src/net/disk_cache/mem_entry_impl.h - cobalt - Git at Google

 // Copyright (c) 2012 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 NET_DISK_CACHE_MEM_ENTRY_IMPL_H_
 #define NET_DISK_CACHE_MEM_ENTRY_IMPL_H_

 #include "base/gtest_prod_util.h"
 #include "base/hash_tables.h"
 #include "base/memory/scoped_ptr.h"
 #include "net/base/net_log.h"
 #include "net/disk_cache/disk_cache.h"

 namespace disk_cache {

 class MemBackendImpl;

 // This class implements the Entry interface for the memory-only cache. An
 // object of this class represents a single entry on the cache. We use two
 // types of entries, parent and child to support sparse caching.
 //
 // A parent entry is non-sparse until a sparse method is invoked (i.e.
 // ReadSparseData, WriteSparseData, GetAvailableRange) when sparse information
 // is initialized. It then manages a list of child entries and delegates the
 // sparse API calls to the child entries. It creates and deletes child entries
 // and updates the list when needed.
 //
 // A child entry is used to carry partial cache content, non-sparse methods like
 // ReadData and WriteData cannot be applied to them. The lifetime of a child
 // entry is managed by the parent entry that created it except that the entry
 // can be evicted independently. A child entry does not have a key and it is not
 // registered in the backend's entry map. It is registered in the backend's
 // ranking list to enable eviction of a partial content.
 //
 // A sparse entry has a fixed maximum size and can be partially filled. There
 // can only be one continous filled region in a sparse entry, as illustrated by
 // the following example:
 // | xxx ooooo |
 // x = unfilled region
 // o = filled region
 // It is guranteed that there is at most one unfilled region and one filled
 // region, and the unfilled region (if there is one) is always before the filled
 // region. The book keeping for filled region in a sparse entry is done by using
 // the variable |child_first_pos_| (inclusive).

 class MemEntryImpl : public Entry {
  public:
   enum EntryType {
     kParentEntry,
     kChildEntry,
   };

   explicit MemEntryImpl(MemBackendImpl* backend);

   // Performs the initialization of a EntryImpl that will be added to the
   // cache.
   bool CreateEntry(const std::string& key, net::NetLog* net_log);

   // Permanently destroys this entry.
   void InternalDoom();

   void Open();
   bool InUse();

   MemEntryImpl* next() const {
     return next_;
   }

   MemEntryImpl* prev() const {
     return prev_;
   }

   void set_next(MemEntryImpl* next) {
     next_ = next;
   }

   void set_prev(MemEntryImpl* prev) {
     prev_ = prev;
   }

   EntryType type() const {
     return parent_ ? kChildEntry : kParentEntry;
   }

   std::string& key() {
     return key_;
   }

   net::BoundNetLog& net_log() {
     return net_log_;
   }

   // Entry interface.
   virtual void Doom() OVERRIDE;
   virtual void Close() OVERRIDE;
   virtual std::string GetKey() const OVERRIDE;
   virtual base::Time GetLastUsed() const OVERRIDE;
   virtual base::Time GetLastModified() const OVERRIDE;
   virtual int32 GetDataSize(int index) const OVERRIDE;
   virtual int ReadData(int index, int offset, IOBuffer* buf, int buf_len,
                        const CompletionCallback& callback) OVERRIDE;
   virtual int WriteData(int index, int offset, IOBuffer* buf, int buf_len,
                         const CompletionCallback& callback,
                         bool truncate) OVERRIDE;
   virtual int ReadSparseData(int64 offset, IOBuffer* buf, int buf_len,
                              const CompletionCallback& callback) OVERRIDE;
   virtual int WriteSparseData(int64 offset, IOBuffer* buf, int buf_len,
                               const CompletionCallback& callback) OVERRIDE;
   virtual int GetAvailableRange(int64 offset, int len, int64* start,
                                 const CompletionCallback& callback) OVERRIDE;
   virtual bool CouldBeSparse() const OVERRIDE;
   virtual void CancelSparseIO() OVERRIDE {}
   virtual int ReadyForSparseIO(const CompletionCallback& callback) OVERRIDE;

  private:
   typedef base::hash_map<int, MemEntryImpl*> EntryMap;

   enum {
     NUM_STREAMS = 3
   };

   virtual ~MemEntryImpl();

   // Do all the work for corresponding public functions.  Implemented as
   // separate functions to make logging of results simpler.
   int InternalReadData(int index, int offset, IOBuffer* buf, int buf_len);
   int InternalWriteData(int index, int offset, IOBuffer* buf, int buf_len,
                         bool truncate);
   int InternalReadSparseData(int64 offset, IOBuffer* buf, int buf_len);
   int InternalWriteSparseData(int64 offset, IOBuffer* buf, int buf_len);

   // Old Entry interface.
   int GetAvailableRange(int64 offset, int len, int64* start);

   // Grows and cleans up the data buffer.
   void PrepareTarget(int index, int offset, int buf_len);

   // Updates ranking information.
   void UpdateRank(bool modified);

   // Initializes the children map and sparse info. This method is only called
   // on a parent entry.
   bool InitSparseInfo();

   // Performs the initialization of a MemEntryImpl as a child entry.
   // |parent| is the pointer to the parent entry. |child_id| is the ID of
   // the new child.
   bool InitChildEntry(MemEntryImpl* parent, int child_id, net::NetLog* net_log);

   // Returns an entry responsible for |offset|. The returned entry can be a
   // child entry or this entry itself if |offset| points to the first range.
   // If such entry does not exist and |create| is true, a new child entry is
   // created.
   MemEntryImpl* OpenChild(int64 offset, bool create);

   // Finds the first child located within the range [|offset|, |offset + len|).
   // Returns the number of bytes ahead of |offset| to reach the first available
   // bytes in the entry. The first child found is output to |child|.
   int FindNextChild(int64 offset, int len, MemEntryImpl** child);

   // Removes child indexed by |child_id| from the children map.
   void DetachChild(int child_id);

   std::string key_;
   std::vector<char> data_[NUM_STREAMS];  // User data.
   int32 data_size_[NUM_STREAMS];
   int ref_count_;

   int child_id_;              // The ID of a child entry.
   int child_first_pos_;       // The position of the first byte in a child
                               // entry.
   MemEntryImpl* next_;        // Pointers for the LRU list.
   MemEntryImpl* prev_;
   MemEntryImpl* parent_;      // Pointer to the parent entry.
   scoped_ptr<EntryMap> children_;

   base::Time last_modified_;  // LRU information.
   base::Time last_used_;
   MemBackendImpl* backend_;   // Back pointer to the cache.
   bool doomed_;               // True if this entry was removed from the cache.

   net::BoundNetLog net_log_;

   DISALLOW_COPY_AND_ASSIGN(MemEntryImpl);
 };

 }  // namespace disk_cache

 #endif  // NET_DISK_CACHE_MEM_ENTRY_IMPL_H_
	// Copyright (c) 2012 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 NET_DISK_CACHE_MEM_ENTRY_IMPL_H_
	#define NET_DISK_CACHE_MEM_ENTRY_IMPL_H_

	#include "base/gtest_prod_util.h"
	#include "base/hash_tables.h"
	#include "base/memory/scoped_ptr.h"
	#include "net/base/net_log.h"
	#include "net/disk_cache/disk_cache.h"

	namespace disk_cache {

	class MemBackendImpl;

	// This class implements the Entry interface for the memory-only cache. An
	// object of this class represents a single entry on the cache. We use two
	// types of entries, parent and child to support sparse caching.
	//
	// A parent entry is non-sparse until a sparse method is invoked (i.e.
	// ReadSparseData, WriteSparseData, GetAvailableRange) when sparse information
	// is initialized. It then manages a list of child entries and delegates the
	// sparse API calls to the child entries. It creates and deletes child entries
	// and updates the list when needed.
	//
	// A child entry is used to carry partial cache content, non-sparse methods like
	// ReadData and WriteData cannot be applied to them. The lifetime of a child
	// entry is managed by the parent entry that created it except that the entry
	// can be evicted independently. A child entry does not have a key and it is not
	// registered in the backend's entry map. It is registered in the backend's
	// ranking list to enable eviction of a partial content.
	//
	// A sparse entry has a fixed maximum size and can be partially filled. There
	// can only be one continous filled region in a sparse entry, as illustrated by
	// the following example:
	// \| xxx ooooo \|
	// x = unfilled region
	// o = filled region
	// It is guranteed that there is at most one unfilled region and one filled
	// region, and the unfilled region (if there is one) is always before the filled
	// region. The book keeping for filled region in a sparse entry is done by using
	// the variable \|child_first_pos_\| (inclusive).

	class MemEntryImpl : public Entry {
	public:
	enum EntryType {
	kParentEntry,
	kChildEntry,
	};

	explicit MemEntryImpl(MemBackendImpl* backend);

	// Performs the initialization of a EntryImpl that will be added to the
	// cache.
	bool CreateEntry(const std::string& key, net::NetLog* net_log);

	// Permanently destroys this entry.
	void InternalDoom();

	void Open();
	bool InUse();

	MemEntryImpl* next() const {
	return next_;
	}

	MemEntryImpl* prev() const {
	return prev_;
	}

	void set_next(MemEntryImpl* next) {
	next_ = next;
	}

	void set_prev(MemEntryImpl* prev) {
	prev_ = prev;
	}

	EntryType type() const {
	return parent_ ? kChildEntry : kParentEntry;
	}

	std::string& key() {
	return key_;
	}

	net::BoundNetLog& net_log() {
	return net_log_;
	}

	// Entry interface.
	virtual void Doom() OVERRIDE;
	virtual void Close() OVERRIDE;
	virtual std::string GetKey() const OVERRIDE;
	virtual base::Time GetLastUsed() const OVERRIDE;
	virtual base::Time GetLastModified() const OVERRIDE;
	virtual int32 GetDataSize(int index) const OVERRIDE;
	virtual int ReadData(int index, int offset, IOBuffer* buf, int buf_len,
	const CompletionCallback& callback) OVERRIDE;
	virtual int WriteData(int index, int offset, IOBuffer* buf, int buf_len,
	const CompletionCallback& callback,
	bool truncate) OVERRIDE;
	virtual int ReadSparseData(int64 offset, IOBuffer* buf, int buf_len,
	const CompletionCallback& callback) OVERRIDE;
	virtual int WriteSparseData(int64 offset, IOBuffer* buf, int buf_len,
	const CompletionCallback& callback) OVERRIDE;
	virtual int GetAvailableRange(int64 offset, int len, int64* start,
	const CompletionCallback& callback) OVERRIDE;
	virtual bool CouldBeSparse() const OVERRIDE;
	virtual void CancelSparseIO() OVERRIDE {}
	virtual int ReadyForSparseIO(const CompletionCallback& callback) OVERRIDE;

	private:
	typedef base::hash_map<int, MemEntryImpl*> EntryMap;

	enum {
	NUM_STREAMS = 3
	};

	virtual ~MemEntryImpl();

	// Do all the work for corresponding public functions. Implemented as
	// separate functions to make logging of results simpler.
	int InternalReadData(int index, int offset, IOBuffer* buf, int buf_len);
	int InternalWriteData(int index, int offset, IOBuffer* buf, int buf_len,
	bool truncate);
	int InternalReadSparseData(int64 offset, IOBuffer* buf, int buf_len);
	int InternalWriteSparseData(int64 offset, IOBuffer* buf, int buf_len);

	// Old Entry interface.
	int GetAvailableRange(int64 offset, int len, int64* start);

	// Grows and cleans up the data buffer.
	void PrepareTarget(int index, int offset, int buf_len);

	// Updates ranking information.
	void UpdateRank(bool modified);

	// Initializes the children map and sparse info. This method is only called
	// on a parent entry.
	bool InitSparseInfo();

	// Performs the initialization of a MemEntryImpl as a child entry.
	// \|parent\| is the pointer to the parent entry. \|child_id\| is the ID of
	// the new child.
	bool InitChildEntry(MemEntryImpl* parent, int child_id, net::NetLog* net_log);

	// Returns an entry responsible for \|offset\|. The returned entry can be a
	// child entry or this entry itself if \|offset\| points to the first range.
	// If such entry does not exist and \|create\| is true, a new child entry is
	// created.
	MemEntryImpl* OpenChild(int64 offset, bool create);

	// Finds the first child located within the range [\|offset\|, \|offset + len\|).
	// Returns the number of bytes ahead of \|offset\| to reach the first available
	// bytes in the entry. The first child found is output to \|child\|.
	int FindNextChild(int64 offset, int len, MemEntryImpl** child);

	// Removes child indexed by \|child_id\| from the children map.
	void DetachChild(int child_id);

	std::string key_;
	std::vector<char> data_[NUM_STREAMS]; // User data.
	int32 data_size_[NUM_STREAMS];
	int ref_count_;

	int child_id_; // The ID of a child entry.
	int child_first_pos_; // The position of the first byte in a child
	// entry.
	MemEntryImpl* next_; // Pointers for the LRU list.
	MemEntryImpl* prev_;
	MemEntryImpl* parent_; // Pointer to the parent entry.
	scoped_ptr<EntryMap> children_;

	base::Time last_modified_; // LRU information.
	base::Time last_used_;
	MemBackendImpl* backend_; // Back pointer to the cache.
	bool doomed_; // True if this entry was removed from the cache.

	net::BoundNetLog net_log_;

	DISALLOW_COPY_AND_ASSIGN(MemEntryImpl);
	};

	} // namespace disk_cache

	#endif // NET_DISK_CACHE_MEM_ENTRY_IMPL_H_