src/builtins/builtins-call-gen.cc - v8/v8 - Git at Google

 // Copyright 2017 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/builtins/builtins-call-gen.h"

 #include "src/builtins/builtins-utils-gen.h"
 #include "src/builtins/builtins.h"
 #include "src/globals.h"
 #include "src/heap/heap-inl.h"
 #include "src/isolate.h"
 #include "src/macro-assembler.h"
 #include "src/objects/arguments.h"

 namespace v8 {
 namespace internal {

 void Builtins::Generate_CallFunction_ReceiverIsNullOrUndefined(
     MacroAssembler* masm) {
   Generate_CallFunction(masm, ConvertReceiverMode::kNullOrUndefined);
 }

 void Builtins::Generate_CallFunction_ReceiverIsNotNullOrUndefined(
     MacroAssembler* masm) {
   Generate_CallFunction(masm, ConvertReceiverMode::kNotNullOrUndefined);
 }

 void Builtins::Generate_CallFunction_ReceiverIsAny(MacroAssembler* masm) {
   Generate_CallFunction(masm, ConvertReceiverMode::kAny);
 }

 void Builtins::Generate_CallBoundFunction(MacroAssembler* masm) {
   Generate_CallBoundFunctionImpl(masm);
 }

 void Builtins::Generate_Call_ReceiverIsNullOrUndefined(MacroAssembler* masm) {
   Generate_Call(masm, ConvertReceiverMode::kNullOrUndefined);
 }

 void Builtins::Generate_Call_ReceiverIsNotNullOrUndefined(
     MacroAssembler* masm) {
   Generate_Call(masm, ConvertReceiverMode::kNotNullOrUndefined);
 }

 void Builtins::Generate_Call_ReceiverIsAny(MacroAssembler* masm) {
   Generate_Call(masm, ConvertReceiverMode::kAny);
 }

 void Builtins::Generate_CallVarargs(MacroAssembler* masm) {
   Generate_CallOrConstructVarargs(masm, masm->isolate()->builtins()->Call());
 }

 void Builtins::Generate_CallForwardVarargs(MacroAssembler* masm) {
   Generate_CallOrConstructForwardVarargs(masm, CallOrConstructMode::kCall,
                                          masm->isolate()->builtins()->Call());
 }

 void Builtins::Generate_CallFunctionForwardVarargs(MacroAssembler* masm) {
   Generate_CallOrConstructForwardVarargs(
       masm, CallOrConstructMode::kCall,
       masm->isolate()->builtins()->CallFunction());
 }

 void CallOrConstructBuiltinsAssembler::CallOrConstructWithArrayLike(
     Node* target, Node* new_target, Node* arguments_list, Node* context) {
   VARIABLE(var_elements, MachineRepresentation::kTagged);
   VARIABLE(var_length, MachineRepresentation::kWord32);
   Label if_done(this), if_arguments(this), if_array(this),
       if_holey_array(this, Label::kDeferred),
       if_runtime(this, Label::kDeferred);

   // Perform appropriate checks on {target} (and {new_target} first).
   if (new_target == nullptr) {
     // Check that {target} is Callable.
     Label if_target_callable(this),
         if_target_not_callable(this, Label::kDeferred);
     GotoIf(TaggedIsSmi(target), &if_target_not_callable);
     Branch(IsCallable(target), &if_target_callable, &if_target_not_callable);
     BIND(&if_target_not_callable);
     {
       CallRuntime(Runtime::kThrowApplyNonFunction, context, target);
       Unreachable();
     }
     BIND(&if_target_callable);
   } else {
     // Check that {target} is a Constructor.
     Label if_target_constructor(this),
         if_target_not_constructor(this, Label::kDeferred);
     GotoIf(TaggedIsSmi(target), &if_target_not_constructor);
     Branch(IsConstructor(target), &if_target_constructor,
            &if_target_not_constructor);
     BIND(&if_target_not_constructor);
     {
       CallRuntime(Runtime::kThrowNotConstructor, context, target);
       Unreachable();
     }
     BIND(&if_target_constructor);

     // Check that {new_target} is a Constructor.
     Label if_new_target_constructor(this),
         if_new_target_not_constructor(this, Label::kDeferred);
     GotoIf(TaggedIsSmi(new_target), &if_new_target_not_constructor);
     Branch(IsConstructor(new_target), &if_new_target_constructor,
            &if_new_target_not_constructor);
     BIND(&if_new_target_not_constructor);
     {
       CallRuntime(Runtime::kThrowNotConstructor, context, new_target);
       Unreachable();
     }
     BIND(&if_new_target_constructor);
   }

   GotoIf(TaggedIsSmi(arguments_list), &if_runtime);
   Node* arguments_list_map = LoadMap(arguments_list);
   Node* native_context = LoadNativeContext(context);

   // Check if {arguments_list} is an (unmodified) arguments object.
   Node* sloppy_arguments_map =
       LoadContextElement(native_context, Context::SLOPPY_ARGUMENTS_MAP_INDEX);
   GotoIf(WordEqual(arguments_list_map, sloppy_arguments_map), &if_arguments);
   Node* strict_arguments_map =
       LoadContextElement(native_context, Context::STRICT_ARGUMENTS_MAP_INDEX);
   GotoIf(WordEqual(arguments_list_map, strict_arguments_map), &if_arguments);

   // Check if {arguments_list} is a fast JSArray.
   Branch(IsJSArrayMap(arguments_list_map), &if_array, &if_runtime);

   BIND(&if_array);
   {
     // Try to extract the elements from a JSArray object.
     var_elements.Bind(
         LoadObjectField(arguments_list, JSArray::kElementsOffset));
     var_length.Bind(LoadAndUntagToWord32ObjectField(arguments_list,
                                                     JSArray::kLengthOffset));

     // Holey arrays and double backing stores need special treatment.
     STATIC_ASSERT(PACKED_SMI_ELEMENTS == 0);
     STATIC_ASSERT(HOLEY_SMI_ELEMENTS == 1);
     STATIC_ASSERT(PACKED_ELEMENTS == 2);
     STATIC_ASSERT(HOLEY_ELEMENTS == 3);
     STATIC_ASSERT(PACKED_DOUBLE_ELEMENTS == 4);
     STATIC_ASSERT(HOLEY_DOUBLE_ELEMENTS == 5);
     STATIC_ASSERT(LAST_FAST_ELEMENTS_KIND == HOLEY_DOUBLE_ELEMENTS);

     Node* kind = LoadMapElementsKind(arguments_list_map);

     GotoIf(Int32GreaterThan(kind, Int32Constant(LAST_FAST_ELEMENTS_KIND)),
            &if_runtime);
     Branch(Word32And(kind, Int32Constant(1)), &if_holey_array, &if_done);
   }

   BIND(&if_holey_array);
   {
     // For holey JSArrays we need to check that the array prototype chain
     // protector is intact and our prototype is the Array.prototype actually.
     GotoIfNot(IsPrototypeInitialArrayPrototype(context, arguments_list_map),
               &if_runtime);
     Branch(IsNoElementsProtectorCellInvalid(), &if_runtime, &if_done);
   }

   BIND(&if_arguments);
   {
     // Try to extract the elements from an JSArgumentsObject.
     Node* length =
         LoadObjectField(arguments_list, JSArgumentsObject::kLengthOffset);
     Node* elements =
         LoadObjectField(arguments_list, JSArgumentsObject::kElementsOffset);
     Node* elements_length = LoadFixedArrayBaseLength(elements);
     GotoIfNot(WordEqual(length, elements_length), &if_runtime);
     var_elements.Bind(elements);
     var_length.Bind(SmiToWord32(length));
     Goto(&if_done);
   }

   BIND(&if_runtime);
   {
     // Ask the runtime to create the list (actually a FixedArray).
     Node* elements =
         CallRuntime(Runtime::kCreateListFromArrayLike, context, arguments_list);
     var_elements.Bind(elements);
     var_length.Bind(
         LoadAndUntagToWord32ObjectField(elements, FixedArray::kLengthOffset));
     Goto(&if_done);
   }

   // Tail call to the appropriate builtin (depending on whether we have
   // a {new_target} passed).
   BIND(&if_done);
   {
     Label if_not_double(this), if_double(this);
     Node* elements = var_elements.value();
     Node* length = var_length.value();
     Node* args_count = Int32Constant(0);  // args already on the stack

     Branch(IsFixedDoubleArray(elements), &if_double, &if_not_double);

     BIND(&if_not_double);
     if (new_target == nullptr) {
       Callable callable = CodeFactory::CallVarargs(isolate());
       TailCallStub(callable, context, target, args_count, elements, length);
     } else {
       Callable callable = CodeFactory::ConstructVarargs(isolate());
       TailCallStub(callable, context, target, new_target, args_count, elements,
                    length);
     }

     BIND(&if_double);
     {
       // Kind is hardcoded here because CreateListFromArrayLike will only
       // produce holey double arrays.
       CallOrConstructDoubleVarargs(target, new_target, elements, length,
                                    args_count, context,
                                    Int32Constant(HOLEY_DOUBLE_ELEMENTS));
     }
   }
 }

 // Takes a FixedArray of doubles and creates a new FixedArray with those doubles
 // boxed as HeapNumbers, then tail calls CallVarargs/ConstructVarargs depending
 // on whether {new_target} was passed.
 void CallOrConstructBuiltinsAssembler::CallOrConstructDoubleVarargs(
     Node* target, Node* new_target, Node* elements, Node* length,
     Node* args_count, Node* context, Node* kind) {
   Label if_holey_double(this), if_packed_double(this), if_done(this);

   const ElementsKind new_kind = PACKED_ELEMENTS;
   const ParameterMode mode = INTPTR_PARAMETERS;
   const WriteBarrierMode barrier_mode = UPDATE_WRITE_BARRIER;
   Node* intptr_length = ChangeInt32ToIntPtr(length);

   // Allocate a new FixedArray of Objects.
   Node* new_elements =
       AllocateFixedArray(new_kind, intptr_length, mode,
                          CodeStubAssembler::kAllowLargeObjectAllocation);
   Branch(Word32Equal(kind, Int32Constant(HOLEY_DOUBLE_ELEMENTS)),
          &if_holey_double, &if_packed_double);

   BIND(&if_holey_double);
   {
     // Fill the FixedArray with pointers to HeapObjects.
     CopyFixedArrayElements(HOLEY_DOUBLE_ELEMENTS, elements, new_kind,
                            new_elements, intptr_length, intptr_length,
                            barrier_mode);
     Goto(&if_done);
   }

   BIND(&if_packed_double);
   {
     CopyFixedArrayElements(PACKED_DOUBLE_ELEMENTS, elements, new_kind,
                            new_elements, intptr_length, intptr_length,
                            barrier_mode);
     Goto(&if_done);
   }

   BIND(&if_done);
   {
     if (new_target == nullptr) {
       Callable callable = CodeFactory::CallVarargs(isolate());
       TailCallStub(callable, context, target, args_count, new_elements, length);
     } else {
       Callable callable = CodeFactory::ConstructVarargs(isolate());
       TailCallStub(callable, context, target, new_target, args_count,
                    new_elements, length);
     }
   }
 }

 void CallOrConstructBuiltinsAssembler::CallOrConstructWithSpread(
     Node* target, Node* new_target, Node* spread, Node* args_count,
     Node* context) {
   Label if_done(this), if_holey(this), if_runtime(this, Label::kDeferred);

   VARIABLE(spread_result, MachineRepresentation::kTagged, spread);

   GotoIf(TaggedIsSmi(spread), &if_runtime);
   Node* spread_map = LoadMap(spread);
   GotoIfNot(IsJSArrayMap(spread_map), &if_runtime);

   // Check that we have the original ArrayPrototype.
   GotoIfNot(IsPrototypeInitialArrayPrototype(context, spread_map), &if_runtime);

   // Check that the ArrayPrototype hasn't been modified in a way that would
   // affect iteration.
   Node* protector_cell = LoadRoot(Heap::kArrayIteratorProtectorRootIndex);
   DCHECK(isolate()->heap()->array_iterator_protector()->IsPropertyCell());
   GotoIfNot(
       WordEqual(LoadObjectField(protector_cell, PropertyCell::kValueOffset),
                 SmiConstant(Isolate::kProtectorValid)),
       &if_runtime);

   // Check that the map of the initial array iterator hasn't changed.
   Node* native_context = LoadNativeContext(context);
   Node* arr_it_proto_map = LoadMap(CAST(LoadContextElement(
       native_context, Context::INITIAL_ARRAY_ITERATOR_PROTOTYPE_INDEX)));
   Node* initial_map = LoadContextElement(
       native_context, Context::INITIAL_ARRAY_ITERATOR_PROTOTYPE_MAP_INDEX);
   GotoIfNot(WordEqual(arr_it_proto_map, initial_map), &if_runtime);

   Node* kind = LoadMapElementsKind(spread_map);

   STATIC_ASSERT(PACKED_SMI_ELEMENTS == 0);
   STATIC_ASSERT(HOLEY_SMI_ELEMENTS == 1);
   STATIC_ASSERT(PACKED_ELEMENTS == 2);
   STATIC_ASSERT(HOLEY_ELEMENTS == 3);
   STATIC_ASSERT(PACKED_DOUBLE_ELEMENTS == 4);
   STATIC_ASSERT(HOLEY_DOUBLE_ELEMENTS == 5);
   STATIC_ASSERT(LAST_FAST_ELEMENTS_KIND == HOLEY_DOUBLE_ELEMENTS);

   GotoIf(Int32GreaterThan(kind, Int32Constant(LAST_FAST_ELEMENTS_KIND)),
          &if_runtime);
   Branch(Word32And(kind, Int32Constant(1)), &if_holey, &if_done);

   // Check the NoElementsProtector cell for holey arrays.
   BIND(&if_holey);
   { Branch(IsNoElementsProtectorCellInvalid(), &if_runtime, &if_done); }

   BIND(&if_runtime);
   {
     Node* spread_iterable = LoadContextElement(LoadNativeContext(context),
                                                Context::SPREAD_ITERABLE_INDEX);
     spread_result.Bind(CallJS(CodeFactory::Call(isolate()), context,
                               spread_iterable, UndefinedConstant(), spread));
     CSA_ASSERT(this, IsJSArray(spread_result.value()));
     Goto(&if_done);
   }

   BIND(&if_done);
   {
     // The result from if_runtime can be an array of doubles.
     Label if_not_double(this), if_double(this);
     Node* elements =
         LoadObjectField(spread_result.value(), JSArray::kElementsOffset);
     Node* length = LoadAndUntagToWord32ObjectField(spread_result.value(),
                                                    JSArray::kLengthOffset);

     Node* kind = LoadMapElementsKind(LoadMap(elements));
     CSA_ASSERT(this, Int32LessThanOrEqual(
                          kind, Int32Constant(LAST_FAST_ELEMENTS_KIND)));

     Branch(Int32GreaterThan(kind, Int32Constant(HOLEY_ELEMENTS)), &if_double,
            &if_not_double);

     BIND(&if_not_double);
     {
       if (new_target == nullptr) {
         Callable callable = CodeFactory::CallVarargs(isolate());
         TailCallStub(callable, context, target, args_count, elements, length);
       } else {
         Callable callable = CodeFactory::ConstructVarargs(isolate());
         TailCallStub(callable, context, target, new_target, args_count,
                      elements, length);
       }
     }

     BIND(&if_double);
     {
       CallOrConstructDoubleVarargs(target, new_target, elements, length,
                                    args_count, context, kind);
     }
   }
 }

 TF_BUILTIN(CallWithArrayLike, CallOrConstructBuiltinsAssembler) {
   Node* target = Parameter(CallWithArrayLikeDescriptor::kTarget);
   Node* new_target = nullptr;
   Node* arguments_list = Parameter(CallWithArrayLikeDescriptor::kArgumentsList);
   Node* context = Parameter(CallWithArrayLikeDescriptor::kContext);
   CallOrConstructWithArrayLike(target, new_target, arguments_list, context);
 }

 TF_BUILTIN(CallWithSpread, CallOrConstructBuiltinsAssembler) {
   Node* target = Parameter(CallWithSpreadDescriptor::kTarget);
   Node* new_target = nullptr;
   Node* spread = Parameter(CallWithSpreadDescriptor::kSpread);
   Node* args_count = Parameter(CallWithSpreadDescriptor::kArgumentsCount);
   Node* context = Parameter(CallWithSpreadDescriptor::kContext);
   CallOrConstructWithSpread(target, new_target, spread, args_count, context);
 }

 }  // namespace internal
 }  // namespace v8
	// Copyright 2017 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/builtins/builtins-call-gen.h"

	#include "src/builtins/builtins-utils-gen.h"
	#include "src/builtins/builtins.h"
	#include "src/globals.h"
	#include "src/heap/heap-inl.h"
	#include "src/isolate.h"
	#include "src/macro-assembler.h"
	#include "src/objects/arguments.h"

	namespace v8 {
	namespace internal {

	void Builtins::Generate_CallFunction_ReceiverIsNullOrUndefined(
	MacroAssembler* masm) {
	Generate_CallFunction(masm, ConvertReceiverMode::kNullOrUndefined);
	}

	void Builtins::Generate_CallFunction_ReceiverIsNotNullOrUndefined(
	MacroAssembler* masm) {
	Generate_CallFunction(masm, ConvertReceiverMode::kNotNullOrUndefined);
	}

	void Builtins::Generate_CallFunction_ReceiverIsAny(MacroAssembler* masm) {
	Generate_CallFunction(masm, ConvertReceiverMode::kAny);
	}

	void Builtins::Generate_CallBoundFunction(MacroAssembler* masm) {
	Generate_CallBoundFunctionImpl(masm);
	}

	void Builtins::Generate_Call_ReceiverIsNullOrUndefined(MacroAssembler* masm) {
	Generate_Call(masm, ConvertReceiverMode::kNullOrUndefined);
	}

	void Builtins::Generate_Call_ReceiverIsNotNullOrUndefined(
	MacroAssembler* masm) {
	Generate_Call(masm, ConvertReceiverMode::kNotNullOrUndefined);
	}

	void Builtins::Generate_Call_ReceiverIsAny(MacroAssembler* masm) {
	Generate_Call(masm, ConvertReceiverMode::kAny);
	}

	void Builtins::Generate_CallVarargs(MacroAssembler* masm) {
	Generate_CallOrConstructVarargs(masm, masm->isolate()->builtins()->Call());
	}

	void Builtins::Generate_CallForwardVarargs(MacroAssembler* masm) {
	Generate_CallOrConstructForwardVarargs(masm, CallOrConstructMode::kCall,
	masm->isolate()->builtins()->Call());
	}

	void Builtins::Generate_CallFunctionForwardVarargs(MacroAssembler* masm) {
	Generate_CallOrConstructForwardVarargs(
	masm, CallOrConstructMode::kCall,
	masm->isolate()->builtins()->CallFunction());
	}

	void CallOrConstructBuiltinsAssembler::CallOrConstructWithArrayLike(
	Node* target, Node* new_target, Node* arguments_list, Node* context) {
	VARIABLE(var_elements, MachineRepresentation::kTagged);
	VARIABLE(var_length, MachineRepresentation::kWord32);
	Label if_done(this), if_arguments(this), if_array(this),
	if_holey_array(this, Label::kDeferred),
	if_runtime(this, Label::kDeferred);

	// Perform appropriate checks on {target} (and {new_target} first).
	if (new_target == nullptr) {
	// Check that {target} is Callable.
	Label if_target_callable(this),
	if_target_not_callable(this, Label::kDeferred);
	GotoIf(TaggedIsSmi(target), &if_target_not_callable);
	Branch(IsCallable(target), &if_target_callable, &if_target_not_callable);
	BIND(&if_target_not_callable);
	{
	CallRuntime(Runtime::kThrowApplyNonFunction, context, target);
	Unreachable();
	}
	BIND(&if_target_callable);
	} else {
	// Check that {target} is a Constructor.
	Label if_target_constructor(this),
	if_target_not_constructor(this, Label::kDeferred);
	GotoIf(TaggedIsSmi(target), &if_target_not_constructor);
	Branch(IsConstructor(target), &if_target_constructor,
	&if_target_not_constructor);
	BIND(&if_target_not_constructor);
	{
	CallRuntime(Runtime::kThrowNotConstructor, context, target);
	Unreachable();
	}
	BIND(&if_target_constructor);

	// Check that {new_target} is a Constructor.
	Label if_new_target_constructor(this),
	if_new_target_not_constructor(this, Label::kDeferred);
	GotoIf(TaggedIsSmi(new_target), &if_new_target_not_constructor);
	Branch(IsConstructor(new_target), &if_new_target_constructor,
	&if_new_target_not_constructor);
	BIND(&if_new_target_not_constructor);
	{
	CallRuntime(Runtime::kThrowNotConstructor, context, new_target);
	Unreachable();
	}
	BIND(&if_new_target_constructor);
	}

	GotoIf(TaggedIsSmi(arguments_list), &if_runtime);
	Node* arguments_list_map = LoadMap(arguments_list);
	Node* native_context = LoadNativeContext(context);

	// Check if {arguments_list} is an (unmodified) arguments object.
	Node* sloppy_arguments_map =
	LoadContextElement(native_context, Context::SLOPPY_ARGUMENTS_MAP_INDEX);
	GotoIf(WordEqual(arguments_list_map, sloppy_arguments_map), &if_arguments);
	Node* strict_arguments_map =
	LoadContextElement(native_context, Context::STRICT_ARGUMENTS_MAP_INDEX);
	GotoIf(WordEqual(arguments_list_map, strict_arguments_map), &if_arguments);

	// Check if {arguments_list} is a fast JSArray.
	Branch(IsJSArrayMap(arguments_list_map), &if_array, &if_runtime);

	BIND(&if_array);
	{
	// Try to extract the elements from a JSArray object.
	var_elements.Bind(
	LoadObjectField(arguments_list, JSArray::kElementsOffset));
	var_length.Bind(LoadAndUntagToWord32ObjectField(arguments_list,
	JSArray::kLengthOffset));

	// Holey arrays and double backing stores need special treatment.
	STATIC_ASSERT(PACKED_SMI_ELEMENTS == 0);
	STATIC_ASSERT(HOLEY_SMI_ELEMENTS == 1);
	STATIC_ASSERT(PACKED_ELEMENTS == 2);
	STATIC_ASSERT(HOLEY_ELEMENTS == 3);
	STATIC_ASSERT(PACKED_DOUBLE_ELEMENTS == 4);
	STATIC_ASSERT(HOLEY_DOUBLE_ELEMENTS == 5);
	STATIC_ASSERT(LAST_FAST_ELEMENTS_KIND == HOLEY_DOUBLE_ELEMENTS);

	Node* kind = LoadMapElementsKind(arguments_list_map);

	GotoIf(Int32GreaterThan(kind, Int32Constant(LAST_FAST_ELEMENTS_KIND)),
	&if_runtime);
	Branch(Word32And(kind, Int32Constant(1)), &if_holey_array, &if_done);
	}

	BIND(&if_holey_array);
	{
	// For holey JSArrays we need to check that the array prototype chain
	// protector is intact and our prototype is the Array.prototype actually.
	GotoIfNot(IsPrototypeInitialArrayPrototype(context, arguments_list_map),
	&if_runtime);
	Branch(IsNoElementsProtectorCellInvalid(), &if_runtime, &if_done);
	}

	BIND(&if_arguments);
	{
	// Try to extract the elements from an JSArgumentsObject.
	Node* length =
	LoadObjectField(arguments_list, JSArgumentsObject::kLengthOffset);
	Node* elements =
	LoadObjectField(arguments_list, JSArgumentsObject::kElementsOffset);
	Node* elements_length = LoadFixedArrayBaseLength(elements);
	GotoIfNot(WordEqual(length, elements_length), &if_runtime);
	var_elements.Bind(elements);
	var_length.Bind(SmiToWord32(length));
	Goto(&if_done);
	}

	BIND(&if_runtime);
	{
	// Ask the runtime to create the list (actually a FixedArray).
	Node* elements =
	CallRuntime(Runtime::kCreateListFromArrayLike, context, arguments_list);
	var_elements.Bind(elements);
	var_length.Bind(
	LoadAndUntagToWord32ObjectField(elements, FixedArray::kLengthOffset));
	Goto(&if_done);
	}

	// Tail call to the appropriate builtin (depending on whether we have
	// a {new_target} passed).
	BIND(&if_done);
	{
	Label if_not_double(this), if_double(this);
	Node* elements = var_elements.value();
	Node* length = var_length.value();
	Node* args_count = Int32Constant(0); // args already on the stack

	Branch(IsFixedDoubleArray(elements), &if_double, &if_not_double);

	BIND(&if_not_double);
	if (new_target == nullptr) {
	Callable callable = CodeFactory::CallVarargs(isolate());
	TailCallStub(callable, context, target, args_count, elements, length);
	} else {
	Callable callable = CodeFactory::ConstructVarargs(isolate());
	TailCallStub(callable, context, target, new_target, args_count, elements,
	length);
	}

	BIND(&if_double);
	{
	// Kind is hardcoded here because CreateListFromArrayLike will only
	// produce holey double arrays.
	CallOrConstructDoubleVarargs(target, new_target, elements, length,
	args_count, context,
	Int32Constant(HOLEY_DOUBLE_ELEMENTS));
	}
	}
	}

	// Takes a FixedArray of doubles and creates a new FixedArray with those doubles
	// boxed as HeapNumbers, then tail calls CallVarargs/ConstructVarargs depending
	// on whether {new_target} was passed.
	void CallOrConstructBuiltinsAssembler::CallOrConstructDoubleVarargs(
	Node* target, Node* new_target, Node* elements, Node* length,
	Node* args_count, Node* context, Node* kind) {
	Label if_holey_double(this), if_packed_double(this), if_done(this);

	const ElementsKind new_kind = PACKED_ELEMENTS;
	const ParameterMode mode = INTPTR_PARAMETERS;
	const WriteBarrierMode barrier_mode = UPDATE_WRITE_BARRIER;
	Node* intptr_length = ChangeInt32ToIntPtr(length);

	// Allocate a new FixedArray of Objects.
	Node* new_elements =
	AllocateFixedArray(new_kind, intptr_length, mode,
	CodeStubAssembler::kAllowLargeObjectAllocation);
	Branch(Word32Equal(kind, Int32Constant(HOLEY_DOUBLE_ELEMENTS)),
	&if_holey_double, &if_packed_double);

	BIND(&if_holey_double);
	{
	// Fill the FixedArray with pointers to HeapObjects.
	CopyFixedArrayElements(HOLEY_DOUBLE_ELEMENTS, elements, new_kind,
	new_elements, intptr_length, intptr_length,
	barrier_mode);
	Goto(&if_done);
	}

	BIND(&if_packed_double);
	{
	CopyFixedArrayElements(PACKED_DOUBLE_ELEMENTS, elements, new_kind,
	new_elements, intptr_length, intptr_length,
	barrier_mode);
	Goto(&if_done);
	}

	BIND(&if_done);
	{
	if (new_target == nullptr) {
	Callable callable = CodeFactory::CallVarargs(isolate());
	TailCallStub(callable, context, target, args_count, new_elements, length);
	} else {
	Callable callable = CodeFactory::ConstructVarargs(isolate());
	TailCallStub(callable, context, target, new_target, args_count,
	new_elements, length);
	}
	}
	}

	void CallOrConstructBuiltinsAssembler::CallOrConstructWithSpread(
	Node* target, Node* new_target, Node* spread, Node* args_count,
	Node* context) {
	Label if_done(this), if_holey(this), if_runtime(this, Label::kDeferred);

	VARIABLE(spread_result, MachineRepresentation::kTagged, spread);

	GotoIf(TaggedIsSmi(spread), &if_runtime);
	Node* spread_map = LoadMap(spread);
	GotoIfNot(IsJSArrayMap(spread_map), &if_runtime);

	// Check that we have the original ArrayPrototype.
	GotoIfNot(IsPrototypeInitialArrayPrototype(context, spread_map), &if_runtime);

	// Check that the ArrayPrototype hasn't been modified in a way that would
	// affect iteration.
	Node* protector_cell = LoadRoot(Heap::kArrayIteratorProtectorRootIndex);
	DCHECK(isolate()->heap()->array_iterator_protector()->IsPropertyCell());
	GotoIfNot(
	WordEqual(LoadObjectField(protector_cell, PropertyCell::kValueOffset),
	SmiConstant(Isolate::kProtectorValid)),
	&if_runtime);

	// Check that the map of the initial array iterator hasn't changed.
	Node* native_context = LoadNativeContext(context);
	Node* arr_it_proto_map = LoadMap(CAST(LoadContextElement(
	native_context, Context::INITIAL_ARRAY_ITERATOR_PROTOTYPE_INDEX)));
	Node* initial_map = LoadContextElement(
	native_context, Context::INITIAL_ARRAY_ITERATOR_PROTOTYPE_MAP_INDEX);
	GotoIfNot(WordEqual(arr_it_proto_map, initial_map), &if_runtime);

	Node* kind = LoadMapElementsKind(spread_map);

	STATIC_ASSERT(PACKED_SMI_ELEMENTS == 0);
	STATIC_ASSERT(HOLEY_SMI_ELEMENTS == 1);
	STATIC_ASSERT(PACKED_ELEMENTS == 2);
	STATIC_ASSERT(HOLEY_ELEMENTS == 3);
	STATIC_ASSERT(PACKED_DOUBLE_ELEMENTS == 4);
	STATIC_ASSERT(HOLEY_DOUBLE_ELEMENTS == 5);
	STATIC_ASSERT(LAST_FAST_ELEMENTS_KIND == HOLEY_DOUBLE_ELEMENTS);

	GotoIf(Int32GreaterThan(kind, Int32Constant(LAST_FAST_ELEMENTS_KIND)),
	&if_runtime);
	Branch(Word32And(kind, Int32Constant(1)), &if_holey, &if_done);

	// Check the NoElementsProtector cell for holey arrays.
	BIND(&if_holey);
	{ Branch(IsNoElementsProtectorCellInvalid(), &if_runtime, &if_done); }

	BIND(&if_runtime);
	{
	Node* spread_iterable = LoadContextElement(LoadNativeContext(context),
	Context::SPREAD_ITERABLE_INDEX);
	spread_result.Bind(CallJS(CodeFactory::Call(isolate()), context,
	spread_iterable, UndefinedConstant(), spread));
	CSA_ASSERT(this, IsJSArray(spread_result.value()));
	Goto(&if_done);
	}

	BIND(&if_done);
	{
	// The result from if_runtime can be an array of doubles.
	Label if_not_double(this), if_double(this);
	Node* elements =
	LoadObjectField(spread_result.value(), JSArray::kElementsOffset);
	Node* length = LoadAndUntagToWord32ObjectField(spread_result.value(),
	JSArray::kLengthOffset);

	Node* kind = LoadMapElementsKind(LoadMap(elements));
	CSA_ASSERT(this, Int32LessThanOrEqual(
	kind, Int32Constant(LAST_FAST_ELEMENTS_KIND)));

	Branch(Int32GreaterThan(kind, Int32Constant(HOLEY_ELEMENTS)), &if_double,
	&if_not_double);

	BIND(&if_not_double);
	{
	if (new_target == nullptr) {
	Callable callable = CodeFactory::CallVarargs(isolate());
	TailCallStub(callable, context, target, args_count, elements, length);
	} else {
	Callable callable = CodeFactory::ConstructVarargs(isolate());
	TailCallStub(callable, context, target, new_target, args_count,
	elements, length);
	}
	}

	BIND(&if_double);
	{
	CallOrConstructDoubleVarargs(target, new_target, elements, length,
	args_count, context, kind);
	}
	}
	}

	TF_BUILTIN(CallWithArrayLike, CallOrConstructBuiltinsAssembler) {
	Node* target = Parameter(CallWithArrayLikeDescriptor::kTarget);
	Node* new_target = nullptr;
	Node* arguments_list = Parameter(CallWithArrayLikeDescriptor::kArgumentsList);
	Node* context = Parameter(CallWithArrayLikeDescriptor::kContext);
	CallOrConstructWithArrayLike(target, new_target, arguments_list, context);
	}

	TF_BUILTIN(CallWithSpread, CallOrConstructBuiltinsAssembler) {
	Node* target = Parameter(CallWithSpreadDescriptor::kTarget);
	Node* new_target = nullptr;
	Node* spread = Parameter(CallWithSpreadDescriptor::kSpread);
	Node* args_count = Parameter(CallWithSpreadDescriptor::kArgumentsCount);
	Node* context = Parameter(CallWithSpreadDescriptor::kContext);
	CallOrConstructWithSpread(target, new_target, spread, args_count, context);
	}

	} // namespace internal
	} // namespace v8