src/compiler/state-values-utils.cc - v8/v8.git - 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/state-values-utils.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 StateValuesCache::StateValuesCache(JSGraph* js_graph)
     : js_graph_(js_graph),
       hash_map_(AreKeysEqual, ZoneHashMap::kDefaultHashMapCapacity,
                 ZoneAllocationPolicy(zone())),
       working_space_(zone()),
       empty_state_values_(nullptr) {}


 // static
 bool StateValuesCache::AreKeysEqual(void* key1, void* key2) {
   NodeKey* node_key1 = reinterpret_cast<NodeKey*>(key1);
   NodeKey* node_key2 = reinterpret_cast<NodeKey*>(key2);

   if (node_key1->node == nullptr) {
     if (node_key2->node == nullptr) {
       return AreValueKeysEqual(reinterpret_cast<StateValuesKey*>(key1),
                                reinterpret_cast<StateValuesKey*>(key2));
     } else {
       return IsKeysEqualToNode(reinterpret_cast<StateValuesKey*>(key1),
                                node_key2->node);
     }
   } else {
     if (node_key2->node == nullptr) {
       // If the nodes are already processed, they must be the same.
       return IsKeysEqualToNode(reinterpret_cast<StateValuesKey*>(key2),
                                node_key1->node);
     } else {
       return node_key1->node == node_key2->node;
     }
   }
   UNREACHABLE();
 }


 // static
 bool StateValuesCache::IsKeysEqualToNode(StateValuesKey* key, Node* node) {
   if (key->count != static_cast<size_t>(node->InputCount())) {
     return false;
   }
   for (size_t i = 0; i < key->count; i++) {
     if (key->values[i] != node->InputAt(static_cast<int>(i))) {
       return false;
     }
   }
   return true;
 }


 // static
 bool StateValuesCache::AreValueKeysEqual(StateValuesKey* key1,
                                          StateValuesKey* key2) {
   if (key1->count != key2->count) {
     return false;
   }
   for (size_t i = 0; i < key1->count; i++) {
     if (key1->values[i] != key2->values[i]) {
       return false;
     }
   }
   return true;
 }


 Node* StateValuesCache::GetEmptyStateValues() {
   if (empty_state_values_ == nullptr) {
     empty_state_values_ = graph()->NewNode(common()->StateValues(0));
   }
   return empty_state_values_;
 }


 NodeVector* StateValuesCache::GetWorkingSpace(size_t level) {
   while (working_space_.size() <= level) {
     void* space = zone()->New(sizeof(NodeVector));
     working_space_.push_back(new (space)
                                  NodeVector(kMaxInputCount, nullptr, zone()));
   }
   return working_space_[level];
 }

 namespace {

 int StateValuesHashKey(Node** nodes, size_t count) {
   size_t hash = count;
   for (size_t i = 0; i < count; i++) {
     hash = hash * 23 + nodes[i]->id();
   }
   return static_cast<int>(hash & 0x7fffffff);
 }

 }  // namespace


 Node* StateValuesCache::GetValuesNodeFromCache(Node** nodes, size_t count) {
   StateValuesKey key(count, nodes);
   int hash = StateValuesHashKey(nodes, count);
   ZoneHashMap::Entry* lookup =
       hash_map_.LookupOrInsert(&key, hash, ZoneAllocationPolicy(zone()));
   DCHECK_NOT_NULL(lookup);
   Node* node;
   if (lookup->value == nullptr) {
     int input_count = static_cast<int>(count);
     node = graph()->NewNode(common()->StateValues(input_count), input_count,
                             nodes);
     NodeKey* new_key = new (zone()->New(sizeof(NodeKey))) NodeKey(node);
     lookup->key = new_key;
     lookup->value = node;
   } else {
     node = reinterpret_cast<Node*>(lookup->value);
   }
   return node;
 }


 class StateValuesCache::ValueArrayIterator {
  public:
   ValueArrayIterator(Node** values, size_t count)
       : values_(values), count_(count), current_(0) {}

   void Advance() {
     if (!done()) {
       current_++;
     }
   }

   bool done() { return current_ >= count_; }

   Node* node() {
     DCHECK(!done());
     return values_[current_];
   }

  private:
   Node** values_;
   size_t count_;
   size_t current_;
 };


 Node* StateValuesCache::BuildTree(ValueArrayIterator* it, size_t max_height) {
   if (max_height == 0) {
     Node* node = it->node();
     it->Advance();
     return node;
   }
   DCHECK(!it->done());

   NodeVector* buffer = GetWorkingSpace(max_height);
   size_t count = 0;
   for (; count < kMaxInputCount; count++) {
     if (it->done()) break;
     (*buffer)[count] = BuildTree(it, max_height - 1);
   }
   if (count == 1) {
     return (*buffer)[0];
   } else {
     return GetValuesNodeFromCache(&(buffer->front()), count);
   }
 }


 Node* StateValuesCache::GetNodeForValues(Node** values, size_t count) {
 #if DEBUG
   for (size_t i = 0; i < count; i++) {
     DCHECK_NE(values[i]->opcode(), IrOpcode::kStateValues);
     DCHECK_NE(values[i]->opcode(), IrOpcode::kTypedStateValues);
   }
 #endif
   if (count == 0) {
     return GetEmptyStateValues();
   }
   size_t height = 0;
   size_t max_nodes = 1;
   while (count > max_nodes) {
     height++;
     max_nodes *= kMaxInputCount;
   }

   ValueArrayIterator it(values, count);

   Node* tree = BuildTree(&it, height);

   // If the 'tree' is a single node, equip it with a StateValues wrapper.
   if (tree->opcode() != IrOpcode::kStateValues &&
       tree->opcode() != IrOpcode::kTypedStateValues) {
     tree = GetValuesNodeFromCache(&tree, 1);
   }

   return tree;
 }


 StateValuesAccess::iterator::iterator(Node* node) : current_depth_(0) {
   // A hacky way initialize - just set the index before the node we want
   // to process and then advance to it.
   stack_[current_depth_].node = node;
   stack_[current_depth_].index = -1;
   Advance();
 }


 StateValuesAccess::iterator::StatePos* StateValuesAccess::iterator::Top() {
   DCHECK(current_depth_ >= 0);
   DCHECK(current_depth_ < kMaxInlineDepth);
   return &(stack_[current_depth_]);
 }


 void StateValuesAccess::iterator::Push(Node* node) {
   current_depth_++;
   CHECK(current_depth_ < kMaxInlineDepth);
   stack_[current_depth_].node = node;
   stack_[current_depth_].index = 0;
 }


 void StateValuesAccess::iterator::Pop() {
   DCHECK(current_depth_ >= 0);
   current_depth_--;
 }


 bool StateValuesAccess::iterator::done() { return current_depth_ < 0; }


 void StateValuesAccess::iterator::Advance() {
   // Advance the current index.
   Top()->index++;

   // Fix up the position to point to a valid node.
   while (true) {
     // TODO(jarin): Factor to a separate method.
     Node* node = Top()->node;
     int index = Top()->index;

     if (index >= node->InputCount()) {
       // Pop stack and move to the next sibling.
       Pop();
       if (done()) {
         // Stack is exhausted, we have reached the end.
         return;
       }
       Top()->index++;
     } else if (node->InputAt(index)->opcode() == IrOpcode::kStateValues ||
                node->InputAt(index)->opcode() == IrOpcode::kTypedStateValues) {
       // Nested state, we need to push to the stack.
       Push(node->InputAt(index));
     } else {
       // We are on a valid node, we can stop the iteration.
       return;
     }
   }
 }


 Node* StateValuesAccess::iterator::node() {
   return Top()->node->InputAt(Top()->index);
 }


 MachineType StateValuesAccess::iterator::type() {
   Node* state = Top()->node;
   if (state->opcode() == IrOpcode::kStateValues) {
     return MachineType::AnyTagged();
   } else {
     DCHECK_EQ(IrOpcode::kTypedStateValues, state->opcode());
     const ZoneVector<MachineType>* types =
         OpParameter<const ZoneVector<MachineType>*>(state);
     return (*types)[Top()->index];
   }
 }


 bool StateValuesAccess::iterator::operator!=(iterator& other) {
   // We only allow comparison with end().
   CHECK(other.done());
   return !done();
 }


 StateValuesAccess::iterator& StateValuesAccess::iterator::operator++() {
   Advance();
   return *this;
 }


 StateValuesAccess::TypedNode StateValuesAccess::iterator::operator*() {
   return TypedNode(node(), type());
 }


 size_t StateValuesAccess::size() {
   size_t count = 0;
   for (int i = 0; i < node_->InputCount(); i++) {
     if (node_->InputAt(i)->opcode() == IrOpcode::kStateValues ||
         node_->InputAt(i)->opcode() == IrOpcode::kTypedStateValues) {
       count += StateValuesAccess(node_->InputAt(i)).size();
     } else {
       count++;
     }
   }
   return count;
 }

 }  // 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/state-values-utils.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	StateValuesCache::StateValuesCache(JSGraph* js_graph)
	: js_graph_(js_graph),
	hash_map_(AreKeysEqual, ZoneHashMap::kDefaultHashMapCapacity,
	ZoneAllocationPolicy(zone())),
	working_space_(zone()),
	empty_state_values_(nullptr) {}


	// static
	bool StateValuesCache::AreKeysEqual(void* key1, void* key2) {
	NodeKey* node_key1 = reinterpret_cast<NodeKey*>(key1);
	NodeKey* node_key2 = reinterpret_cast<NodeKey*>(key2);

	if (node_key1->node == nullptr) {
	if (node_key2->node == nullptr) {
	return AreValueKeysEqual(reinterpret_cast<StateValuesKey*>(key1),
	reinterpret_cast<StateValuesKey*>(key2));
	} else {
	return IsKeysEqualToNode(reinterpret_cast<StateValuesKey*>(key1),
	node_key2->node);
	}
	} else {
	if (node_key2->node == nullptr) {
	// If the nodes are already processed, they must be the same.
	return IsKeysEqualToNode(reinterpret_cast<StateValuesKey*>(key2),
	node_key1->node);
	} else {
	return node_key1->node == node_key2->node;
	}
	}
	UNREACHABLE();
	}


	// static
	bool StateValuesCache::IsKeysEqualToNode(StateValuesKey* key, Node* node) {
	if (key->count != static_cast<size_t>(node->InputCount())) {
	return false;
	}
	for (size_t i = 0; i < key->count; i++) {
	if (key->values[i] != node->InputAt(static_cast<int>(i))) {
	return false;
	}
	}
	return true;
	}


	// static
	bool StateValuesCache::AreValueKeysEqual(StateValuesKey* key1,
	StateValuesKey* key2) {
	if (key1->count != key2->count) {
	return false;
	}
	for (size_t i = 0; i < key1->count; i++) {
	if (key1->values[i] != key2->values[i]) {
	return false;
	}
	}
	return true;
	}


	Node* StateValuesCache::GetEmptyStateValues() {
	if (empty_state_values_ == nullptr) {
	empty_state_values_ = graph()->NewNode(common()->StateValues(0));
	}
	return empty_state_values_;
	}


	NodeVector* StateValuesCache::GetWorkingSpace(size_t level) {
	while (working_space_.size() <= level) {
	void* space = zone()->New(sizeof(NodeVector));
	working_space_.push_back(new (space)
	NodeVector(kMaxInputCount, nullptr, zone()));
	}
	return working_space_[level];
	}

	namespace {

	int StateValuesHashKey(Node** nodes, size_t count) {
	size_t hash = count;
	for (size_t i = 0; i < count; i++) {
	hash = hash * 23 + nodes[i]->id();
	}
	return static_cast<int>(hash & 0x7fffffff);
	}

	} // namespace


	Node* StateValuesCache::GetValuesNodeFromCache(Node** nodes, size_t count) {
	StateValuesKey key(count, nodes);
	int hash = StateValuesHashKey(nodes, count);
	ZoneHashMap::Entry* lookup =
	hash_map_.LookupOrInsert(&key, hash, ZoneAllocationPolicy(zone()));
	DCHECK_NOT_NULL(lookup);
	Node* node;
	if (lookup->value == nullptr) {
	int input_count = static_cast<int>(count);
	node = graph()->NewNode(common()->StateValues(input_count), input_count,
	nodes);
	NodeKey* new_key = new (zone()->New(sizeof(NodeKey))) NodeKey(node);
	lookup->key = new_key;
	lookup->value = node;
	} else {
	node = reinterpret_cast<Node*>(lookup->value);
	}
	return node;
	}


	class StateValuesCache::ValueArrayIterator {
	public:
	ValueArrayIterator(Node** values, size_t count)
	: values_(values), count_(count), current_(0) {}

	void Advance() {
	if (!done()) {
	current_++;
	}
	}

	bool done() { return current_ >= count_; }

	Node* node() {
	DCHECK(!done());
	return values_[current_];
	}

	private:
	Node** values_;
	size_t count_;
	size_t current_;
	};


	Node* StateValuesCache::BuildTree(ValueArrayIterator* it, size_t max_height) {
	if (max_height == 0) {
	Node* node = it->node();
	it->Advance();
	return node;
	}
	DCHECK(!it->done());

	NodeVector* buffer = GetWorkingSpace(max_height);
	size_t count = 0;
	for (; count < kMaxInputCount; count++) {
	if (it->done()) break;
	(*buffer)[count] = BuildTree(it, max_height - 1);
	}
	if (count == 1) {
	return (*buffer)[0];
	} else {
	return GetValuesNodeFromCache(&(buffer->front()), count);
	}
	}


	Node* StateValuesCache::GetNodeForValues(Node** values, size_t count) {
	#if DEBUG
	for (size_t i = 0; i < count; i++) {
	DCHECK_NE(values[i]->opcode(), IrOpcode::kStateValues);
	DCHECK_NE(values[i]->opcode(), IrOpcode::kTypedStateValues);
	}
	#endif
	if (count == 0) {
	return GetEmptyStateValues();
	}
	size_t height = 0;
	size_t max_nodes = 1;
	while (count > max_nodes) {
	height++;
	max_nodes *= kMaxInputCount;
	}

	ValueArrayIterator it(values, count);

	Node* tree = BuildTree(&it, height);

	// If the 'tree' is a single node, equip it with a StateValues wrapper.
	if (tree->opcode() != IrOpcode::kStateValues &&
	tree->opcode() != IrOpcode::kTypedStateValues) {
	tree = GetValuesNodeFromCache(&tree, 1);
	}

	return tree;
	}


	StateValuesAccess::iterator::iterator(Node* node) : current_depth_(0) {
	// A hacky way initialize - just set the index before the node we want
	// to process and then advance to it.
	stack_[current_depth_].node = node;
	stack_[current_depth_].index = -1;
	Advance();
	}


	StateValuesAccess::iterator::StatePos* StateValuesAccess::iterator::Top() {
	DCHECK(current_depth_ >= 0);
	DCHECK(current_depth_ < kMaxInlineDepth);
	return &(stack_[current_depth_]);
	}


	void StateValuesAccess::iterator::Push(Node* node) {
	current_depth_++;
	CHECK(current_depth_ < kMaxInlineDepth);
	stack_[current_depth_].node = node;
	stack_[current_depth_].index = 0;
	}


	void StateValuesAccess::iterator::Pop() {
	DCHECK(current_depth_ >= 0);
	current_depth_--;
	}


	bool StateValuesAccess::iterator::done() { return current_depth_ < 0; }


	void StateValuesAccess::iterator::Advance() {
	// Advance the current index.
	Top()->index++;

	// Fix up the position to point to a valid node.
	while (true) {
	// TODO(jarin): Factor to a separate method.
	Node* node = Top()->node;
	int index = Top()->index;

	if (index >= node->InputCount()) {
	// Pop stack and move to the next sibling.
	Pop();
	if (done()) {
	// Stack is exhausted, we have reached the end.
	return;
	}
	Top()->index++;
	} else if (node->InputAt(index)->opcode() == IrOpcode::kStateValues \|\|
	node->InputAt(index)->opcode() == IrOpcode::kTypedStateValues) {
	// Nested state, we need to push to the stack.
	Push(node->InputAt(index));
	} else {
	// We are on a valid node, we can stop the iteration.
	return;
	}
	}
	}


	Node* StateValuesAccess::iterator::node() {
	return Top()->node->InputAt(Top()->index);
	}


	MachineType StateValuesAccess::iterator::type() {
	Node* state = Top()->node;
	if (state->opcode() == IrOpcode::kStateValues) {
	return MachineType::AnyTagged();
	} else {
	DCHECK_EQ(IrOpcode::kTypedStateValues, state->opcode());
	const ZoneVector<MachineType>* types =
	OpParameter<const ZoneVector<MachineType>*>(state);
	return (*types)[Top()->index];
	}
	}


	bool StateValuesAccess::iterator::operator!=(iterator& other) {
	// We only allow comparison with end().
	CHECK(other.done());
	return !done();
	}


	StateValuesAccess::iterator& StateValuesAccess::iterator::operator++() {
	Advance();
	return *this;
	}


	StateValuesAccess::TypedNode StateValuesAccess::iterator::operator*() {
	return TypedNode(node(), type());
	}


	size_t StateValuesAccess::size() {
	size_t count = 0;
	for (int i = 0; i < node_->InputCount(); i++) {
	if (node_->InputAt(i)->opcode() == IrOpcode::kStateValues \|\|
	node_->InputAt(i)->opcode() == IrOpcode::kTypedStateValues) {
	count += StateValuesAccess(node_->InputAt(i)).size();
	} else {
	count++;
	}
	}
	return count;
	}

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