src/hashmap.h - platform/external/chromium_org/v8 - Git at Google

 // Copyright 2012 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.

 #ifndef V8_HASHMAP_H_
 #define V8_HASHMAP_H_

 #include "src/allocation.h"
 #include "src/base/bits.h"
 #include "src/base/logging.h"
 #include "src/utils.h"

 namespace v8 {
 namespace internal {

 template<class AllocationPolicy>
 class TemplateHashMapImpl {
  public:
   typedef bool (*MatchFun) (void* key1, void* key2);

   // The default capacity.  This is used by the call sites which want
   // to pass in a non-default AllocationPolicy but want to use the
   // default value of capacity specified by the implementation.
   static const uint32_t kDefaultHashMapCapacity = 8;

   // initial_capacity is the size of the initial hash map;
   // it must be a power of 2 (and thus must not be 0).
   TemplateHashMapImpl(MatchFun match,
                       uint32_t capacity = kDefaultHashMapCapacity,
                       AllocationPolicy allocator = AllocationPolicy());

   ~TemplateHashMapImpl();

   // HashMap entries are (key, value, hash) triplets.
   // Some clients may not need to use the value slot
   // (e.g. implementers of sets, where the key is the value).
   struct Entry {
     void* key;
     void* value;
     uint32_t hash;  // The full hash value for key
     int order;  // If you never remove entries this is the insertion order.
   };

   // If an entry with matching key is found, Lookup()
   // returns that entry. If no matching entry is found,
   // but insert is set, a new entry is inserted with
   // corresponding key, key hash, and NULL value.
   // Otherwise, NULL is returned.
   Entry* Lookup(void* key, uint32_t hash, bool insert,
                 AllocationPolicy allocator = AllocationPolicy());

   // Removes the entry with matching key.
   // It returns the value of the deleted entry
   // or null if there is no value for such key.
   void* Remove(void* key, uint32_t hash);

   // Empties the hash map (occupancy() == 0).
   void Clear();

   // The number of (non-empty) entries in the table.
   uint32_t occupancy() const { return occupancy_; }

   // The capacity of the table. The implementation
   // makes sure that occupancy is at most 80% of
   // the table capacity.
   uint32_t capacity() const { return capacity_; }

   // Iteration
   //
   // for (Entry* p = map.Start(); p != NULL; p = map.Next(p)) {
   //   ...
   // }
   //
   // If entries are inserted during iteration, the effect of
   // calling Next() is undefined.
   Entry* Start() const;
   Entry* Next(Entry* p) const;

   // Some match functions defined for convenience.
   static bool PointersMatch(void* key1, void* key2) {
     return key1 == key2;
   }

  private:
   MatchFun match_;
   Entry* map_;
   uint32_t capacity_;
   uint32_t occupancy_;

   Entry* map_end() const { return map_ + capacity_; }
   Entry* Probe(void* key, uint32_t hash);
   void Initialize(uint32_t capacity, AllocationPolicy allocator);
   void Resize(AllocationPolicy allocator);
 };

 typedef TemplateHashMapImpl<FreeStoreAllocationPolicy> HashMap;

 template<class AllocationPolicy>
 TemplateHashMapImpl<AllocationPolicy>::TemplateHashMapImpl(
     MatchFun match, uint32_t initial_capacity, AllocationPolicy allocator) {
   match_ = match;
   Initialize(initial_capacity, allocator);
 }


 template<class AllocationPolicy>
 TemplateHashMapImpl<AllocationPolicy>::~TemplateHashMapImpl() {
   AllocationPolicy::Delete(map_);
 }


 template<class AllocationPolicy>
 typename TemplateHashMapImpl<AllocationPolicy>::Entry*
 TemplateHashMapImpl<AllocationPolicy>::Lookup(
     void* key, uint32_t hash, bool insert, AllocationPolicy allocator) {
   // Find a matching entry.
   Entry* p = Probe(key, hash);
   if (p->key != NULL) {
     return p;
   }

   // No entry found; insert one if necessary.
   if (insert) {
     p->key = key;
     p->value = NULL;
     p->hash = hash;
     p->order = occupancy_;
     occupancy_++;

     // Grow the map if we reached >= 80% occupancy.
     if (occupancy_ + occupancy_/4 >= capacity_) {
       Resize(allocator);
       p = Probe(key, hash);
     }

     return p;
   }

   // No entry found and none inserted.
   return NULL;
 }


 template<class AllocationPolicy>
 void* TemplateHashMapImpl<AllocationPolicy>::Remove(void* key, uint32_t hash) {
   // Lookup the entry for the key to remove.
   Entry* p = Probe(key, hash);
   if (p->key == NULL) {
     // Key not found nothing to remove.
     return NULL;
   }

   void* value = p->value;
   // To remove an entry we need to ensure that it does not create an empty
   // entry that will cause the search for another entry to stop too soon. If all
   // the entries between the entry to remove and the next empty slot have their
   // initial position inside this interval, clearing the entry to remove will
   // not break the search. If, while searching for the next empty entry, an
   // entry is encountered which does not have its initial position between the
   // entry to remove and the position looked at, then this entry can be moved to
   // the place of the entry to remove without breaking the search for it. The
   // entry made vacant by this move is now the entry to remove and the process
   // starts over.
   // Algorithm from http://en.wikipedia.org/wiki/Open_addressing.

   // This guarantees loop termination as there is at least one empty entry so
   // eventually the removed entry will have an empty entry after it.
   DCHECK(occupancy_ < capacity_);

   // p is the candidate entry to clear. q is used to scan forwards.
   Entry* q = p;  // Start at the entry to remove.
   while (true) {
     // Move q to the next entry.
     q = q + 1;
     if (q == map_end()) {
       q = map_;
     }

     // All entries between p and q have their initial position between p and q
     // and the entry p can be cleared without breaking the search for these
     // entries.
     if (q->key == NULL) {
       break;
     }

     // Find the initial position for the entry at position q.
     Entry* r = map_ + (q->hash & (capacity_ - 1));

     // If the entry at position q has its initial position outside the range
     // between p and q it can be moved forward to position p and will still be
     // found. There is now a new candidate entry for clearing.
     if ((q > p && (r <= p || r > q)) ||
         (q < p && (r <= p && r > q))) {
       *p = *q;
       p = q;
     }
   }

   // Clear the entry which is allowed to en emptied.
   p->key = NULL;
   occupancy_--;
   return value;
 }


 template<class AllocationPolicy>
 void TemplateHashMapImpl<AllocationPolicy>::Clear() {
   // Mark all entries as empty.
   const Entry* end = map_end();
   for (Entry* p = map_; p < end; p++) {
     p->key = NULL;
   }
   occupancy_ = 0;
 }


 template<class AllocationPolicy>
 typename TemplateHashMapImpl<AllocationPolicy>::Entry*
     TemplateHashMapImpl<AllocationPolicy>::Start() const {
   return Next(map_ - 1);
 }


 template<class AllocationPolicy>
 typename TemplateHashMapImpl<AllocationPolicy>::Entry*
     TemplateHashMapImpl<AllocationPolicy>::Next(Entry* p) const {
   const Entry* end = map_end();
   DCHECK(map_ - 1 <= p && p < end);
   for (p++; p < end; p++) {
     if (p->key != NULL) {
       return p;
     }
   }
   return NULL;
 }


 template<class AllocationPolicy>
 typename TemplateHashMapImpl<AllocationPolicy>::Entry*
     TemplateHashMapImpl<AllocationPolicy>::Probe(void* key, uint32_t hash) {
   DCHECK(key != NULL);

   DCHECK(base::bits::IsPowerOfTwo32(capacity_));
   Entry* p = map_ + (hash & (capacity_ - 1));
   const Entry* end = map_end();
   DCHECK(map_ <= p && p < end);

   DCHECK(occupancy_ < capacity_);  // Guarantees loop termination.
   while (p->key != NULL && (hash != p->hash || !match_(key, p->key))) {
     p++;
     if (p >= end) {
       p = map_;
     }
   }

   return p;
 }


 template<class AllocationPolicy>
 void TemplateHashMapImpl<AllocationPolicy>::Initialize(
     uint32_t capacity, AllocationPolicy allocator) {
   DCHECK(base::bits::IsPowerOfTwo32(capacity));
   map_ = reinterpret_cast<Entry*>(allocator.New(capacity * sizeof(Entry)));
   if (map_ == NULL) {
     v8::internal::FatalProcessOutOfMemory("HashMap::Initialize");
     return;
   }
   capacity_ = capacity;
   Clear();
 }


 template<class AllocationPolicy>
 void TemplateHashMapImpl<AllocationPolicy>::Resize(AllocationPolicy allocator) {
   Entry* map = map_;
   uint32_t n = occupancy_;

   // Allocate larger map.
   Initialize(capacity_ * 2, allocator);

   // Rehash all current entries.
   for (Entry* p = map; n > 0; p++) {
     if (p->key != NULL) {
       Entry* entry = Lookup(p->key, p->hash, true, allocator);
       entry->value = p->value;
       entry->order = p->order;
       n--;
     }
   }

   // Delete old map.
   AllocationPolicy::Delete(map);
 }


 // A hash map for pointer keys and values with an STL-like interface.
 template<class Key, class Value, class AllocationPolicy>
 class TemplateHashMap: private TemplateHashMapImpl<AllocationPolicy> {
  public:
   STATIC_ASSERT(sizeof(Key*) == sizeof(void*));  // NOLINT
   STATIC_ASSERT(sizeof(Value*) == sizeof(void*));  // NOLINT
   struct value_type {
     Key* first;
     Value* second;
   };

   class Iterator {
    public:
     Iterator& operator++() {
       entry_ = map_->Next(entry_);
       return *this;
     }

     value_type* operator->() { return reinterpret_cast<value_type*>(entry_); }
     bool operator!=(const Iterator& other) { return  entry_ != other.entry_; }

    private:
     Iterator(const TemplateHashMapImpl<AllocationPolicy>* map,
              typename TemplateHashMapImpl<AllocationPolicy>::Entry* entry) :
         map_(map), entry_(entry) { }

     const TemplateHashMapImpl<AllocationPolicy>* map_;
     typename TemplateHashMapImpl<AllocationPolicy>::Entry* entry_;

     friend class TemplateHashMap;
   };

   TemplateHashMap(
       typename TemplateHashMapImpl<AllocationPolicy>::MatchFun match,
       AllocationPolicy allocator = AllocationPolicy())
         : TemplateHashMapImpl<AllocationPolicy>(
             match,
             TemplateHashMapImpl<AllocationPolicy>::kDefaultHashMapCapacity,
             allocator) { }

   Iterator begin() const { return Iterator(this, this->Start()); }
   Iterator end() const { return Iterator(this, NULL); }
   Iterator find(Key* key, bool insert = false,
                 AllocationPolicy allocator = AllocationPolicy()) {
     return Iterator(this, this->Lookup(key, key->Hash(), insert, allocator));
   }
 };

 } }  // namespace v8::internal

 #endif  // V8_HASHMAP_H_
	// Copyright 2012 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.

	#ifndef V8_HASHMAP_H_
	#define V8_HASHMAP_H_

	#include "src/allocation.h"
	#include "src/base/bits.h"
	#include "src/base/logging.h"
	#include "src/utils.h"

	namespace v8 {
	namespace internal {

	template<class AllocationPolicy>
	class TemplateHashMapImpl {
	public:
	typedef bool (MatchFun) (void key1, void* key2);

	// The default capacity. This is used by the call sites which want
	// to pass in a non-default AllocationPolicy but want to use the
	// default value of capacity specified by the implementation.
	static const uint32_t kDefaultHashMapCapacity = 8;

	// initial_capacity is the size of the initial hash map;
	// it must be a power of 2 (and thus must not be 0).
	TemplateHashMapImpl(MatchFun match,
	uint32_t capacity = kDefaultHashMapCapacity,
	AllocationPolicy allocator = AllocationPolicy());

	~TemplateHashMapImpl();

	// HashMap entries are (key, value, hash) triplets.
	// Some clients may not need to use the value slot
	// (e.g. implementers of sets, where the key is the value).
	struct Entry {
	void* key;
	void* value;
	uint32_t hash; // The full hash value for key
	int order; // If you never remove entries this is the insertion order.
	};

	// If an entry with matching key is found, Lookup()
	// returns that entry. If no matching entry is found,
	// but insert is set, a new entry is inserted with
	// corresponding key, key hash, and NULL value.
	// Otherwise, NULL is returned.
	Entry* Lookup(void* key, uint32_t hash, bool insert,
	AllocationPolicy allocator = AllocationPolicy());

	// Removes the entry with matching key.
	// It returns the value of the deleted entry
	// or null if there is no value for such key.
	void* Remove(void* key, uint32_t hash);

	// Empties the hash map (occupancy() == 0).
	void Clear();

	// The number of (non-empty) entries in the table.
	uint32_t occupancy() const { return occupancy_; }

	// The capacity of the table. The implementation
	// makes sure that occupancy is at most 80% of
	// the table capacity.
	uint32_t capacity() const { return capacity_; }

	// Iteration
	//
	// for (Entry* p = map.Start(); p != NULL; p = map.Next(p)) {
	// ...
	// }
	//
	// If entries are inserted during iteration, the effect of
	// calling Next() is undefined.
	Entry* Start() const;
	Entry* Next(Entry* p) const;

	// Some match functions defined for convenience.
	static bool PointersMatch(void* key1, void* key2) {
	return key1 == key2;
	}

	private:
	MatchFun match_;
	Entry* map_;
	uint32_t capacity_;
	uint32_t occupancy_;

	Entry* map_end() const { return map_ + capacity_; }
	Entry* Probe(void* key, uint32_t hash);
	void Initialize(uint32_t capacity, AllocationPolicy allocator);
	void Resize(AllocationPolicy allocator);
	};

	typedef TemplateHashMapImpl<FreeStoreAllocationPolicy> HashMap;

	template<class AllocationPolicy>
	TemplateHashMapImpl<AllocationPolicy>::TemplateHashMapImpl(
	MatchFun match, uint32_t initial_capacity, AllocationPolicy allocator) {
	match_ = match;
	Initialize(initial_capacity, allocator);
	}


	template<class AllocationPolicy>
	TemplateHashMapImpl<AllocationPolicy>::~TemplateHashMapImpl() {
	AllocationPolicy::Delete(map_);
	}


	template<class AllocationPolicy>
	typename TemplateHashMapImpl<AllocationPolicy>::Entry*
	TemplateHashMapImpl<AllocationPolicy>::Lookup(
	void* key, uint32_t hash, bool insert, AllocationPolicy allocator) {
	// Find a matching entry.
	Entry* p = Probe(key, hash);
	if (p->key != NULL) {
	return p;
	}

	// No entry found; insert one if necessary.
	if (insert) {
	p->key = key;
	p->value = NULL;
	p->hash = hash;
	p->order = occupancy_;
	occupancy_++;

	// Grow the map if we reached >= 80% occupancy.
	if (occupancy_ + occupancy_/4 >= capacity_) {
	Resize(allocator);
	p = Probe(key, hash);
	}

	return p;
	}

	// No entry found and none inserted.
	return NULL;
	}


	template<class AllocationPolicy>
	void* TemplateHashMapImpl<AllocationPolicy>::Remove(void* key, uint32_t hash) {
	// Lookup the entry for the key to remove.
	Entry* p = Probe(key, hash);
	if (p->key == NULL) {
	// Key not found nothing to remove.
	return NULL;
	}

	void* value = p->value;
	// To remove an entry we need to ensure that it does not create an empty
	// entry that will cause the search for another entry to stop too soon. If all
	// the entries between the entry to remove and the next empty slot have their
	// initial position inside this interval, clearing the entry to remove will
	// not break the search. If, while searching for the next empty entry, an
	// entry is encountered which does not have its initial position between the
	// entry to remove and the position looked at, then this entry can be moved to
	// the place of the entry to remove without breaking the search for it. The
	// entry made vacant by this move is now the entry to remove and the process
	// starts over.
	// Algorithm from http://en.wikipedia.org/wiki/Open_addressing.

	// This guarantees loop termination as there is at least one empty entry so
	// eventually the removed entry will have an empty entry after it.
	DCHECK(occupancy_ < capacity_);

	// p is the candidate entry to clear. q is used to scan forwards.
	Entry* q = p; // Start at the entry to remove.
	while (true) {
	// Move q to the next entry.
	q = q + 1;
	if (q == map_end()) {
	q = map_;
	}

	// All entries between p and q have their initial position between p and q
	// and the entry p can be cleared without breaking the search for these
	// entries.
	if (q->key == NULL) {
	break;
	}

	// Find the initial position for the entry at position q.
	Entry* r = map_ + (q->hash & (capacity_ - 1));

	// If the entry at position q has its initial position outside the range
	// between p and q it can be moved forward to position p and will still be
	// found. There is now a new candidate entry for clearing.
	if ((q > p && (r <= p \|\| r > q)) \|\|
	(q < p && (r <= p && r > q))) {
	p = q;
	p = q;
	}
	}

	// Clear the entry which is allowed to en emptied.
	p->key = NULL;
	occupancy_--;
	return value;
	}


	template<class AllocationPolicy>
	void TemplateHashMapImpl<AllocationPolicy>::Clear() {
	// Mark all entries as empty.
	const Entry* end = map_end();
	for (Entry* p = map_; p < end; p++) {
	p->key = NULL;
	}
	occupancy_ = 0;
	}


	template<class AllocationPolicy>
	typename TemplateHashMapImpl<AllocationPolicy>::Entry*
	TemplateHashMapImpl<AllocationPolicy>::Start() const {
	return Next(map_ - 1);
	}


	template<class AllocationPolicy>
	typename TemplateHashMapImpl<AllocationPolicy>::Entry*
	TemplateHashMapImpl<AllocationPolicy>::Next(Entry* p) const {
	const Entry* end = map_end();
	DCHECK(map_ - 1 <= p && p < end);
	for (p++; p < end; p++) {
	if (p->key != NULL) {
	return p;
	}
	}
	return NULL;
	}


	template<class AllocationPolicy>
	typename TemplateHashMapImpl<AllocationPolicy>::Entry*
	TemplateHashMapImpl<AllocationPolicy>::Probe(void* key, uint32_t hash) {
	DCHECK(key != NULL);

	DCHECK(base::bits::IsPowerOfTwo32(capacity_));
	Entry* p = map_ + (hash & (capacity_ - 1));
	const Entry* end = map_end();
	DCHECK(map_ <= p && p < end);

	DCHECK(occupancy_ < capacity_); // Guarantees loop termination.
	while (p->key != NULL && (hash != p->hash \|\| !match_(key, p->key))) {
	p++;
	if (p >= end) {
	p = map_;
	}
	}

	return p;
	}


	template<class AllocationPolicy>
	void TemplateHashMapImpl<AllocationPolicy>::Initialize(
	uint32_t capacity, AllocationPolicy allocator) {
	DCHECK(base::bits::IsPowerOfTwo32(capacity));
	map_ = reinterpret_cast<Entry>(allocator.New(capacity sizeof(Entry)));
	if (map_ == NULL) {
	v8::internal::FatalProcessOutOfMemory("HashMap::Initialize");
	return;
	}
	capacity_ = capacity;
	Clear();
	}


	template<class AllocationPolicy>
	void TemplateHashMapImpl<AllocationPolicy>::Resize(AllocationPolicy allocator) {
	Entry* map = map_;
	uint32_t n = occupancy_;

	// Allocate larger map.
	Initialize(capacity_ * 2, allocator);

	// Rehash all current entries.
	for (Entry* p = map; n > 0; p++) {
	if (p->key != NULL) {
	Entry* entry = Lookup(p->key, p->hash, true, allocator);
	entry->value = p->value;
	entry->order = p->order;
	n--;
	}
	}

	// Delete old map.
	AllocationPolicy::Delete(map);
	}


	// A hash map for pointer keys and values with an STL-like interface.
	template<class Key, class Value, class AllocationPolicy>
	class TemplateHashMap: private TemplateHashMapImpl<AllocationPolicy> {
	public:
	STATIC_ASSERT(sizeof(Key) == sizeof(void)); // NOLINT
	STATIC_ASSERT(sizeof(Value) == sizeof(void)); // NOLINT
	struct value_type {
	Key* first;
	Value* second;
	};

	class Iterator {
	public:
	Iterator& operator++() {
	entry_ = map_->Next(entry_);
	return *this;
	}

	value_type* operator->() { return reinterpret_cast<value_type*>(entry_); }
	bool operator!=(const Iterator& other) { return entry_ != other.entry_; }

	private:
	Iterator(const TemplateHashMapImpl<AllocationPolicy>* map,
	typename TemplateHashMapImpl<AllocationPolicy>::Entry* entry) :
	map_(map), entry_(entry) { }

	const TemplateHashMapImpl<AllocationPolicy>* map_;
	typename TemplateHashMapImpl<AllocationPolicy>::Entry* entry_;

	friend class TemplateHashMap;
	};

	TemplateHashMap(
	typename TemplateHashMapImpl<AllocationPolicy>::MatchFun match,
	AllocationPolicy allocator = AllocationPolicy())
	: TemplateHashMapImpl<AllocationPolicy>(
	match,
	TemplateHashMapImpl<AllocationPolicy>::kDefaultHashMapCapacity,
	allocator) { }

	Iterator begin() const { return Iterator(this, this->Start()); }
	Iterator end() const { return Iterator(this, NULL); }
	Iterator find(Key* key, bool insert = false,
	AllocationPolicy allocator = AllocationPolicy()) {
	return Iterator(this, this->Lookup(key, key->Hash(), insert, allocator));
	}
	};

	} } // namespace v8::internal

	#endif // V8_HASHMAP_H_