src/compiler/js-inlining.cc - fp2-dev/platform/external/v8 - Gitiles

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

 #include "src/compiler/js-inlining.h"

 #include "src/ast/ast-numbering.h"
 #include "src/ast/ast.h"
 #include "src/ast/scopes.h"
 #include "src/compiler.h"
 #include "src/compiler/ast-graph-builder.h"
 #include "src/compiler/ast-loop-assignment-analyzer.h"
 #include "src/compiler/common-operator.h"
 #include "src/compiler/graph-reducer.h"
 #include "src/compiler/js-operator.h"
 #include "src/compiler/node-matchers.h"
 #include "src/compiler/node-properties.h"
 #include "src/compiler/operator-properties.h"
 #include "src/compiler/type-hint-analyzer.h"
 #include "src/isolate-inl.h"
 #include "src/parsing/parser.h"
 #include "src/parsing/rewriter.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 #define TRACE(...)                                      \
   do {                                                  \
     if (FLAG_trace_turbo_inlining) PrintF(__VA_ARGS__); \
   } while (false)


 // Provides convenience accessors for the common layout of nodes having either
 // the {JSCallFunction} or the {JSCallConstruct} operator.
 class JSCallAccessor {
  public:
   explicit JSCallAccessor(Node* call) : call_(call) {
     DCHECK(call->opcode() == IrOpcode::kJSCallFunction ||
            call->opcode() == IrOpcode::kJSCallConstruct);
   }

   Node* target() {
     // Both, {JSCallFunction} and {JSCallConstruct}, have same layout here.
     return call_->InputAt(0);
   }

   Node* receiver() {
     DCHECK_EQ(IrOpcode::kJSCallFunction, call_->opcode());
     return call_->InputAt(1);
   }

   Node* new_target() {
     DCHECK_EQ(IrOpcode::kJSCallConstruct, call_->opcode());
     return call_->InputAt(formal_arguments() + 1);
   }

   Node* frame_state() {
     // Both, {JSCallFunction} and {JSCallConstruct}, have frame state.
     return NodeProperties::GetFrameStateInput(call_, 0);
   }

   int formal_arguments() {
     // Both, {JSCallFunction} and {JSCallConstruct}, have two extra inputs:
     //  - JSCallConstruct: Includes target function and new target.
     //  - JSCallFunction: Includes target function and receiver.
     return call_->op()->ValueInputCount() - 2;
   }

  private:
   Node* call_;
 };


 Reduction JSInliner::InlineCall(Node* call, Node* new_target, Node* context,
                                 Node* frame_state, Node* start, Node* end) {
   // The scheduler is smart enough to place our code; we just ensure {control}
   // becomes the control input of the start of the inlinee, and {effect} becomes
   // the effect input of the start of the inlinee.
   Node* control = NodeProperties::GetControlInput(call);
   Node* effect = NodeProperties::GetEffectInput(call);

   int const inlinee_new_target_index =
       static_cast<int>(start->op()->ValueOutputCount()) - 3;
   int const inlinee_arity_index =
       static_cast<int>(start->op()->ValueOutputCount()) - 2;
   int const inlinee_context_index =
       static_cast<int>(start->op()->ValueOutputCount()) - 1;

   // {inliner_inputs} counts JSFunction, receiver, arguments, but not
   // new target value, argument count, context, effect or 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 + ParameterIndexOf(use->op());
         DCHECK_LE(index, inlinee_context_index);
         if (index < inliner_inputs && index < inlinee_new_target_index) {
           // There is an input from the call, and the index is a value
           // projection but not the context, so rewire the input.
           Replace(use, call->InputAt(index));
         } else if (index == inlinee_new_target_index) {
           // The projection is requesting the new target value.
           Replace(use, new_target);
         } else if (index == inlinee_arity_index) {
           // The projection is requesting the number of arguments.
           Replace(use, jsgraph_->Int32Constant(inliner_inputs - 2));
         } else if (index == inlinee_context_index) {
           // The projection is requesting the inlinee function context.
           Replace(use, context);
         } else {
           // Call has fewer arguments than required, fill with undefined.
           Replace(use, jsgraph_->UndefinedConstant());
         }
         break;
       }
       default:
         if (NodeProperties::IsEffectEdge(edge)) {
           edge.UpdateTo(effect);
         } else if (NodeProperties::IsControlEdge(edge)) {
           edge.UpdateTo(control);
         } else if (NodeProperties::IsFrameStateEdge(edge)) {
           edge.UpdateTo(frame_state);
         } else {
           UNREACHABLE();
         }
         break;
     }
   }

   NodeVector values(local_zone_);
   NodeVector effects(local_zone_);
   NodeVector controls(local_zone_);
   for (Node* const input : end->inputs()) {
     switch (input->opcode()) {
       case IrOpcode::kReturn:
         values.push_back(NodeProperties::GetValueInput(input, 0));
         effects.push_back(NodeProperties::GetEffectInput(input));
         controls.push_back(NodeProperties::GetControlInput(input));
         break;
       case IrOpcode::kDeoptimize:
       case IrOpcode::kTerminate:
       case IrOpcode::kThrow:
         NodeProperties::MergeControlToEnd(jsgraph_->graph(), jsgraph_->common(),
                                           input);
         Revisit(jsgraph_->graph()->end());
         break;
       default:
         UNREACHABLE();
         break;
     }
   }
   DCHECK_EQ(values.size(), effects.size());
   DCHECK_EQ(values.size(), controls.size());

   // Depending on whether the inlinee produces a value, we either replace value
   // uses with said value or kill value uses if no value can be returned.
   if (values.size() > 0) {
     int const input_count = static_cast<int>(controls.size());
     Node* control_output = jsgraph_->graph()->NewNode(
         jsgraph_->common()->Merge(input_count), input_count, &controls.front());
     values.push_back(control_output);
     effects.push_back(control_output);
     Node* value_output = jsgraph_->graph()->NewNode(
         jsgraph_->common()->Phi(MachineRepresentation::kTagged, input_count),
         static_cast<int>(values.size()), &values.front());
     Node* effect_output = jsgraph_->graph()->NewNode(
         jsgraph_->common()->EffectPhi(input_count),
         static_cast<int>(effects.size()), &effects.front());
     ReplaceWithValue(call, value_output, effect_output, control_output);
     return Changed(value_output);
   } else {
     ReplaceWithValue(call, call, call, jsgraph_->Dead());
     return Changed(call);
   }
 }


 Node* JSInliner::CreateArtificialFrameState(Node* node, Node* outer_frame_state,
                                             int parameter_count,
                                             FrameStateType frame_state_type,
                                             Handle<SharedFunctionInfo> shared) {
   const FrameStateFunctionInfo* state_info =
       jsgraph_->common()->CreateFrameStateFunctionInfo(
           frame_state_type, parameter_count + 1, 0, shared);

   const Operator* op = jsgraph_->common()->FrameState(
       BailoutId(-1), OutputFrameStateCombine::Ignore(), state_info);
   const Operator* op0 = jsgraph_->common()->StateValues(0);
   Node* node0 = jsgraph_->graph()->NewNode(op0);
   NodeVector params(local_zone_);
   for (int parameter = 0; parameter < parameter_count + 1; ++parameter) {
     params.push_back(node->InputAt(1 + parameter));
   }
   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(),
                                     node->InputAt(0), outer_frame_state);
 }

 Node* JSInliner::CreateTailCallerFrameState(Node* node, Node* frame_state) {
   FrameStateInfo const& frame_info = OpParameter<FrameStateInfo>(frame_state);
   Handle<SharedFunctionInfo> shared;
   frame_info.shared_info().ToHandle(&shared);

   Node* function = frame_state->InputAt(kFrameStateFunctionInput);

   // If we are inlining a tail call drop caller's frame state and an
   // arguments adaptor if it exists.
   frame_state = NodeProperties::GetFrameStateInput(frame_state, 0);
   if (frame_state->opcode() == IrOpcode::kFrameState) {
     FrameStateInfo const& frame_info = OpParameter<FrameStateInfo>(frame_state);
     if (frame_info.type() == FrameStateType::kArgumentsAdaptor) {
       frame_state = NodeProperties::GetFrameStateInput(frame_state, 0);
     }
   }

   const FrameStateFunctionInfo* state_info =
       jsgraph_->common()->CreateFrameStateFunctionInfo(
           FrameStateType::kTailCallerFunction, 0, 0, shared);

   const Operator* op = jsgraph_->common()->FrameState(
       BailoutId(-1), OutputFrameStateCombine::Ignore(), state_info);
   const Operator* op0 = jsgraph_->common()->StateValues(0);
   Node* node0 = jsgraph_->graph()->NewNode(op0);
   return jsgraph_->graph()->NewNode(op, node0, node0, node0,
                                     jsgraph_->UndefinedConstant(), function,
                                     frame_state);
 }

 namespace {

 // TODO(mstarzinger,verwaest): Move this predicate onto SharedFunctionInfo?
 bool NeedsImplicitReceiver(Handle<SharedFunctionInfo> shared_info) {
   DisallowHeapAllocation no_gc;
   Isolate* const isolate = shared_info->GetIsolate();
   Code* const construct_stub = shared_info->construct_stub();
   return construct_stub != *isolate->builtins()->JSBuiltinsConstructStub() &&
          construct_stub !=
              *isolate->builtins()->JSBuiltinsConstructStubForDerived() &&
          construct_stub != *isolate->builtins()->JSConstructStubApi();
 }

 bool IsNonConstructible(Handle<SharedFunctionInfo> shared_info) {
   DisallowHeapAllocation no_gc;
   Isolate* const isolate = shared_info->GetIsolate();
   Code* const construct_stub = shared_info->construct_stub();
   return construct_stub == *isolate->builtins()->ConstructedNonConstructable();
 }

 }  // namespace


 Reduction JSInliner::Reduce(Node* node) {
   if (!IrOpcode::IsInlineeOpcode(node->opcode())) return NoChange();

   // This reducer can handle both normal function calls as well a constructor
   // calls whenever the target is a constant function object, as follows:
   //  - JSCallFunction(target:constant, receiver, args...)
   //  - JSCallConstruct(target:constant, args..., new.target)
   HeapObjectMatcher match(node->InputAt(0));
   if (!match.HasValue() || !match.Value()->IsJSFunction()) return NoChange();
   Handle<JSFunction> function = Handle<JSFunction>::cast(match.Value());

   return ReduceJSCall(node, function);
 }


 Reduction JSInliner::ReduceJSCall(Node* node, Handle<JSFunction> function) {
   DCHECK(IrOpcode::IsInlineeOpcode(node->opcode()));
   JSCallAccessor call(node);
   Handle<SharedFunctionInfo> shared_info(function->shared());

   // Function must be inlineable.
   if (!shared_info->IsInlineable()) {
     TRACE("Not inlining %s into %s because callee is not inlineable\n",
           shared_info->DebugName()->ToCString().get(),
           info_->shared_info()->DebugName()->ToCString().get());
     return NoChange();
   }

   // Constructor must be constructable.
   if (node->opcode() == IrOpcode::kJSCallConstruct &&
       IsNonConstructible(shared_info)) {
     TRACE("Not inlining %s into %s because constructor is not constructable.\n",
           shared_info->DebugName()->ToCString().get(),
           info_->shared_info()->DebugName()->ToCString().get());
     return NoChange();
   }

   // Class constructors are callable, but [[Call]] will raise an exception.
   // See ES6 section 9.2.1 [[Call]] ( thisArgument, argumentsList ).
   if (node->opcode() == IrOpcode::kJSCallFunction &&
       IsClassConstructor(shared_info->kind())) {
     TRACE("Not inlining %s into %s because callee is a class constructor.\n",
           shared_info->DebugName()->ToCString().get(),
           info_->shared_info()->DebugName()->ToCString().get());
     return NoChange();
   }

   // Function contains break points.
   if (shared_info->HasDebugInfo()) {
     TRACE("Not inlining %s into %s because callee may contain break points\n",
           shared_info->DebugName()->ToCString().get(),
           info_->shared_info()->DebugName()->ToCString().get());
     return NoChange();
   }

   // Disallow cross native-context inlining for now. This means that all parts
   // of the resulting code will operate on the same global object.
   // This also prevents cross context leaks for asm.js code, where we could
   // inline functions from a different context and hold on to that context (and
   // closure) from the code object.
   // TODO(turbofan): We might want to revisit this restriction later when we
   // have a need for this, and we know how to model different native contexts
   // in the same graph in a compositional way.
   if (function->context()->native_context() !=
       info_->context()->native_context()) {
     TRACE("Not inlining %s into %s because of different native contexts\n",
           shared_info->DebugName()->ToCString().get(),
           info_->shared_info()->DebugName()->ToCString().get());
     return NoChange();
   }

   // TODO(turbofan): TranslatedState::GetAdaptedArguments() currently relies on
   // not inlining recursive functions. We might want to relax that at some
   // point.
   for (Node* frame_state = call.frame_state();
        frame_state->opcode() == IrOpcode::kFrameState;
        frame_state = frame_state->InputAt(kFrameStateOuterStateInput)) {
     FrameStateInfo const& frame_info = OpParameter<FrameStateInfo>(frame_state);
     Handle<SharedFunctionInfo> frame_shared_info;
     if (frame_info.shared_info().ToHandle(&frame_shared_info) &&
         *frame_shared_info == *shared_info) {
       TRACE("Not inlining %s into %s because call is recursive\n",
             shared_info->DebugName()->ToCString().get(),
             info_->shared_info()->DebugName()->ToCString().get());
       return NoChange();
     }
   }

   // TODO(turbofan): Inlining into a try-block is not yet supported.
   if (NodeProperties::IsExceptionalCall(node)) {
     TRACE("Not inlining %s into %s because of surrounding try-block\n",
           shared_info->DebugName()->ToCString().get(),
           info_->shared_info()->DebugName()->ToCString().get());
     return NoChange();
   }

   Zone zone(info_->isolate()->allocator());
   ParseInfo parse_info(&zone, function);
   CompilationInfo info(&parse_info, function);
   if (info_->is_deoptimization_enabled()) info.MarkAsDeoptimizationEnabled();
   if (info_->is_type_feedback_enabled()) info.MarkAsTypeFeedbackEnabled();

   if (!Compiler::ParseAndAnalyze(info.parse_info())) {
     TRACE("Not inlining %s into %s because parsing failed\n",
           shared_info->DebugName()->ToCString().get(),
           info_->shared_info()->DebugName()->ToCString().get());
     if (info_->isolate()->has_pending_exception()) {
       info_->isolate()->clear_pending_exception();
     }
     return NoChange();
   }

   if (!Compiler::EnsureDeoptimizationSupport(&info)) {
     TRACE("Not inlining %s into %s because deoptimization support failed\n",
           shared_info->DebugName()->ToCString().get(),
           info_->shared_info()->DebugName()->ToCString().get());
     return NoChange();
   }

   // Remember that we inlined this function. This needs to be called right
   // after we ensure deoptimization support so that the code flusher
   // does not remove the code with the deoptimization support.
   info_->AddInlinedFunction(shared_info);

   // ----------------------------------------------------------------
   // After this point, we've made a decision to inline this function.
   // We shall not bailout from inlining if we got here.

   TRACE("Inlining %s into %s\n",
         shared_info->DebugName()->ToCString().get(),
         info_->shared_info()->DebugName()->ToCString().get());

   // If function was lazily compiled, it's literals array may not yet be set up.
   JSFunction::EnsureLiterals(function);

   // Create the subgraph for the inlinee.
   Node* start;
   Node* end;
   {
     // Run the loop assignment analyzer on the inlinee.
     AstLoopAssignmentAnalyzer loop_assignment_analyzer(&zone, &info);
     LoopAssignmentAnalysis* loop_assignment =
         loop_assignment_analyzer.Analyze();

     // Run the type hint analyzer on the inlinee.
     TypeHintAnalyzer type_hint_analyzer(&zone);
     TypeHintAnalysis* type_hint_analysis =
         type_hint_analyzer.Analyze(handle(shared_info->code(), info.isolate()));

     // Run the AstGraphBuilder to create the subgraph.
     Graph::SubgraphScope scope(graph());
     AstGraphBuilder graph_builder(&zone, &info, jsgraph(), loop_assignment,
                                   type_hint_analysis);
     graph_builder.CreateGraph(false);

     // Extract the inlinee start/end nodes.
     start = graph()->start();
     end = graph()->end();
   }

   Node* frame_state = call.frame_state();
   Node* new_target = jsgraph_->UndefinedConstant();

   // Inline {JSCallConstruct} requires some additional magic.
   if (node->opcode() == IrOpcode::kJSCallConstruct) {
     // Insert nodes around the call that model the behavior required for a
     // constructor dispatch (allocate implicit receiver and check return value).
     // This models the behavior usually accomplished by our {JSConstructStub}.
     // Note that the context has to be the callers context (input to call node).
     Node* receiver = jsgraph_->UndefinedConstant();  // Implicit receiver.
     if (NeedsImplicitReceiver(shared_info)) {
       Node* frame_state_before = NodeProperties::FindFrameStateBefore(node);
       Node* effect = NodeProperties::GetEffectInput(node);
       Node* context = NodeProperties::GetContextInput(node);
       Node* create = jsgraph_->graph()->NewNode(
           jsgraph_->javascript()->Create(), call.target(), call.new_target(),
           context, frame_state_before, effect);
       NodeProperties::ReplaceEffectInput(node, create);
       // Insert a check of the return value to determine whether the return
       // value
       // or the implicit receiver should be selected as a result of the call.
       Node* check = jsgraph_->graph()->NewNode(
           jsgraph_->javascript()->CallRuntime(Runtime::kInlineIsJSReceiver, 1),
           node, context, node, start);
       Node* select = jsgraph_->graph()->NewNode(
           jsgraph_->common()->Select(MachineRepresentation::kTagged), check,
           node, create);
       NodeProperties::ReplaceUses(node, select, check, node, node);
       NodeProperties::ReplaceValueInput(select, node, 1);
       NodeProperties::ReplaceValueInput(check, node, 0);
       NodeProperties::ReplaceEffectInput(check, node);
       receiver = create;  // The implicit receiver.
     }

     // Swizzle the inputs of the {JSCallConstruct} node to look like inputs to a
     // normal {JSCallFunction} node so that the rest of the inlining machinery
     // behaves as if we were dealing with a regular function invocation.
     new_target = call.new_target();  // Retrieve new target value input.
     node->RemoveInput(call.formal_arguments() + 1);  // Drop new target.
     node->InsertInput(jsgraph_->graph()->zone(), 1, receiver);

     // Insert a construct stub frame into the chain of frame states. This will
     // reconstruct the proper frame when deoptimizing within the constructor.
     frame_state = CreateArtificialFrameState(
         node, frame_state, call.formal_arguments(),
         FrameStateType::kConstructStub, info.shared_info());
   }

   // The inlinee specializes to the context from the JSFunction object.
   // TODO(turbofan): We might want to load the context from the JSFunction at
   // runtime in case we only know the SharedFunctionInfo once we have dynamic
   // type feedback in the compiler.
   Node* context = jsgraph_->Constant(handle(function->context()));

   // Insert a JSConvertReceiver node for sloppy callees. Note that the context
   // passed into this node has to be the callees context (loaded above). Note
   // that the frame state passed to the JSConvertReceiver must be the frame
   // state _before_ the call; it is not necessary to fiddle with the receiver
   // in that frame state tho, as the conversion of the receiver can be repeated
   // any number of times, it's not observable.
   if (node->opcode() == IrOpcode::kJSCallFunction &&
       is_sloppy(parse_info.language_mode()) && !shared_info->native()) {
     const CallFunctionParameters& p = CallFunctionParametersOf(node->op());
     Node* frame_state_before = NodeProperties::FindFrameStateBefore(node);
     Node* effect = NodeProperties::GetEffectInput(node);
     Node* convert = jsgraph_->graph()->NewNode(
         jsgraph_->javascript()->ConvertReceiver(p.convert_mode()),
         call.receiver(), context, frame_state_before, effect, start);
     NodeProperties::ReplaceValueInput(node, convert, 1);
     NodeProperties::ReplaceEffectInput(node, convert);
   }

   // If we are inlining a JS call at tail position then we have to pop current
   // frame state and its potential arguments adaptor frame state in order to
   // make the call stack be consistent with non-inlining case.
   // After that we add a tail caller frame state which lets deoptimizer handle
   // the case when the outermost function inlines a tail call (it should remove
   // potential arguments adaptor frame that belongs to outermost function when
   // deopt happens).
   if (node->opcode() == IrOpcode::kJSCallFunction) {
     const CallFunctionParameters& p = CallFunctionParametersOf(node->op());
     if (p.tail_call_mode() == TailCallMode::kAllow) {
       frame_state = CreateTailCallerFrameState(node, frame_state);
     }
   }

   // Insert argument adaptor frame if required. The callees formal parameter
   // count (i.e. value outputs of start node minus target, receiver, new target,
   // arguments count and context) have to match the number of arguments passed
   // to the call.
   int parameter_count = info.literal()->parameter_count();
   DCHECK_EQ(parameter_count, start->op()->ValueOutputCount() - 5);
   if (call.formal_arguments() != parameter_count) {
     frame_state = CreateArtificialFrameState(
         node, frame_state, call.formal_arguments(),
         FrameStateType::kArgumentsAdaptor, shared_info);
   }

   return InlineCall(node, new_target, context, frame_state, start, end);
 }

 Graph* JSInliner::graph() const { return jsgraph()->graph(); }

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8
	// 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/compiler/js-inlining.h"

	#include "src/ast/ast-numbering.h"
	#include "src/ast/ast.h"
	#include "src/ast/scopes.h"
	#include "src/compiler.h"
	#include "src/compiler/ast-graph-builder.h"
	#include "src/compiler/ast-loop-assignment-analyzer.h"
	#include "src/compiler/common-operator.h"
	#include "src/compiler/graph-reducer.h"
	#include "src/compiler/js-operator.h"
	#include "src/compiler/node-matchers.h"
	#include "src/compiler/node-properties.h"
	#include "src/compiler/operator-properties.h"
	#include "src/compiler/type-hint-analyzer.h"
	#include "src/isolate-inl.h"
	#include "src/parsing/parser.h"
	#include "src/parsing/rewriter.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	#define TRACE(...) \
	do { \
	if (FLAG_trace_turbo_inlining) PrintF(__VA_ARGS__); \
	} while (false)


	// Provides convenience accessors for the common layout of nodes having either
	// the {JSCallFunction} or the {JSCallConstruct} operator.
	class JSCallAccessor {
	public:
	explicit JSCallAccessor(Node* call) : call_(call) {
	DCHECK(call->opcode() == IrOpcode::kJSCallFunction \|\|
	call->opcode() == IrOpcode::kJSCallConstruct);
	}

	Node* target() {
	// Both, {JSCallFunction} and {JSCallConstruct}, have same layout here.
	return call_->InputAt(0);
	}

	Node* receiver() {
	DCHECK_EQ(IrOpcode::kJSCallFunction, call_->opcode());
	return call_->InputAt(1);
	}

	Node* new_target() {
	DCHECK_EQ(IrOpcode::kJSCallConstruct, call_->opcode());
	return call_->InputAt(formal_arguments() + 1);
	}

	Node* frame_state() {
	// Both, {JSCallFunction} and {JSCallConstruct}, have frame state.
	return NodeProperties::GetFrameStateInput(call_, 0);
	}

	int formal_arguments() {
	// Both, {JSCallFunction} and {JSCallConstruct}, have two extra inputs:
	// - JSCallConstruct: Includes target function and new target.
	// - JSCallFunction: Includes target function and receiver.
	return call_->op()->ValueInputCount() - 2;
	}

	private:
	Node* call_;
	};


	Reduction JSInliner::InlineCall(Node* call, Node* new_target, Node* context,
	Node* frame_state, Node* start, Node* end) {
	// The scheduler is smart enough to place our code; we just ensure {control}
	// becomes the control input of the start of the inlinee, and {effect} becomes
	// the effect input of the start of the inlinee.
	Node* control = NodeProperties::GetControlInput(call);
	Node* effect = NodeProperties::GetEffectInput(call);

	int const inlinee_new_target_index =
	static_cast<int>(start->op()->ValueOutputCount()) - 3;
	int const inlinee_arity_index =
	static_cast<int>(start->op()->ValueOutputCount()) - 2;
	int const inlinee_context_index =
	static_cast<int>(start->op()->ValueOutputCount()) - 1;

	// {inliner_inputs} counts JSFunction, receiver, arguments, but not
	// new target value, argument count, context, effect or 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 + ParameterIndexOf(use->op());
	DCHECK_LE(index, inlinee_context_index);
	if (index < inliner_inputs && index < inlinee_new_target_index) {
	// There is an input from the call, and the index is a value
	// projection but not the context, so rewire the input.
	Replace(use, call->InputAt(index));
	} else if (index == inlinee_new_target_index) {
	// The projection is requesting the new target value.
	Replace(use, new_target);
	} else if (index == inlinee_arity_index) {
	// The projection is requesting the number of arguments.
	Replace(use, jsgraph_->Int32Constant(inliner_inputs - 2));
	} else if (index == inlinee_context_index) {
	// The projection is requesting the inlinee function context.
	Replace(use, context);
	} else {
	// Call has fewer arguments than required, fill with undefined.
	Replace(use, jsgraph_->UndefinedConstant());
	}
	break;
	}
	default:
	if (NodeProperties::IsEffectEdge(edge)) {
	edge.UpdateTo(effect);
	} else if (NodeProperties::IsControlEdge(edge)) {
	edge.UpdateTo(control);
	} else if (NodeProperties::IsFrameStateEdge(edge)) {
	edge.UpdateTo(frame_state);
	} else {
	UNREACHABLE();
	}
	break;
	}
	}

	NodeVector values(local_zone_);
	NodeVector effects(local_zone_);
	NodeVector controls(local_zone_);
	for (Node* const input : end->inputs()) {
	switch (input->opcode()) {
	case IrOpcode::kReturn:
	values.push_back(NodeProperties::GetValueInput(input, 0));
	effects.push_back(NodeProperties::GetEffectInput(input));
	controls.push_back(NodeProperties::GetControlInput(input));
	break;
	case IrOpcode::kDeoptimize:
	case IrOpcode::kTerminate:
	case IrOpcode::kThrow:
	NodeProperties::MergeControlToEnd(jsgraph_->graph(), jsgraph_->common(),
	input);
	Revisit(jsgraph_->graph()->end());
	break;
	default:
	UNREACHABLE();
	break;
	}
	}
	DCHECK_EQ(values.size(), effects.size());
	DCHECK_EQ(values.size(), controls.size());

	// Depending on whether the inlinee produces a value, we either replace value
	// uses with said value or kill value uses if no value can be returned.
	if (values.size() > 0) {
	int const input_count = static_cast<int>(controls.size());
	Node* control_output = jsgraph_->graph()->NewNode(
	jsgraph_->common()->Merge(input_count), input_count, &controls.front());
	values.push_back(control_output);
	effects.push_back(control_output);
	Node* value_output = jsgraph_->graph()->NewNode(
	jsgraph_->common()->Phi(MachineRepresentation::kTagged, input_count),
	static_cast<int>(values.size()), &values.front());
	Node* effect_output = jsgraph_->graph()->NewNode(
	jsgraph_->common()->EffectPhi(input_count),
	static_cast<int>(effects.size()), &effects.front());
	ReplaceWithValue(call, value_output, effect_output, control_output);
	return Changed(value_output);
	} else {
	ReplaceWithValue(call, call, call, jsgraph_->Dead());
	return Changed(call);
	}
	}


	Node* JSInliner::CreateArtificialFrameState(Node* node, Node* outer_frame_state,
	int parameter_count,
	FrameStateType frame_state_type,
	Handle<SharedFunctionInfo> shared) {
	const FrameStateFunctionInfo* state_info =
	jsgraph_->common()->CreateFrameStateFunctionInfo(
	frame_state_type, parameter_count + 1, 0, shared);

	const Operator* op = jsgraph_->common()->FrameState(
	BailoutId(-1), OutputFrameStateCombine::Ignore(), state_info);
	const Operator* op0 = jsgraph_->common()->StateValues(0);
	Node* node0 = jsgraph_->graph()->NewNode(op0);
	NodeVector params(local_zone_);
	for (int parameter = 0; parameter < parameter_count + 1; ++parameter) {
	params.push_back(node->InputAt(1 + parameter));
	}
	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(),
	node->InputAt(0), outer_frame_state);
	}

	Node* JSInliner::CreateTailCallerFrameState(Node* node, Node* frame_state) {
	FrameStateInfo const& frame_info = OpParameter<FrameStateInfo>(frame_state);
	Handle<SharedFunctionInfo> shared;
	frame_info.shared_info().ToHandle(&shared);

	Node* function = frame_state->InputAt(kFrameStateFunctionInput);

	// If we are inlining a tail call drop caller's frame state and an
	// arguments adaptor if it exists.
	frame_state = NodeProperties::GetFrameStateInput(frame_state, 0);
	if (frame_state->opcode() == IrOpcode::kFrameState) {
	FrameStateInfo const& frame_info = OpParameter<FrameStateInfo>(frame_state);
	if (frame_info.type() == FrameStateType::kArgumentsAdaptor) {
	frame_state = NodeProperties::GetFrameStateInput(frame_state, 0);
	}
	}

	const FrameStateFunctionInfo* state_info =
	jsgraph_->common()->CreateFrameStateFunctionInfo(
	FrameStateType::kTailCallerFunction, 0, 0, shared);

	const Operator* op = jsgraph_->common()->FrameState(
	BailoutId(-1), OutputFrameStateCombine::Ignore(), state_info);
	const Operator* op0 = jsgraph_->common()->StateValues(0);
	Node* node0 = jsgraph_->graph()->NewNode(op0);
	return jsgraph_->graph()->NewNode(op, node0, node0, node0,
	jsgraph_->UndefinedConstant(), function,
	frame_state);
	}

	namespace {

	// TODO(mstarzinger,verwaest): Move this predicate onto SharedFunctionInfo?
	bool NeedsImplicitReceiver(Handle<SharedFunctionInfo> shared_info) {
	DisallowHeapAllocation no_gc;
	Isolate* const isolate = shared_info->GetIsolate();
	Code* const construct_stub = shared_info->construct_stub();
	return construct_stub != *isolate->builtins()->JSBuiltinsConstructStub() &&
	construct_stub !=
	*isolate->builtins()->JSBuiltinsConstructStubForDerived() &&
	construct_stub != *isolate->builtins()->JSConstructStubApi();
	}

	bool IsNonConstructible(Handle<SharedFunctionInfo> shared_info) {
	DisallowHeapAllocation no_gc;
	Isolate* const isolate = shared_info->GetIsolate();
	Code* const construct_stub = shared_info->construct_stub();
	return construct_stub == *isolate->builtins()->ConstructedNonConstructable();
	}

	} // namespace


	Reduction JSInliner::Reduce(Node* node) {
	if (!IrOpcode::IsInlineeOpcode(node->opcode())) return NoChange();

	// This reducer can handle both normal function calls as well a constructor
	// calls whenever the target is a constant function object, as follows:
	// - JSCallFunction(target:constant, receiver, args...)
	// - JSCallConstruct(target:constant, args..., new.target)
	HeapObjectMatcher match(node->InputAt(0));
	if (!match.HasValue() \|\| !match.Value()->IsJSFunction()) return NoChange();
	Handle<JSFunction> function = Handle<JSFunction>::cast(match.Value());

	return ReduceJSCall(node, function);
	}


	Reduction JSInliner::ReduceJSCall(Node* node, Handle<JSFunction> function) {
	DCHECK(IrOpcode::IsInlineeOpcode(node->opcode()));
	JSCallAccessor call(node);
	Handle<SharedFunctionInfo> shared_info(function->shared());

	// Function must be inlineable.
	if (!shared_info->IsInlineable()) {
	TRACE("Not inlining %s into %s because callee is not inlineable\n",
	shared_info->DebugName()->ToCString().get(),
	info_->shared_info()->DebugName()->ToCString().get());
	return NoChange();
	}

	// Constructor must be constructable.
	if (node->opcode() == IrOpcode::kJSCallConstruct &&
	IsNonConstructible(shared_info)) {
	TRACE("Not inlining %s into %s because constructor is not constructable.\n",
	shared_info->DebugName()->ToCString().get(),
	info_->shared_info()->DebugName()->ToCString().get());
	return NoChange();
	}

	// Class constructors are callable, but [[Call]] will raise an exception.
	// See ES6 section 9.2.1 [[Call]] ( thisArgument, argumentsList ).
	if (node->opcode() == IrOpcode::kJSCallFunction &&
	IsClassConstructor(shared_info->kind())) {
	TRACE("Not inlining %s into %s because callee is a class constructor.\n",
	shared_info->DebugName()->ToCString().get(),
	info_->shared_info()->DebugName()->ToCString().get());
	return NoChange();
	}

	// Function contains break points.
	if (shared_info->HasDebugInfo()) {
	TRACE("Not inlining %s into %s because callee may contain break points\n",
	shared_info->DebugName()->ToCString().get(),
	info_->shared_info()->DebugName()->ToCString().get());
	return NoChange();
	}

	// Disallow cross native-context inlining for now. This means that all parts
	// of the resulting code will operate on the same global object.
	// This also prevents cross context leaks for asm.js code, where we could
	// inline functions from a different context and hold on to that context (and
	// closure) from the code object.
	// TODO(turbofan): We might want to revisit this restriction later when we
	// have a need for this, and we know how to model different native contexts
	// in the same graph in a compositional way.
	if (function->context()->native_context() !=
	info_->context()->native_context()) {
	TRACE("Not inlining %s into %s because of different native contexts\n",
	shared_info->DebugName()->ToCString().get(),
	info_->shared_info()->DebugName()->ToCString().get());
	return NoChange();
	}

	// TODO(turbofan): TranslatedState::GetAdaptedArguments() currently relies on
	// not inlining recursive functions. We might want to relax that at some
	// point.
	for (Node* frame_state = call.frame_state();
	frame_state->opcode() == IrOpcode::kFrameState;
	frame_state = frame_state->InputAt(kFrameStateOuterStateInput)) {
	FrameStateInfo const& frame_info = OpParameter<FrameStateInfo>(frame_state);
	Handle<SharedFunctionInfo> frame_shared_info;
	if (frame_info.shared_info().ToHandle(&frame_shared_info) &&
	frame_shared_info == shared_info) {
	TRACE("Not inlining %s into %s because call is recursive\n",
	shared_info->DebugName()->ToCString().get(),
	info_->shared_info()->DebugName()->ToCString().get());
	return NoChange();
	}
	}

	// TODO(turbofan): Inlining into a try-block is not yet supported.
	if (NodeProperties::IsExceptionalCall(node)) {
	TRACE("Not inlining %s into %s because of surrounding try-block\n",
	shared_info->DebugName()->ToCString().get(),
	info_->shared_info()->DebugName()->ToCString().get());
	return NoChange();
	}

	Zone zone(info_->isolate()->allocator());
	ParseInfo parse_info(&zone, function);
	CompilationInfo info(&parse_info, function);
	if (info_->is_deoptimization_enabled()) info.MarkAsDeoptimizationEnabled();
	if (info_->is_type_feedback_enabled()) info.MarkAsTypeFeedbackEnabled();

	if (!Compiler::ParseAndAnalyze(info.parse_info())) {
	TRACE("Not inlining %s into %s because parsing failed\n",
	shared_info->DebugName()->ToCString().get(),
	info_->shared_info()->DebugName()->ToCString().get());
	if (info_->isolate()->has_pending_exception()) {
	info_->isolate()->clear_pending_exception();
	}
	return NoChange();
	}

	if (!Compiler::EnsureDeoptimizationSupport(&info)) {
	TRACE("Not inlining %s into %s because deoptimization support failed\n",
	shared_info->DebugName()->ToCString().get(),
	info_->shared_info()->DebugName()->ToCString().get());
	return NoChange();
	}

	// Remember that we inlined this function. This needs to be called right
	// after we ensure deoptimization support so that the code flusher
	// does not remove the code with the deoptimization support.
	info_->AddInlinedFunction(shared_info);

	// ----------------------------------------------------------------
	// After this point, we've made a decision to inline this function.
	// We shall not bailout from inlining if we got here.

	TRACE("Inlining %s into %s\n",
	shared_info->DebugName()->ToCString().get(),
	info_->shared_info()->DebugName()->ToCString().get());

	// If function was lazily compiled, it's literals array may not yet be set up.
	JSFunction::EnsureLiterals(function);

	// Create the subgraph for the inlinee.
	Node* start;
	Node* end;
	{
	// Run the loop assignment analyzer on the inlinee.
	AstLoopAssignmentAnalyzer loop_assignment_analyzer(&zone, &info);
	LoopAssignmentAnalysis* loop_assignment =
	loop_assignment_analyzer.Analyze();

	// Run the type hint analyzer on the inlinee.
	TypeHintAnalyzer type_hint_analyzer(&zone);
	TypeHintAnalysis* type_hint_analysis =
	type_hint_analyzer.Analyze(handle(shared_info->code(), info.isolate()));

	// Run the AstGraphBuilder to create the subgraph.
	Graph::SubgraphScope scope(graph());
	AstGraphBuilder graph_builder(&zone, &info, jsgraph(), loop_assignment,
	type_hint_analysis);
	graph_builder.CreateGraph(false);

	// Extract the inlinee start/end nodes.
	start = graph()->start();
	end = graph()->end();
	}

	Node* frame_state = call.frame_state();
	Node* new_target = jsgraph_->UndefinedConstant();

	// Inline {JSCallConstruct} requires some additional magic.
	if (node->opcode() == IrOpcode::kJSCallConstruct) {
	// Insert nodes around the call that model the behavior required for a
	// constructor dispatch (allocate implicit receiver and check return value).
	// This models the behavior usually accomplished by our {JSConstructStub}.
	// Note that the context has to be the callers context (input to call node).
	Node* receiver = jsgraph_->UndefinedConstant(); // Implicit receiver.
	if (NeedsImplicitReceiver(shared_info)) {
	Node* frame_state_before = NodeProperties::FindFrameStateBefore(node);
	Node* effect = NodeProperties::GetEffectInput(node);
	Node* context = NodeProperties::GetContextInput(node);
	Node* create = jsgraph_->graph()->NewNode(
	jsgraph_->javascript()->Create(), call.target(), call.new_target(),
	context, frame_state_before, effect);
	NodeProperties::ReplaceEffectInput(node, create);
	// Insert a check of the return value to determine whether the return
	// value
	// or the implicit receiver should be selected as a result of the call.
	Node* check = jsgraph_->graph()->NewNode(
	jsgraph_->javascript()->CallRuntime(Runtime::kInlineIsJSReceiver, 1),
	node, context, node, start);
	Node* select = jsgraph_->graph()->NewNode(
	jsgraph_->common()->Select(MachineRepresentation::kTagged), check,
	node, create);
	NodeProperties::ReplaceUses(node, select, check, node, node);
	NodeProperties::ReplaceValueInput(select, node, 1);
	NodeProperties::ReplaceValueInput(check, node, 0);
	NodeProperties::ReplaceEffectInput(check, node);
	receiver = create; // The implicit receiver.
	}

	// Swizzle the inputs of the {JSCallConstruct} node to look like inputs to a
	// normal {JSCallFunction} node so that the rest of the inlining machinery
	// behaves as if we were dealing with a regular function invocation.
	new_target = call.new_target(); // Retrieve new target value input.
	node->RemoveInput(call.formal_arguments() + 1); // Drop new target.
	node->InsertInput(jsgraph_->graph()->zone(), 1, receiver);

	// Insert a construct stub frame into the chain of frame states. This will
	// reconstruct the proper frame when deoptimizing within the constructor.
	frame_state = CreateArtificialFrameState(
	node, frame_state, call.formal_arguments(),
	FrameStateType::kConstructStub, info.shared_info());
	}

	// The inlinee specializes to the context from the JSFunction object.
	// TODO(turbofan): We might want to load the context from the JSFunction at
	// runtime in case we only know the SharedFunctionInfo once we have dynamic
	// type feedback in the compiler.
	Node* context = jsgraph_->Constant(handle(function->context()));

	// Insert a JSConvertReceiver node for sloppy callees. Note that the context
	// passed into this node has to be the callees context (loaded above). Note
	// that the frame state passed to the JSConvertReceiver must be the frame
	// state _before_ the call; it is not necessary to fiddle with the receiver
	// in that frame state tho, as the conversion of the receiver can be repeated
	// any number of times, it's not observable.
	if (node->opcode() == IrOpcode::kJSCallFunction &&
	is_sloppy(parse_info.language_mode()) && !shared_info->native()) {
	const CallFunctionParameters& p = CallFunctionParametersOf(node->op());
	Node* frame_state_before = NodeProperties::FindFrameStateBefore(node);
	Node* effect = NodeProperties::GetEffectInput(node);
	Node* convert = jsgraph_->graph()->NewNode(
	jsgraph_->javascript()->ConvertReceiver(p.convert_mode()),
	call.receiver(), context, frame_state_before, effect, start);
	NodeProperties::ReplaceValueInput(node, convert, 1);
	NodeProperties::ReplaceEffectInput(node, convert);
	}

	// If we are inlining a JS call at tail position then we have to pop current
	// frame state and its potential arguments adaptor frame state in order to
	// make the call stack be consistent with non-inlining case.
	// After that we add a tail caller frame state which lets deoptimizer handle
	// the case when the outermost function inlines a tail call (it should remove
	// potential arguments adaptor frame that belongs to outermost function when
	// deopt happens).
	if (node->opcode() == IrOpcode::kJSCallFunction) {
	const CallFunctionParameters& p = CallFunctionParametersOf(node->op());
	if (p.tail_call_mode() == TailCallMode::kAllow) {
	frame_state = CreateTailCallerFrameState(node, frame_state);
	}
	}

	// Insert argument adaptor frame if required. The callees formal parameter
	// count (i.e. value outputs of start node minus target, receiver, new target,
	// arguments count and context) have to match the number of arguments passed
	// to the call.
	int parameter_count = info.literal()->parameter_count();
	DCHECK_EQ(parameter_count, start->op()->ValueOutputCount() - 5);
	if (call.formal_arguments() != parameter_count) {
	frame_state = CreateArtificialFrameState(
	node, frame_state, call.formal_arguments(),
	FrameStateType::kArgumentsAdaptor, shared_info);
	}

	return InlineCall(node, new_target, context, frame_state, start, end);
	}

	Graph* JSInliner::graph() const { return jsgraph()->graph(); }

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