src/v8/src/compiler/loop-variable-optimizer.cc - cobalt - Git at Google

 // Copyright 2016 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/loop-variable-optimizer.h"

 #include "src/compiler/common-operator.h"
 #include "src/compiler/graph.h"
 #include "src/compiler/node-marker.h"
 #include "src/compiler/node-properties.h"
 #include "src/compiler/node.h"
 #include "src/zone/zone-containers.h"
 #include "src/zone/zone.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 // Macro for outputting trace information from representation inference.
 #define TRACE(...)                                  \
   do {                                              \
     if (FLAG_trace_turbo_loop) PrintF(__VA_ARGS__); \
   } while (false)

 LoopVariableOptimizer::LoopVariableOptimizer(Graph* graph,
                                              CommonOperatorBuilder* common,
                                              Zone* zone)
     : graph_(graph),
       common_(common),
       zone_(zone),
       limits_(graph->NodeCount(), zone),
       induction_vars_(zone) {}

 void LoopVariableOptimizer::Run() {
   ZoneQueue<Node*> queue(zone());
   queue.push(graph()->start());
   NodeMarker<bool> queued(graph(), 2);
   while (!queue.empty()) {
     Node* node = queue.front();
     queue.pop();
     queued.Set(node, false);

     DCHECK_NULL(limits_[node->id()]);
     bool all_inputs_visited = true;
     int inputs_end = (node->opcode() == IrOpcode::kLoop)
                          ? kFirstBackedge
                          : node->op()->ControlInputCount();
     for (int i = 0; i < inputs_end; i++) {
       if (limits_[NodeProperties::GetControlInput(node, i)->id()] == nullptr) {
         all_inputs_visited = false;
         break;
       }
     }
     if (!all_inputs_visited) continue;

     VisitNode(node);
     DCHECK_NOT_NULL(limits_[node->id()]);

     // Queue control outputs.
     for (Edge edge : node->use_edges()) {
       if (NodeProperties::IsControlEdge(edge) &&
           edge.from()->op()->ControlOutputCount() > 0) {
         Node* use = edge.from();
         if (use->opcode() == IrOpcode::kLoop &&
             edge.index() != kAssumedLoopEntryIndex) {
           VisitBackedge(node, use);
         } else if (!queued.Get(use)) {
           queue.push(use);
           queued.Set(use, true);
         }
       }
     }
   }
 }

 class LoopVariableOptimizer::Constraint : public ZoneObject {
  public:
   InductionVariable::ConstraintKind kind() const { return kind_; }
   Node* left() const { return left_; }
   Node* right() const { return right_; }

   const Constraint* next() const { return next_; }

   Constraint(Node* left, InductionVariable::ConstraintKind kind, Node* right,
              const Constraint* next)
       : left_(left), right_(right), kind_(kind), next_(next) {}

  private:
   Node* left_;
   Node* right_;
   InductionVariable::ConstraintKind kind_;
   const Constraint* next_;
 };

 class LoopVariableOptimizer::VariableLimits : public ZoneObject {
  public:
   static VariableLimits* Empty(Zone* zone) {
     return new (zone) VariableLimits();
   }

   VariableLimits* Copy(Zone* zone) const {
     return new (zone) VariableLimits(this);
   }

   void Add(Node* left, InductionVariable::ConstraintKind kind, Node* right,
            Zone* zone) {
     head_ = new (zone) Constraint(left, kind, right, head_);
     limit_count_++;
   }

   void Merge(const VariableLimits* other) {
     // Change the current condition list to a longest common tail
     // of this condition list and the other list. (The common tail
     // should correspond to the list from the common dominator.)

     // First, we throw away the prefix of the longer list, so that
     // we have lists of the same length.
     size_t other_size = other->limit_count_;
     const Constraint* other_limit = other->head_;
     while (other_size > limit_count_) {
       other_limit = other_limit->next();
       other_size--;
     }
     while (limit_count_ > other_size) {
       head_ = head_->next();
       limit_count_--;
     }

     // Then we go through both lists in lock-step until we find
     // the common tail.
     while (head_ != other_limit) {
       DCHECK_LT(0, limit_count_);
       limit_count_--;
       other_limit = other_limit->next();
       head_ = head_->next();
     }
   }

   const Constraint* head() const { return head_; }

  private:
   VariableLimits() {}
   explicit VariableLimits(const VariableLimits* other)
       : head_(other->head_), limit_count_(other->limit_count_) {}

   const Constraint* head_ = nullptr;
   size_t limit_count_ = 0;
 };

 void InductionVariable::AddUpperBound(Node* bound,
                                       InductionVariable::ConstraintKind kind) {
   if (FLAG_trace_turbo_loop) {
     OFStream os(stdout);
     os << "New upper bound for " << phi()->id() << " (loop "
        << NodeProperties::GetControlInput(phi())->id() << "): " << *bound
        << std::endl;
   }
   upper_bounds_.push_back(Bound(bound, kind));
 }

 void InductionVariable::AddLowerBound(Node* bound,
                                       InductionVariable::ConstraintKind kind) {
   if (FLAG_trace_turbo_loop) {
     OFStream os(stdout);
     os << "New lower bound for " << phi()->id() << " (loop "
        << NodeProperties::GetControlInput(phi())->id() << "): " << *bound;
   }
   lower_bounds_.push_back(Bound(bound, kind));
 }

 void LoopVariableOptimizer::VisitBackedge(Node* from, Node* loop) {
   if (loop->op()->ControlInputCount() != 2) return;

   // Go through the constraints, and update the induction variables in
   // this loop if they are involved in the constraint.
   const VariableLimits* limits = limits_[from->id()];
   for (const Constraint* constraint = limits->head(); constraint != nullptr;
        constraint = constraint->next()) {
     if (constraint->left()->opcode() == IrOpcode::kPhi &&
         NodeProperties::GetControlInput(constraint->left()) == loop) {
       auto var = induction_vars_.find(constraint->left()->id());
       if (var != induction_vars_.end()) {
         var->second->AddUpperBound(constraint->right(), constraint->kind());
       }
     }
     if (constraint->right()->opcode() == IrOpcode::kPhi &&
         NodeProperties::GetControlInput(constraint->right()) == loop) {
       auto var = induction_vars_.find(constraint->right()->id());
       if (var != induction_vars_.end()) {
         var->second->AddLowerBound(constraint->left(), constraint->kind());
       }
     }
   }
 }

 void LoopVariableOptimizer::VisitNode(Node* node) {
   switch (node->opcode()) {
     case IrOpcode::kMerge:
       return VisitMerge(node);
     case IrOpcode::kLoop:
       return VisitLoop(node);
     case IrOpcode::kIfFalse:
       return VisitIf(node, false);
     case IrOpcode::kIfTrue:
       return VisitIf(node, true);
     case IrOpcode::kStart:
       return VisitStart(node);
     case IrOpcode::kLoopExit:
       return VisitLoopExit(node);
     default:
       return VisitOtherControl(node);
   }
 }

 void LoopVariableOptimizer::VisitMerge(Node* node) {
   // Merge the limits of all incoming edges.
   VariableLimits* merged = limits_[node->InputAt(0)->id()]->Copy(zone());
   for (int i = 1; i < node->InputCount(); i++) {
     merged->Merge(limits_[node->InputAt(i)->id()]);
   }
   limits_[node->id()] = merged;
 }

 void LoopVariableOptimizer::VisitLoop(Node* node) {
   DetectInductionVariables(node);
   // Conservatively take the limits from the loop entry here.
   return TakeConditionsFromFirstControl(node);
 }

 void LoopVariableOptimizer::VisitIf(Node* node, bool polarity) {
   Node* branch = node->InputAt(0);
   Node* cond = branch->InputAt(0);
   VariableLimits* limits = limits_[branch->id()]->Copy(zone());
   // Normalize to less than comparison.
   switch (cond->opcode()) {
     case IrOpcode::kJSLessThan:
     case IrOpcode::kSpeculativeNumberLessThan:
       AddCmpToLimits(limits, cond, InductionVariable::kStrict, polarity);
       break;
     case IrOpcode::kJSGreaterThan:
       AddCmpToLimits(limits, cond, InductionVariable::kNonStrict, !polarity);
       break;
     case IrOpcode::kJSLessThanOrEqual:
     case IrOpcode::kSpeculativeNumberLessThanOrEqual:
       AddCmpToLimits(limits, cond, InductionVariable::kNonStrict, polarity);
       break;
     case IrOpcode::kJSGreaterThanOrEqual:
       AddCmpToLimits(limits, cond, InductionVariable::kStrict, !polarity);
       break;
     default:
       break;
   }
   limits_[node->id()] = limits;
 }

 void LoopVariableOptimizer::AddCmpToLimits(
     VariableLimits* limits, Node* node, InductionVariable::ConstraintKind kind,
     bool polarity) {
   Node* left = node->InputAt(0);
   Node* right = node->InputAt(1);
   if (FindInductionVariable(left) || FindInductionVariable(right)) {
     if (polarity) {
       limits->Add(left, kind, right, zone());
     } else {
       kind = (kind == InductionVariable::kStrict)
                  ? InductionVariable::kNonStrict
                  : InductionVariable::kStrict;
       limits->Add(right, kind, left, zone());
     }
   }
 }

 void LoopVariableOptimizer::VisitStart(Node* node) {
   limits_[node->id()] = VariableLimits::Empty(zone());
 }

 void LoopVariableOptimizer::VisitLoopExit(Node* node) {
   return TakeConditionsFromFirstControl(node);
 }

 void LoopVariableOptimizer::VisitOtherControl(Node* node) {
   DCHECK_EQ(1, node->op()->ControlInputCount());
   return TakeConditionsFromFirstControl(node);
 }

 void LoopVariableOptimizer::TakeConditionsFromFirstControl(Node* node) {
   const VariableLimits* limits =
       limits_[NodeProperties::GetControlInput(node, 0)->id()];
   DCHECK_NOT_NULL(limits);
   limits_[node->id()] = limits;
 }

 const InductionVariable* LoopVariableOptimizer::FindInductionVariable(
     Node* node) {
   auto var = induction_vars_.find(node->id());
   if (var != induction_vars_.end()) {
     return var->second;
   }
   return nullptr;
 }

 InductionVariable* LoopVariableOptimizer::TryGetInductionVariable(Node* phi) {
   DCHECK_EQ(2, phi->op()->ValueInputCount());
   DCHECK_EQ(IrOpcode::kLoop, NodeProperties::GetControlInput(phi)->opcode());
   Node* initial = phi->InputAt(0);
   Node* arith = phi->InputAt(1);
   InductionVariable::ArithmeticType arithmeticType;
   if (arith->opcode() == IrOpcode::kJSAdd ||
       arith->opcode() == IrOpcode::kSpeculativeNumberAdd ||
       arith->opcode() == IrOpcode::kSpeculativeSafeIntegerAdd) {
     arithmeticType = InductionVariable::ArithmeticType::kAddition;
   } else if (arith->opcode() == IrOpcode::kJSSubtract ||
              arith->opcode() == IrOpcode::kSpeculativeNumberSubtract ||
              arith->opcode() == IrOpcode::kSpeculativeSafeIntegerSubtract) {
     arithmeticType = InductionVariable::ArithmeticType::kSubtraction;
   } else {
     return nullptr;
   }

   // TODO(jarin) Support both sides.
   if (arith->InputAt(0) != phi) {
     if ((arith->InputAt(0)->opcode() != IrOpcode::kJSToNumber &&
          arith->InputAt(0)->opcode() != IrOpcode::kSpeculativeToNumber) ||
         arith->InputAt(0)->InputAt(0) != phi) {
       return nullptr;
     }
   }
   Node* incr = arith->InputAt(1);
   return new (zone())
       InductionVariable(phi, arith, incr, initial, zone(), arithmeticType);
 }

 void LoopVariableOptimizer::DetectInductionVariables(Node* loop) {
   if (loop->op()->ControlInputCount() != 2) return;
   TRACE("Loop variables for loop %i:", loop->id());
   for (Edge edge : loop->use_edges()) {
     if (NodeProperties::IsControlEdge(edge) &&
         edge.from()->opcode() == IrOpcode::kPhi) {
       Node* phi = edge.from();
       InductionVariable* induction_var = TryGetInductionVariable(phi);
       if (induction_var) {
         induction_vars_[phi->id()] = induction_var;
         TRACE(" %i", induction_var->phi()->id());
       }
     }
   }
   TRACE("\n");
 }

 void LoopVariableOptimizer::ChangeToInductionVariablePhis() {
   for (auto entry : induction_vars_) {
     // It only make sense to analyze the induction variables if
     // there is a bound.
     InductionVariable* induction_var = entry.second;
     DCHECK_EQ(MachineRepresentation::kTagged,
               PhiRepresentationOf(induction_var->phi()->op()));
     if (induction_var->upper_bounds().size() == 0 &&
         induction_var->lower_bounds().size() == 0) {
       continue;
     }
     // Insert the increment value to the value inputs.
     induction_var->phi()->InsertInput(graph()->zone(),
                                       induction_var->phi()->InputCount() - 1,
                                       induction_var->increment());
     // Insert the bound inputs to the value inputs.
     for (auto bound : induction_var->lower_bounds()) {
       induction_var->phi()->InsertInput(
           graph()->zone(), induction_var->phi()->InputCount() - 1, bound.bound);
     }
     for (auto bound : induction_var->upper_bounds()) {
       induction_var->phi()->InsertInput(
           graph()->zone(), induction_var->phi()->InputCount() - 1, bound.bound);
     }
     NodeProperties::ChangeOp(
         induction_var->phi(),
         common()->InductionVariablePhi(induction_var->phi()->InputCount() - 1));
   }
 }

 void LoopVariableOptimizer::ChangeToPhisAndInsertGuards() {
   for (auto entry : induction_vars_) {
     InductionVariable* induction_var = entry.second;
     if (induction_var->phi()->opcode() == IrOpcode::kInductionVariablePhi) {
       // Turn the induction variable phi back to normal phi.
       int value_count = 2;
       Node* control = NodeProperties::GetControlInput(induction_var->phi());
       DCHECK_EQ(value_count, control->op()->ControlInputCount());
       induction_var->phi()->TrimInputCount(value_count + 1);
       induction_var->phi()->ReplaceInput(value_count, control);
       NodeProperties::ChangeOp(
           induction_var->phi(),
           common()->Phi(MachineRepresentation::kTagged, value_count));

       // If the backedge is not a subtype of the phi's type, we insert a sigma
       // to get the typing right.
       Node* backedge_value = induction_var->phi()->InputAt(1);
       Type* backedge_type = NodeProperties::GetType(backedge_value);
       Type* phi_type = NodeProperties::GetType(induction_var->phi());
       if (!backedge_type->Is(phi_type)) {
         Node* backedge_control =
             NodeProperties::GetControlInput(induction_var->phi())->InputAt(1);
         Node* rename = graph()->NewNode(common()->TypeGuard(phi_type),
                                         backedge_value, backedge_control);
         induction_var->phi()->ReplaceInput(1, rename);
       }
     }
   }
 }

 #undef TRACE

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8
	// Copyright 2016 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/loop-variable-optimizer.h"

	#include "src/compiler/common-operator.h"
	#include "src/compiler/graph.h"
	#include "src/compiler/node-marker.h"
	#include "src/compiler/node-properties.h"
	#include "src/compiler/node.h"
	#include "src/zone/zone-containers.h"
	#include "src/zone/zone.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	// Macro for outputting trace information from representation inference.
	#define TRACE(...) \
	do { \
	if (FLAG_trace_turbo_loop) PrintF(__VA_ARGS__); \
	} while (false)

	LoopVariableOptimizer::LoopVariableOptimizer(Graph* graph,
	CommonOperatorBuilder* common,
	Zone* zone)
	: graph_(graph),
	common_(common),
	zone_(zone),
	limits_(graph->NodeCount(), zone),
	induction_vars_(zone) {}

	void LoopVariableOptimizer::Run() {
	ZoneQueue<Node*> queue(zone());
	queue.push(graph()->start());
	NodeMarker<bool> queued(graph(), 2);
	while (!queue.empty()) {
	Node* node = queue.front();
	queue.pop();
	queued.Set(node, false);

	DCHECK_NULL(limits_[node->id()]);
	bool all_inputs_visited = true;
	int inputs_end = (node->opcode() == IrOpcode::kLoop)
	? kFirstBackedge
	: node->op()->ControlInputCount();
	for (int i = 0; i < inputs_end; i++) {
	if (limits_[NodeProperties::GetControlInput(node, i)->id()] == nullptr) {
	all_inputs_visited = false;
	break;
	}
	}
	if (!all_inputs_visited) continue;

	VisitNode(node);
	DCHECK_NOT_NULL(limits_[node->id()]);

	// Queue control outputs.
	for (Edge edge : node->use_edges()) {
	if (NodeProperties::IsControlEdge(edge) &&
	edge.from()->op()->ControlOutputCount() > 0) {
	Node* use = edge.from();
	if (use->opcode() == IrOpcode::kLoop &&
	edge.index() != kAssumedLoopEntryIndex) {
	VisitBackedge(node, use);
	} else if (!queued.Get(use)) {
	queue.push(use);
	queued.Set(use, true);
	}
	}
	}
	}
	}

	class LoopVariableOptimizer::Constraint : public ZoneObject {
	public:
	InductionVariable::ConstraintKind kind() const { return kind_; }
	Node* left() const { return left_; }
	Node* right() const { return right_; }

	const Constraint* next() const { return next_; }

	Constraint(Node* left, InductionVariable::ConstraintKind kind, Node* right,
	const Constraint* next)
	: left_(left), right_(right), kind_(kind), next_(next) {}

	private:
	Node* left_;
	Node* right_;
	InductionVariable::ConstraintKind kind_;
	const Constraint* next_;
	};

	class LoopVariableOptimizer::VariableLimits : public ZoneObject {
	public:
	static VariableLimits* Empty(Zone* zone) {
	return new (zone) VariableLimits();
	}

	VariableLimits* Copy(Zone* zone) const {
	return new (zone) VariableLimits(this);
	}

	void Add(Node* left, InductionVariable::ConstraintKind kind, Node* right,
	Zone* zone) {
	head_ = new (zone) Constraint(left, kind, right, head_);
	limit_count_++;
	}

	void Merge(const VariableLimits* other) {
	// Change the current condition list to a longest common tail
	// of this condition list and the other list. (The common tail
	// should correspond to the list from the common dominator.)

	// First, we throw away the prefix of the longer list, so that
	// we have lists of the same length.
	size_t other_size = other->limit_count_;
	const Constraint* other_limit = other->head_;
	while (other_size > limit_count_) {
	other_limit = other_limit->next();
	other_size--;
	}
	while (limit_count_ > other_size) {
	head_ = head_->next();
	limit_count_--;
	}

	// Then we go through both lists in lock-step until we find
	// the common tail.
	while (head_ != other_limit) {
	DCHECK_LT(0, limit_count_);
	limit_count_--;
	other_limit = other_limit->next();
	head_ = head_->next();
	}
	}

	const Constraint* head() const { return head_; }

	private:
	VariableLimits() {}
	explicit VariableLimits(const VariableLimits* other)
	: head_(other->head_), limit_count_(other->limit_count_) {}

	const Constraint* head_ = nullptr;
	size_t limit_count_ = 0;
	};

	void InductionVariable::AddUpperBound(Node* bound,
	InductionVariable::ConstraintKind kind) {
	if (FLAG_trace_turbo_loop) {
	OFStream os(stdout);
	os << "New upper bound for " << phi()->id() << " (loop "
	<< NodeProperties::GetControlInput(phi())->id() << "): " << *bound
	<< std::endl;
	}
	upper_bounds_.push_back(Bound(bound, kind));
	}

	void InductionVariable::AddLowerBound(Node* bound,
	InductionVariable::ConstraintKind kind) {
	if (FLAG_trace_turbo_loop) {
	OFStream os(stdout);
	os << "New lower bound for " << phi()->id() << " (loop "
	<< NodeProperties::GetControlInput(phi())->id() << "): " << *bound;
	}
	lower_bounds_.push_back(Bound(bound, kind));
	}

	void LoopVariableOptimizer::VisitBackedge(Node* from, Node* loop) {
	if (loop->op()->ControlInputCount() != 2) return;

	// Go through the constraints, and update the induction variables in
	// this loop if they are involved in the constraint.
	const VariableLimits* limits = limits_[from->id()];
	for (const Constraint* constraint = limits->head(); constraint != nullptr;
	constraint = constraint->next()) {
	if (constraint->left()->opcode() == IrOpcode::kPhi &&
	NodeProperties::GetControlInput(constraint->left()) == loop) {
	auto var = induction_vars_.find(constraint->left()->id());
	if (var != induction_vars_.end()) {
	var->second->AddUpperBound(constraint->right(), constraint->kind());
	}
	}
	if (constraint->right()->opcode() == IrOpcode::kPhi &&
	NodeProperties::GetControlInput(constraint->right()) == loop) {
	auto var = induction_vars_.find(constraint->right()->id());
	if (var != induction_vars_.end()) {
	var->second->AddLowerBound(constraint->left(), constraint->kind());
	}
	}
	}
	}

	void LoopVariableOptimizer::VisitNode(Node* node) {
	switch (node->opcode()) {
	case IrOpcode::kMerge:
	return VisitMerge(node);
	case IrOpcode::kLoop:
	return VisitLoop(node);
	case IrOpcode::kIfFalse:
	return VisitIf(node, false);
	case IrOpcode::kIfTrue:
	return VisitIf(node, true);
	case IrOpcode::kStart:
	return VisitStart(node);
	case IrOpcode::kLoopExit:
	return VisitLoopExit(node);
	default:
	return VisitOtherControl(node);
	}
	}

	void LoopVariableOptimizer::VisitMerge(Node* node) {
	// Merge the limits of all incoming edges.
	VariableLimits* merged = limits_[node->InputAt(0)->id()]->Copy(zone());
	for (int i = 1; i < node->InputCount(); i++) {
	merged->Merge(limits_[node->InputAt(i)->id()]);
	}
	limits_[node->id()] = merged;
	}

	void LoopVariableOptimizer::VisitLoop(Node* node) {
	DetectInductionVariables(node);
	// Conservatively take the limits from the loop entry here.
	return TakeConditionsFromFirstControl(node);
	}

	void LoopVariableOptimizer::VisitIf(Node* node, bool polarity) {
	Node* branch = node->InputAt(0);
	Node* cond = branch->InputAt(0);
	VariableLimits* limits = limits_[branch->id()]->Copy(zone());
	// Normalize to less than comparison.
	switch (cond->opcode()) {
	case IrOpcode::kJSLessThan:
	case IrOpcode::kSpeculativeNumberLessThan:
	AddCmpToLimits(limits, cond, InductionVariable::kStrict, polarity);
	break;
	case IrOpcode::kJSGreaterThan:
	AddCmpToLimits(limits, cond, InductionVariable::kNonStrict, !polarity);
	break;
	case IrOpcode::kJSLessThanOrEqual:
	case IrOpcode::kSpeculativeNumberLessThanOrEqual:
	AddCmpToLimits(limits, cond, InductionVariable::kNonStrict, polarity);
	break;
	case IrOpcode::kJSGreaterThanOrEqual:
	AddCmpToLimits(limits, cond, InductionVariable::kStrict, !polarity);
	break;
	default:
	break;
	}
	limits_[node->id()] = limits;
	}

	void LoopVariableOptimizer::AddCmpToLimits(
	VariableLimits* limits, Node* node, InductionVariable::ConstraintKind kind,
	bool polarity) {
	Node* left = node->InputAt(0);
	Node* right = node->InputAt(1);
	if (FindInductionVariable(left) \|\| FindInductionVariable(right)) {
	if (polarity) {
	limits->Add(left, kind, right, zone());
	} else {
	kind = (kind == InductionVariable::kStrict)
	? InductionVariable::kNonStrict
	: InductionVariable::kStrict;
	limits->Add(right, kind, left, zone());
	}
	}
	}

	void LoopVariableOptimizer::VisitStart(Node* node) {
	limits_[node->id()] = VariableLimits::Empty(zone());
	}

	void LoopVariableOptimizer::VisitLoopExit(Node* node) {
	return TakeConditionsFromFirstControl(node);
	}

	void LoopVariableOptimizer::VisitOtherControl(Node* node) {
	DCHECK_EQ(1, node->op()->ControlInputCount());
	return TakeConditionsFromFirstControl(node);
	}

	void LoopVariableOptimizer::TakeConditionsFromFirstControl(Node* node) {
	const VariableLimits* limits =
	limits_[NodeProperties::GetControlInput(node, 0)->id()];
	DCHECK_NOT_NULL(limits);
	limits_[node->id()] = limits;
	}

	const InductionVariable* LoopVariableOptimizer::FindInductionVariable(
	Node* node) {
	auto var = induction_vars_.find(node->id());
	if (var != induction_vars_.end()) {
	return var->second;
	}
	return nullptr;
	}

	InductionVariable* LoopVariableOptimizer::TryGetInductionVariable(Node* phi) {
	DCHECK_EQ(2, phi->op()->ValueInputCount());
	DCHECK_EQ(IrOpcode::kLoop, NodeProperties::GetControlInput(phi)->opcode());
	Node* initial = phi->InputAt(0);
	Node* arith = phi->InputAt(1);
	InductionVariable::ArithmeticType arithmeticType;
	if (arith->opcode() == IrOpcode::kJSAdd \|\|
	arith->opcode() == IrOpcode::kSpeculativeNumberAdd \|\|
	arith->opcode() == IrOpcode::kSpeculativeSafeIntegerAdd) {
	arithmeticType = InductionVariable::ArithmeticType::kAddition;
	} else if (arith->opcode() == IrOpcode::kJSSubtract \|\|
	arith->opcode() == IrOpcode::kSpeculativeNumberSubtract \|\|
	arith->opcode() == IrOpcode::kSpeculativeSafeIntegerSubtract) {
	arithmeticType = InductionVariable::ArithmeticType::kSubtraction;
	} else {
	return nullptr;
	}

	// TODO(jarin) Support both sides.
	if (arith->InputAt(0) != phi) {
	if ((arith->InputAt(0)->opcode() != IrOpcode::kJSToNumber &&
	arith->InputAt(0)->opcode() != IrOpcode::kSpeculativeToNumber) \|\|
	arith->InputAt(0)->InputAt(0) != phi) {
	return nullptr;
	}
	}
	Node* incr = arith->InputAt(1);
	return new (zone())
	InductionVariable(phi, arith, incr, initial, zone(), arithmeticType);
	}

	void LoopVariableOptimizer::DetectInductionVariables(Node* loop) {
	if (loop->op()->ControlInputCount() != 2) return;
	TRACE("Loop variables for loop %i:", loop->id());
	for (Edge edge : loop->use_edges()) {
	if (NodeProperties::IsControlEdge(edge) &&
	edge.from()->opcode() == IrOpcode::kPhi) {
	Node* phi = edge.from();
	InductionVariable* induction_var = TryGetInductionVariable(phi);
	if (induction_var) {
	induction_vars_[phi->id()] = induction_var;
	TRACE(" %i", induction_var->phi()->id());
	}
	}
	}
	TRACE("\n");
	}

	void LoopVariableOptimizer::ChangeToInductionVariablePhis() {
	for (auto entry : induction_vars_) {
	// It only make sense to analyze the induction variables if
	// there is a bound.
	InductionVariable* induction_var = entry.second;
	DCHECK_EQ(MachineRepresentation::kTagged,
	PhiRepresentationOf(induction_var->phi()->op()));
	if (induction_var->upper_bounds().size() == 0 &&
	induction_var->lower_bounds().size() == 0) {
	continue;
	}
	// Insert the increment value to the value inputs.
	induction_var->phi()->InsertInput(graph()->zone(),
	induction_var->phi()->InputCount() - 1,
	induction_var->increment());
	// Insert the bound inputs to the value inputs.
	for (auto bound : induction_var->lower_bounds()) {
	induction_var->phi()->InsertInput(
	graph()->zone(), induction_var->phi()->InputCount() - 1, bound.bound);
	}
	for (auto bound : induction_var->upper_bounds()) {
	induction_var->phi()->InsertInput(
	graph()->zone(), induction_var->phi()->InputCount() - 1, bound.bound);
	}
	NodeProperties::ChangeOp(
	induction_var->phi(),
	common()->InductionVariablePhi(induction_var->phi()->InputCount() - 1));
	}
	}

	void LoopVariableOptimizer::ChangeToPhisAndInsertGuards() {
	for (auto entry : induction_vars_) {
	InductionVariable* induction_var = entry.second;
	if (induction_var->phi()->opcode() == IrOpcode::kInductionVariablePhi) {
	// Turn the induction variable phi back to normal phi.
	int value_count = 2;
	Node* control = NodeProperties::GetControlInput(induction_var->phi());
	DCHECK_EQ(value_count, control->op()->ControlInputCount());
	induction_var->phi()->TrimInputCount(value_count + 1);
	induction_var->phi()->ReplaceInput(value_count, control);
	NodeProperties::ChangeOp(
	induction_var->phi(),
	common()->Phi(MachineRepresentation::kTagged, value_count));

	// If the backedge is not a subtype of the phi's type, we insert a sigma
	// to get the typing right.
	Node* backedge_value = induction_var->phi()->InputAt(1);
	Type* backedge_type = NodeProperties::GetType(backedge_value);
	Type* phi_type = NodeProperties::GetType(induction_var->phi());
	if (!backedge_type->Is(phi_type)) {
	Node* backedge_control =
	NodeProperties::GetControlInput(induction_var->phi())->InputAt(1);
	Node* rename = graph()->NewNode(common()->TypeGuard(phi_type),
	backedge_value, backedge_control);
	induction_var->phi()->ReplaceInput(1, rename);
	}
	}
	}
	}

	#undef TRACE

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