test/unittests/compiler/effect-control-linearizer-unittest.cc - fp2-dev/platform/external/v8 - Gitiles

 // 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 "src/compiler/effect-control-linearizer.h"
 #include "src/compiler/access-builder.h"
 #include "src/compiler/js-graph.h"
 #include "src/compiler/linkage.h"
 #include "src/compiler/node-properties.h"
 #include "src/compiler/schedule.h"
 #include "src/compiler/simplified-operator.h"
 #include "test/unittests/compiler/graph-unittest.h"
 #include "test/unittests/compiler/node-test-utils.h"
 #include "test/unittests/test-utils.h"
 #include "testing/gmock/include/gmock/gmock.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 class EffectControlLinearizerTest : public TypedGraphTest {
  public:
   EffectControlLinearizerTest()
       : TypedGraphTest(3),
         machine_(zone()),
         javascript_(zone()),
         simplified_(zone()),
         jsgraph_(isolate(), graph(), common(), &javascript_, &simplified_,
                  &machine_) {}

   JSGraph* jsgraph() { return &jsgraph_; }
   SimplifiedOperatorBuilder* simplified() { return &simplified_; }

  private:
   MachineOperatorBuilder machine_;
   JSOperatorBuilder javascript_;
   SimplifiedOperatorBuilder simplified_;
   JSGraph jsgraph_;
 };

 namespace {

 BasicBlock* AddBlockToSchedule(Schedule* schedule) {
   BasicBlock* block = schedule->NewBasicBlock();
   block->set_rpo_number(static_cast<int32_t>(schedule->rpo_order()->size()));
   schedule->rpo_order()->push_back(block);
   return block;
 }

 }  // namespace

 TEST_F(EffectControlLinearizerTest, SimpleLoad) {
   Schedule schedule(zone());

   // Create the graph.
   Node* heap_number = NumberConstant(0.5);
   Node* load = graph()->NewNode(
       simplified()->LoadField(AccessBuilder::ForHeapNumberValue()), heap_number,
       graph()->start(), graph()->start());
   Node* ret = graph()->NewNode(common()->Return(), load, graph()->start(),
                                graph()->start());

   // Build the basic block structure.
   BasicBlock* start = schedule.start();
   schedule.rpo_order()->push_back(start);
   start->set_rpo_number(0);

   // Populate the basic blocks with nodes.
   schedule.AddNode(start, graph()->start());
   schedule.AddNode(start, heap_number);
   schedule.AddNode(start, load);
   schedule.AddReturn(start, ret);

   // Run the state effect introducer.
   EffectControlLinearizer introducer(jsgraph(), &schedule, zone());
   introducer.Run();

   EXPECT_THAT(load,
               IsLoadField(AccessBuilder::ForHeapNumberValue(), heap_number,
                           graph()->start(), graph()->start()));
   // The return should have reconnected effect edge to the load.
   EXPECT_THAT(ret, IsReturn(load, load, graph()->start()));
 }

 TEST_F(EffectControlLinearizerTest, DiamondLoad) {
   Schedule schedule(zone());

   // Create the graph.
   Node* branch =
       graph()->NewNode(common()->Branch(), Int32Constant(0), graph()->start());

   Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
   Node* heap_number = NumberConstant(0.5);
   Node* vtrue = graph()->NewNode(
       simplified()->LoadField(AccessBuilder::ForHeapNumberValue()), heap_number,
       graph()->start(), if_true);

   Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
   Node* vfalse = Float64Constant(2);

   Node* merge = graph()->NewNode(common()->Merge(2), if_true, if_false);
   Node* phi = graph()->NewNode(
       common()->Phi(MachineRepresentation::kFloat64, 2), vtrue, vfalse, merge);

   Node* ret =
       graph()->NewNode(common()->Return(), phi, graph()->start(), merge);

   // Build the basic block structure.
   BasicBlock* start = schedule.start();
   schedule.rpo_order()->push_back(start);
   start->set_rpo_number(0);

   BasicBlock* tblock = AddBlockToSchedule(&schedule);
   BasicBlock* fblock = AddBlockToSchedule(&schedule);
   BasicBlock* mblock = AddBlockToSchedule(&schedule);

   // Populate the basic blocks with nodes.
   schedule.AddNode(start, graph()->start());
   schedule.AddBranch(start, branch, tblock, fblock);

   schedule.AddNode(tblock, if_true);
   schedule.AddNode(tblock, heap_number);
   schedule.AddNode(tblock, vtrue);
   schedule.AddGoto(tblock, mblock);

   schedule.AddNode(fblock, if_false);
   schedule.AddNode(fblock, vfalse);
   schedule.AddGoto(fblock, mblock);

   schedule.AddNode(mblock, merge);
   schedule.AddNode(mblock, phi);
   schedule.AddReturn(mblock, ret);

   // Run the state effect introducer.
   EffectControlLinearizer introducer(jsgraph(), &schedule, zone());
   introducer.Run();

   // The effect input to the return should be an effect phi with the
   // newly introduced effectful change operators.
   ASSERT_THAT(
       ret, IsReturn(phi, IsEffectPhi(vtrue, graph()->start(), merge), merge));
 }

 TEST_F(EffectControlLinearizerTest, FloatingDiamondsControlWiring) {
   Schedule schedule(zone());

   // Create the graph and schedule. Roughly (omitting effects and unimportant
   // nodes):
   //
   //            BLOCK 0:
   //             r1: Start
   //             c1: Call
   //             b1: Branch(const0, s1)
   //                |
   //        +-------+------+
   //        |              |
   //   BLOCK 1:           BLOCK 2:
   //    t1: IfTrue(b1)     f1: IfFalse(b1)
   //        |              |
   //        +-------+------+
   //                |
   //            BLOCK 3:
   //             m1: Merge(t1, f1)
   //             c2: IfSuccess(c1)
   //             b2: Branch(const0 , s1)
   //                |
   //        +-------+------+
   //        |              |
   //   BLOCK 4:           BLOCK 5:
   //    t2: IfTrue(b2)     f2:IfFalse(b2)
   //        |              |
   //        +-------+------+
   //                |
   //            BLOCK 6:
   //             m2: Merge(t2, f2)
   //             r1: Return(c1, c2)
   MachineType kMachineSignature[] = {MachineType::AnyTagged(),
                                      MachineType::AnyTagged()};
   LinkageLocation kLocationSignature[] = {LinkageLocation::ForRegister(0),
                                           LinkageLocation::ForRegister(1)};
   const CallDescriptor* kCallDescriptor = new (zone()) CallDescriptor(
       CallDescriptor::kCallCodeObject, MachineType::AnyTagged(),
       LinkageLocation::ForRegister(0),
       new (zone()) MachineSignature(1, 1, kMachineSignature),
       new (zone()) LocationSignature(1, 1, kLocationSignature), 0,
       Operator::kNoProperties, 0, 0, CallDescriptor::kNoFlags);
   Node* p0 = Parameter(0);
   Node* p1 = Parameter(1);
   Node* const0 = Int32Constant(0);
   Node* call = graph()->NewNode(common()->Call(kCallDescriptor), p0, p1,
                                 graph()->start(), graph()->start());
   Node* if_success = graph()->NewNode(common()->IfSuccess(), call);

   // First Floating diamond.
   Node* branch1 =
       graph()->NewNode(common()->Branch(), const0, graph()->start());
   Node* if_true1 = graph()->NewNode(common()->IfTrue(), branch1);
   Node* if_false1 = graph()->NewNode(common()->IfFalse(), branch1);
   Node* merge1 = graph()->NewNode(common()->Merge(2), if_true1, if_false1);

   // Second floating diamond.
   Node* branch2 =
       graph()->NewNode(common()->Branch(), const0, graph()->start());
   Node* if_true2 = graph()->NewNode(common()->IfTrue(), branch2);
   Node* if_false2 = graph()->NewNode(common()->IfFalse(), branch2);
   Node* merge2 = graph()->NewNode(common()->Merge(2), if_true2, if_false2);

   Node* ret =
       graph()->NewNode(common()->Return(), call, graph()->start(), if_success);

   // Build the basic block structure.
   BasicBlock* start = schedule.start();
   schedule.rpo_order()->push_back(start);
   start->set_rpo_number(0);

   BasicBlock* t1block = AddBlockToSchedule(&schedule);
   BasicBlock* f1block = AddBlockToSchedule(&schedule);
   BasicBlock* m1block = AddBlockToSchedule(&schedule);

   BasicBlock* t2block = AddBlockToSchedule(&schedule);
   BasicBlock* f2block = AddBlockToSchedule(&schedule);
   BasicBlock* m2block = AddBlockToSchedule(&schedule);

   // Populate the basic blocks with nodes.
   schedule.AddNode(start, graph()->start());
   schedule.AddNode(start, p0);
   schedule.AddNode(start, p1);
   schedule.AddNode(start, const0);
   schedule.AddNode(start, call);
   schedule.AddBranch(start, branch1, t1block, f1block);

   schedule.AddNode(t1block, if_true1);
   schedule.AddGoto(t1block, m1block);

   schedule.AddNode(f1block, if_false1);
   schedule.AddGoto(f1block, m1block);

   schedule.AddNode(m1block, merge1);
   // The scheduler does not always put the IfSuccess node to the corresponding
   // call's block, simulate that here.
   schedule.AddNode(m1block, if_success);
   schedule.AddBranch(m1block, branch2, t2block, f2block);

   schedule.AddNode(t2block, if_true2);
   schedule.AddGoto(t2block, m2block);

   schedule.AddNode(f2block, if_false2);
   schedule.AddGoto(f2block, m2block);

   schedule.AddNode(m2block, merge2);
   schedule.AddReturn(m2block, ret);

   // Run the state effect introducer.
   EffectControlLinearizer introducer(jsgraph(), &schedule, zone());
   introducer.Run();

   // The effect input to the return should be an effect phi with the
   // newly introduced effectful change operators.
   ASSERT_THAT(ret, IsReturn(call, call, merge2));
   ASSERT_THAT(branch2, IsBranch(const0, merge1));
   ASSERT_THAT(branch1, IsBranch(const0, if_success));
   ASSERT_THAT(if_success, IsIfSuccess(call));
 }

 TEST_F(EffectControlLinearizerTest, LoopLoad) {
   Schedule schedule(zone());

   // Create the graph.
   Node* loop = graph()->NewNode(common()->Loop(1), graph()->start());
   Node* effect_phi =
       graph()->NewNode(common()->EffectPhi(1), graph()->start(), loop);

   Node* cond = Int32Constant(0);
   Node* branch = graph()->NewNode(common()->Branch(), cond, loop);

   Node* if_true = graph()->NewNode(common()->IfTrue(), branch);

   Node* if_false = graph()->NewNode(common()->IfFalse(), branch);

   loop->AppendInput(zone(), if_false);
   NodeProperties::ChangeOp(loop, common()->Loop(2));

   effect_phi->InsertInput(zone(), 1, effect_phi);
   NodeProperties::ChangeOp(effect_phi, common()->EffectPhi(2));

   Node* heap_number = NumberConstant(0.5);
   Node* load = graph()->NewNode(
       simplified()->LoadField(AccessBuilder::ForHeapNumberValue()), heap_number,
       graph()->start(), loop);

   Node* ret = graph()->NewNode(common()->Return(), load, effect_phi, if_true);

   // Build the basic block structure.
   BasicBlock* start = schedule.start();
   schedule.rpo_order()->push_back(start);
   start->set_rpo_number(0);

   BasicBlock* lblock = AddBlockToSchedule(&schedule);
   BasicBlock* fblock = AddBlockToSchedule(&schedule);
   BasicBlock* rblock = AddBlockToSchedule(&schedule);

   // Populate the basic blocks with nodes.
   schedule.AddNode(start, graph()->start());
   schedule.AddGoto(start, lblock);

   schedule.AddNode(lblock, loop);
   schedule.AddNode(lblock, effect_phi);
   schedule.AddNode(lblock, heap_number);
   schedule.AddNode(lblock, load);
   schedule.AddNode(lblock, cond);
   schedule.AddBranch(lblock, branch, rblock, fblock);

   schedule.AddNode(fblock, if_false);
   schedule.AddGoto(fblock, lblock);

   schedule.AddNode(rblock, if_true);
   schedule.AddReturn(rblock, ret);

   // Run the state effect introducer.
   EffectControlLinearizer introducer(jsgraph(), &schedule, zone());
   introducer.Run();

   ASSERT_THAT(ret, IsReturn(load, load, if_true));
   EXPECT_THAT(load, IsLoadField(AccessBuilder::ForHeapNumberValue(),
                                 heap_number, effect_phi, loop));
 }

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8
	// 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 "src/compiler/effect-control-linearizer.h"
	#include "src/compiler/access-builder.h"
	#include "src/compiler/js-graph.h"
	#include "src/compiler/linkage.h"
	#include "src/compiler/node-properties.h"
	#include "src/compiler/schedule.h"
	#include "src/compiler/simplified-operator.h"
	#include "test/unittests/compiler/graph-unittest.h"
	#include "test/unittests/compiler/node-test-utils.h"
	#include "test/unittests/test-utils.h"
	#include "testing/gmock/include/gmock/gmock.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	class EffectControlLinearizerTest : public TypedGraphTest {
	public:
	EffectControlLinearizerTest()
	: TypedGraphTest(3),
	machine_(zone()),
	javascript_(zone()),
	simplified_(zone()),
	jsgraph_(isolate(), graph(), common(), &javascript_, &simplified_,
	&machine_) {}

	JSGraph* jsgraph() { return &jsgraph_; }
	SimplifiedOperatorBuilder* simplified() { return &simplified_; }

	private:
	MachineOperatorBuilder machine_;
	JSOperatorBuilder javascript_;
	SimplifiedOperatorBuilder simplified_;
	JSGraph jsgraph_;
	};

	namespace {

	BasicBlock* AddBlockToSchedule(Schedule* schedule) {
	BasicBlock* block = schedule->NewBasicBlock();
	block->set_rpo_number(static_cast<int32_t>(schedule->rpo_order()->size()));
	schedule->rpo_order()->push_back(block);
	return block;
	}

	} // namespace

	TEST_F(EffectControlLinearizerTest, SimpleLoad) {
	Schedule schedule(zone());

	// Create the graph.
	Node* heap_number = NumberConstant(0.5);
	Node* load = graph()->NewNode(
	simplified()->LoadField(AccessBuilder::ForHeapNumberValue()), heap_number,
	graph()->start(), graph()->start());
	Node* ret = graph()->NewNode(common()->Return(), load, graph()->start(),
	graph()->start());

	// Build the basic block structure.
	BasicBlock* start = schedule.start();
	schedule.rpo_order()->push_back(start);
	start->set_rpo_number(0);

	// Populate the basic blocks with nodes.
	schedule.AddNode(start, graph()->start());
	schedule.AddNode(start, heap_number);
	schedule.AddNode(start, load);
	schedule.AddReturn(start, ret);

	// Run the state effect introducer.
	EffectControlLinearizer introducer(jsgraph(), &schedule, zone());
	introducer.Run();

	EXPECT_THAT(load,
	IsLoadField(AccessBuilder::ForHeapNumberValue(), heap_number,
	graph()->start(), graph()->start()));
	// The return should have reconnected effect edge to the load.
	EXPECT_THAT(ret, IsReturn(load, load, graph()->start()));
	}

	TEST_F(EffectControlLinearizerTest, DiamondLoad) {
	Schedule schedule(zone());

	// Create the graph.
	Node* branch =
	graph()->NewNode(common()->Branch(), Int32Constant(0), graph()->start());

	Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
	Node* heap_number = NumberConstant(0.5);
	Node* vtrue = graph()->NewNode(
	simplified()->LoadField(AccessBuilder::ForHeapNumberValue()), heap_number,
	graph()->start(), if_true);

	Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
	Node* vfalse = Float64Constant(2);

	Node* merge = graph()->NewNode(common()->Merge(2), if_true, if_false);
	Node* phi = graph()->NewNode(
	common()->Phi(MachineRepresentation::kFloat64, 2), vtrue, vfalse, merge);

	Node* ret =
	graph()->NewNode(common()->Return(), phi, graph()->start(), merge);

	// Build the basic block structure.
	BasicBlock* start = schedule.start();
	schedule.rpo_order()->push_back(start);
	start->set_rpo_number(0);

	BasicBlock* tblock = AddBlockToSchedule(&schedule);
	BasicBlock* fblock = AddBlockToSchedule(&schedule);
	BasicBlock* mblock = AddBlockToSchedule(&schedule);

	// Populate the basic blocks with nodes.
	schedule.AddNode(start, graph()->start());
	schedule.AddBranch(start, branch, tblock, fblock);

	schedule.AddNode(tblock, if_true);
	schedule.AddNode(tblock, heap_number);
	schedule.AddNode(tblock, vtrue);
	schedule.AddGoto(tblock, mblock);

	schedule.AddNode(fblock, if_false);
	schedule.AddNode(fblock, vfalse);
	schedule.AddGoto(fblock, mblock);

	schedule.AddNode(mblock, merge);
	schedule.AddNode(mblock, phi);
	schedule.AddReturn(mblock, ret);

	// Run the state effect introducer.
	EffectControlLinearizer introducer(jsgraph(), &schedule, zone());
	introducer.Run();

	// The effect input to the return should be an effect phi with the
	// newly introduced effectful change operators.
	ASSERT_THAT(
	ret, IsReturn(phi, IsEffectPhi(vtrue, graph()->start(), merge), merge));
	}

	TEST_F(EffectControlLinearizerTest, FloatingDiamondsControlWiring) {
	Schedule schedule(zone());

	// Create the graph and schedule. Roughly (omitting effects and unimportant
	// nodes):
	//
	// BLOCK 0:
	// r1: Start
	// c1: Call
	// b1: Branch(const0, s1)
	// \|
	// +-------+------+
	// \| \|
	// BLOCK 1: BLOCK 2:
	// t1: IfTrue(b1) f1: IfFalse(b1)
	// \| \|
	// +-------+------+
	// \|
	// BLOCK 3:
	// m1: Merge(t1, f1)
	// c2: IfSuccess(c1)
	// b2: Branch(const0 , s1)
	// \|
	// +-------+------+
	// \| \|
	// BLOCK 4: BLOCK 5:
	// t2: IfTrue(b2) f2:IfFalse(b2)
	// \| \|
	// +-------+------+
	// \|
	// BLOCK 6:
	// m2: Merge(t2, f2)
	// r1: Return(c1, c2)
	MachineType kMachineSignature[] = {MachineType::AnyTagged(),
	MachineType::AnyTagged()};
	LinkageLocation kLocationSignature[] = {LinkageLocation::ForRegister(0),
	LinkageLocation::ForRegister(1)};
	const CallDescriptor* kCallDescriptor = new (zone()) CallDescriptor(
	CallDescriptor::kCallCodeObject, MachineType::AnyTagged(),
	LinkageLocation::ForRegister(0),
	new (zone()) MachineSignature(1, 1, kMachineSignature),
	new (zone()) LocationSignature(1, 1, kLocationSignature), 0,
	Operator::kNoProperties, 0, 0, CallDescriptor::kNoFlags);
	Node* p0 = Parameter(0);
	Node* p1 = Parameter(1);
	Node* const0 = Int32Constant(0);
	Node* call = graph()->NewNode(common()->Call(kCallDescriptor), p0, p1,
	graph()->start(), graph()->start());
	Node* if_success = graph()->NewNode(common()->IfSuccess(), call);

	// First Floating diamond.
	Node* branch1 =
	graph()->NewNode(common()->Branch(), const0, graph()->start());
	Node* if_true1 = graph()->NewNode(common()->IfTrue(), branch1);
	Node* if_false1 = graph()->NewNode(common()->IfFalse(), branch1);
	Node* merge1 = graph()->NewNode(common()->Merge(2), if_true1, if_false1);

	// Second floating diamond.
	Node* branch2 =
	graph()->NewNode(common()->Branch(), const0, graph()->start());
	Node* if_true2 = graph()->NewNode(common()->IfTrue(), branch2);
	Node* if_false2 = graph()->NewNode(common()->IfFalse(), branch2);
	Node* merge2 = graph()->NewNode(common()->Merge(2), if_true2, if_false2);

	Node* ret =
	graph()->NewNode(common()->Return(), call, graph()->start(), if_success);

	// Build the basic block structure.
	BasicBlock* start = schedule.start();
	schedule.rpo_order()->push_back(start);
	start->set_rpo_number(0);

	BasicBlock* t1block = AddBlockToSchedule(&schedule);
	BasicBlock* f1block = AddBlockToSchedule(&schedule);
	BasicBlock* m1block = AddBlockToSchedule(&schedule);

	BasicBlock* t2block = AddBlockToSchedule(&schedule);
	BasicBlock* f2block = AddBlockToSchedule(&schedule);
	BasicBlock* m2block = AddBlockToSchedule(&schedule);

	// Populate the basic blocks with nodes.
	schedule.AddNode(start, graph()->start());
	schedule.AddNode(start, p0);
	schedule.AddNode(start, p1);
	schedule.AddNode(start, const0);
	schedule.AddNode(start, call);
	schedule.AddBranch(start, branch1, t1block, f1block);

	schedule.AddNode(t1block, if_true1);
	schedule.AddGoto(t1block, m1block);

	schedule.AddNode(f1block, if_false1);
	schedule.AddGoto(f1block, m1block);

	schedule.AddNode(m1block, merge1);
	// The scheduler does not always put the IfSuccess node to the corresponding
	// call's block, simulate that here.
	schedule.AddNode(m1block, if_success);
	schedule.AddBranch(m1block, branch2, t2block, f2block);

	schedule.AddNode(t2block, if_true2);
	schedule.AddGoto(t2block, m2block);

	schedule.AddNode(f2block, if_false2);
	schedule.AddGoto(f2block, m2block);

	schedule.AddNode(m2block, merge2);
	schedule.AddReturn(m2block, ret);

	// Run the state effect introducer.
	EffectControlLinearizer introducer(jsgraph(), &schedule, zone());
	introducer.Run();

	// The effect input to the return should be an effect phi with the
	// newly introduced effectful change operators.
	ASSERT_THAT(ret, IsReturn(call, call, merge2));
	ASSERT_THAT(branch2, IsBranch(const0, merge1));
	ASSERT_THAT(branch1, IsBranch(const0, if_success));
	ASSERT_THAT(if_success, IsIfSuccess(call));
	}

	TEST_F(EffectControlLinearizerTest, LoopLoad) {
	Schedule schedule(zone());

	// Create the graph.
	Node* loop = graph()->NewNode(common()->Loop(1), graph()->start());
	Node* effect_phi =
	graph()->NewNode(common()->EffectPhi(1), graph()->start(), loop);

	Node* cond = Int32Constant(0);
	Node* branch = graph()->NewNode(common()->Branch(), cond, loop);

	Node* if_true = graph()->NewNode(common()->IfTrue(), branch);

	Node* if_false = graph()->NewNode(common()->IfFalse(), branch);

	loop->AppendInput(zone(), if_false);
	NodeProperties::ChangeOp(loop, common()->Loop(2));

	effect_phi->InsertInput(zone(), 1, effect_phi);
	NodeProperties::ChangeOp(effect_phi, common()->EffectPhi(2));

	Node* heap_number = NumberConstant(0.5);
	Node* load = graph()->NewNode(
	simplified()->LoadField(AccessBuilder::ForHeapNumberValue()), heap_number,
	graph()->start(), loop);

	Node* ret = graph()->NewNode(common()->Return(), load, effect_phi, if_true);

	// Build the basic block structure.
	BasicBlock* start = schedule.start();
	schedule.rpo_order()->push_back(start);
	start->set_rpo_number(0);

	BasicBlock* lblock = AddBlockToSchedule(&schedule);
	BasicBlock* fblock = AddBlockToSchedule(&schedule);
	BasicBlock* rblock = AddBlockToSchedule(&schedule);

	// Populate the basic blocks with nodes.
	schedule.AddNode(start, graph()->start());
	schedule.AddGoto(start, lblock);

	schedule.AddNode(lblock, loop);
	schedule.AddNode(lblock, effect_phi);
	schedule.AddNode(lblock, heap_number);
	schedule.AddNode(lblock, load);
	schedule.AddNode(lblock, cond);
	schedule.AddBranch(lblock, branch, rblock, fblock);

	schedule.AddNode(fblock, if_false);
	schedule.AddGoto(fblock, lblock);

	schedule.AddNode(rblock, if_true);
	schedule.AddReturn(rblock, ret);

	// Run the state effect introducer.
	EffectControlLinearizer introducer(jsgraph(), &schedule, zone());
	introducer.Run();

	ASSERT_THAT(ret, IsReturn(load, load, if_true));
	EXPECT_THAT(load, IsLoadField(AccessBuilder::ForHeapNumberValue(),
	heap_number, effect_phi, loop));
	}

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