src/compiler/js-inlining.cc - platform/external/v8 - Git at Google

 // Copyright 2014 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "src/ast.h"
 #include "src/ast-numbering.h"
 #include "src/compiler/access-builder.h"
 #include "src/compiler/ast-graph-builder.h"
 #include "src/compiler/common-operator.h"
 #include "src/compiler/graph-inl.h"
 #include "src/compiler/graph-visualizer.h"
 #include "src/compiler/js-inlining.h"
 #include "src/compiler/js-intrinsic-builder.h"
 #include "src/compiler/js-operator.h"
 #include "src/compiler/node-aux-data-inl.h"
 #include "src/compiler/node-matchers.h"
 #include "src/compiler/node-properties-inl.h"
 #include "src/compiler/simplified-operator.h"
 #include "src/compiler/typer.h"
 #include "src/full-codegen.h"
 #include "src/parser.h"
 #include "src/rewriter.h"
 #include "src/scopes.h"


 namespace v8 {
 namespace internal {
 namespace compiler {

 class InlinerVisitor : public NullNodeVisitor {
  public:
   explicit InlinerVisitor(JSInliner* inliner) : inliner_(inliner) {}

   void Post(Node* node) {
     switch (node->opcode()) {
       case IrOpcode::kJSCallFunction:
         inliner_->TryInlineJSCall(node);
         break;
       case IrOpcode::kJSCallRuntime:
         if (FLAG_turbo_inlining_intrinsics) {
           inliner_->TryInlineRuntimeCall(node);
         }
         break;
       default:
         break;
     }
   }

  private:
   JSInliner* inliner_;
 };


 void JSInliner::Inline() {
   InlinerVisitor visitor(this);
   jsgraph_->graph()->VisitNodeInputsFromEnd(&visitor);
 }


 // A facade on a JSFunction's graph to facilitate inlining. It assumes the
 // that the function graph has only one return statement, and provides
 // {UnifyReturn} to convert a function graph to that end.
 class Inlinee {
  public:
   Inlinee(Node* start, Node* end) : start_(start), end_(end) {}

   // Returns the last regular control node, that is
   // the last control node before the end node.
   Node* end_block() { return NodeProperties::GetControlInput(unique_return()); }

   // Return the effect output of the graph,
   // that is the effect input of the return statement of the inlinee.
   Node* effect_output() {
     return NodeProperties::GetEffectInput(unique_return());
   }
   // Return the value output of the graph,
   // that is the value input of the return statement of the inlinee.
   Node* value_output() {
     return NodeProperties::GetValueInput(unique_return(), 0);
   }
   // Return the unique return statement of the graph.
   Node* unique_return() {
     Node* unique_return = NodeProperties::GetControlInput(end_);
     DCHECK_EQ(IrOpcode::kReturn, unique_return->opcode());
     return unique_return;
   }

   // Counts JSFunction, Receiver, arguments, context but not effect, control.
   size_t total_parameters() { return start_->op()->ValueOutputCount(); }

   // Counts only formal parameters.
   size_t formal_parameters() {
     DCHECK_GE(total_parameters(), 3);
     return total_parameters() - 3;
   }

   // Inline this graph at {call}, use {jsgraph} and its zone to create
   // any new nodes.
   void InlineAtCall(JSGraph* jsgraph, Node* call);

   // Ensure that only a single return reaches the end node.
   static void UnifyReturn(JSGraph* jsgraph);

  private:
   Node* start_;
   Node* end_;
 };


 void Inlinee::UnifyReturn(JSGraph* jsgraph) {
   Graph* graph = jsgraph->graph();

   Node* final_merge = NodeProperties::GetControlInput(graph->end(), 0);
   if (final_merge->opcode() == IrOpcode::kReturn) {
     // nothing to do
     return;
   }
   DCHECK_EQ(IrOpcode::kMerge, final_merge->opcode());

   int predecessors = final_merge->op()->ControlInputCount();

   const Operator* op_phi = jsgraph->common()->Phi(kMachAnyTagged, predecessors);
   const Operator* op_ephi = jsgraph->common()->EffectPhi(predecessors);

   NodeVector values(jsgraph->zone());
   NodeVector effects(jsgraph->zone());
   // Iterate over all control flow predecessors,
   // which must be return statements.
   for (Edge edge : final_merge->input_edges()) {
     Node* input = edge.to();
     switch (input->opcode()) {
       case IrOpcode::kReturn:
         values.push_back(NodeProperties::GetValueInput(input, 0));
         effects.push_back(NodeProperties::GetEffectInput(input));
         edge.UpdateTo(NodeProperties::GetControlInput(input));
         input->RemoveAllInputs();
         break;
       default:
         UNREACHABLE();
         break;
     }
   }
   values.push_back(final_merge);
   effects.push_back(final_merge);
   Node* phi =
       graph->NewNode(op_phi, static_cast<int>(values.size()), &values.front());
   Node* ephi = graph->NewNode(op_ephi, static_cast<int>(effects.size()),
                               &effects.front());
   Node* new_return =
       graph->NewNode(jsgraph->common()->Return(), phi, ephi, final_merge);
   graph->end()->ReplaceInput(0, new_return);
 }


 class CopyVisitor : public NullNodeVisitor {
  public:
   CopyVisitor(Graph* source_graph, Graph* target_graph, Zone* temp_zone)
       : copies_(source_graph->NodeCount(), NULL, temp_zone),
         sentinels_(source_graph->NodeCount(), NULL, temp_zone),
         source_graph_(source_graph),
         target_graph_(target_graph),
         temp_zone_(temp_zone),
         sentinel_op_(IrOpcode::kDead, Operator::kNoProperties, "sentinel", 0, 0,
                      0, 0, 0, 0) {}

   void Post(Node* original) {
     NodeVector inputs(temp_zone_);
     for (Node* const node : original->inputs()) {
       inputs.push_back(GetCopy(node));
     }

     // Reuse the operator in the copy. This assumes that op lives in a zone
     // that lives longer than graph()'s zone.
     Node* copy =
         target_graph_->NewNode(original->op(), static_cast<int>(inputs.size()),
                                (inputs.empty() ? NULL : &inputs.front()));
     copies_[original->id()] = copy;
   }

   Node* GetCopy(Node* original) {
     Node* copy = copies_[original->id()];
     if (copy == NULL) {
       copy = GetSentinel(original);
     }
     DCHECK_NE(NULL, copy);
     return copy;
   }

   void CopyGraph() {
     source_graph_->VisitNodeInputsFromEnd(this);
     ReplaceSentinels();
   }

   const NodeVector& copies() { return copies_; }

  private:
   void ReplaceSentinels() {
     for (NodeId id = 0; id < source_graph_->NodeCount(); ++id) {
       Node* sentinel = sentinels_[id];
       if (sentinel == NULL) continue;
       Node* copy = copies_[id];
       DCHECK_NE(NULL, copy);
       sentinel->ReplaceUses(copy);
     }
   }

   Node* GetSentinel(Node* original) {
     if (sentinels_[original->id()] == NULL) {
       sentinels_[original->id()] = target_graph_->NewNode(&sentinel_op_);
     }
     return sentinels_[original->id()];
   }

   NodeVector copies_;
   NodeVector sentinels_;
   Graph* source_graph_;
   Graph* target_graph_;
   Zone* temp_zone_;
   Operator sentinel_op_;
 };


 void Inlinee::InlineAtCall(JSGraph* jsgraph, Node* call) {
   // The scheduler is smart enough to place our code; we just ensure {control}
   // becomes the control input of the start of the inlinee.
   Node* control = NodeProperties::GetControlInput(call);

   // The inlinee uses the context from the JSFunction object. This will
   // also be the effect dependency for the inlinee as it produces an effect.
   SimplifiedOperatorBuilder simplified(jsgraph->zone());
   Node* context = jsgraph->graph()->NewNode(
       simplified.LoadField(AccessBuilder::ForJSFunctionContext()),
       NodeProperties::GetValueInput(call, 0),
       NodeProperties::GetEffectInput(call), control);

   // Context is last argument.
   int inlinee_context_index = static_cast<int>(total_parameters()) - 1;
   // {inliner_inputs} counts JSFunction, Receiver, arguments, but not
   // context, effect, control.
   int inliner_inputs = call->op()->ValueInputCount();
   // Iterate over all uses of the start node.
   for (Edge edge : start_->use_edges()) {
     Node* use = edge.from();
     switch (use->opcode()) {
       case IrOpcode::kParameter: {
         int index = 1 + OpParameter<int>(use->op());
         if (index < inliner_inputs && index < inlinee_context_index) {
           // There is an input from the call, and the index is a value
           // projection but not the context, so rewire the input.
           NodeProperties::ReplaceWithValue(use, call->InputAt(index));
         } else if (index == inlinee_context_index) {
           // This is the context projection, rewire it to the context from the
           // JSFunction object.
           NodeProperties::ReplaceWithValue(use, context);
         } else if (index < inlinee_context_index) {
           // Call has fewer arguments than required, fill with undefined.
           NodeProperties::ReplaceWithValue(use, jsgraph->UndefinedConstant());
         } else {
           // We got too many arguments, discard for now.
           // TODO(sigurds): Fix to treat arguments array correctly.
         }
         break;
       }
       default:
         if (NodeProperties::IsEffectEdge(edge)) {
           edge.UpdateTo(context);
         } else if (NodeProperties::IsControlEdge(edge)) {
           edge.UpdateTo(control);
         } else {
           UNREACHABLE();
         }
         break;
     }
   }

   NodeProperties::ReplaceWithValue(call, value_output(), effect_output());
   call->RemoveAllInputs();
   DCHECK_EQ(0, call->UseCount());
 }


 // TODO(turbofan) Provide such accessors for every node, possibly even
 // generate them.
 class JSCallFunctionAccessor {
  public:
   explicit JSCallFunctionAccessor(Node* call) : call_(call) {
     DCHECK_EQ(IrOpcode::kJSCallFunction, call->opcode());
   }

   Node* jsfunction() { return call_->InputAt(0); }

   Node* receiver() { return call_->InputAt(1); }

   Node* formal_argument(size_t index) {
     DCHECK(index < formal_arguments());
     return call_->InputAt(static_cast<int>(2 + index));
   }

   size_t formal_arguments() {
     // {value_inputs} includes jsfunction and receiver.
     size_t value_inputs = call_->op()->ValueInputCount();
     DCHECK_GE(call_->InputCount(), 2);
     return value_inputs - 2;
   }

   Node* frame_state() { return NodeProperties::GetFrameStateInput(call_); }

  private:
   Node* call_;
 };


 void JSInliner::AddClosureToFrameState(Node* frame_state,
                                        Handle<JSFunction> jsfunction) {
   FrameStateCallInfo call_info = OpParameter<FrameStateCallInfo>(frame_state);
   const Operator* op = jsgraph_->common()->FrameState(
       FrameStateType::JS_FRAME, call_info.bailout_id(),
       call_info.state_combine(), jsfunction);
   frame_state->set_op(op);
 }


 Node* JSInliner::CreateArgumentsAdaptorFrameState(JSCallFunctionAccessor* call,
                                                   Handle<JSFunction> jsfunction,
                                                   Zone* temp_zone) {
   const Operator* op = jsgraph_->common()->FrameState(
       FrameStateType::ARGUMENTS_ADAPTOR, BailoutId(-1),
       OutputFrameStateCombine::Ignore(), jsfunction);
   const Operator* op0 = jsgraph_->common()->StateValues(0);
   Node* node0 = jsgraph_->graph()->NewNode(op0);
   NodeVector params(temp_zone);
   params.push_back(call->receiver());
   for (size_t argument = 0; argument != call->formal_arguments(); ++argument) {
     params.push_back(call->formal_argument(argument));
   }
   const Operator* op_param =
       jsgraph_->common()->StateValues(static_cast<int>(params.size()));
   Node* params_node = jsgraph_->graph()->NewNode(
       op_param, static_cast<int>(params.size()), &params.front());
   return jsgraph_->graph()->NewNode(op, params_node, node0, node0,
                                     jsgraph_->UndefinedConstant(),
                                     call->frame_state());
 }


 void JSInliner::TryInlineJSCall(Node* call_node) {
   JSCallFunctionAccessor call(call_node);

   HeapObjectMatcher<JSFunction> match(call.jsfunction());
   if (!match.HasValue()) {
     return;
   }

   Handle<JSFunction> function = match.Value().handle();

   if (function->shared()->native()) {
     if (FLAG_trace_turbo_inlining) {
       SmartArrayPointer<char> name =
           function->shared()->DebugName()->ToCString();
       PrintF("Not Inlining %s into %s because inlinee is native\n", name.get(),
              info_->shared_info()->DebugName()->ToCString().get());
     }
     return;
   }

   CompilationInfoWithZone info(function);
   // TODO(wingo): ParseAndAnalyze can fail due to stack overflow.
   CHECK(Compiler::ParseAndAnalyze(&info));
   CHECK(Compiler::EnsureDeoptimizationSupport(&info));

   if (info.scope()->arguments() != NULL && info.strict_mode() != STRICT) {
     // For now do not inline functions that use their arguments array.
     SmartArrayPointer<char> name = function->shared()->DebugName()->ToCString();
     if (FLAG_trace_turbo_inlining) {
       PrintF(
           "Not Inlining %s into %s because inlinee uses arguments "
           "array\n",
           name.get(), info_->shared_info()->DebugName()->ToCString().get());
     }
     return;
   }

   if (FLAG_trace_turbo_inlining) {
     SmartArrayPointer<char> name = function->shared()->DebugName()->ToCString();
     PrintF("Inlining %s into %s\n", name.get(),
            info_->shared_info()->DebugName()->ToCString().get());
   }

   Graph graph(info.zone());
   JSGraph jsgraph(&graph, jsgraph_->common(), jsgraph_->javascript(),
                   jsgraph_->machine());

   AstGraphBuilder graph_builder(local_zone_, &info, &jsgraph);
   graph_builder.CreateGraph();
   Inlinee::UnifyReturn(&jsgraph);

   CopyVisitor visitor(&graph, jsgraph_->graph(), info.zone());
   visitor.CopyGraph();

   Inlinee inlinee(visitor.GetCopy(graph.start()), visitor.GetCopy(graph.end()));

   if (FLAG_turbo_deoptimization) {
     Node* outer_frame_state = call.frame_state();
     // Insert argument adaptor frame if required.
     if (call.formal_arguments() != inlinee.formal_parameters()) {
       outer_frame_state =
           CreateArgumentsAdaptorFrameState(&call, function, info.zone());
     }

     for (NodeVectorConstIter it = visitor.copies().begin();
          it != visitor.copies().end(); ++it) {
       Node* node = *it;
       if (node != NULL && node->opcode() == IrOpcode::kFrameState) {
         AddClosureToFrameState(node, function);
         NodeProperties::ReplaceFrameStateInput(node, outer_frame_state);
       }
     }
   }

   inlinee.InlineAtCall(jsgraph_, call_node);
 }


 class JSCallRuntimeAccessor {
  public:
   explicit JSCallRuntimeAccessor(Node* call) : call_(call) {
     DCHECK_EQ(IrOpcode::kJSCallRuntime, call->opcode());
   }

   Node* formal_argument(size_t index) {
     DCHECK(index < formal_arguments());
     return call_->InputAt(static_cast<int>(index));
   }

   size_t formal_arguments() {
     size_t value_inputs = call_->op()->ValueInputCount();
     return value_inputs;
   }

   Node* frame_state() const {
     return NodeProperties::GetFrameStateInput(call_);
   }
   Node* context() const { return NodeProperties::GetContextInput(call_); }
   Node* control() const { return NodeProperties::GetControlInput(call_); }
   Node* effect() const { return NodeProperties::GetEffectInput(call_); }

   const Runtime::Function* function() const {
     return Runtime::FunctionForId(CallRuntimeParametersOf(call_->op()).id());
   }

   NodeVector inputs(Zone* zone) const {
     NodeVector inputs(zone);
     for (Node* const node : call_->inputs()) {
       inputs.push_back(node);
     }
     return inputs;
   }

  private:
   Node* call_;
 };


 void JSInliner::TryInlineRuntimeCall(Node* call_node) {
   JSCallRuntimeAccessor call(call_node);
   const Runtime::Function* f = call.function();

   if (f->intrinsic_type != Runtime::IntrinsicType::INLINE) {
     return;
   }

   JSIntrinsicBuilder intrinsic_builder(jsgraph_);

   ResultAndEffect r = intrinsic_builder.BuildGraphFor(
       f->function_id, call.inputs(jsgraph_->zone()));

   if (r.first != NULL) {
     if (FLAG_trace_turbo_inlining) {
       PrintF("Inlining %s into %s\n", f->name,
              info_->shared_info()->DebugName()->ToCString().get());
     }
     NodeProperties::ReplaceWithValue(call_node, r.first, r.second);
     call_node->RemoveAllInputs();
     DCHECK_EQ(0, call_node->UseCount());
   }
 }
 }
 }
 }  // namespace v8::internal::compiler
	// Copyright 2014 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "src/ast.h"
	#include "src/ast-numbering.h"
	#include "src/compiler/access-builder.h"
	#include "src/compiler/ast-graph-builder.h"
	#include "src/compiler/common-operator.h"
	#include "src/compiler/graph-inl.h"
	#include "src/compiler/graph-visualizer.h"
	#include "src/compiler/js-inlining.h"
	#include "src/compiler/js-intrinsic-builder.h"
	#include "src/compiler/js-operator.h"
	#include "src/compiler/node-aux-data-inl.h"
	#include "src/compiler/node-matchers.h"
	#include "src/compiler/node-properties-inl.h"
	#include "src/compiler/simplified-operator.h"
	#include "src/compiler/typer.h"
	#include "src/full-codegen.h"
	#include "src/parser.h"
	#include "src/rewriter.h"
	#include "src/scopes.h"


	namespace v8 {
	namespace internal {
	namespace compiler {

	class InlinerVisitor : public NullNodeVisitor {
	public:
	explicit InlinerVisitor(JSInliner* inliner) : inliner_(inliner) {}

	void Post(Node* node) {
	switch (node->opcode()) {
	case IrOpcode::kJSCallFunction:
	inliner_->TryInlineJSCall(node);
	break;
	case IrOpcode::kJSCallRuntime:
	if (FLAG_turbo_inlining_intrinsics) {
	inliner_->TryInlineRuntimeCall(node);
	}
	break;
	default:
	break;
	}
	}

	private:
	JSInliner* inliner_;
	};


	void JSInliner::Inline() {
	InlinerVisitor visitor(this);
	jsgraph_->graph()->VisitNodeInputsFromEnd(&visitor);
	}


	// A facade on a JSFunction's graph to facilitate inlining. It assumes the
	// that the function graph has only one return statement, and provides
	// {UnifyReturn} to convert a function graph to that end.
	class Inlinee {
	public:
	Inlinee(Node* start, Node* end) : start_(start), end_(end) {}

	// Returns the last regular control node, that is
	// the last control node before the end node.
	Node* end_block() { return NodeProperties::GetControlInput(unique_return()); }

	// Return the effect output of the graph,
	// that is the effect input of the return statement of the inlinee.
	Node* effect_output() {
	return NodeProperties::GetEffectInput(unique_return());
	}
	// Return the value output of the graph,
	// that is the value input of the return statement of the inlinee.
	Node* value_output() {
	return NodeProperties::GetValueInput(unique_return(), 0);
	}
	// Return the unique return statement of the graph.
	Node* unique_return() {
	Node* unique_return = NodeProperties::GetControlInput(end_);
	DCHECK_EQ(IrOpcode::kReturn, unique_return->opcode());
	return unique_return;
	}

	// Counts JSFunction, Receiver, arguments, context but not effect, control.
	size_t total_parameters() { return start_->op()->ValueOutputCount(); }

	// Counts only formal parameters.
	size_t formal_parameters() {
	DCHECK_GE(total_parameters(), 3);
	return total_parameters() - 3;
	}

	// Inline this graph at {call}, use {jsgraph} and its zone to create
	// any new nodes.
	void InlineAtCall(JSGraph* jsgraph, Node* call);

	// Ensure that only a single return reaches the end node.
	static void UnifyReturn(JSGraph* jsgraph);

	private:
	Node* start_;
	Node* end_;
	};


	void Inlinee::UnifyReturn(JSGraph* jsgraph) {
	Graph* graph = jsgraph->graph();

	Node* final_merge = NodeProperties::GetControlInput(graph->end(), 0);
	if (final_merge->opcode() == IrOpcode::kReturn) {
	// nothing to do
	return;
	}
	DCHECK_EQ(IrOpcode::kMerge, final_merge->opcode());

	int predecessors = final_merge->op()->ControlInputCount();

	const Operator* op_phi = jsgraph->common()->Phi(kMachAnyTagged, predecessors);
	const Operator* op_ephi = jsgraph->common()->EffectPhi(predecessors);

	NodeVector values(jsgraph->zone());
	NodeVector effects(jsgraph->zone());
	// Iterate over all control flow predecessors,
	// which must be return statements.
	for (Edge edge : final_merge->input_edges()) {
	Node* input = edge.to();
	switch (input->opcode()) {
	case IrOpcode::kReturn:
	values.push_back(NodeProperties::GetValueInput(input, 0));
	effects.push_back(NodeProperties::GetEffectInput(input));
	edge.UpdateTo(NodeProperties::GetControlInput(input));
	input->RemoveAllInputs();
	break;
	default:
	UNREACHABLE();
	break;
	}
	}
	values.push_back(final_merge);
	effects.push_back(final_merge);
	Node* phi =
	graph->NewNode(op_phi, static_cast<int>(values.size()), &values.front());
	Node* ephi = graph->NewNode(op_ephi, static_cast<int>(effects.size()),
	&effects.front());
	Node* new_return =
	graph->NewNode(jsgraph->common()->Return(), phi, ephi, final_merge);
	graph->end()->ReplaceInput(0, new_return);
	}


	class CopyVisitor : public NullNodeVisitor {
	public:
	CopyVisitor(Graph* source_graph, Graph* target_graph, Zone* temp_zone)
	: copies_(source_graph->NodeCount(), NULL, temp_zone),
	sentinels_(source_graph->NodeCount(), NULL, temp_zone),
	source_graph_(source_graph),
	target_graph_(target_graph),
	temp_zone_(temp_zone),
	sentinel_op_(IrOpcode::kDead, Operator::kNoProperties, "sentinel", 0, 0,
	0, 0, 0, 0) {}

	void Post(Node* original) {
	NodeVector inputs(temp_zone_);
	for (Node* const node : original->inputs()) {
	inputs.push_back(GetCopy(node));
	}

	// Reuse the operator in the copy. This assumes that op lives in a zone
	// that lives longer than graph()'s zone.
	Node* copy =
	target_graph_->NewNode(original->op(), static_cast<int>(inputs.size()),
	(inputs.empty() ? NULL : &inputs.front()));
	copies_[original->id()] = copy;
	}

	Node* GetCopy(Node* original) {
	Node* copy = copies_[original->id()];
	if (copy == NULL) {
	copy = GetSentinel(original);
	}
	DCHECK_NE(NULL, copy);
	return copy;
	}

	void CopyGraph() {
	source_graph_->VisitNodeInputsFromEnd(this);
	ReplaceSentinels();
	}

	const NodeVector& copies() { return copies_; }

	private:
	void ReplaceSentinels() {
	for (NodeId id = 0; id < source_graph_->NodeCount(); ++id) {
	Node* sentinel = sentinels_[id];
	if (sentinel == NULL) continue;
	Node* copy = copies_[id];
	DCHECK_NE(NULL, copy);
	sentinel->ReplaceUses(copy);
	}
	}

	Node* GetSentinel(Node* original) {
	if (sentinels_[original->id()] == NULL) {
	sentinels_[original->id()] = target_graph_->NewNode(&sentinel_op_);
	}
	return sentinels_[original->id()];
	}

	NodeVector copies_;
	NodeVector sentinels_;
	Graph* source_graph_;
	Graph* target_graph_;
	Zone* temp_zone_;
	Operator sentinel_op_;
	};


	void Inlinee::InlineAtCall(JSGraph* jsgraph, Node* call) {
	// The scheduler is smart enough to place our code; we just ensure {control}
	// becomes the control input of the start of the inlinee.
	Node* control = NodeProperties::GetControlInput(call);

	// The inlinee uses the context from the JSFunction object. This will
	// also be the effect dependency for the inlinee as it produces an effect.
	SimplifiedOperatorBuilder simplified(jsgraph->zone());
	Node* context = jsgraph->graph()->NewNode(
	simplified.LoadField(AccessBuilder::ForJSFunctionContext()),
	NodeProperties::GetValueInput(call, 0),
	NodeProperties::GetEffectInput(call), control);

	// Context is last argument.
	int inlinee_context_index = static_cast<int>(total_parameters()) - 1;
	// {inliner_inputs} counts JSFunction, Receiver, arguments, but not
	// context, effect, control.
	int inliner_inputs = call->op()->ValueInputCount();
	// Iterate over all uses of the start node.
	for (Edge edge : start_->use_edges()) {
	Node* use = edge.from();
	switch (use->opcode()) {
	case IrOpcode::kParameter: {
	int index = 1 + OpParameter<int>(use->op());
	if (index < inliner_inputs && index < inlinee_context_index) {
	// There is an input from the call, and the index is a value
	// projection but not the context, so rewire the input.
	NodeProperties::ReplaceWithValue(use, call->InputAt(index));
	} else if (index == inlinee_context_index) {
	// This is the context projection, rewire it to the context from the
	// JSFunction object.
	NodeProperties::ReplaceWithValue(use, context);
	} else if (index < inlinee_context_index) {
	// Call has fewer arguments than required, fill with undefined.
	NodeProperties::ReplaceWithValue(use, jsgraph->UndefinedConstant());
	} else {
	// We got too many arguments, discard for now.
	// TODO(sigurds): Fix to treat arguments array correctly.
	}
	break;
	}
	default:
	if (NodeProperties::IsEffectEdge(edge)) {
	edge.UpdateTo(context);
	} else if (NodeProperties::IsControlEdge(edge)) {
	edge.UpdateTo(control);
	} else {
	UNREACHABLE();
	}
	break;
	}
	}

	NodeProperties::ReplaceWithValue(call, value_output(), effect_output());
	call->RemoveAllInputs();
	DCHECK_EQ(0, call->UseCount());
	}


	// TODO(turbofan) Provide such accessors for every node, possibly even
	// generate them.
	class JSCallFunctionAccessor {
	public:
	explicit JSCallFunctionAccessor(Node* call) : call_(call) {
	DCHECK_EQ(IrOpcode::kJSCallFunction, call->opcode());
	}

	Node* jsfunction() { return call_->InputAt(0); }

	Node* receiver() { return call_->InputAt(1); }

	Node* formal_argument(size_t index) {
	DCHECK(index < formal_arguments());
	return call_->InputAt(static_cast<int>(2 + index));
	}

	size_t formal_arguments() {
	// {value_inputs} includes jsfunction and receiver.
	size_t value_inputs = call_->op()->ValueInputCount();
	DCHECK_GE(call_->InputCount(), 2);
	return value_inputs - 2;
	}

	Node* frame_state() { return NodeProperties::GetFrameStateInput(call_); }

	private:
	Node* call_;
	};


	void JSInliner::AddClosureToFrameState(Node* frame_state,
	Handle<JSFunction> jsfunction) {
	FrameStateCallInfo call_info = OpParameter<FrameStateCallInfo>(frame_state);
	const Operator* op = jsgraph_->common()->FrameState(
	FrameStateType::JS_FRAME, call_info.bailout_id(),
	call_info.state_combine(), jsfunction);
	frame_state->set_op(op);
	}


	Node* JSInliner::CreateArgumentsAdaptorFrameState(JSCallFunctionAccessor* call,
	Handle<JSFunction> jsfunction,
	Zone* temp_zone) {
	const Operator* op = jsgraph_->common()->FrameState(
	FrameStateType::ARGUMENTS_ADAPTOR, BailoutId(-1),
	OutputFrameStateCombine::Ignore(), jsfunction);
	const Operator* op0 = jsgraph_->common()->StateValues(0);
	Node* node0 = jsgraph_->graph()->NewNode(op0);
	NodeVector params(temp_zone);
	params.push_back(call->receiver());
	for (size_t argument = 0; argument != call->formal_arguments(); ++argument) {
	params.push_back(call->formal_argument(argument));
	}
	const Operator* op_param =
	jsgraph_->common()->StateValues(static_cast<int>(params.size()));
	Node* params_node = jsgraph_->graph()->NewNode(
	op_param, static_cast<int>(params.size()), &params.front());
	return jsgraph_->graph()->NewNode(op, params_node, node0, node0,
	jsgraph_->UndefinedConstant(),
	call->frame_state());
	}


	void JSInliner::TryInlineJSCall(Node* call_node) {
	JSCallFunctionAccessor call(call_node);

	HeapObjectMatcher<JSFunction> match(call.jsfunction());
	if (!match.HasValue()) {
	return;
	}

	Handle<JSFunction> function = match.Value().handle();

	if (function->shared()->native()) {
	if (FLAG_trace_turbo_inlining) {
	SmartArrayPointer<char> name =
	function->shared()->DebugName()->ToCString();
	PrintF("Not Inlining %s into %s because inlinee is native\n", name.get(),
	info_->shared_info()->DebugName()->ToCString().get());
	}
	return;
	}

	CompilationInfoWithZone info(function);
	// TODO(wingo): ParseAndAnalyze can fail due to stack overflow.
	CHECK(Compiler::ParseAndAnalyze(&info));
	CHECK(Compiler::EnsureDeoptimizationSupport(&info));

	if (info.scope()->arguments() != NULL && info.strict_mode() != STRICT) {
	// For now do not inline functions that use their arguments array.
	SmartArrayPointer<char> name = function->shared()->DebugName()->ToCString();
	if (FLAG_trace_turbo_inlining) {
	PrintF(
	"Not Inlining %s into %s because inlinee uses arguments "
	"array\n",
	name.get(), info_->shared_info()->DebugName()->ToCString().get());
	}
	return;
	}

	if (FLAG_trace_turbo_inlining) {
	SmartArrayPointer<char> name = function->shared()->DebugName()->ToCString();
	PrintF("Inlining %s into %s\n", name.get(),
	info_->shared_info()->DebugName()->ToCString().get());
	}

	Graph graph(info.zone());
	JSGraph jsgraph(&graph, jsgraph_->common(), jsgraph_->javascript(),
	jsgraph_->machine());

	AstGraphBuilder graph_builder(local_zone_, &info, &jsgraph);
	graph_builder.CreateGraph();
	Inlinee::UnifyReturn(&jsgraph);

	CopyVisitor visitor(&graph, jsgraph_->graph(), info.zone());
	visitor.CopyGraph();

	Inlinee inlinee(visitor.GetCopy(graph.start()), visitor.GetCopy(graph.end()));

	if (FLAG_turbo_deoptimization) {
	Node* outer_frame_state = call.frame_state();
	// Insert argument adaptor frame if required.
	if (call.formal_arguments() != inlinee.formal_parameters()) {
	outer_frame_state =
	CreateArgumentsAdaptorFrameState(&call, function, info.zone());
	}

	for (NodeVectorConstIter it = visitor.copies().begin();
	it != visitor.copies().end(); ++it) {
	Node* node = *it;
	if (node != NULL && node->opcode() == IrOpcode::kFrameState) {
	AddClosureToFrameState(node, function);
	NodeProperties::ReplaceFrameStateInput(node, outer_frame_state);
	}
	}
	}

	inlinee.InlineAtCall(jsgraph_, call_node);
	}


	class JSCallRuntimeAccessor {
	public:
	explicit JSCallRuntimeAccessor(Node* call) : call_(call) {
	DCHECK_EQ(IrOpcode::kJSCallRuntime, call->opcode());
	}

	Node* formal_argument(size_t index) {
	DCHECK(index < formal_arguments());
	return call_->InputAt(static_cast<int>(index));
	}

	size_t formal_arguments() {
	size_t value_inputs = call_->op()->ValueInputCount();
	return value_inputs;
	}

	Node* frame_state() const {
	return NodeProperties::GetFrameStateInput(call_);
	}
	Node* context() const { return NodeProperties::GetContextInput(call_); }
	Node* control() const { return NodeProperties::GetControlInput(call_); }
	Node* effect() const { return NodeProperties::GetEffectInput(call_); }

	const Runtime::Function* function() const {
	return Runtime::FunctionForId(CallRuntimeParametersOf(call_->op()).id());
	}

	NodeVector inputs(Zone* zone) const {
	NodeVector inputs(zone);
	for (Node* const node : call_->inputs()) {
	inputs.push_back(node);
	}
	return inputs;
	}

	private:
	Node* call_;
	};


	void JSInliner::TryInlineRuntimeCall(Node* call_node) {
	JSCallRuntimeAccessor call(call_node);
	const Runtime::Function* f = call.function();

	if (f->intrinsic_type != Runtime::IntrinsicType::INLINE) {
	return;
	}

	JSIntrinsicBuilder intrinsic_builder(jsgraph_);

	ResultAndEffect r = intrinsic_builder.BuildGraphFor(
	f->function_id, call.inputs(jsgraph_->zone()));

	if (r.first != NULL) {
	if (FLAG_trace_turbo_inlining) {
	PrintF("Inlining %s into %s\n", f->name,
	info_->shared_info()->DebugName()->ToCString().get());
	}
	NodeProperties::ReplaceWithValue(call_node, r.first, r.second);
	call_node->RemoveAllInputs();
	DCHECK_EQ(0, call_node->UseCount());
	}
	}
	}
	}
	} // namespace v8::internal::compiler