test/cctest/compiler/test-changes-lowering.cc - fp2-dev/platform/external/v8 - Gitiles

 // 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 <limits>

 #include "src/compiler/change-lowering.h"
 #include "src/compiler/control-builders.h"
 #include "src/compiler/generic-node-inl.h"
 #include "src/compiler/js-graph.h"
 #include "src/compiler/node-properties-inl.h"
 #include "src/compiler/pipeline.h"
 #include "src/compiler/typer.h"
 #include "src/compiler/verifier.h"
 #include "src/execution.h"
 #include "src/globals.h"
 #include "src/parser.h"
 #include "src/rewriter.h"
 #include "src/scopes.h"
 #include "test/cctest/cctest.h"
 #include "test/cctest/compiler/codegen-tester.h"
 #include "test/cctest/compiler/graph-builder-tester.h"
 #include "test/cctest/compiler/value-helper.h"

 using namespace v8::internal;
 using namespace v8::internal::compiler;

 template <typename ReturnType>
 class ChangesLoweringTester : public GraphBuilderTester<ReturnType> {
  public:
   explicit ChangesLoweringTester(MachineType p0 = kMachNone)
       : GraphBuilderTester<ReturnType>(p0),
         typer(this->zone()),
         javascript(this->zone()),
         jsgraph(this->graph(), this->common(), &javascript, &typer,
                 this->machine()),
         function(Handle<JSFunction>::null()) {}

   Typer typer;
   JSOperatorBuilder javascript;
   JSGraph jsgraph;
   Handle<JSFunction> function;

   Node* start() { return this->graph()->start(); }

   template <typename T>
   T* CallWithPotentialGC() {
     // TODO(titzer): we need to wrap the code in a JSFunction and call it via
     // Execution::Call() so that the GC knows about the frame, can walk it,
     // relocate the code object if necessary, etc.
     // This is pretty ugly and at the least should be moved up to helpers.
     if (function.is_null()) {
       function =
           v8::Utils::OpenHandle(*v8::Handle<v8::Function>::Cast(CompileRun(
               "(function() { 'use strict'; return 2.7123; })")));
       CompilationInfoWithZone info(function);
       CHECK(Parser::Parse(&info));
       info.SetOptimizing(BailoutId::None(), Handle<Code>(function->code()));
       CHECK(Rewriter::Rewrite(&info));
       CHECK(Scope::Analyze(&info));
       CHECK_NE(NULL, info.scope());
       Handle<ScopeInfo> scope_info =
           ScopeInfo::Create(info.scope(), info.zone());
       info.shared_info()->set_scope_info(*scope_info);
       Pipeline pipeline(&info);
       Linkage linkage(&info);
       Handle<Code> code =
           pipeline.GenerateCodeForMachineGraph(&linkage, this->graph());
       CHECK(!code.is_null());
       function->ReplaceCode(*code);
     }
     Handle<Object>* args = NULL;
     MaybeHandle<Object> result =
         Execution::Call(this->isolate(), function, factory()->undefined_value(),
                         0, args, false);
     return T::cast(*result.ToHandleChecked());
   }

   void StoreFloat64(Node* node, double* ptr) {
     Node* ptr_node = this->PointerConstant(ptr);
     this->Store(kMachFloat64, ptr_node, node);
   }

   Node* LoadInt32(int32_t* ptr) {
     Node* ptr_node = this->PointerConstant(ptr);
     return this->Load(kMachInt32, ptr_node);
   }

   Node* LoadUint32(uint32_t* ptr) {
     Node* ptr_node = this->PointerConstant(ptr);
     return this->Load(kMachUint32, ptr_node);
   }

   Node* LoadFloat64(double* ptr) {
     Node* ptr_node = this->PointerConstant(ptr);
     return this->Load(kMachFloat64, ptr_node);
   }

   void CheckNumber(double expected, Object* number) {
     CHECK(this->isolate()->factory()->NewNumber(expected)->SameValue(number));
   }

   void BuildAndLower(const Operator* op) {
     // We build a graph by hand here, because the raw machine assembler
     // does not add the correct control and effect nodes.
     Node* p0 = this->Parameter(0);
     Node* change = this->graph()->NewNode(op, p0);
     Node* ret = this->graph()->NewNode(this->common()->Return(), change,
                                        this->start(), this->start());
     Node* end = this->graph()->NewNode(this->common()->End(), ret);
     this->graph()->SetEnd(end);
     LowerChange(change);
   }

   void BuildStoreAndLower(const Operator* op, const Operator* store_op,
                           void* location) {
     // We build a graph by hand here, because the raw machine assembler
     // does not add the correct control and effect nodes.
     Node* p0 = this->Parameter(0);
     Node* change = this->graph()->NewNode(op, p0);
     Node* store = this->graph()->NewNode(
         store_op, this->PointerConstant(location), this->Int32Constant(0),
         change, this->start(), this->start());
     Node* ret = this->graph()->NewNode(
         this->common()->Return(), this->Int32Constant(0), store, this->start());
     Node* end = this->graph()->NewNode(this->common()->End(), ret);
     this->graph()->SetEnd(end);
     LowerChange(change);
   }

   void BuildLoadAndLower(const Operator* op, const Operator* load_op,
                          void* location) {
     // We build a graph by hand here, because the raw machine assembler
     // does not add the correct control and effect nodes.
     Node* load =
         this->graph()->NewNode(load_op, this->PointerConstant(location),
                                this->Int32Constant(0), this->start());
     Node* change = this->graph()->NewNode(op, load);
     Node* ret = this->graph()->NewNode(this->common()->Return(), change,
                                        this->start(), this->start());
     Node* end = this->graph()->NewNode(this->common()->End(), ret);
     this->graph()->SetEnd(end);
     LowerChange(change);
   }

   void LowerChange(Node* change) {
     // Run the graph reducer with changes lowering on a single node.
     CompilationInfo info(this->isolate(), this->zone());
     Linkage linkage(&info);
     ChangeLowering lowering(&jsgraph, &linkage);
     GraphReducer reducer(this->graph());
     reducer.AddReducer(&lowering);
     reducer.ReduceNode(change);
     Verifier::Run(this->graph());
   }

   Factory* factory() { return this->isolate()->factory(); }
   Heap* heap() { return this->isolate()->heap(); }
 };


 TEST(RunChangeTaggedToInt32) {
   // Build and lower a graph by hand.
   ChangesLoweringTester<int32_t> t(kMachAnyTagged);
   t.BuildAndLower(t.simplified()->ChangeTaggedToInt32());

   if (Pipeline::SupportedTarget()) {
     FOR_INT32_INPUTS(i) {
       int32_t input = *i;

       if (Smi::IsValid(input)) {
         int32_t result = t.Call(Smi::FromInt(input));
         CHECK_EQ(input, result);
       }

       {
         Handle<Object> number = t.factory()->NewNumber(input);
         int32_t result = t.Call(*number);
         CHECK_EQ(input, result);
       }

       {
         Handle<HeapNumber> number = t.factory()->NewHeapNumber(input);
         int32_t result = t.Call(*number);
         CHECK_EQ(input, result);
       }
     }
   }
 }


 TEST(RunChangeTaggedToUint32) {
   // Build and lower a graph by hand.
   ChangesLoweringTester<uint32_t> t(kMachAnyTagged);
   t.BuildAndLower(t.simplified()->ChangeTaggedToUint32());

   if (Pipeline::SupportedTarget()) {
     FOR_UINT32_INPUTS(i) {
       uint32_t input = *i;

       if (Smi::IsValid(input)) {
         uint32_t result = t.Call(Smi::FromInt(input));
         CHECK_EQ(static_cast<int32_t>(input), static_cast<int32_t>(result));
       }

       {
         Handle<Object> number = t.factory()->NewNumber(input);
         uint32_t result = t.Call(*number);
         CHECK_EQ(static_cast<int32_t>(input), static_cast<int32_t>(result));
       }

       {
         Handle<HeapNumber> number = t.factory()->NewHeapNumber(input);
         uint32_t result = t.Call(*number);
         CHECK_EQ(static_cast<int32_t>(input), static_cast<int32_t>(result));
       }
     }
   }
 }


 TEST(RunChangeTaggedToFloat64) {
   ChangesLoweringTester<int32_t> t(kMachAnyTagged);
   double result;

   t.BuildStoreAndLower(
       t.simplified()->ChangeTaggedToFloat64(),
       t.machine()->Store(StoreRepresentation(kMachFloat64, kNoWriteBarrier)),
       &result);

   if (Pipeline::SupportedTarget()) {
     FOR_INT32_INPUTS(i) {
       int32_t input = *i;

       if (Smi::IsValid(input)) {
         t.Call(Smi::FromInt(input));
         CHECK_EQ(input, static_cast<int32_t>(result));
       }

       {
         Handle<Object> number = t.factory()->NewNumber(input);
         t.Call(*number);
         CHECK_EQ(input, static_cast<int32_t>(result));
       }

       {
         Handle<HeapNumber> number = t.factory()->NewHeapNumber(input);
         t.Call(*number);
         CHECK_EQ(input, static_cast<int32_t>(result));
       }
     }
   }

   if (Pipeline::SupportedTarget()) {
     FOR_FLOAT64_INPUTS(i) {
       double input = *i;
       {
         Handle<Object> number = t.factory()->NewNumber(input);
         t.Call(*number);
         CHECK_EQ(input, result);
       }

       {
         Handle<HeapNumber> number = t.factory()->NewHeapNumber(input);
         t.Call(*number);
         CHECK_EQ(input, result);
       }
     }
   }
 }


 TEST(RunChangeBoolToBit) {
   ChangesLoweringTester<int32_t> t(kMachAnyTagged);
   t.BuildAndLower(t.simplified()->ChangeBoolToBit());

   if (Pipeline::SupportedTarget()) {
     Object* true_obj = t.heap()->true_value();
     int32_t result = t.Call(true_obj);
     CHECK_EQ(1, result);
   }

   if (Pipeline::SupportedTarget()) {
     Object* false_obj = t.heap()->false_value();
     int32_t result = t.Call(false_obj);
     CHECK_EQ(0, result);
   }
 }


 TEST(RunChangeBitToBool) {
   ChangesLoweringTester<Object*> t(kMachInt32);
   t.BuildAndLower(t.simplified()->ChangeBitToBool());

   if (Pipeline::SupportedTarget()) {
     Object* result = t.Call(1);
     Object* true_obj = t.heap()->true_value();
     CHECK_EQ(true_obj, result);
   }

   if (Pipeline::SupportedTarget()) {
     Object* result = t.Call(0);
     Object* false_obj = t.heap()->false_value();
     CHECK_EQ(false_obj, result);
   }
 }


 #if V8_TURBOFAN_BACKEND
 // TODO(titzer): disabled on ARM

 TEST(RunChangeInt32ToTaggedSmi) {
   ChangesLoweringTester<Object*> t;
   int32_t input;
   t.BuildLoadAndLower(t.simplified()->ChangeInt32ToTagged(),
                       t.machine()->Load(kMachInt32), &input);

   if (Pipeline::SupportedTarget()) {
     FOR_INT32_INPUTS(i) {
       input = *i;
       if (!Smi::IsValid(input)) continue;
       Object* result = t.Call();
       t.CheckNumber(static_cast<double>(input), result);
     }
   }
 }


 TEST(RunChangeUint32ToTaggedSmi) {
   ChangesLoweringTester<Object*> t;
   uint32_t input;
   t.BuildLoadAndLower(t.simplified()->ChangeUint32ToTagged(),
                       t.machine()->Load(kMachUint32), &input);

   if (Pipeline::SupportedTarget()) {
     FOR_UINT32_INPUTS(i) {
       input = *i;
       if (input > static_cast<uint32_t>(Smi::kMaxValue)) continue;
       Object* result = t.Call();
       double expected = static_cast<double>(input);
       t.CheckNumber(expected, result);
     }
   }
 }


 TEST(RunChangeInt32ToTagged) {
   ChangesLoweringTester<Object*> t;
   int32_t input;
   t.BuildLoadAndLower(t.simplified()->ChangeInt32ToTagged(),
                       t.machine()->Load(kMachInt32), &input);

   if (Pipeline::SupportedTarget()) {
     for (int m = 0; m < 3; m++) {  // Try 3 GC modes.
       FOR_INT32_INPUTS(i) {
         if (m == 0) CcTest::heap()->EnableInlineAllocation();
         if (m == 1) CcTest::heap()->DisableInlineAllocation();
         if (m == 2) SimulateFullSpace(CcTest::heap()->new_space());

         input = *i;
         Object* result = t.CallWithPotentialGC<Object>();
         t.CheckNumber(static_cast<double>(input), result);
       }
     }
   }
 }


 TEST(RunChangeUint32ToTagged) {
   ChangesLoweringTester<Object*> t;
   uint32_t input;
   t.BuildLoadAndLower(t.simplified()->ChangeUint32ToTagged(),
                       t.machine()->Load(kMachUint32), &input);

   if (Pipeline::SupportedTarget()) {
     for (int m = 0; m < 3; m++) {  // Try 3 GC modes.
       FOR_UINT32_INPUTS(i) {
         if (m == 0) CcTest::heap()->EnableInlineAllocation();
         if (m == 1) CcTest::heap()->DisableInlineAllocation();
         if (m == 2) SimulateFullSpace(CcTest::heap()->new_space());

         input = *i;
         Object* result = t.CallWithPotentialGC<Object>();
         double expected = static_cast<double>(input);
         t.CheckNumber(expected, result);
       }
     }
   }
 }


 TEST(RunChangeFloat64ToTagged) {
   ChangesLoweringTester<Object*> t;
   double input;
   t.BuildLoadAndLower(t.simplified()->ChangeFloat64ToTagged(),
                       t.machine()->Load(kMachFloat64), &input);

   if (Pipeline::SupportedTarget()) {
     for (int m = 0; m < 3; m++) {  // Try 3 GC modes.
       FOR_FLOAT64_INPUTS(i) {
         if (m == 0) CcTest::heap()->EnableInlineAllocation();
         if (m == 1) CcTest::heap()->DisableInlineAllocation();
         if (m == 2) SimulateFullSpace(CcTest::heap()->new_space());

         input = *i;
         Object* result = t.CallWithPotentialGC<Object>();
         t.CheckNumber(input, result);
       }
     }
   }
 }

 #endif  // V8_TURBOFAN_BACKEND
	// 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 <limits>

	#include "src/compiler/change-lowering.h"
	#include "src/compiler/control-builders.h"
	#include "src/compiler/generic-node-inl.h"
	#include "src/compiler/js-graph.h"
	#include "src/compiler/node-properties-inl.h"
	#include "src/compiler/pipeline.h"
	#include "src/compiler/typer.h"
	#include "src/compiler/verifier.h"
	#include "src/execution.h"
	#include "src/globals.h"
	#include "src/parser.h"
	#include "src/rewriter.h"
	#include "src/scopes.h"
	#include "test/cctest/cctest.h"
	#include "test/cctest/compiler/codegen-tester.h"
	#include "test/cctest/compiler/graph-builder-tester.h"
	#include "test/cctest/compiler/value-helper.h"

	using namespace v8::internal;
	using namespace v8::internal::compiler;

	template <typename ReturnType>
	class ChangesLoweringTester : public GraphBuilderTester<ReturnType> {
	public:
	explicit ChangesLoweringTester(MachineType p0 = kMachNone)
	: GraphBuilderTester<ReturnType>(p0),
	typer(this->zone()),
	javascript(this->zone()),
	jsgraph(this->graph(), this->common(), &javascript, &typer,
	this->machine()),
	function(Handle<JSFunction>::null()) {}

	Typer typer;
	JSOperatorBuilder javascript;
	JSGraph jsgraph;
	Handle<JSFunction> function;

	Node* start() { return this->graph()->start(); }

	template <typename T>
	T* CallWithPotentialGC() {
	// TODO(titzer): we need to wrap the code in a JSFunction and call it via
	// Execution::Call() so that the GC knows about the frame, can walk it,
	// relocate the code object if necessary, etc.
	// This is pretty ugly and at the least should be moved up to helpers.
	if (function.is_null()) {
	function =
	v8::Utils::OpenHandle(*v8::Handle<v8::Function>::Cast(CompileRun(
	"(function() { 'use strict'; return 2.7123; })")));
	CompilationInfoWithZone info(function);
	CHECK(Parser::Parse(&info));
	info.SetOptimizing(BailoutId::None(), Handle<Code>(function->code()));
	CHECK(Rewriter::Rewrite(&info));
	CHECK(Scope::Analyze(&info));
	CHECK_NE(NULL, info.scope());
	Handle<ScopeInfo> scope_info =
	ScopeInfo::Create(info.scope(), info.zone());
	info.shared_info()->set_scope_info(*scope_info);
	Pipeline pipeline(&info);
	Linkage linkage(&info);
	Handle<Code> code =
	pipeline.GenerateCodeForMachineGraph(&linkage, this->graph());
	CHECK(!code.is_null());
	function->ReplaceCode(*code);
	}
	Handle<Object>* args = NULL;
	MaybeHandle<Object> result =
	Execution::Call(this->isolate(), function, factory()->undefined_value(),
	0, args, false);
	return T::cast(*result.ToHandleChecked());
	}

	void StoreFloat64(Node* node, double* ptr) {
	Node* ptr_node = this->PointerConstant(ptr);
	this->Store(kMachFloat64, ptr_node, node);
	}

	Node* LoadInt32(int32_t* ptr) {
	Node* ptr_node = this->PointerConstant(ptr);
	return this->Load(kMachInt32, ptr_node);
	}

	Node* LoadUint32(uint32_t* ptr) {
	Node* ptr_node = this->PointerConstant(ptr);
	return this->Load(kMachUint32, ptr_node);
	}

	Node* LoadFloat64(double* ptr) {
	Node* ptr_node = this->PointerConstant(ptr);
	return this->Load(kMachFloat64, ptr_node);
	}

	void CheckNumber(double expected, Object* number) {
	CHECK(this->isolate()->factory()->NewNumber(expected)->SameValue(number));
	}

	void BuildAndLower(const Operator* op) {
	// We build a graph by hand here, because the raw machine assembler
	// does not add the correct control and effect nodes.
	Node* p0 = this->Parameter(0);
	Node* change = this->graph()->NewNode(op, p0);
	Node* ret = this->graph()->NewNode(this->common()->Return(), change,
	this->start(), this->start());
	Node* end = this->graph()->NewNode(this->common()->End(), ret);
	this->graph()->SetEnd(end);
	LowerChange(change);
	}

	void BuildStoreAndLower(const Operator* op, const Operator* store_op,
	void* location) {
	// We build a graph by hand here, because the raw machine assembler
	// does not add the correct control and effect nodes.
	Node* p0 = this->Parameter(0);
	Node* change = this->graph()->NewNode(op, p0);
	Node* store = this->graph()->NewNode(
	store_op, this->PointerConstant(location), this->Int32Constant(0),
	change, this->start(), this->start());
	Node* ret = this->graph()->NewNode(
	this->common()->Return(), this->Int32Constant(0), store, this->start());
	Node* end = this->graph()->NewNode(this->common()->End(), ret);
	this->graph()->SetEnd(end);
	LowerChange(change);
	}

	void BuildLoadAndLower(const Operator* op, const Operator* load_op,
	void* location) {
	// We build a graph by hand here, because the raw machine assembler
	// does not add the correct control and effect nodes.
	Node* load =
	this->graph()->NewNode(load_op, this->PointerConstant(location),
	this->Int32Constant(0), this->start());
	Node* change = this->graph()->NewNode(op, load);
	Node* ret = this->graph()->NewNode(this->common()->Return(), change,
	this->start(), this->start());
	Node* end = this->graph()->NewNode(this->common()->End(), ret);
	this->graph()->SetEnd(end);
	LowerChange(change);
	}

	void LowerChange(Node* change) {
	// Run the graph reducer with changes lowering on a single node.
	CompilationInfo info(this->isolate(), this->zone());
	Linkage linkage(&info);
	ChangeLowering lowering(&jsgraph, &linkage);
	GraphReducer reducer(this->graph());
	reducer.AddReducer(&lowering);
	reducer.ReduceNode(change);
	Verifier::Run(this->graph());
	}

	Factory* factory() { return this->isolate()->factory(); }
	Heap* heap() { return this->isolate()->heap(); }
	};


	TEST(RunChangeTaggedToInt32) {
	// Build and lower a graph by hand.
	ChangesLoweringTester<int32_t> t(kMachAnyTagged);
	t.BuildAndLower(t.simplified()->ChangeTaggedToInt32());

	if (Pipeline::SupportedTarget()) {
	FOR_INT32_INPUTS(i) {
	int32_t input = *i;

	if (Smi::IsValid(input)) {
	int32_t result = t.Call(Smi::FromInt(input));
	CHECK_EQ(input, result);
	}

	{
	Handle<Object> number = t.factory()->NewNumber(input);
	int32_t result = t.Call(*number);
	CHECK_EQ(input, result);
	}

	{
	Handle<HeapNumber> number = t.factory()->NewHeapNumber(input);
	int32_t result = t.Call(*number);
	CHECK_EQ(input, result);
	}
	}
	}
	}


	TEST(RunChangeTaggedToUint32) {
	// Build and lower a graph by hand.
	ChangesLoweringTester<uint32_t> t(kMachAnyTagged);
	t.BuildAndLower(t.simplified()->ChangeTaggedToUint32());

	if (Pipeline::SupportedTarget()) {
	FOR_UINT32_INPUTS(i) {
	uint32_t input = *i;

	if (Smi::IsValid(input)) {
	uint32_t result = t.Call(Smi::FromInt(input));
	CHECK_EQ(static_cast<int32_t>(input), static_cast<int32_t>(result));
	}

	{
	Handle<Object> number = t.factory()->NewNumber(input);
	uint32_t result = t.Call(*number);
	CHECK_EQ(static_cast<int32_t>(input), static_cast<int32_t>(result));
	}

	{
	Handle<HeapNumber> number = t.factory()->NewHeapNumber(input);
	uint32_t result = t.Call(*number);
	CHECK_EQ(static_cast<int32_t>(input), static_cast<int32_t>(result));
	}
	}
	}
	}


	TEST(RunChangeTaggedToFloat64) {
	ChangesLoweringTester<int32_t> t(kMachAnyTagged);
	double result;

	t.BuildStoreAndLower(
	t.simplified()->ChangeTaggedToFloat64(),
	t.machine()->Store(StoreRepresentation(kMachFloat64, kNoWriteBarrier)),
	&result);

	if (Pipeline::SupportedTarget()) {
	FOR_INT32_INPUTS(i) {
	int32_t input = *i;

	if (Smi::IsValid(input)) {
	t.Call(Smi::FromInt(input));
	CHECK_EQ(input, static_cast<int32_t>(result));
	}

	{
	Handle<Object> number = t.factory()->NewNumber(input);
	t.Call(*number);
	CHECK_EQ(input, static_cast<int32_t>(result));
	}

	{
	Handle<HeapNumber> number = t.factory()->NewHeapNumber(input);
	t.Call(*number);
	CHECK_EQ(input, static_cast<int32_t>(result));
	}
	}
	}

	if (Pipeline::SupportedTarget()) {
	FOR_FLOAT64_INPUTS(i) {
	double input = *i;
	{
	Handle<Object> number = t.factory()->NewNumber(input);
	t.Call(*number);
	CHECK_EQ(input, result);
	}

	{
	Handle<HeapNumber> number = t.factory()->NewHeapNumber(input);
	t.Call(*number);
	CHECK_EQ(input, result);
	}
	}
	}
	}


	TEST(RunChangeBoolToBit) {
	ChangesLoweringTester<int32_t> t(kMachAnyTagged);
	t.BuildAndLower(t.simplified()->ChangeBoolToBit());

	if (Pipeline::SupportedTarget()) {
	Object* true_obj = t.heap()->true_value();
	int32_t result = t.Call(true_obj);
	CHECK_EQ(1, result);
	}

	if (Pipeline::SupportedTarget()) {
	Object* false_obj = t.heap()->false_value();
	int32_t result = t.Call(false_obj);
	CHECK_EQ(0, result);
	}
	}


	TEST(RunChangeBitToBool) {
	ChangesLoweringTester<Object*> t(kMachInt32);
	t.BuildAndLower(t.simplified()->ChangeBitToBool());

	if (Pipeline::SupportedTarget()) {
	Object* result = t.Call(1);
	Object* true_obj = t.heap()->true_value();
	CHECK_EQ(true_obj, result);
	}

	if (Pipeline::SupportedTarget()) {
	Object* result = t.Call(0);
	Object* false_obj = t.heap()->false_value();
	CHECK_EQ(false_obj, result);
	}
	}


	#if V8_TURBOFAN_BACKEND
	// TODO(titzer): disabled on ARM

	TEST(RunChangeInt32ToTaggedSmi) {
	ChangesLoweringTester<Object*> t;
	int32_t input;
	t.BuildLoadAndLower(t.simplified()->ChangeInt32ToTagged(),
	t.machine()->Load(kMachInt32), &input);

	if (Pipeline::SupportedTarget()) {
	FOR_INT32_INPUTS(i) {
	input = *i;
	if (!Smi::IsValid(input)) continue;
	Object* result = t.Call();
	t.CheckNumber(static_cast<double>(input), result);
	}
	}
	}


	TEST(RunChangeUint32ToTaggedSmi) {
	ChangesLoweringTester<Object*> t;
	uint32_t input;
	t.BuildLoadAndLower(t.simplified()->ChangeUint32ToTagged(),
	t.machine()->Load(kMachUint32), &input);

	if (Pipeline::SupportedTarget()) {
	FOR_UINT32_INPUTS(i) {
	input = *i;
	if (input > static_cast<uint32_t>(Smi::kMaxValue)) continue;
	Object* result = t.Call();
	double expected = static_cast<double>(input);
	t.CheckNumber(expected, result);
	}
	}
	}


	TEST(RunChangeInt32ToTagged) {
	ChangesLoweringTester<Object*> t;
	int32_t input;
	t.BuildLoadAndLower(t.simplified()->ChangeInt32ToTagged(),
	t.machine()->Load(kMachInt32), &input);

	if (Pipeline::SupportedTarget()) {
	for (int m = 0; m < 3; m++) { // Try 3 GC modes.
	FOR_INT32_INPUTS(i) {
	if (m == 0) CcTest::heap()->EnableInlineAllocation();
	if (m == 1) CcTest::heap()->DisableInlineAllocation();
	if (m == 2) SimulateFullSpace(CcTest::heap()->new_space());

	input = *i;
	Object* result = t.CallWithPotentialGC<Object>();
	t.CheckNumber(static_cast<double>(input), result);
	}
	}
	}
	}


	TEST(RunChangeUint32ToTagged) {
	ChangesLoweringTester<Object*> t;
	uint32_t input;
	t.BuildLoadAndLower(t.simplified()->ChangeUint32ToTagged(),
	t.machine()->Load(kMachUint32), &input);

	if (Pipeline::SupportedTarget()) {
	for (int m = 0; m < 3; m++) { // Try 3 GC modes.
	FOR_UINT32_INPUTS(i) {
	if (m == 0) CcTest::heap()->EnableInlineAllocation();
	if (m == 1) CcTest::heap()->DisableInlineAllocation();
	if (m == 2) SimulateFullSpace(CcTest::heap()->new_space());

	input = *i;
	Object* result = t.CallWithPotentialGC<Object>();
	double expected = static_cast<double>(input);
	t.CheckNumber(expected, result);
	}
	}
	}
	}


	TEST(RunChangeFloat64ToTagged) {
	ChangesLoweringTester<Object*> t;
	double input;
	t.BuildLoadAndLower(t.simplified()->ChangeFloat64ToTagged(),
	t.machine()->Load(kMachFloat64), &input);

	if (Pipeline::SupportedTarget()) {
	for (int m = 0; m < 3; m++) { // Try 3 GC modes.
	FOR_FLOAT64_INPUTS(i) {
	if (m == 0) CcTest::heap()->EnableInlineAllocation();
	if (m == 1) CcTest::heap()->DisableInlineAllocation();
	if (m == 2) SimulateFullSpace(CcTest::heap()->new_space());

	input = *i;
	Object* result = t.CallWithPotentialGC<Object>();
	t.CheckNumber(input, result);
	}
	}
	}
	}

	#endif // V8_TURBOFAN_BACKEND