_(nullptr),
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num_general_registers_(Register::kNumRegisters),
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num_double_registers_(DoubleRegister::kNumRegisters),
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instruction_blocks_(zone()),
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current_block_(nullptr),
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block_returns_(false) {}
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void InstructionSequenceTest::SetNumRegs(int num_general_registers,
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int num_double_registers) {
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CHECK(!config_);
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CHECK(instructions_.empty());
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CHECK(instruction_blocks_.empty());
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CHECK_GE(Register::kNumRegisters, num_general_registers);
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CHECK_GE(DoubleRegister::kNumRegisters, num_double_registers);
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num_general_registers_ = num_general_registers;
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num_double_registers_ = num_double_registers;
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}
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int InstructionSequenceTest::GetNumRegs(MachineRepresentation rep) {
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switch (rep) {
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case MachineRepresentation::kFloat32:
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return config()->num_float_registers();
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case MachineRepresentation::kFloat64:
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return config()->num_double_registers();
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case MachineRepresentation::kSimd128:
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return config()->num_simd128_registers();
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default:
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return config()->num_general_registers();
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}
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}
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int InstructionSequenceTest::GetAllocatableCode(int index,
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MachineRepresentation rep) {
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switch (rep) {
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case MachineRepresentation::kFloat32:
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return config()->GetAllocatableFloatCode(index);
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case MachineRepresentation::kFloat64:
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return config()->GetAllocatableDoubleCode(index);
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case MachineRepresentation::kSimd128:
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return config()->GetAllocatableSimd128Code(index);
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default:
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return config()->GetAllocatableGeneralCode(index);
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}
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}
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const RegisterConfiguration* InstructionSequenceTest::config() {
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if (!config_) {
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config_.reset(new RegisterConfiguration(
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num_general_registers_, num_double_registers_, num_general_registers_,
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num_double_registers_, kAllocatableCodes.data(),
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kAllocatableCodes.data(),
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kSimpleFPAliasing ? RegisterConfiguration::OVERLAP
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: RegisterConfiguration::COMBINE));
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}
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return config_.get();
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}
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InstructionSequence* InstructionSequenceTest::sequence() {
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if (sequence_ == nullptr) {
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sequence_ = new (zone())
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InstructionSequence(isolate(), zone(), &instruction_blocks_);
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sequence_->SetRegisterConfigurationForTesting(
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InstructionSequenceTest::config());
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}
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return sequence_;
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}
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void InstructionSequenceTest::StartLoop(int loop_blocks) {
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CHECK_NULL(current_block_);
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if (!loop_blocks_.empty()) {
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CHECK(!loop_blocks_.back().loop_header_.IsValid());
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}
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LoopData loop_data = {Rpo::Invalid(), loop_blocks};
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loop_blocks_.push_back(loop_data);
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}
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void InstructionSequenceTest::EndLoop() {
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CHECK_NULL(current_block_);
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CHECK(!loop_blocks_.empty());
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CHECK_EQ(0, loop_blocks_.back().expected_blocks_);
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loop_blocks_.pop_back();
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}
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void InstructionSequenceTest::StartBlock(bool deferred) {
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block_returns_ = false;
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NewBlock(deferred);
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}
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Instruction* InstructionSequenceTest::EndBlock(BlockCompletion completion) {
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Instruction* result = nullptr;
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if (block_returns_) {
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CHECK(completion.type_ == kBlockEnd || completion.type_ == kFallThrough);
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completion.type_ = kBlockEnd;
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}
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switch (completion.type_) {
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case kBlockEnd:
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break;
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case kFallThrough:
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result = EmitJump();
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break;
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case kJump:
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CHECK(!block_returns_);
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result = EmitJump();
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break;
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case kBranch:
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CHECK(!block_returns_);
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result = EmitBranch(completion.op_);
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break;
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}
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completions_.push_back(completion);
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CHECK_NOT_NULL(current_block_);
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int end = static_cast<int>(sequence()->instructions().size());
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if (current_block_->code_start() == end) { // Empty block. Insert a nop.
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sequence()->AddInstruction(Instruction::New(zone(), kArchNop));
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}
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sequence()->EndBlock(current_block_->rpo_number());
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current_block_ = nullptr;
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return result;
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}
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InstructionSequenceTest::TestOperand InstructionSequenceTest::Imm(int32_t imm) {
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return TestOperand(kImmediate, imm);
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}
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InstructionSequenceTest::VReg InstructionSequenceTest::Define(
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TestOperand output_op) {
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VReg vreg = NewReg(output_op);
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InstructionOperand outputs[1]{ConvertOutputOp(vreg, output_op)};
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Emit(kArchNop, 1, outputs);
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return vreg;
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}
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Instruction* InstructionSequenceTest::Return(TestOperand input_op_0) {
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block_returns_ = true;
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InstructionOperand inputs[1]{ConvertInputOp(input_op_0)};
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return Emit(kArchRet, 0, nullptr, 1, inputs);
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}
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PhiInstruction* InstructionSequenceTest::Phi(VReg incoming_vreg_0,
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VReg incoming_vreg_1,
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VReg incoming_vreg_2,
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VReg incoming_vreg_3) {
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VReg inputs[] = {incoming_vreg_0, incoming_vreg_1, incoming_vreg_2,
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incoming_vreg_3};
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size_t input_count = 0;
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for (; input_count < arraysize(inputs); ++input_count) {
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if (inputs[input_count].value_ == kNoValue) break;
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}
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CHECK_LT(0, input_count);
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auto phi = new (zone()) PhiInstruction(zone(), NewReg().value_, input_count);
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for (size_t i = 0; i < input_count; ++i) {
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SetInput(phi, i, inputs[i]);
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}
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current_block_->AddPhi(phi);
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return phi;
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}
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PhiInstruction* InstructionSequenceTest::Phi(VReg incoming_vreg_0,
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size_t input_count) {
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auto phi = new (zone()) PhiInstruction(zone(), NewReg().value_, input_count);
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SetInput(phi, 0, incoming_vreg_0);
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current_block_->AddPhi(phi);
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return phi;
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}
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void InstructionSequenceTest::SetInput(PhiInstruction* phi, size_t input,
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VReg vreg) {
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CHECK_NE(kNoValue, vreg.value_);
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phi->SetInput(input, vreg.value_);
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}
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InstructionSequenceTest::VReg InstructionSequenceTest::DefineConstant(
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int32_t imm) {
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VReg vreg = NewReg();
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sequence()->AddConstant(vreg.value_, Constant(imm));
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InstructionOperand outputs[1]{ConstantOperand(vreg.value_)};
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Emit(kArchNop, 1, outputs);
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return vreg;
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}
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Instruction* InstructionSequenceTest::EmitNop() { return Emit(kArchNop); }
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static size_t CountInputs(size_t size,
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InstructionSequenceTest::TestOperand* inputs) {
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size_t i = 0;
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for (; i < size; ++i) {
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if (inputs[i].type_ == InstructionSequenceTest::kInvalid) break;
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}
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return i;
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}
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Instruction* InstructionSequenceTest::EmitI(size_t input_size,
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TestOperand* inputs) {
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InstructionOperand* mapped_inputs = ConvertInputs(input_size, inputs);
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return Emit(kArchNop, 0, nullptr, input_size, mapped_inputs);
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}
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Instruction* InstructionSequenceTest::EmitI(TestOperand input_op_0,
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TestOperand input_op_1,
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TestOperand input_op_2,
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TestOperand input_op_3) {
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TestOperand inputs[] = {input_op_0, input_op_1, input_op_2, input_op_3};
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return EmitI(CountInputs(arraysize(inputs), inputs), inputs);
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}
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InstructionSequenceTest::VReg InstructionSequenceTest::EmitOI(
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TestOperand output_op, size_t input_size, TestOperand* inputs) {
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VReg output_vreg = NewReg(output_op);
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InstructionOperand outputs[1]{ConvertOutputOp(output_vreg, output_op)};
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InstructionOperand* mapped_inputs = ConvertInputs(input_size, inputs);
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Emit(kArchNop, 1, outputs, input_size, mapped_inputs);
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return output_vreg;
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}
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InstructionSequenceTest::VReg InstructionSequenceTest::EmitOI(
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TestOperand output_op, TestOperand input_op_0, TestOperand input_op_1,
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TestOperand input_op_2, TestOperand input_op_3) {
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TestOperand inputs[] = {input_op_0, input_op_1, input_op_2, input_op_3};
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return EmitOI(output_op, CountInputs(arraysize(inputs), inputs), inputs);
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}
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InstructionSequenceTest::VRegPair InstructionSequenceTest::EmitOOI(
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TestOperand output_op_0, TestOperand output_op_1, size_t input_size,
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TestOperand* inputs) {
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VRegPair output_vregs =
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std::make_pair(NewReg(output_op_0), NewReg(output_op_1));
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InstructionOperand outputs[2]{
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ConvertOutputOp(output_vregs.first, output_op_0),
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ConvertOutputOp(output_vregs.second, output_op_1)};
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InstructionOperand* mapped_inputs = ConvertInputs(input_size, inputs);
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Emit(kArchNop, 2, outputs, input_size, mapped_inputs);
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return output_vregs;
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}
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InstructionSequenceTest::VRegPair InstructionSequenceTest::EmitOOI(
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TestOperand output_op_0, TestOperand output_op_1, TestOperand input_op_0,
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TestOperand input_op_1, TestOperand input_op_2, TestOperand input_op_3) {
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TestOperand inputs[] = {input_op_0, input_op_1, input_op_2, input_op_3};
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return EmitOOI(output_op_0, output_op_1,
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CountInputs(arraysize(inputs), inputs), inputs);
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}
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InstructionSequenceTest::VReg InstructionSequenceTest::EmitCall(
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TestOperand output_op, size_t input_size, TestOperand* inputs) {
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VReg output_vreg = NewReg(output_op);
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InstructionOperand outputs[1]{ConvertOutputOp(output_vreg, output_op)};
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CHECK(UnallocatedOperand::cast(outputs[0]).HasFixedPolicy());
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InstructionOperand* mapped_inputs = ConvertInputs(input_size, inputs);
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Emit(kArchCallCodeObject, 1, outputs, input_size, mapped_inputs, 0, nullptr,
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true);
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return output_vreg;
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}
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InstructionSequenceTest::VReg InstructionSequenceTest::EmitCall(
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TestOperand output_op, TestOperand input_op_0, TestOperand input_op_1,
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TestOperand input_op_2, TestOperand input_op_3) {
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TestOperand inputs[] = {input_op_0, input_op_1, input_op_2, input_op_3};
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return EmitCall(output_op, CountInputs(arraysize(inputs), inputs), inputs);
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}
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Instruction* InstructionSequenceTest::EmitBranch(TestOperand input_op) {
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InstructionOperand inputs[4]{ConvertInputOp(input_op), ConvertInputOp(Imm()),
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ConvertInputOp(Imm()), ConvertInputOp(Imm())};
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InstructionCode opcode = kArchJmp | FlagsModeField::encode(kFlags_branch) |
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FlagsConditionField::encode(kEqual);
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auto instruction = NewInstruction(opcode, 0, nullptr, 4, inputs);
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return AddInstruction(instruction);
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}
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Instruction* InstructionSequenceTest::EmitFallThrough() {
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auto instruction = NewInstruction(kArchNop, 0, nullptr);
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return AddInstruction(instruction);
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}
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Instruction* InstructionSequenceTest::EmitJump() {
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InstructionOperand inputs[1]{ConvertInputOp(Imm())};
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auto instruction = NewInstruction(kArchJmp, 0, nullptr, 1, inputs);
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return AddInstruction(instruction);
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}
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Instruction* InstructionSequenceTest::NewInstruction(
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InstructionCode code, size_t outputs_size, InstructionOperand* outputs,
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size_t inputs_size, InstructionOperand* inputs, size_t temps_size,
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InstructionOperand* temps) {
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CHECK(current_block_);
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return Instruction::New(zone(), code, outputs_size, outputs, inputs_size,
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inputs, temps_size, temps);
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}
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InstructionOperand InstructionSequenceTest::Unallocated(
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TestOperand op, UnallocatedOperand::ExtendedPolicy policy) {
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return UnallocatedOperand(policy, op.vreg_.value_);
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}
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InstructionOperand InstructionSequenceTest::Unallocated(
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TestOperand op, UnallocatedOperand::ExtendedPolicy policy,
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UnallocatedOperand::Lifetime lifetime) {
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return UnallocatedOperand(policy, lifetime, op.vreg_.value_);
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}
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InstructionOperand InstructionSequenceTest::Unallocated(
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TestOperand op, UnallocatedOperand::ExtendedPolicy policy, int index) {
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return UnallocatedOperand(policy, index, op.vreg_.value_);
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}
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InstructionOperand InstructionSequenceTest::Unallocated(
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TestOperand op, UnallocatedOperand::BasicPolicy policy, int index) {
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return UnallocatedOperand(policy, index, op.vreg_.value_);
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}
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InstructionOperand* InstructionSequenceTest::ConvertInputs(
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size_t input_size, TestOperand* inputs) {
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InstructionOperand* mapped_inputs =
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zone()->NewArray<InstructionOperand>(static_cast<int>(input_size));
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for (size_t i = 0; i < input_size; ++i) {
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mapped_inputs[i] = ConvertInputOp(inputs[i]);
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}
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return mapped_inputs;
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}
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InstructionOperand InstructionSequenceTest::ConvertInputOp(TestOperand op) {
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if (op.type_ == kImmediate) {
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CHECK_EQ(op.vreg_.value_, kNoValue);
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return ImmediateOperand(ImmediateOperand::INLINE, op.value_);
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}
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CHECK_NE(op.vreg_.value_, kNoValue);
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switch (op.type_) {
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case kNone:
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return Unallocated(op, UnallocatedOperand::NONE,
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UnallocatedOperand::USED_AT_START);
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case kUnique:
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return Unallocated(op, UnallocatedOperand::NONE);
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case kUniqueRegister:
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return Unallocated(op, UnallocatedOperand::MUST_HAVE_REGISTER);
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case kRegister:
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return Unallocated(op, UnallocatedOperand::MUST_HAVE_REGISTER,
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UnallocatedOperand::USED_AT_START);
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case kSlot:
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return Unallocated(op, UnallocatedOperand::MUST_HAVE_SLOT,
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UnallocatedOperand::USED_AT_START);
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case kFixedRegister: {
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MachineRepresentation rep = GetCanonicalRep(op);
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CHECK(0 <= op.value_ && op.value_ < GetNumRegs(rep));
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if (DoesRegisterAllocation()) {
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auto extended_policy = IsFloatingPoint(rep)
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? UnallocatedOperand::FIXED_FP_REGISTER
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: UnallocatedOperand::FIXED_REGISTER;
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return Unallocated(op, extended_policy, op.value_);
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} else {
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return AllocatedOperand(LocationOperand::REGISTER, rep, op.value_);
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}
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}
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case kFixedSlot:
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if (DoesRegisterAllocation()) {
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return Unallocated(op, UnallocatedOperand::FIXED_SLOT, op.value_);
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} else {
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return AllocatedOperand(LocationOperand::STACK_SLOT,
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GetCanonicalRep(op), op.value_);
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}
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default:
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break;
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}
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UNREACHABLE();
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}
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InstructionOperand InstructionSequenceTest::ConvertOutputOp(VReg vreg,
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TestOperand op) {
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CHECK_EQ(op.vreg_.value_, kNoValue);
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op.vreg_ = vreg;
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switch (op.type_) {
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case kSameAsFirst:
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return Unallocated(op, UnallocatedOperand::SAME_AS_FIRST_INPUT);
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case kRegister:
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return Unallocated(op, UnallocatedOperand::MUST_HAVE_REGISTER);
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case kFixedSlot:
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if (DoesRegisterAllocation()) {
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return Unallocated(op, UnallocatedOperand::FIXED_SLOT, op.value_);
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} else {
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return AllocatedOperand(LocationOperand::STACK_SLOT,
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GetCanonicalRep(op), op.value_);
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}
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case kFixedRegister: {
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MachineRepresentation rep = GetCanonicalRep(op);
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CHECK(0 <= op.value_ && op.value_ < GetNumRegs(rep));
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if (DoesRegisterAllocation()) {
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auto extended_policy = IsFloatingPoint(rep)
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? UnallocatedOperand::FIXED_FP_REGISTER
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: UnallocatedOperand::FIXED_REGISTER;
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return Unallocated(op, extended_policy, op.value_);
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} else {
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return AllocatedOperand(LocationOperand::REGISTER, rep, op.value_);
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}
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}
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default:
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break;
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}
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UNREACHABLE();
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}
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InstructionBlock* InstructionSequenceTest::NewBlock(bool deferred) {
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CHECK_NULL(current_block_);
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Rpo rpo = Rpo::FromInt(static_cast<int>(instruction_blocks_.size()));
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Rpo loop_header = Rpo::Invalid();
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Rpo loop_end = Rpo::Invalid();
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if (!loop_blocks_.empty()) {
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auto& loop_data = loop_blocks_.back();
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// This is a loop header.
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if (!loop_data.loop_header_.IsValid()) {
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loop_end = Rpo::FromInt(rpo.ToInt() + loop_data.expected_blocks_);
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loop_data.expected_blocks_--;
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loop_data.loop_header_ = rpo;
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} else {
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// This is a loop body.
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CHECK_NE(0, loop_data.expected_blocks_);
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// TODO(dcarney): handle nested loops.
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loop_data.expected_blocks_--;
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loop_header = loop_data.loop_header_;
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}
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}
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// Construct instruction block.
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auto instruction_block = new (zone())
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InstructionBlock(zone(), rpo, loop_header, loop_end, deferred, false);
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instruction_blocks_.push_back(instruction_block);
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current_block_ = instruction_block;
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sequence()->StartBlock(rpo);
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return instruction_block;
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}
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void InstructionSequenceTest::WireBlocks() {
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CHECK(!current_block());
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CHECK(instruction_blocks_.size() == completions_.size());
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CHECK(loop_blocks_.empty());
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|
// Wire in end block to look like a scheduler produced cfg.
|
|
auto end_block = NewBlock();
|
|
Emit(kArchNop);
|
|
current_block_ = nullptr;
|
|
sequence()->EndBlock(end_block->rpo_number());
|
|
size_t offset = 0;
|
|
for (const auto& completion : completions_) {
|
|
switch (completion.type_) {
|
|
case kBlockEnd: {
|
|
auto block = instruction_blocks_[offset];
|
|
block->successors().push_back(end_block->rpo_number());
|
|
end_block->predecessors().push_back(block->rpo_number());
|
|
break;
|
|
}
|
|
case kFallThrough: // Fallthrough.
|
|
case kJump:
|
|
WireBlock(offset, completion.offset_0_);
|
|
break;
|
|
case kBranch:
|
|
WireBlock(offset, completion.offset_0_);
|
|
WireBlock(offset, completion.offset_1_);
|
|
break;
|
|
}
|
|
++offset;
|
|
}
|
|
}
|
|
|
|
void InstructionSequenceTest::WireBlock(size_t block_offset, int jump_offset) {
|
|
size_t target_block_offset = block_offset + static_cast<size_t>(jump_offset);
|
|
CHECK(block_offset < instruction_blocks_.size());
|
|
CHECK(target_block_offset < instruction_blocks_.size());
|
|
auto block = instruction_blocks_[block_offset];
|
|
auto target = instruction_blocks_[target_block_offset];
|
|
block->successors().push_back(target->rpo_number());
|
|
target->predecessors().push_back(block->rpo_number());
|
|
}
|
|
|
|
Instruction* InstructionSequenceTest::Emit(
|
|
InstructionCode code, size_t outputs_size, InstructionOperand* outputs,
|
|
size_t inputs_size, InstructionOperand* inputs, size_t temps_size,
|
|
InstructionOperand* temps, bool is_call) {
|
|
auto instruction = NewInstruction(code, outputs_size, outputs, inputs_size,
|
|
inputs, temps_size, temps);
|
|
if (is_call) instruction->MarkAsCall();
|
|
return AddInstruction(instruction);
|
|
}
|
|
|
|
Instruction* InstructionSequenceTest::AddInstruction(Instruction* instruction) {
|
|
sequence()->AddInstruction(instruction);
|
|
return instruction;
|
|
}
|
|
|
|
} // namespace compiler
|
|
} // namespace internal
|
|
} // namespace v8
|