src/base/id_map.h - cobalt - Git at Google

 // Copyright (c) 2011 The Chromium 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 BASE_ID_MAP_H_
 #define BASE_ID_MAP_H_

 #include <set>

 #include "base/basictypes.h"
 #include "base/hash_tables.h"
 #include "base/logging.h"
 #include "base/threading/non_thread_safe.h"

 // Ownership semantics - own pointer means the pointer is deleted in Remove()
 // & during destruction
 enum IDMapOwnershipSemantics {
   IDMapExternalPointer,
   IDMapOwnPointer
 };

 // This object maintains a list of IDs that can be quickly converted to
 // pointers to objects. It is implemented as a hash table, optimized for
 // relatively small data sets (in the common case, there will be exactly one
 // item in the list).
 //
 // Items can be inserted into the container with arbitrary ID, but the caller
 // must ensure they are unique. Inserting IDs and relying on automatically
 // generated ones is not allowed because they can collide.
 //
 // This class does not have a virtual destructor, do not inherit from it when
 // ownership semantics are set to own because pointers will leak.
 template<typename T, IDMapOwnershipSemantics OS = IDMapExternalPointer>
 class IDMap : public base::NonThreadSafe {
  private:
   typedef int32 KeyType;
   typedef base::hash_map<KeyType, T*> HashTable;

  public:
   IDMap() : iteration_depth_(0), next_id_(1), check_on_null_data_(false) {
     // A number of consumers of IDMap create it on one thread but always access
     // it from a different, but consitent, thread post-construction.
     DetachFromThread();
   }

   ~IDMap() {
     // Many IDMap's are static, and hence will be destroyed on the main thread.
     // However, all the accesses may take place on another thread, such as the
     // IO thread. Detaching again to clean this up.
     DetachFromThread();
     Releaser<OS, 0>::release_all(&data_);
   }

   // Sets whether Add should CHECK if passed in NULL data. Default is false.
   void set_check_on_null_data(bool value) { check_on_null_data_ = value; }

   // Adds a view with an automatically generated unique ID. See AddWithID.
   KeyType Add(T* data) {
     DCHECK(CalledOnValidThread());
     CHECK(!check_on_null_data_ || data);
     KeyType this_id = next_id_;
     DCHECK(data_.find(this_id) == data_.end()) << "Inserting duplicate item";
     data_[this_id] = data;
     next_id_++;
     return this_id;
   }

   // Adds a new data member with the specified ID. The ID must not be in
   // the list. The caller either must generate all unique IDs itself and use
   // this function, or allow this object to generate IDs and call Add. These
   // two methods may not be mixed, or duplicate IDs may be generated
   void AddWithID(T* data, KeyType id) {
     DCHECK(CalledOnValidThread());
     CHECK(!check_on_null_data_ || data);
     DCHECK(data_.find(id) == data_.end()) << "Inserting duplicate item";
     data_[id] = data;
   }

   void Remove(KeyType id) {
     DCHECK(CalledOnValidThread());
     typename HashTable::iterator i = data_.find(id);
     if (i == data_.end()) {
       NOTREACHED() << "Attempting to remove an item not in the list";
       return;
     }

     if (iteration_depth_ == 0) {
       Releaser<OS, 0>::release(i->second);
       data_.erase(i);
     } else {
       removed_ids_.insert(id);
     }
   }

   void Clear() {
     DCHECK(CalledOnValidThread());
     if (iteration_depth_ == 0) {
       Releaser<OS, 0>::release_all(&data_);
     } else {
       for (typename HashTable::iterator i = data_.begin();
            i != data_.end(); ++i)
         removed_ids_.insert(i->first);
     }
   }

   bool IsEmpty() const {
     DCHECK(CalledOnValidThread());
     return size() == 0u;
   }

   T* Lookup(KeyType id) const {
     DCHECK(CalledOnValidThread());
     typename HashTable::const_iterator i = data_.find(id);
     if (i == data_.end())
       return NULL;
     return i->second;
   }

   size_t size() const {
     DCHECK(CalledOnValidThread());
     return data_.size() - removed_ids_.size();
   }

 #if defined(UNIT_TEST)
   int iteration_depth() const {
     return iteration_depth_;
   }
 #endif  // defined(UNIT_TEST)

   // It is safe to remove elements from the map during iteration. All iterators
   // will remain valid.
   template<class ReturnType>
   class Iterator {
    public:
     Iterator(IDMap<T, OS>* map)
         : map_(map),
           iter_(map_->data_.begin()) {
       Init();
     }

     Iterator(const Iterator& iter)
         : map_(iter.map_),
           iter_(iter.iter_) {
       Init();
     }

     const Iterator& operator=(const Iterator& iter) {
       map_ = iter.map;
       iter_ = iter.iter;
       Init();
       return *this;
     }

     ~Iterator() {
       DCHECK(map_->CalledOnValidThread());

       // We're going to decrement iteration depth. Make sure it's greater than
       // zero so that it doesn't become negative.
       DCHECK_LT(0, map_->iteration_depth_);

       if (--map_->iteration_depth_ == 0)
         map_->Compact();
     }

     bool IsAtEnd() const {
       DCHECK(map_->CalledOnValidThread());
       return iter_ == map_->data_.end();
     }

     KeyType GetCurrentKey() const {
       DCHECK(map_->CalledOnValidThread());
       return iter_->first;
     }

     ReturnType* GetCurrentValue() const {
       DCHECK(map_->CalledOnValidThread());
       return iter_->second;
     }

     void Advance() {
       DCHECK(map_->CalledOnValidThread());
       ++iter_;
       SkipRemovedEntries();
     }

    private:
     void Init() {
       DCHECK(map_->CalledOnValidThread());
       ++map_->iteration_depth_;
       SkipRemovedEntries();
     }

     void SkipRemovedEntries() {
       while (iter_ != map_->data_.end() &&
              map_->removed_ids_.find(iter_->first) !=
              map_->removed_ids_.end()) {
         ++iter_;
       }
     }

     IDMap<T, OS>* map_;
     typename HashTable::const_iterator iter_;
   };

   typedef Iterator<T> iterator;
   typedef Iterator<const T> const_iterator;

  private:

   // The dummy parameter is there because C++ standard does not allow
   // explicitly specialized templates inside classes
   template<IDMapOwnershipSemantics OI, int dummy> struct Releaser {
     static inline void release(T* ptr) {}
     static inline void release_all(HashTable* table) {}
   };

   template<int dummy> struct Releaser<IDMapOwnPointer, dummy> {
     static inline void release(T* ptr) { delete ptr;}
     static inline void release_all(HashTable* table) {
       for (typename HashTable::iterator i = table->begin();
            i != table->end(); ++i) {
         delete i->second;
       }
       table->clear();
     }
   };

   void Compact() {
     DCHECK_EQ(0, iteration_depth_);
     for (std::set<KeyType>::const_iterator i = removed_ids_.begin();
          i != removed_ids_.end(); ++i) {
       Remove(*i);
     }
     removed_ids_.clear();
   }

   // Keep track of how many iterators are currently iterating on us to safely
   // handle removing items during iteration.
   int iteration_depth_;

   // Keep set of IDs that should be removed after the outermost iteration has
   // finished. This way we manage to not invalidate the iterator when an element
   // is removed.
   std::set<KeyType> removed_ids_;

   // The next ID that we will return from Add()
   KeyType next_id_;

   HashTable data_;

   // See description above setter.
   bool check_on_null_data_;

   DISALLOW_COPY_AND_ASSIGN(IDMap);
 };

 #endif  // BASE_ID_MAP_H_
	// Copyright (c) 2011 The Chromium 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 BASE_ID_MAP_H_
	#define BASE_ID_MAP_H_

	#include <set>

	#include "base/basictypes.h"
	#include "base/hash_tables.h"
	#include "base/logging.h"
	#include "base/threading/non_thread_safe.h"

	// Ownership semantics - own pointer means the pointer is deleted in Remove()
	// & during destruction
	enum IDMapOwnershipSemantics {
	IDMapExternalPointer,
	IDMapOwnPointer
	};

	// This object maintains a list of IDs that can be quickly converted to
	// pointers to objects. It is implemented as a hash table, optimized for
	// relatively small data sets (in the common case, there will be exactly one
	// item in the list).
	//
	// Items can be inserted into the container with arbitrary ID, but the caller
	// must ensure they are unique. Inserting IDs and relying on automatically
	// generated ones is not allowed because they can collide.
	//
	// This class does not have a virtual destructor, do not inherit from it when
	// ownership semantics are set to own because pointers will leak.
	template<typename T, IDMapOwnershipSemantics OS = IDMapExternalPointer>
	class IDMap : public base::NonThreadSafe {
	private:
	typedef int32 KeyType;
	typedef base::hash_map<KeyType, T*> HashTable;

	public:
	IDMap() : iteration_depth_(0), next_id_(1), check_on_null_data_(false) {
	// A number of consumers of IDMap create it on one thread but always access
	// it from a different, but consitent, thread post-construction.
	DetachFromThread();
	}

	~IDMap() {
	// Many IDMap's are static, and hence will be destroyed on the main thread.
	// However, all the accesses may take place on another thread, such as the
	// IO thread. Detaching again to clean this up.
	DetachFromThread();
	Releaser<OS, 0>::release_all(&data_);
	}

	// Sets whether Add should CHECK if passed in NULL data. Default is false.
	void set_check_on_null_data(bool value) { check_on_null_data_ = value; }

	// Adds a view with an automatically generated unique ID. See AddWithID.
	KeyType Add(T* data) {
	DCHECK(CalledOnValidThread());
	CHECK(!check_on_null_data_ \|\| data);
	KeyType this_id = next_id_;
	DCHECK(data_.find(this_id) == data_.end()) << "Inserting duplicate item";
	data_[this_id] = data;
	next_id_++;
	return this_id;
	}

	// Adds a new data member with the specified ID. The ID must not be in
	// the list. The caller either must generate all unique IDs itself and use
	// this function, or allow this object to generate IDs and call Add. These
	// two methods may not be mixed, or duplicate IDs may be generated
	void AddWithID(T* data, KeyType id) {
	DCHECK(CalledOnValidThread());
	CHECK(!check_on_null_data_ \|\| data);
	DCHECK(data_.find(id) == data_.end()) << "Inserting duplicate item";
	data_[id] = data;
	}

	void Remove(KeyType id) {
	DCHECK(CalledOnValidThread());
	typename HashTable::iterator i = data_.find(id);
	if (i == data_.end()) {
	NOTREACHED() << "Attempting to remove an item not in the list";
	return;
	}

	if (iteration_depth_ == 0) {
	Releaser<OS, 0>::release(i->second);
	data_.erase(i);
	} else {
	removed_ids_.insert(id);
	}
	}

	void Clear() {
	DCHECK(CalledOnValidThread());
	if (iteration_depth_ == 0) {
	Releaser<OS, 0>::release_all(&data_);
	} else {
	for (typename HashTable::iterator i = data_.begin();
	i != data_.end(); ++i)
	removed_ids_.insert(i->first);
	}
	}

	bool IsEmpty() const {
	DCHECK(CalledOnValidThread());
	return size() == 0u;
	}

	T* Lookup(KeyType id) const {
	DCHECK(CalledOnValidThread());
	typename HashTable::const_iterator i = data_.find(id);
	if (i == data_.end())
	return NULL;
	return i->second;
	}

	size_t size() const {
	DCHECK(CalledOnValidThread());
	return data_.size() - removed_ids_.size();
	}

	#if defined(UNIT_TEST)
	int iteration_depth() const {
	return iteration_depth_;
	}
	#endif // defined(UNIT_TEST)

	// It is safe to remove elements from the map during iteration. All iterators
	// will remain valid.
	template<class ReturnType>
	class Iterator {
	public:
	Iterator(IDMap<T, OS>* map)
	: map_(map),
	iter_(map_->data_.begin()) {
	Init();
	}

	Iterator(const Iterator& iter)
	: map_(iter.map_),
	iter_(iter.iter_) {
	Init();
	}

	const Iterator& operator=(const Iterator& iter) {
	map_ = iter.map;
	iter_ = iter.iter;
	Init();
	return *this;
	}

	~Iterator() {
	DCHECK(map_->CalledOnValidThread());

	// We're going to decrement iteration depth. Make sure it's greater than
	// zero so that it doesn't become negative.
	DCHECK_LT(0, map_->iteration_depth_);

	if (--map_->iteration_depth_ == 0)
	map_->Compact();
	}

	bool IsAtEnd() const {
	DCHECK(map_->CalledOnValidThread());
	return iter_ == map_->data_.end();
	}

	KeyType GetCurrentKey() const {
	DCHECK(map_->CalledOnValidThread());
	return iter_->first;
	}

	ReturnType* GetCurrentValue() const {
	DCHECK(map_->CalledOnValidThread());
	return iter_->second;
	}

	void Advance() {
	DCHECK(map_->CalledOnValidThread());
	++iter_;
	SkipRemovedEntries();
	}

	private:
	void Init() {
	DCHECK(map_->CalledOnValidThread());
	++map_->iteration_depth_;
	SkipRemovedEntries();
	}

	void SkipRemovedEntries() {
	while (iter_ != map_->data_.end() &&
	map_->removed_ids_.find(iter_->first) !=
	map_->removed_ids_.end()) {
	++iter_;
	}
	}

	IDMap<T, OS>* map_;
	typename HashTable::const_iterator iter_;
	};

	typedef Iterator<T> iterator;
	typedef Iterator<const T> const_iterator;

	private:

	// The dummy parameter is there because C++ standard does not allow
	// explicitly specialized templates inside classes
	template<IDMapOwnershipSemantics OI, int dummy> struct Releaser {
	static inline void release(T* ptr) {}
	static inline void release_all(HashTable* table) {}
	};

	template<int dummy> struct Releaser<IDMapOwnPointer, dummy> {
	static inline void release(T* ptr) { delete ptr;}
	static inline void release_all(HashTable* table) {
	for (typename HashTable::iterator i = table->begin();
	i != table->end(); ++i) {
	delete i->second;
	}
	table->clear();
	}
	};

	void Compact() {
	DCHECK_EQ(0, iteration_depth_);
	for (std::set<KeyType>::const_iterator i = removed_ids_.begin();
	i != removed_ids_.end(); ++i) {
	Remove(*i);
	}
	removed_ids_.clear();
	}

	// Keep track of how many iterators are currently iterating on us to safely
	// handle removing items during iteration.
	int iteration_depth_;

	// Keep set of IDs that should be removed after the outermost iteration has
	// finished. This way we manage to not invalidate the iterator when an element
	// is removed.
	std::set<KeyType> removed_ids_;

	// The next ID that we will return from Add()
	KeyType next_id_;

	HashTable data_;

	// See description above setter.
	bool check_on_null_data_;

	DISALLOW_COPY_AND_ASSIGN(IDMap);
	};

	#endif // BASE_ID_MAP_H_