src/v8/src/compiler/branch-elimination.cc - cobalt - Git at Google

 // Copyright 2015 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/branch-elimination.h"

 #include "src/compiler/js-graph.h"
 #include "src/compiler/node-properties.h"
 #include "src/compiler/simplified-operator.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 BranchElimination::BranchElimination(Editor* editor, JSGraph* js_graph,
                                      Zone* zone)
     : AdvancedReducer(editor),
       jsgraph_(js_graph),
       node_conditions_(zone, js_graph->graph()->NodeCount()),
       zone_(zone),
       dead_(js_graph->Dead()) {}

 BranchElimination::~BranchElimination() {}


 Reduction BranchElimination::Reduce(Node* node) {
   switch (node->opcode()) {
     case IrOpcode::kDead:
       return NoChange();
     case IrOpcode::kDeoptimizeIf:
     case IrOpcode::kDeoptimizeUnless:
       return ReduceDeoptimizeConditional(node);
     case IrOpcode::kMerge:
       return ReduceMerge(node);
     case IrOpcode::kLoop:
       return ReduceLoop(node);
     case IrOpcode::kBranch:
       return ReduceBranch(node);
     case IrOpcode::kIfFalse:
       return ReduceIf(node, false);
     case IrOpcode::kIfTrue:
       return ReduceIf(node, true);
     case IrOpcode::kStart:
       return ReduceStart(node);
     default:
       if (node->op()->ControlOutputCount() > 0) {
         return ReduceOtherControl(node);
       }
       break;
   }
   return NoChange();
 }


 Reduction BranchElimination::ReduceBranch(Node* node) {
   Node* condition = node->InputAt(0);
   Node* control_input = NodeProperties::GetControlInput(node, 0);
   const ControlPathConditions* from_input = node_conditions_.Get(control_input);
   if (from_input != nullptr) {
     Maybe<bool> condition_value = from_input->LookupCondition(condition);
     // If we know the condition we can discard the branch.
     if (condition_value.IsJust()) {
       bool known_value = condition_value.FromJust();
       for (Node* const use : node->uses()) {
         switch (use->opcode()) {
           case IrOpcode::kIfTrue:
             Replace(use, known_value ? control_input : dead());
             break;
           case IrOpcode::kIfFalse:
             Replace(use, known_value ? dead() : control_input);
             break;
           default:
             UNREACHABLE();
         }
       }
       return Replace(dead());
     }
   }
   return TakeConditionsFromFirstControl(node);
 }

 Reduction BranchElimination::ReduceDeoptimizeConditional(Node* node) {
   DCHECK(node->opcode() == IrOpcode::kDeoptimizeIf ||
          node->opcode() == IrOpcode::kDeoptimizeUnless);
   bool condition_is_true = node->opcode() == IrOpcode::kDeoptimizeUnless;
   DeoptimizeParameters p = DeoptimizeParametersOf(node->op());
   Node* condition = NodeProperties::GetValueInput(node, 0);
   Node* frame_state = NodeProperties::GetValueInput(node, 1);
   Node* effect = NodeProperties::GetEffectInput(node);
   Node* control = NodeProperties::GetControlInput(node);
   ControlPathConditions const* conditions = node_conditions_.Get(control);
   // If we do not know anything about the predecessor, do not propagate just
   // yet because we will have to recompute anyway once we compute the
   // predecessor.
   if (conditions == nullptr) {
     return UpdateConditions(node, conditions);
   }
   Maybe<bool> condition_value = conditions->LookupCondition(condition);
   if (condition_value.IsJust()) {
     // If we know the condition we can discard the branch.
     if (condition_is_true == condition_value.FromJust()) {
       // We don't update the conditions here, because we're replacing {node}
       // with the {control} node that already contains the right information.
       ReplaceWithValue(node, dead(), effect, control);
     } else {
       control = graph()->NewNode(
           common()->Deoptimize(p.kind(), p.reason(), VectorSlotPair()),
           frame_state, effect, control);
       // TODO(bmeurer): This should be on the AdvancedReducer somehow.
       NodeProperties::MergeControlToEnd(graph(), common(), control);
       Revisit(graph()->end());
     }
     return Replace(dead());
   }
   return UpdateConditions(node, conditions, condition, condition_is_true);
 }

 Reduction BranchElimination::ReduceIf(Node* node, bool is_true_branch) {
   // Add the condition to the list arriving from the input branch.
   Node* branch = NodeProperties::GetControlInput(node, 0);
   const ControlPathConditions* from_branch = node_conditions_.Get(branch);
   // If we do not know anything about the predecessor, do not propagate just
   // yet because we will have to recompute anyway once we compute the
   // predecessor.
   if (from_branch == nullptr) {
     return UpdateConditions(node, nullptr);
   }
   Node* condition = branch->InputAt(0);
   return UpdateConditions(node, from_branch, condition, is_true_branch);
 }


 Reduction BranchElimination::ReduceLoop(Node* node) {
   // Here we rely on having only reducible loops:
   // The loop entry edge always dominates the header, so we can just use
   // the information from the loop entry edge.
   return TakeConditionsFromFirstControl(node);
 }


 Reduction BranchElimination::ReduceMerge(Node* node) {
   // Shortcut for the case when we do not know anything about some
   // input.
   Node::Inputs inputs = node->inputs();
   for (Node* input : inputs) {
     if (node_conditions_.Get(input) == nullptr) {
       return UpdateConditions(node, nullptr);
     }
   }

   auto input_it = inputs.begin();

   DCHECK_GT(inputs.count(), 0);

   const ControlPathConditions* first = node_conditions_.Get(*input_it);
   ++input_it;
   // Make a copy of the first input's conditions and merge with the conditions
   // from other inputs.
   ControlPathConditions* conditions =
       new (zone_->New(sizeof(ControlPathConditions)))
           ControlPathConditions(*first);
   auto input_end = inputs.end();
   for (; input_it != input_end; ++input_it) {
     conditions->Merge(*(node_conditions_.Get(*input_it)));
   }

   return UpdateConditions(node, conditions);
 }


 Reduction BranchElimination::ReduceStart(Node* node) {
   return UpdateConditions(node, ControlPathConditions::Empty(zone_));
 }

 const BranchElimination::ControlPathConditions*
 BranchElimination::PathConditionsForControlNodes::Get(Node* node) const {
   if (static_cast<size_t>(node->id()) < info_for_node_.size()) {
     return info_for_node_[node->id()];
   }
   return nullptr;
 }


 void BranchElimination::PathConditionsForControlNodes::Set(
     Node* node, const ControlPathConditions* conditions) {
   size_t index = static_cast<size_t>(node->id());
   if (index >= info_for_node_.size()) {
     info_for_node_.resize(index + 1, nullptr);
   }
   info_for_node_[index] = conditions;
 }


 Reduction BranchElimination::ReduceOtherControl(Node* node) {
   DCHECK_EQ(1, node->op()->ControlInputCount());
   return TakeConditionsFromFirstControl(node);
 }


 Reduction BranchElimination::TakeConditionsFromFirstControl(Node* node) {
   // We just propagate the information from the control input (ideally,
   // we would only revisit control uses if there is change).
   const ControlPathConditions* from_input =
       node_conditions_.Get(NodeProperties::GetControlInput(node, 0));
   return UpdateConditions(node, from_input);
 }


 Reduction BranchElimination::UpdateConditions(
     Node* node, const ControlPathConditions* conditions) {
   const ControlPathConditions* original = node_conditions_.Get(node);
   // Only signal that the node has Changed if the condition information has
   // changed.
   if (conditions != original) {
     if (conditions == nullptr || original == nullptr ||
         *conditions != *original) {
       node_conditions_.Set(node, conditions);
       return Changed(node);
     }
   }
   return NoChange();
 }

 Reduction BranchElimination::UpdateConditions(
     Node* node, const ControlPathConditions* prev_conditions,
     Node* current_condition, bool is_true_branch) {
   const ControlPathConditions* original = node_conditions_.Get(node);
   DCHECK(prev_conditions != nullptr && current_condition != nullptr);
   // The control path for the node is the path obtained by appending the
   // current_condition to the prev_conditions. Check if this new control path
   // would be the same as the already recorded path (original).
   if (original == nullptr || !prev_conditions->EqualsAfterAddingCondition(
                                  original, current_condition, is_true_branch)) {
     // If this is the first visit or if the control path is different from the
     // recorded path create the new control path and record it.
     const ControlPathConditions* new_condition =
         prev_conditions->AddCondition(zone_, current_condition, is_true_branch);
     node_conditions_.Set(node, new_condition);
     return Changed(node);
   }
   return NoChange();
 }

 // static
 const BranchElimination::ControlPathConditions*
 BranchElimination::ControlPathConditions::Empty(Zone* zone) {
   return new (zone->New(sizeof(ControlPathConditions)))
       ControlPathConditions(nullptr, 0);
 }


 void BranchElimination::ControlPathConditions::Merge(
     const ControlPathConditions& 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.condition_count_;
   BranchCondition* other_condition = other.head_;
   while (other_size > condition_count_) {
     other_condition = other_condition->next;
     other_size--;
   }
   while (condition_count_ > other_size) {
     head_ = head_->next;
     condition_count_--;
   }

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


 const BranchElimination::ControlPathConditions*
 BranchElimination::ControlPathConditions::AddCondition(Zone* zone,
                                                        Node* condition,
                                                        bool is_true) const {
   DCHECK(LookupCondition(condition).IsNothing());

   BranchCondition* new_head = new (zone->New(sizeof(BranchCondition)))
       BranchCondition(condition, is_true, head_);

   ControlPathConditions* conditions =
       new (zone->New(sizeof(ControlPathConditions)))
           ControlPathConditions(new_head, condition_count_ + 1);
   return conditions;
 }


 Maybe<bool> BranchElimination::ControlPathConditions::LookupCondition(
     Node* condition) const {
   for (BranchCondition* current = head_; current != nullptr;
        current = current->next) {
     if (current->condition == condition) {
       return Just<bool>(current->is_true);
     }
   }
   return Nothing<bool>();
 }

 bool BranchElimination::ControlPathConditions::IsSamePath(
     BranchCondition* this_condition, BranchCondition* other_condition) const {
   while (true) {
     if (this_condition == other_condition) return true;
     if (this_condition->condition != other_condition->condition ||
         this_condition->is_true != other_condition->is_true) {
       return false;
     }
     this_condition = this_condition->next;
     other_condition = other_condition->next;
   }
   UNREACHABLE();
 }

 bool BranchElimination::ControlPathConditions::operator==(
     const ControlPathConditions& other) const {
   if (condition_count_ != other.condition_count_) return false;
   return IsSamePath(head_, other.head_);
 }

 bool BranchElimination::ControlPathConditions::EqualsAfterAddingCondition(
     const ControlPathConditions* other, const Node* new_condition,
     bool new_branch_direction) const {
   // When an extra condition is added to the current chain, the count of
   // the resulting chain would increase by 1. Quick check to see if counts
   // match.
   if (other->condition_count_ != condition_count_ + 1) return false;

   // Check if the head of the other chain is same as the new condition that
   // would be added.
   if (other->head_->condition != new_condition ||
       other->head_->is_true != new_branch_direction) {
     return false;
   }

   // Check if the rest of the path is the same as the prev_condition.
   return IsSamePath(other->head_->next, head_);
 }

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

 CommonOperatorBuilder* BranchElimination::common() const {
   return jsgraph()->common();
 }

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8
	// Copyright 2015 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/branch-elimination.h"

	#include "src/compiler/js-graph.h"
	#include "src/compiler/node-properties.h"
	#include "src/compiler/simplified-operator.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	BranchElimination::BranchElimination(Editor* editor, JSGraph* js_graph,
	Zone* zone)
	: AdvancedReducer(editor),
	jsgraph_(js_graph),
	node_conditions_(zone, js_graph->graph()->NodeCount()),
	zone_(zone),
	dead_(js_graph->Dead()) {}

	BranchElimination::~BranchElimination() {}


	Reduction BranchElimination::Reduce(Node* node) {
	switch (node->opcode()) {
	case IrOpcode::kDead:
	return NoChange();
	case IrOpcode::kDeoptimizeIf:
	case IrOpcode::kDeoptimizeUnless:
	return ReduceDeoptimizeConditional(node);
	case IrOpcode::kMerge:
	return ReduceMerge(node);
	case IrOpcode::kLoop:
	return ReduceLoop(node);
	case IrOpcode::kBranch:
	return ReduceBranch(node);
	case IrOpcode::kIfFalse:
	return ReduceIf(node, false);
	case IrOpcode::kIfTrue:
	return ReduceIf(node, true);
	case IrOpcode::kStart:
	return ReduceStart(node);
	default:
	if (node->op()->ControlOutputCount() > 0) {
	return ReduceOtherControl(node);
	}
	break;
	}
	return NoChange();
	}


	Reduction BranchElimination::ReduceBranch(Node* node) {
	Node* condition = node->InputAt(0);
	Node* control_input = NodeProperties::GetControlInput(node, 0);
	const ControlPathConditions* from_input = node_conditions_.Get(control_input);
	if (from_input != nullptr) {
	Maybe<bool> condition_value = from_input->LookupCondition(condition);
	// If we know the condition we can discard the branch.
	if (condition_value.IsJust()) {
	bool known_value = condition_value.FromJust();
	for (Node* const use : node->uses()) {
	switch (use->opcode()) {
	case IrOpcode::kIfTrue:
	Replace(use, known_value ? control_input : dead());
	break;
	case IrOpcode::kIfFalse:
	Replace(use, known_value ? dead() : control_input);
	break;
	default:
	UNREACHABLE();
	}
	}
	return Replace(dead());
	}
	}
	return TakeConditionsFromFirstControl(node);
	}

	Reduction BranchElimination::ReduceDeoptimizeConditional(Node* node) {
	DCHECK(node->opcode() == IrOpcode::kDeoptimizeIf \|\|
	node->opcode() == IrOpcode::kDeoptimizeUnless);
	bool condition_is_true = node->opcode() == IrOpcode::kDeoptimizeUnless;
	DeoptimizeParameters p = DeoptimizeParametersOf(node->op());
	Node* condition = NodeProperties::GetValueInput(node, 0);
	Node* frame_state = NodeProperties::GetValueInput(node, 1);
	Node* effect = NodeProperties::GetEffectInput(node);
	Node* control = NodeProperties::GetControlInput(node);
	ControlPathConditions const* conditions = node_conditions_.Get(control);
	// If we do not know anything about the predecessor, do not propagate just
	// yet because we will have to recompute anyway once we compute the
	// predecessor.
	if (conditions == nullptr) {
	return UpdateConditions(node, conditions);
	}
	Maybe<bool> condition_value = conditions->LookupCondition(condition);
	if (condition_value.IsJust()) {
	// If we know the condition we can discard the branch.
	if (condition_is_true == condition_value.FromJust()) {
	// We don't update the conditions here, because we're replacing {node}
	// with the {control} node that already contains the right information.
	ReplaceWithValue(node, dead(), effect, control);
	} else {
	control = graph()->NewNode(
	common()->Deoptimize(p.kind(), p.reason(), VectorSlotPair()),
	frame_state, effect, control);
	// TODO(bmeurer): This should be on the AdvancedReducer somehow.
	NodeProperties::MergeControlToEnd(graph(), common(), control);
	Revisit(graph()->end());
	}
	return Replace(dead());
	}
	return UpdateConditions(node, conditions, condition, condition_is_true);
	}

	Reduction BranchElimination::ReduceIf(Node* node, bool is_true_branch) {
	// Add the condition to the list arriving from the input branch.
	Node* branch = NodeProperties::GetControlInput(node, 0);
	const ControlPathConditions* from_branch = node_conditions_.Get(branch);
	// If we do not know anything about the predecessor, do not propagate just
	// yet because we will have to recompute anyway once we compute the
	// predecessor.
	if (from_branch == nullptr) {
	return UpdateConditions(node, nullptr);
	}
	Node* condition = branch->InputAt(0);
	return UpdateConditions(node, from_branch, condition, is_true_branch);
	}


	Reduction BranchElimination::ReduceLoop(Node* node) {
	// Here we rely on having only reducible loops:
	// The loop entry edge always dominates the header, so we can just use
	// the information from the loop entry edge.
	return TakeConditionsFromFirstControl(node);
	}


	Reduction BranchElimination::ReduceMerge(Node* node) {
	// Shortcut for the case when we do not know anything about some
	// input.
	Node::Inputs inputs = node->inputs();
	for (Node* input : inputs) {
	if (node_conditions_.Get(input) == nullptr) {
	return UpdateConditions(node, nullptr);
	}
	}

	auto input_it = inputs.begin();

	DCHECK_GT(inputs.count(), 0);

	const ControlPathConditions* first = node_conditions_.Get(*input_it);
	++input_it;
	// Make a copy of the first input's conditions and merge with the conditions
	// from other inputs.
	ControlPathConditions* conditions =
	new (zone_->New(sizeof(ControlPathConditions)))
	ControlPathConditions(*first);
	auto input_end = inputs.end();
	for (; input_it != input_end; ++input_it) {
	conditions->Merge((node_conditions_.Get(input_it)));
	}

	return UpdateConditions(node, conditions);
	}


	Reduction BranchElimination::ReduceStart(Node* node) {
	return UpdateConditions(node, ControlPathConditions::Empty(zone_));
	}

	const BranchElimination::ControlPathConditions*
	BranchElimination::PathConditionsForControlNodes::Get(Node* node) const {
	if (static_cast<size_t>(node->id()) < info_for_node_.size()) {
	return info_for_node_[node->id()];
	}
	return nullptr;
	}


	void BranchElimination::PathConditionsForControlNodes::Set(
	Node* node, const ControlPathConditions* conditions) {
	size_t index = static_cast<size_t>(node->id());
	if (index >= info_for_node_.size()) {
	info_for_node_.resize(index + 1, nullptr);
	}
	info_for_node_[index] = conditions;
	}


	Reduction BranchElimination::ReduceOtherControl(Node* node) {
	DCHECK_EQ(1, node->op()->ControlInputCount());
	return TakeConditionsFromFirstControl(node);
	}


	Reduction BranchElimination::TakeConditionsFromFirstControl(Node* node) {
	// We just propagate the information from the control input (ideally,
	// we would only revisit control uses if there is change).
	const ControlPathConditions* from_input =
	node_conditions_.Get(NodeProperties::GetControlInput(node, 0));
	return UpdateConditions(node, from_input);
	}


	Reduction BranchElimination::UpdateConditions(
	Node* node, const ControlPathConditions* conditions) {
	const ControlPathConditions* original = node_conditions_.Get(node);
	// Only signal that the node has Changed if the condition information has
	// changed.
	if (conditions != original) {
	if (conditions == nullptr \|\| original == nullptr \|\|
	conditions != original) {
	node_conditions_.Set(node, conditions);
	return Changed(node);
	}
	}
	return NoChange();
	}

	Reduction BranchElimination::UpdateConditions(
	Node* node, const ControlPathConditions* prev_conditions,
	Node* current_condition, bool is_true_branch) {
	const ControlPathConditions* original = node_conditions_.Get(node);
	DCHECK(prev_conditions != nullptr && current_condition != nullptr);
	// The control path for the node is the path obtained by appending the
	// current_condition to the prev_conditions. Check if this new control path
	// would be the same as the already recorded path (original).
	if (original == nullptr \|\| !prev_conditions->EqualsAfterAddingCondition(
	original, current_condition, is_true_branch)) {
	// If this is the first visit or if the control path is different from the
	// recorded path create the new control path and record it.
	const ControlPathConditions* new_condition =
	prev_conditions->AddCondition(zone_, current_condition, is_true_branch);
	node_conditions_.Set(node, new_condition);
	return Changed(node);
	}
	return NoChange();
	}

	// static
	const BranchElimination::ControlPathConditions*
	BranchElimination::ControlPathConditions::Empty(Zone* zone) {
	return new (zone->New(sizeof(ControlPathConditions)))
	ControlPathConditions(nullptr, 0);
	}


	void BranchElimination::ControlPathConditions::Merge(
	const ControlPathConditions& 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.condition_count_;
	BranchCondition* other_condition = other.head_;
	while (other_size > condition_count_) {
	other_condition = other_condition->next;
	other_size--;
	}
	while (condition_count_ > other_size) {
	head_ = head_->next;
	condition_count_--;
	}

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


	const BranchElimination::ControlPathConditions*
	BranchElimination::ControlPathConditions::AddCondition(Zone* zone,
	Node* condition,
	bool is_true) const {
	DCHECK(LookupCondition(condition).IsNothing());

	BranchCondition* new_head = new (zone->New(sizeof(BranchCondition)))
	BranchCondition(condition, is_true, head_);

	ControlPathConditions* conditions =
	new (zone->New(sizeof(ControlPathConditions)))
	ControlPathConditions(new_head, condition_count_ + 1);
	return conditions;
	}


	Maybe<bool> BranchElimination::ControlPathConditions::LookupCondition(
	Node* condition) const {
	for (BranchCondition* current = head_; current != nullptr;
	current = current->next) {
	if (current->condition == condition) {
	return Just<bool>(current->is_true);
	}
	}
	return Nothing<bool>();
	}

	bool BranchElimination::ControlPathConditions::IsSamePath(
	BranchCondition* this_condition, BranchCondition* other_condition) const {
	while (true) {
	if (this_condition == other_condition) return true;
	if (this_condition->condition != other_condition->condition \|\|
	this_condition->is_true != other_condition->is_true) {
	return false;
	}
	this_condition = this_condition->next;
	other_condition = other_condition->next;
	}
	UNREACHABLE();
	}

	bool BranchElimination::ControlPathConditions::operator==(
	const ControlPathConditions& other) const {
	if (condition_count_ != other.condition_count_) return false;
	return IsSamePath(head_, other.head_);
	}

	bool BranchElimination::ControlPathConditions::EqualsAfterAddingCondition(
	const ControlPathConditions* other, const Node* new_condition,
	bool new_branch_direction) const {
	// When an extra condition is added to the current chain, the count of
	// the resulting chain would increase by 1. Quick check to see if counts
	// match.
	if (other->condition_count_ != condition_count_ + 1) return false;

	// Check if the head of the other chain is same as the new condition that
	// would be added.
	if (other->head_->condition != new_condition \|\|
	other->head_->is_true != new_branch_direction) {
	return false;
	}

	// Check if the rest of the path is the same as the prev_condition.
	return IsSamePath(other->head_->next, head_);
	}

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

	CommonOperatorBuilder* BranchElimination::common() const {
	return jsgraph()->common();
	}

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