src/v8/test/unittests/compiler/js-call-reducer-unittest.cc - cobalt - Git at Google

 // Copyright 2018 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 <cctype>

 #include "src/codegen/tick-counter.h"
 #include "src/compiler/compilation-dependencies.h"
 #include "src/compiler/js-call-reducer.h"
 #include "src/compiler/js-graph.h"
 #include "src/compiler/simplified-operator.h"
 #include "src/execution/isolate.h"
 #include "src/heap/factory.h"
 #include "src/objects/feedback-vector.h"
 #include "test/unittests/compiler/graph-unittest.h"
 #include "test/unittests/compiler/node-test-utils.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 class JSCallReducerTest : public TypedGraphTest {
  public:
   JSCallReducerTest()
       : TypedGraphTest(3), javascript_(zone()), deps_(broker(), zone()) {
     broker()->SerializeStandardObjects();
   }
   ~JSCallReducerTest() override = default;

  protected:
   Reduction Reduce(Node* node) {
     MachineOperatorBuilder machine(zone());
     SimplifiedOperatorBuilder simplified(zone());
     JSGraph jsgraph(isolate(), graph(), common(), javascript(), &simplified,
                     &machine);
     // TODO(titzer): mock the GraphReducer here for better unit testing.
     GraphReducer graph_reducer(zone(), graph(), tick_counter());

     JSCallReducer reducer(&graph_reducer, &jsgraph, broker(),
                           JSCallReducer::kNoFlags, &deps_);
     return reducer.Reduce(node);
   }

   JSOperatorBuilder* javascript() { return &javascript_; }

   Node* GlobalFunction(const char* name) {
     Handle<JSFunction> f = Handle<JSFunction>::cast(
         Object::GetProperty(
             isolate(), isolate()->global_object(),
             isolate()->factory()->NewStringFromAsciiChecked(name))
             .ToHandleChecked());
     return HeapConstant(f);
   }

   Node* MathFunction(const std::string& name) {
     Handle<Object> m =
         JSObject::GetProperty(
             isolate(), isolate()->global_object(),
             isolate()->factory()->NewStringFromAsciiChecked("Math"))
             .ToHandleChecked();
     Handle<JSFunction> f = Handle<JSFunction>::cast(
         Object::GetProperty(
             isolate(), m,
             isolate()->factory()->NewStringFromAsciiChecked(name.c_str()))
             .ToHandleChecked());
     return HeapConstant(f);
   }

   Node* StringFunction(const char* name) {
     Handle<Object> m =
         JSObject::GetProperty(
             isolate(), isolate()->global_object(),
             isolate()->factory()->NewStringFromAsciiChecked("String"))
             .ToHandleChecked();
     Handle<JSFunction> f = Handle<JSFunction>::cast(
         Object::GetProperty(
             isolate(), m, isolate()->factory()->NewStringFromAsciiChecked(name))
             .ToHandleChecked());
     return HeapConstant(f);
   }

   Node* NumberFunction(const char* name) {
     Handle<Object> m =
         JSObject::GetProperty(
             isolate(), isolate()->global_object(),
             isolate()->factory()->NewStringFromAsciiChecked("Number"))
             .ToHandleChecked();
     Handle<JSFunction> f = Handle<JSFunction>::cast(
         Object::GetProperty(
             isolate(), m, isolate()->factory()->NewStringFromAsciiChecked(name))
             .ToHandleChecked());
     return HeapConstant(f);
   }

   std::string op_name_for(const char* fnc) {
     std::string string_fnc(fnc);
     char initial = std::toupper(fnc[0]);
     return std::string("Number") + initial +
            string_fnc.substr(1, std::string::npos);
   }

   const Operator* Call(int arity) {
     FeedbackVectorSpec spec(zone());
     spec.AddCallICSlot();
     Handle<FeedbackMetadata> metadata = FeedbackMetadata::New(isolate(), &spec);
     Handle<SharedFunctionInfo> shared =
         isolate()->factory()->NewSharedFunctionInfoForBuiltin(
             isolate()->factory()->empty_string(), Builtins::kIllegal);
     // Set the raw feedback metadata to circumvent checks that we are not
     // overwriting existing metadata.
     shared->set_raw_outer_scope_info_or_feedback_metadata(*metadata);
     Handle<ClosureFeedbackCellArray> closure_feedback_cell_array =
         ClosureFeedbackCellArray::New(isolate(), shared);
     Handle<FeedbackVector> vector =
         FeedbackVector::New(isolate(), shared, closure_feedback_cell_array);
     VectorSlotPair feedback(vector, FeedbackSlot(0), UNINITIALIZED);
     return javascript()->Call(arity, CallFrequency(), feedback,
                               ConvertReceiverMode::kAny,
                               SpeculationMode::kAllowSpeculation);
   }

  private:
   JSOperatorBuilder javascript_;
   CompilationDependencies deps_;
 };

 TEST_F(JSCallReducerTest, PromiseConstructorNoArgs) {
   Node* promise =
       HeapConstant(handle(native_context()->promise_function(), isolate()));
   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();

   Node* construct =
       graph()->NewNode(javascript()->Construct(2), promise, promise, context,
                        frame_state, effect, control);

   Reduction r = Reduce(construct);

   ASSERT_FALSE(r.Changed());
 }

 TEST_F(JSCallReducerTest, PromiseConstructorSubclass) {
   Node* promise =
       HeapConstant(handle(native_context()->promise_function(), isolate()));
   Node* new_target =
       HeapConstant(handle(native_context()->array_function(), isolate()));
   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();

   Node* executor = UndefinedConstant();
   Node* construct =
       graph()->NewNode(javascript()->Construct(3), promise, executor,
                        new_target, context, frame_state, effect, control);

   Reduction r = Reduce(construct);

   ASSERT_FALSE(r.Changed());
 }

 TEST_F(JSCallReducerTest, PromiseConstructorBasic) {
   Node* promise =
       HeapConstant(handle(native_context()->promise_function(), isolate()));
   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();

   Node* executor = UndefinedConstant();
   Node* construct =
       graph()->NewNode(javascript()->Construct(3), promise, executor, promise,
                        context, frame_state, effect, control);

   Reduction r = Reduce(construct);

   if (FLAG_experimental_inline_promise_constructor) {
     ASSERT_TRUE(r.Changed());
   } else {
     ASSERT_FALSE(r.Changed());
   }
 }

 // Exactly the same as PromiseConstructorBasic which expects a reduction,
 // except that we invalidate the protector cell.
 TEST_F(JSCallReducerTest, PromiseConstructorWithHook) {
   Node* promise =
       HeapConstant(handle(native_context()->promise_function(), isolate()));
   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();

   Node* executor = UndefinedConstant();
   Node* construct =
       graph()->NewNode(javascript()->Construct(3), promise, executor, promise,
                        context, frame_state, effect, control);

   isolate()->InvalidatePromiseHookProtector();

   Reduction r = Reduce(construct);

   ASSERT_FALSE(r.Changed());
 }

 // -----------------------------------------------------------------------------
 // Math unaries

 namespace {

 const char* kMathUnaries[] = {
     "abs",  "acos",  "acosh", "asin", "asinh", "atan",  "cbrt",
     "ceil", "cos",   "cosh",  "exp",  "expm1", "floor", "fround",
     "log",  "log1p", "log10", "log2", "round", "sign",  "sin",
     "sinh", "sqrt",  "tan",   "tanh", "trunc"};

 }  // namespace

 TEST_F(JSCallReducerTest, MathUnaryWithNumber) {
   TRACED_FOREACH(const char*, fnc, kMathUnaries) {
     Node* effect = graph()->start();
     Node* control = graph()->start();
     Node* context = UndefinedConstant();
     Node* frame_state = graph()->start();
     Node* jsfunction = MathFunction(fnc);
     Node* p0 = Parameter(Type::Any(), 0);
     Node* call = graph()->NewNode(Call(3), jsfunction, UndefinedConstant(), p0,
                                   context, frame_state, effect, control);
     Reduction r = Reduce(call);
     ASSERT_TRUE(r.Changed());
     EXPECT_THAT(std::string(IrOpcode::Mnemonic(r.replacement()->opcode())),
                 op_name_for(fnc));
   }
 }

 // -----------------------------------------------------------------------------
 // Math binaries

 namespace {

 const char* kMathBinaries[] = {"atan2", "pow"};

 }  // namespace

 TEST_F(JSCallReducerTest, MathBinaryWithNumber) {
   TRACED_FOREACH(const char*, fnc, kMathBinaries) {
     Node* jsfunction = MathFunction(fnc);

     Node* effect = graph()->start();
     Node* control = graph()->start();
     Node* context = UndefinedConstant();
     Node* frame_state = graph()->start();
     Node* p0 = Parameter(Type::Any(), 0);
     Node* p1 = Parameter(Type::Any(), 0);
     Node* call = graph()->NewNode(Call(4), jsfunction, UndefinedConstant(), p0,
                                   p1, context, frame_state, effect, control);
     Reduction r = Reduce(call);

     ASSERT_TRUE(r.Changed());
     EXPECT_THAT(std::string(IrOpcode::Mnemonic(r.replacement()->opcode())),
                 op_name_for(fnc));
   }
 }

 // -----------------------------------------------------------------------------
 // Math.clz32

 TEST_F(JSCallReducerTest, MathClz32WithUnsigned32) {
   Node* jsfunction = MathFunction("clz32");
   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();

   Node* p0 = Parameter(Type::Unsigned32(), 0);
   Node* call = graph()->NewNode(Call(3), jsfunction, UndefinedConstant(), p0,
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(),
               IsNumberClz32(IsNumberToUint32(IsSpeculativeToNumber(p0))));
 }

 TEST_F(JSCallReducerTest, MathClz32WithUnsigned32NoArg) {
   Node* jsfunction = MathFunction("clz32");
   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();

   Node* call = graph()->NewNode(Call(2), jsfunction, UndefinedConstant(),
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsNumberConstant(32));
 }

 // -----------------------------------------------------------------------------
 // Math.imul

 TEST_F(JSCallReducerTest, MathImulWithUnsigned32) {
   Node* jsfunction = MathFunction("imul");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Unsigned32(), 0);
   Node* p1 = Parameter(Type::Unsigned32(), 1);
   Node* call = graph()->NewNode(Call(4), jsfunction, UndefinedConstant(), p0,
                                 p1, context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(std::string(IrOpcode::Mnemonic(r.replacement()->opcode())),
               op_name_for("imul"));
 }

 // -----------------------------------------------------------------------------
 // Math.min

 TEST_F(JSCallReducerTest, MathMinWithNoArguments) {
   Node* jsfunction = MathFunction("min");
   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* call = graph()->NewNode(Call(2), jsfunction, UndefinedConstant(),
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsNumberConstant(V8_INFINITY));
 }

 TEST_F(JSCallReducerTest, MathMinWithNumber) {
   Node* jsfunction = MathFunction("min");
   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* call = graph()->NewNode(Call(3), jsfunction, UndefinedConstant(), p0,
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsSpeculativeToNumber(p0));
 }

 TEST_F(JSCallReducerTest, MathMinWithTwoArguments) {
   Node* jsfunction = MathFunction("min");
   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* p1 = Parameter(Type::Any(), 1);
   Node* call = graph()->NewNode(Call(4), jsfunction, UndefinedConstant(), p0,
                                 p1, context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsNumberMin(IsSpeculativeToNumber(p0),
                                            IsSpeculativeToNumber(p1)));
 }

 // -----------------------------------------------------------------------------
 // Math.max

 TEST_F(JSCallReducerTest, MathMaxWithNoArguments) {
   Node* jsfunction = MathFunction("max");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* call = graph()->NewNode(Call(2), jsfunction, UndefinedConstant(),
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsNumberConstant(-V8_INFINITY));
 }

 TEST_F(JSCallReducerTest, MathMaxWithNumber) {
   Node* jsfunction = MathFunction("max");
   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* call = graph()->NewNode(Call(3), jsfunction, UndefinedConstant(), p0,
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsSpeculativeToNumber(p0));
 }

 TEST_F(JSCallReducerTest, MathMaxWithTwoArguments) {
   Node* jsfunction = MathFunction("max");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* p1 = Parameter(Type::Any(), 1);
   Node* call = graph()->NewNode(Call(4), jsfunction, UndefinedConstant(), p0,
                                 p1, context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsNumberMax(IsSpeculativeToNumber(p0),
                                            IsSpeculativeToNumber(p1)));
 }

 // -----------------------------------------------------------------------------
 // String.fromCharCode

 TEST_F(JSCallReducerTest, StringFromSingleCharCodeWithNumber) {
   Node* function = StringFunction("fromCharCode");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* call = graph()->NewNode(Call(3), function, UndefinedConstant(), p0,
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(),
               IsStringFromSingleCharCode(IsSpeculativeToNumber(p0)));
 }

 TEST_F(JSCallReducerTest, StringFromSingleCharCodeWithPlainPrimitive) {
   Node* function = StringFunction("fromCharCode");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::PlainPrimitive(), 0);
   Node* call = graph()->NewNode(Call(3), function, UndefinedConstant(), p0,
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(),
               IsStringFromSingleCharCode(IsSpeculativeToNumber(p0)));
 }

 // -----------------------------------------------------------------------------
 // Number.isFinite

 TEST_F(JSCallReducerTest, NumberIsFinite) {
   Node* function = NumberFunction("isFinite");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* call = graph()->NewNode(Call(3), function, UndefinedConstant(), p0,
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsObjectIsFiniteNumber(p0));
 }

 // -----------------------------------------------------------------------------
 // Number.isInteger

 TEST_F(JSCallReducerTest, NumberIsIntegerWithNumber) {
   Node* function = NumberFunction("isInteger");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* call =
       graph()->NewNode(javascript()->Call(3), function, UndefinedConstant(), p0,
                        context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsObjectIsInteger(p0));
 }

 // -----------------------------------------------------------------------------
 // Number.isNaN

 TEST_F(JSCallReducerTest, NumberIsNaNWithNumber) {
   Node* function = NumberFunction("isNaN");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* call =
       graph()->NewNode(javascript()->Call(3), function, UndefinedConstant(), p0,
                        context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsObjectIsNaN(p0));
 }

 // -----------------------------------------------------------------------------
 // Number.isSafeInteger

 TEST_F(JSCallReducerTest, NumberIsSafeIntegerWithIntegral32) {
   Node* function = NumberFunction("isSafeInteger");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* call =
       graph()->NewNode(javascript()->Call(3), function, UndefinedConstant(), p0,
                        context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsObjectIsSafeInteger(p0));
 }

 // -----------------------------------------------------------------------------
 // isFinite

 TEST_F(JSCallReducerTest, GlobalIsFiniteWithNumber) {
   Node* function = GlobalFunction("isFinite");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* call = graph()->NewNode(Call(3), function, UndefinedConstant(), p0,
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsNumberIsFinite(IsSpeculativeToNumber(p0)));
 }

 // -----------------------------------------------------------------------------
 // isNaN

 TEST_F(JSCallReducerTest, GlobalIsNaN) {
   Node* function = GlobalFunction("isNaN");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* call = graph()->NewNode(Call(3), function, UndefinedConstant(), p0,
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsNumberIsNaN(IsSpeculativeToNumber(p0)));
 }

 // -----------------------------------------------------------------------------
 // Number.parseInt

 TEST_F(JSCallReducerTest, NumberParseInt) {
   Node* function = NumberFunction("parseInt");

   Node* effect = graph()->start();
   Node* control = graph()->start();
   Node* context = UndefinedConstant();
   Node* frame_state = graph()->start();
   Node* p0 = Parameter(Type::Any(), 0);
   Node* p1 = Parameter(Type::Any(), 1);
   Node* call = graph()->NewNode(Call(4), function, UndefinedConstant(), p0, p1,
                                 context, frame_state, effect, control);
   Reduction r = Reduce(call);

   ASSERT_TRUE(r.Changed());
   EXPECT_THAT(r.replacement(), IsJSParseInt(p0, p1));
 }

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8
	// Copyright 2018 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 <cctype>

	#include "src/codegen/tick-counter.h"
	#include "src/compiler/compilation-dependencies.h"
	#include "src/compiler/js-call-reducer.h"
	#include "src/compiler/js-graph.h"
	#include "src/compiler/simplified-operator.h"
	#include "src/execution/isolate.h"
	#include "src/heap/factory.h"
	#include "src/objects/feedback-vector.h"
	#include "test/unittests/compiler/graph-unittest.h"
	#include "test/unittests/compiler/node-test-utils.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	class JSCallReducerTest : public TypedGraphTest {
	public:
	JSCallReducerTest()
	: TypedGraphTest(3), javascript_(zone()), deps_(broker(), zone()) {
	broker()->SerializeStandardObjects();
	}
	~JSCallReducerTest() override = default;

	protected:
	Reduction Reduce(Node* node) {
	MachineOperatorBuilder machine(zone());
	SimplifiedOperatorBuilder simplified(zone());
	JSGraph jsgraph(isolate(), graph(), common(), javascript(), &simplified,
	&machine);
	// TODO(titzer): mock the GraphReducer here for better unit testing.
	GraphReducer graph_reducer(zone(), graph(), tick_counter());

	JSCallReducer reducer(&graph_reducer, &jsgraph, broker(),
	JSCallReducer::kNoFlags, &deps_);
	return reducer.Reduce(node);
	}

	JSOperatorBuilder* javascript() { return &javascript_; }

	Node* GlobalFunction(const char* name) {
	Handle<JSFunction> f = Handle<JSFunction>::cast(
	Object::GetProperty(
	isolate(), isolate()->global_object(),
	isolate()->factory()->NewStringFromAsciiChecked(name))
	.ToHandleChecked());
	return HeapConstant(f);
	}

	Node* MathFunction(const std::string& name) {
	Handle<Object> m =
	JSObject::GetProperty(
	isolate(), isolate()->global_object(),
	isolate()->factory()->NewStringFromAsciiChecked("Math"))
	.ToHandleChecked();
	Handle<JSFunction> f = Handle<JSFunction>::cast(
	Object::GetProperty(
	isolate(), m,
	isolate()->factory()->NewStringFromAsciiChecked(name.c_str()))
	.ToHandleChecked());
	return HeapConstant(f);
	}

	Node* StringFunction(const char* name) {
	Handle<Object> m =
	JSObject::GetProperty(
	isolate(), isolate()->global_object(),
	isolate()->factory()->NewStringFromAsciiChecked("String"))
	.ToHandleChecked();
	Handle<JSFunction> f = Handle<JSFunction>::cast(
	Object::GetProperty(
	isolate(), m, isolate()->factory()->NewStringFromAsciiChecked(name))
	.ToHandleChecked());
	return HeapConstant(f);
	}

	Node* NumberFunction(const char* name) {
	Handle<Object> m =
	JSObject::GetProperty(
	isolate(), isolate()->global_object(),
	isolate()->factory()->NewStringFromAsciiChecked("Number"))
	.ToHandleChecked();
	Handle<JSFunction> f = Handle<JSFunction>::cast(
	Object::GetProperty(
	isolate(), m, isolate()->factory()->NewStringFromAsciiChecked(name))
	.ToHandleChecked());
	return HeapConstant(f);
	}

	std::string op_name_for(const char* fnc) {
	std::string string_fnc(fnc);
	char initial = std::toupper(fnc[0]);
	return std::string("Number") + initial +
	string_fnc.substr(1, std::string::npos);
	}

	const Operator* Call(int arity) {
	FeedbackVectorSpec spec(zone());
	spec.AddCallICSlot();
	Handle<FeedbackMetadata> metadata = FeedbackMetadata::New(isolate(), &spec);
	Handle<SharedFunctionInfo> shared =
	isolate()->factory()->NewSharedFunctionInfoForBuiltin(
	isolate()->factory()->empty_string(), Builtins::kIllegal);
	// Set the raw feedback metadata to circumvent checks that we are not
	// overwriting existing metadata.
	shared->set_raw_outer_scope_info_or_feedback_metadata(*metadata);
	Handle<ClosureFeedbackCellArray> closure_feedback_cell_array =
	ClosureFeedbackCellArray::New(isolate(), shared);
	Handle<FeedbackVector> vector =
	FeedbackVector::New(isolate(), shared, closure_feedback_cell_array);
	VectorSlotPair feedback(vector, FeedbackSlot(0), UNINITIALIZED);
	return javascript()->Call(arity, CallFrequency(), feedback,
	ConvertReceiverMode::kAny,
	SpeculationMode::kAllowSpeculation);
	}

	private:
	JSOperatorBuilder javascript_;
	CompilationDependencies deps_;
	};

	TEST_F(JSCallReducerTest, PromiseConstructorNoArgs) {
	Node* promise =
	HeapConstant(handle(native_context()->promise_function(), isolate()));
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();

	Node* construct =
	graph()->NewNode(javascript()->Construct(2), promise, promise, context,
	frame_state, effect, control);

	Reduction r = Reduce(construct);

	ASSERT_FALSE(r.Changed());
	}

	TEST_F(JSCallReducerTest, PromiseConstructorSubclass) {
	Node* promise =
	HeapConstant(handle(native_context()->promise_function(), isolate()));
	Node* new_target =
	HeapConstant(handle(native_context()->array_function(), isolate()));
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();

	Node* executor = UndefinedConstant();
	Node* construct =
	graph()->NewNode(javascript()->Construct(3), promise, executor,
	new_target, context, frame_state, effect, control);

	Reduction r = Reduce(construct);

	ASSERT_FALSE(r.Changed());
	}

	TEST_F(JSCallReducerTest, PromiseConstructorBasic) {
	Node* promise =
	HeapConstant(handle(native_context()->promise_function(), isolate()));
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();

	Node* executor = UndefinedConstant();
	Node* construct =
	graph()->NewNode(javascript()->Construct(3), promise, executor, promise,
	context, frame_state, effect, control);

	Reduction r = Reduce(construct);

	if (FLAG_experimental_inline_promise_constructor) {
	ASSERT_TRUE(r.Changed());
	} else {
	ASSERT_FALSE(r.Changed());
	}
	}

	// Exactly the same as PromiseConstructorBasic which expects a reduction,
	// except that we invalidate the protector cell.
	TEST_F(JSCallReducerTest, PromiseConstructorWithHook) {
	Node* promise =
	HeapConstant(handle(native_context()->promise_function(), isolate()));
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();

	Node* executor = UndefinedConstant();
	Node* construct =
	graph()->NewNode(javascript()->Construct(3), promise, executor, promise,
	context, frame_state, effect, control);

	isolate()->InvalidatePromiseHookProtector();

	Reduction r = Reduce(construct);

	ASSERT_FALSE(r.Changed());
	}

	// -----------------------------------------------------------------------------
	// Math unaries

	namespace {

	const char* kMathUnaries[] = {
	"abs", "acos", "acosh", "asin", "asinh", "atan", "cbrt",
	"ceil", "cos", "cosh", "exp", "expm1", "floor", "fround",
	"log", "log1p", "log10", "log2", "round", "sign", "sin",
	"sinh", "sqrt", "tan", "tanh", "trunc"};

	} // namespace

	TEST_F(JSCallReducerTest, MathUnaryWithNumber) {
	TRACED_FOREACH(const char*, fnc, kMathUnaries) {
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* jsfunction = MathFunction(fnc);
	Node* p0 = Parameter(Type::Any(), 0);
	Node* call = graph()->NewNode(Call(3), jsfunction, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);
	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(std::string(IrOpcode::Mnemonic(r.replacement()->opcode())),
	op_name_for(fnc));
	}
	}

	// -----------------------------------------------------------------------------
	// Math binaries

	namespace {

	const char* kMathBinaries[] = {"atan2", "pow"};

	} // namespace

	TEST_F(JSCallReducerTest, MathBinaryWithNumber) {
	TRACED_FOREACH(const char*, fnc, kMathBinaries) {
	Node* jsfunction = MathFunction(fnc);

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* p1 = Parameter(Type::Any(), 0);
	Node* call = graph()->NewNode(Call(4), jsfunction, UndefinedConstant(), p0,
	p1, context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(std::string(IrOpcode::Mnemonic(r.replacement()->opcode())),
	op_name_for(fnc));
	}
	}

	// -----------------------------------------------------------------------------
	// Math.clz32

	TEST_F(JSCallReducerTest, MathClz32WithUnsigned32) {
	Node* jsfunction = MathFunction("clz32");
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();

	Node* p0 = Parameter(Type::Unsigned32(), 0);
	Node* call = graph()->NewNode(Call(3), jsfunction, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(),
	IsNumberClz32(IsNumberToUint32(IsSpeculativeToNumber(p0))));
	}

	TEST_F(JSCallReducerTest, MathClz32WithUnsigned32NoArg) {
	Node* jsfunction = MathFunction("clz32");
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();

	Node* call = graph()->NewNode(Call(2), jsfunction, UndefinedConstant(),
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsNumberConstant(32));
	}

	// -----------------------------------------------------------------------------
	// Math.imul

	TEST_F(JSCallReducerTest, MathImulWithUnsigned32) {
	Node* jsfunction = MathFunction("imul");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Unsigned32(), 0);
	Node* p1 = Parameter(Type::Unsigned32(), 1);
	Node* call = graph()->NewNode(Call(4), jsfunction, UndefinedConstant(), p0,
	p1, context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(std::string(IrOpcode::Mnemonic(r.replacement()->opcode())),
	op_name_for("imul"));
	}

	// -----------------------------------------------------------------------------
	// Math.min

	TEST_F(JSCallReducerTest, MathMinWithNoArguments) {
	Node* jsfunction = MathFunction("min");
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* call = graph()->NewNode(Call(2), jsfunction, UndefinedConstant(),
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsNumberConstant(V8_INFINITY));
	}

	TEST_F(JSCallReducerTest, MathMinWithNumber) {
	Node* jsfunction = MathFunction("min");
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* call = graph()->NewNode(Call(3), jsfunction, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsSpeculativeToNumber(p0));
	}

	TEST_F(JSCallReducerTest, MathMinWithTwoArguments) {
	Node* jsfunction = MathFunction("min");
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* p1 = Parameter(Type::Any(), 1);
	Node* call = graph()->NewNode(Call(4), jsfunction, UndefinedConstant(), p0,
	p1, context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsNumberMin(IsSpeculativeToNumber(p0),
	IsSpeculativeToNumber(p1)));
	}

	// -----------------------------------------------------------------------------
	// Math.max

	TEST_F(JSCallReducerTest, MathMaxWithNoArguments) {
	Node* jsfunction = MathFunction("max");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* call = graph()->NewNode(Call(2), jsfunction, UndefinedConstant(),
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsNumberConstant(-V8_INFINITY));
	}

	TEST_F(JSCallReducerTest, MathMaxWithNumber) {
	Node* jsfunction = MathFunction("max");
	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* call = graph()->NewNode(Call(3), jsfunction, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsSpeculativeToNumber(p0));
	}

	TEST_F(JSCallReducerTest, MathMaxWithTwoArguments) {
	Node* jsfunction = MathFunction("max");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* p1 = Parameter(Type::Any(), 1);
	Node* call = graph()->NewNode(Call(4), jsfunction, UndefinedConstant(), p0,
	p1, context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsNumberMax(IsSpeculativeToNumber(p0),
	IsSpeculativeToNumber(p1)));
	}

	// -----------------------------------------------------------------------------
	// String.fromCharCode

	TEST_F(JSCallReducerTest, StringFromSingleCharCodeWithNumber) {
	Node* function = StringFunction("fromCharCode");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* call = graph()->NewNode(Call(3), function, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(),
	IsStringFromSingleCharCode(IsSpeculativeToNumber(p0)));
	}

	TEST_F(JSCallReducerTest, StringFromSingleCharCodeWithPlainPrimitive) {
	Node* function = StringFunction("fromCharCode");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::PlainPrimitive(), 0);
	Node* call = graph()->NewNode(Call(3), function, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(),
	IsStringFromSingleCharCode(IsSpeculativeToNumber(p0)));
	}

	// -----------------------------------------------------------------------------
	// Number.isFinite

	TEST_F(JSCallReducerTest, NumberIsFinite) {
	Node* function = NumberFunction("isFinite");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* call = graph()->NewNode(Call(3), function, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsObjectIsFiniteNumber(p0));
	}

	// -----------------------------------------------------------------------------
	// Number.isInteger

	TEST_F(JSCallReducerTest, NumberIsIntegerWithNumber) {
	Node* function = NumberFunction("isInteger");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* call =
	graph()->NewNode(javascript()->Call(3), function, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsObjectIsInteger(p0));
	}

	// -----------------------------------------------------------------------------
	// Number.isNaN

	TEST_F(JSCallReducerTest, NumberIsNaNWithNumber) {
	Node* function = NumberFunction("isNaN");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* call =
	graph()->NewNode(javascript()->Call(3), function, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsObjectIsNaN(p0));
	}

	// -----------------------------------------------------------------------------
	// Number.isSafeInteger

	TEST_F(JSCallReducerTest, NumberIsSafeIntegerWithIntegral32) {
	Node* function = NumberFunction("isSafeInteger");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* call =
	graph()->NewNode(javascript()->Call(3), function, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsObjectIsSafeInteger(p0));
	}

	// -----------------------------------------------------------------------------
	// isFinite

	TEST_F(JSCallReducerTest, GlobalIsFiniteWithNumber) {
	Node* function = GlobalFunction("isFinite");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* call = graph()->NewNode(Call(3), function, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsNumberIsFinite(IsSpeculativeToNumber(p0)));
	}

	// -----------------------------------------------------------------------------
	// isNaN

	TEST_F(JSCallReducerTest, GlobalIsNaN) {
	Node* function = GlobalFunction("isNaN");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* call = graph()->NewNode(Call(3), function, UndefinedConstant(), p0,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsNumberIsNaN(IsSpeculativeToNumber(p0)));
	}

	// -----------------------------------------------------------------------------
	// Number.parseInt

	TEST_F(JSCallReducerTest, NumberParseInt) {
	Node* function = NumberFunction("parseInt");

	Node* effect = graph()->start();
	Node* control = graph()->start();
	Node* context = UndefinedConstant();
	Node* frame_state = graph()->start();
	Node* p0 = Parameter(Type::Any(), 0);
	Node* p1 = Parameter(Type::Any(), 1);
	Node* call = graph()->NewNode(Call(4), function, UndefinedConstant(), p0, p1,
	context, frame_state, effect, control);
	Reduction r = Reduce(call);

	ASSERT_TRUE(r.Changed());
	EXPECT_THAT(r.replacement(), IsJSParseInt(p0, p1));
	}

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