src/v8/test/cctest/compiler/test-instruction.cc - cobalt - Git at Google

 // 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.

 #include "src/compiler/backend/code-generator.h"
 #include "src/compiler/backend/instruction.h"
 #include "src/compiler/common-operator.h"
 #include "src/compiler/graph.h"
 #include "src/compiler/linkage.h"
 #include "src/compiler/machine-operator.h"
 #include "src/compiler/node.h"
 #include "src/compiler/operator.h"
 #include "src/compiler/schedule.h"
 #include "src/compiler/scheduler.h"
 #include "src/objects/objects-inl.h"
 #include "test/cctest/cctest.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 using TestInstr = v8::internal::compiler::Instruction;
 using TestInstrSeq = v8::internal::compiler::InstructionSequence;

 // A testing helper for the register code abstraction.
 class InstructionTester : public HandleAndZoneScope {
  public:  // We're all friends here.
   InstructionTester()
       : graph(zone()),
         schedule(zone()),
         common(zone()),
         machine(zone()),
         code(nullptr) {}

   Graph graph;
   Schedule schedule;
   CommonOperatorBuilder common;
   MachineOperatorBuilder machine;
   TestInstrSeq* code;

   Zone* zone() { return main_zone(); }

   void allocCode() {
     if (schedule.rpo_order()->size() == 0) {
       // Compute the RPO order.
       Scheduler::ComputeSpecialRPO(main_zone(), &schedule);
       CHECK_NE(0u, schedule.rpo_order()->size());
     }
     InstructionBlocks* instruction_blocks =
         TestInstrSeq::InstructionBlocksFor(main_zone(), &schedule);
     code = new (main_zone())
         TestInstrSeq(main_isolate(), main_zone(), instruction_blocks);
   }

   Node* Int32Constant(int32_t val) {
     Node* node = graph.NewNode(common.Int32Constant(val));
     schedule.AddNode(schedule.start(), node);
     return node;
   }

   Node* Float64Constant(double val) {
     Node* node = graph.NewNode(common.Float64Constant(val));
     schedule.AddNode(schedule.start(), node);
     return node;
   }

   Node* Parameter(int32_t which) {
     Node* node = graph.NewNode(common.Parameter(which));
     schedule.AddNode(schedule.start(), node);
     return node;
   }

   Node* NewNode(BasicBlock* block) {
     Node* node = graph.NewNode(common.Int32Constant(111));
     schedule.AddNode(block, node);
     return node;
   }

   int NewInstr() {
     InstructionCode opcode = static_cast<InstructionCode>(110);
     TestInstr* instr = TestInstr::New(zone(), opcode);
     return code->AddInstruction(instr);
   }

   int NewNop() {
     TestInstr* instr = TestInstr::New(zone(), kArchNop);
     return code->AddInstruction(instr);
   }

   UnallocatedOperand Unallocated(int vreg) {
     return UnallocatedOperand(UnallocatedOperand::REGISTER_OR_SLOT, vreg);
   }

   RpoNumber RpoFor(BasicBlock* block) {
     return RpoNumber::FromInt(block->rpo_number());
   }

   InstructionBlock* BlockAt(BasicBlock* block) {
     return code->InstructionBlockAt(RpoFor(block));
   }
   BasicBlock* GetBasicBlock(int instruction_index) {
     const InstructionBlock* block =
         code->GetInstructionBlock(instruction_index);
     return schedule.rpo_order()->at(block->rpo_number().ToSize());
   }
   int first_instruction_index(BasicBlock* block) {
     return BlockAt(block)->first_instruction_index();
   }
   int last_instruction_index(BasicBlock* block) {
     return BlockAt(block)->last_instruction_index();
   }
 };


 TEST(InstructionBasic) {
   InstructionTester R;

   for (int i = 0; i < 10; i++) {
     R.Int32Constant(i);  // Add some nodes to the graph.
   }

   BasicBlock* last = R.schedule.start();
   for (int i = 0; i < 5; i++) {
     BasicBlock* block = R.schedule.NewBasicBlock();
     R.schedule.AddGoto(last, block);
     last = block;
   }

   R.allocCode();

   BasicBlockVector* blocks = R.schedule.rpo_order();
   CHECK_EQ(static_cast<int>(blocks->size()), R.code->InstructionBlockCount());

   for (auto block : *blocks) {
     CHECK_EQ(block->rpo_number(), R.BlockAt(block)->rpo_number().ToInt());
     CHECK(!block->loop_end());
   }
 }


 TEST(InstructionGetBasicBlock) {
   InstructionTester R;

   BasicBlock* b0 = R.schedule.start();
   BasicBlock* b1 = R.schedule.NewBasicBlock();
   BasicBlock* b2 = R.schedule.NewBasicBlock();
   BasicBlock* b3 = R.schedule.end();

   R.schedule.AddGoto(b0, b1);
   R.schedule.AddGoto(b1, b2);
   R.schedule.AddGoto(b2, b3);

   R.allocCode();

   R.code->StartBlock(R.RpoFor(b0));
   int i0 = R.NewInstr();
   int i1 = R.NewInstr();
   R.code->EndBlock(R.RpoFor(b0));
   R.code->StartBlock(R.RpoFor(b1));
   int i2 = R.NewInstr();
   int i3 = R.NewInstr();
   int i4 = R.NewInstr();
   int i5 = R.NewInstr();
   R.code->EndBlock(R.RpoFor(b1));
   R.code->StartBlock(R.RpoFor(b2));
   int i6 = R.NewInstr();
   int i7 = R.NewInstr();
   int i8 = R.NewInstr();
   R.code->EndBlock(R.RpoFor(b2));
   R.code->StartBlock(R.RpoFor(b3));
   R.NewNop();
   R.code->EndBlock(R.RpoFor(b3));

   CHECK_EQ(b0, R.GetBasicBlock(i0));
   CHECK_EQ(b0, R.GetBasicBlock(i1));

   CHECK_EQ(b1, R.GetBasicBlock(i2));
   CHECK_EQ(b1, R.GetBasicBlock(i3));
   CHECK_EQ(b1, R.GetBasicBlock(i4));
   CHECK_EQ(b1, R.GetBasicBlock(i5));

   CHECK_EQ(b2, R.GetBasicBlock(i6));
   CHECK_EQ(b2, R.GetBasicBlock(i7));
   CHECK_EQ(b2, R.GetBasicBlock(i8));

   CHECK_EQ(b0, R.GetBasicBlock(R.first_instruction_index(b0)));
   CHECK_EQ(b0, R.GetBasicBlock(R.last_instruction_index(b0)));

   CHECK_EQ(b1, R.GetBasicBlock(R.first_instruction_index(b1)));
   CHECK_EQ(b1, R.GetBasicBlock(R.last_instruction_index(b1)));

   CHECK_EQ(b2, R.GetBasicBlock(R.first_instruction_index(b2)));
   CHECK_EQ(b2, R.GetBasicBlock(R.last_instruction_index(b2)));

   CHECK_EQ(b3, R.GetBasicBlock(R.first_instruction_index(b3)));
   CHECK_EQ(b3, R.GetBasicBlock(R.last_instruction_index(b3)));
 }


 TEST(InstructionIsGapAt) {
   InstructionTester R;

   BasicBlock* b0 = R.schedule.start();
   R.schedule.AddReturn(b0, R.Int32Constant(1));

   R.allocCode();
   TestInstr* i0 = TestInstr::New(R.zone(), 100);
   TestInstr* g = TestInstr::New(R.zone(), 103);
   R.code->StartBlock(R.RpoFor(b0));
   R.code->AddInstruction(i0);
   R.code->AddInstruction(g);
   R.code->EndBlock(R.RpoFor(b0));

   CHECK_EQ(2, R.code->instructions().size());
 }


 TEST(InstructionIsGapAt2) {
   InstructionTester R;

   BasicBlock* b0 = R.schedule.start();
   BasicBlock* b1 = R.schedule.end();
   R.schedule.AddGoto(b0, b1);
   R.schedule.AddReturn(b1, R.Int32Constant(1));

   R.allocCode();
   TestInstr* i0 = TestInstr::New(R.zone(), 100);
   TestInstr* g = TestInstr::New(R.zone(), 103);
   R.code->StartBlock(R.RpoFor(b0));
   R.code->AddInstruction(i0);
   R.code->AddInstruction(g);
   R.code->EndBlock(R.RpoFor(b0));

   TestInstr* i1 = TestInstr::New(R.zone(), 102);
   TestInstr* g1 = TestInstr::New(R.zone(), 104);
   R.code->StartBlock(R.RpoFor(b1));
   R.code->AddInstruction(i1);
   R.code->AddInstruction(g1);
   R.code->EndBlock(R.RpoFor(b1));

   CHECK_EQ(4, R.code->instructions().size());
 }


 TEST(InstructionAddGapMove) {
   InstructionTester R;

   BasicBlock* b0 = R.schedule.start();
   R.schedule.AddReturn(b0, R.Int32Constant(1));

   R.allocCode();
   TestInstr* i0 = TestInstr::New(R.zone(), 100);
   TestInstr* g = TestInstr::New(R.zone(), 103);
   R.code->StartBlock(R.RpoFor(b0));
   R.code->AddInstruction(i0);
   R.code->AddInstruction(g);
   R.code->EndBlock(R.RpoFor(b0));

   CHECK_EQ(2, R.code->instructions().size());

   int index = 0;
   for (auto instr : R.code->instructions()) {
     UnallocatedOperand op1 = R.Unallocated(index++);
     UnallocatedOperand op2 = R.Unallocated(index++);
     instr->GetOrCreateParallelMove(TestInstr::START, R.zone())
         ->AddMove(op1, op2);
     ParallelMove* move = instr->GetParallelMove(TestInstr::START);
     CHECK(move);
     CHECK_EQ(1u, move->size());
     MoveOperands* cur = move->at(0);
     CHECK(op1.Equals(cur->source()));
     CHECK(op2.Equals(cur->destination()));
   }
 }


 TEST(InstructionOperands) {
   v8::internal::AccountingAllocator allocator;
   Zone zone(&allocator, ZONE_NAME);

   {
     TestInstr* i = TestInstr::New(&zone, 101);
     CHECK_EQ(0, static_cast<int>(i->OutputCount()));
     CHECK_EQ(0, static_cast<int>(i->InputCount()));
     CHECK_EQ(0, static_cast<int>(i->TempCount()));
   }

   int vreg = 15;
   InstructionOperand outputs[] = {
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg)};

   InstructionOperand inputs[] = {
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg)};

   InstructionOperand temps[] = {
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
       UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg)};

   for (size_t i = 0; i < arraysize(outputs); i++) {
     for (size_t j = 0; j < arraysize(inputs); j++) {
       for (size_t k = 0; k < arraysize(temps); k++) {
         TestInstr* m =
             TestInstr::New(&zone, 101, i, outputs, j, inputs, k, temps);
         CHECK(i == m->OutputCount());
         CHECK(j == m->InputCount());
         CHECK(k == m->TempCount());

         for (size_t z = 0; z < i; z++) {
           CHECK(outputs[z].Equals(*m->OutputAt(z)));
         }

         for (size_t z = 0; z < j; z++) {
           CHECK(inputs[z].Equals(*m->InputAt(z)));
         }

         for (size_t z = 0; z < k; z++) {
           CHECK(temps[z].Equals(*m->TempAt(z)));
         }
       }
     }
   }
 }

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8
	// 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.

	#include "src/compiler/backend/code-generator.h"
	#include "src/compiler/backend/instruction.h"
	#include "src/compiler/common-operator.h"
	#include "src/compiler/graph.h"
	#include "src/compiler/linkage.h"
	#include "src/compiler/machine-operator.h"
	#include "src/compiler/node.h"
	#include "src/compiler/operator.h"
	#include "src/compiler/schedule.h"
	#include "src/compiler/scheduler.h"
	#include "src/objects/objects-inl.h"
	#include "test/cctest/cctest.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	using TestInstr = v8::internal::compiler::Instruction;
	using TestInstrSeq = v8::internal::compiler::InstructionSequence;

	// A testing helper for the register code abstraction.
	class InstructionTester : public HandleAndZoneScope {
	public: // We're all friends here.
	InstructionTester()
	: graph(zone()),
	schedule(zone()),
	common(zone()),
	machine(zone()),
	code(nullptr) {}

	Graph graph;
	Schedule schedule;
	CommonOperatorBuilder common;
	MachineOperatorBuilder machine;
	TestInstrSeq* code;

	Zone* zone() { return main_zone(); }

	void allocCode() {
	if (schedule.rpo_order()->size() == 0) {
	// Compute the RPO order.
	Scheduler::ComputeSpecialRPO(main_zone(), &schedule);
	CHECK_NE(0u, schedule.rpo_order()->size());
	}
	InstructionBlocks* instruction_blocks =
	TestInstrSeq::InstructionBlocksFor(main_zone(), &schedule);
	code = new (main_zone())
	TestInstrSeq(main_isolate(), main_zone(), instruction_blocks);
	}

	Node* Int32Constant(int32_t val) {
	Node* node = graph.NewNode(common.Int32Constant(val));
	schedule.AddNode(schedule.start(), node);
	return node;
	}

	Node* Float64Constant(double val) {
	Node* node = graph.NewNode(common.Float64Constant(val));
	schedule.AddNode(schedule.start(), node);
	return node;
	}

	Node* Parameter(int32_t which) {
	Node* node = graph.NewNode(common.Parameter(which));
	schedule.AddNode(schedule.start(), node);
	return node;
	}

	Node* NewNode(BasicBlock* block) {
	Node* node = graph.NewNode(common.Int32Constant(111));
	schedule.AddNode(block, node);
	return node;
	}

	int NewInstr() {
	InstructionCode opcode = static_cast<InstructionCode>(110);
	TestInstr* instr = TestInstr::New(zone(), opcode);
	return code->AddInstruction(instr);
	}

	int NewNop() {
	TestInstr* instr = TestInstr::New(zone(), kArchNop);
	return code->AddInstruction(instr);
	}

	UnallocatedOperand Unallocated(int vreg) {
	return UnallocatedOperand(UnallocatedOperand::REGISTER_OR_SLOT, vreg);
	}

	RpoNumber RpoFor(BasicBlock* block) {
	return RpoNumber::FromInt(block->rpo_number());
	}

	InstructionBlock* BlockAt(BasicBlock* block) {
	return code->InstructionBlockAt(RpoFor(block));
	}
	BasicBlock* GetBasicBlock(int instruction_index) {
	const InstructionBlock* block =
	code->GetInstructionBlock(instruction_index);
	return schedule.rpo_order()->at(block->rpo_number().ToSize());
	}
	int first_instruction_index(BasicBlock* block) {
	return BlockAt(block)->first_instruction_index();
	}
	int last_instruction_index(BasicBlock* block) {
	return BlockAt(block)->last_instruction_index();
	}
	};


	TEST(InstructionBasic) {
	InstructionTester R;

	for (int i = 0; i < 10; i++) {
	R.Int32Constant(i); // Add some nodes to the graph.
	}

	BasicBlock* last = R.schedule.start();
	for (int i = 0; i < 5; i++) {
	BasicBlock* block = R.schedule.NewBasicBlock();
	R.schedule.AddGoto(last, block);
	last = block;
	}

	R.allocCode();

	BasicBlockVector* blocks = R.schedule.rpo_order();
	CHECK_EQ(static_cast<int>(blocks->size()), R.code->InstructionBlockCount());

	for (auto block : *blocks) {
	CHECK_EQ(block->rpo_number(), R.BlockAt(block)->rpo_number().ToInt());
	CHECK(!block->loop_end());
	}
	}


	TEST(InstructionGetBasicBlock) {
	InstructionTester R;

	BasicBlock* b0 = R.schedule.start();
	BasicBlock* b1 = R.schedule.NewBasicBlock();
	BasicBlock* b2 = R.schedule.NewBasicBlock();
	BasicBlock* b3 = R.schedule.end();

	R.schedule.AddGoto(b0, b1);
	R.schedule.AddGoto(b1, b2);
	R.schedule.AddGoto(b2, b3);

	R.allocCode();

	R.code->StartBlock(R.RpoFor(b0));
	int i0 = R.NewInstr();
	int i1 = R.NewInstr();
	R.code->EndBlock(R.RpoFor(b0));
	R.code->StartBlock(R.RpoFor(b1));
	int i2 = R.NewInstr();
	int i3 = R.NewInstr();
	int i4 = R.NewInstr();
	int i5 = R.NewInstr();
	R.code->EndBlock(R.RpoFor(b1));
	R.code->StartBlock(R.RpoFor(b2));
	int i6 = R.NewInstr();
	int i7 = R.NewInstr();
	int i8 = R.NewInstr();
	R.code->EndBlock(R.RpoFor(b2));
	R.code->StartBlock(R.RpoFor(b3));
	R.NewNop();
	R.code->EndBlock(R.RpoFor(b3));

	CHECK_EQ(b0, R.GetBasicBlock(i0));
	CHECK_EQ(b0, R.GetBasicBlock(i1));

	CHECK_EQ(b1, R.GetBasicBlock(i2));
	CHECK_EQ(b1, R.GetBasicBlock(i3));
	CHECK_EQ(b1, R.GetBasicBlock(i4));
	CHECK_EQ(b1, R.GetBasicBlock(i5));

	CHECK_EQ(b2, R.GetBasicBlock(i6));
	CHECK_EQ(b2, R.GetBasicBlock(i7));
	CHECK_EQ(b2, R.GetBasicBlock(i8));

	CHECK_EQ(b0, R.GetBasicBlock(R.first_instruction_index(b0)));
	CHECK_EQ(b0, R.GetBasicBlock(R.last_instruction_index(b0)));

	CHECK_EQ(b1, R.GetBasicBlock(R.first_instruction_index(b1)));
	CHECK_EQ(b1, R.GetBasicBlock(R.last_instruction_index(b1)));

	CHECK_EQ(b2, R.GetBasicBlock(R.first_instruction_index(b2)));
	CHECK_EQ(b2, R.GetBasicBlock(R.last_instruction_index(b2)));

	CHECK_EQ(b3, R.GetBasicBlock(R.first_instruction_index(b3)));
	CHECK_EQ(b3, R.GetBasicBlock(R.last_instruction_index(b3)));
	}


	TEST(InstructionIsGapAt) {
	InstructionTester R;

	BasicBlock* b0 = R.schedule.start();
	R.schedule.AddReturn(b0, R.Int32Constant(1));

	R.allocCode();
	TestInstr* i0 = TestInstr::New(R.zone(), 100);
	TestInstr* g = TestInstr::New(R.zone(), 103);
	R.code->StartBlock(R.RpoFor(b0));
	R.code->AddInstruction(i0);
	R.code->AddInstruction(g);
	R.code->EndBlock(R.RpoFor(b0));

	CHECK_EQ(2, R.code->instructions().size());
	}


	TEST(InstructionIsGapAt2) {
	InstructionTester R;

	BasicBlock* b0 = R.schedule.start();
	BasicBlock* b1 = R.schedule.end();
	R.schedule.AddGoto(b0, b1);
	R.schedule.AddReturn(b1, R.Int32Constant(1));

	R.allocCode();
	TestInstr* i0 = TestInstr::New(R.zone(), 100);
	TestInstr* g = TestInstr::New(R.zone(), 103);
	R.code->StartBlock(R.RpoFor(b0));
	R.code->AddInstruction(i0);
	R.code->AddInstruction(g);
	R.code->EndBlock(R.RpoFor(b0));

	TestInstr* i1 = TestInstr::New(R.zone(), 102);
	TestInstr* g1 = TestInstr::New(R.zone(), 104);
	R.code->StartBlock(R.RpoFor(b1));
	R.code->AddInstruction(i1);
	R.code->AddInstruction(g1);
	R.code->EndBlock(R.RpoFor(b1));

	CHECK_EQ(4, R.code->instructions().size());
	}


	TEST(InstructionAddGapMove) {
	InstructionTester R;

	BasicBlock* b0 = R.schedule.start();
	R.schedule.AddReturn(b0, R.Int32Constant(1));

	R.allocCode();
	TestInstr* i0 = TestInstr::New(R.zone(), 100);
	TestInstr* g = TestInstr::New(R.zone(), 103);
	R.code->StartBlock(R.RpoFor(b0));
	R.code->AddInstruction(i0);
	R.code->AddInstruction(g);
	R.code->EndBlock(R.RpoFor(b0));

	CHECK_EQ(2, R.code->instructions().size());

	int index = 0;
	for (auto instr : R.code->instructions()) {
	UnallocatedOperand op1 = R.Unallocated(index++);
	UnallocatedOperand op2 = R.Unallocated(index++);
	instr->GetOrCreateParallelMove(TestInstr::START, R.zone())
	->AddMove(op1, op2);
	ParallelMove* move = instr->GetParallelMove(TestInstr::START);
	CHECK(move);
	CHECK_EQ(1u, move->size());
	MoveOperands* cur = move->at(0);
	CHECK(op1.Equals(cur->source()));
	CHECK(op2.Equals(cur->destination()));
	}
	}


	TEST(InstructionOperands) {
	v8::internal::AccountingAllocator allocator;
	Zone zone(&allocator, ZONE_NAME);

	{
	TestInstr* i = TestInstr::New(&zone, 101);
	CHECK_EQ(0, static_cast<int>(i->OutputCount()));
	CHECK_EQ(0, static_cast<int>(i->InputCount()));
	CHECK_EQ(0, static_cast<int>(i->TempCount()));
	}

	int vreg = 15;
	InstructionOperand outputs[] = {
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg)};

	InstructionOperand inputs[] = {
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg)};

	InstructionOperand temps[] = {
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg),
	UnallocatedOperand(UnallocatedOperand::MUST_HAVE_REGISTER, vreg)};

	for (size_t i = 0; i < arraysize(outputs); i++) {
	for (size_t j = 0; j < arraysize(inputs); j++) {
	for (size_t k = 0; k < arraysize(temps); k++) {
	TestInstr* m =
	TestInstr::New(&zone, 101, i, outputs, j, inputs, k, temps);
	CHECK(i == m->OutputCount());
	CHECK(j == m->InputCount());
	CHECK(k == m->TempCount());

	for (size_t z = 0; z < i; z++) {
	CHECK(outputs[z].Equals(*m->OutputAt(z)));
	}

	for (size_t z = 0; z < j; z++) {
	CHECK(inputs[z].Equals(*m->InputAt(z)));
	}

	for (size_t z = 0; z < k; z++) {
	CHECK(temps[z].Equals(*m->TempAt(z)));
	}
	}
	}
	}
	}

	} // namespace compiler
	} // namespace internal
	} // namespace v8