net/disk_cache/in_flight_backend_io.h - platform/external/chromium - Git at Google

 // Copyright (c) 2010 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_IN_FLIGHT_BACKEND_IO_H_
 #define NET_DISK_CACHE_IN_FLIGHT_BACKEND_IO_H_
 #pragma once

 #include <list>
 #include <string>

 #include "base/message_loop_proxy.h"
 #include "base/time.h"
 #include "net/base/completion_callback.h"
 #include "net/base/io_buffer.h"
 #include "net/disk_cache/in_flight_io.h"

 namespace disk_cache {

 class BackendImpl;
 class Entry;
 class EntryImpl;

 // This class represents a single asynchronous disk cache IO operation while it
 // is being bounced between threads.
 class BackendIO : public BackgroundIO {
  public:
   BackendIO(InFlightIO* controller, BackendImpl* backend,
             net::CompletionCallback* callback);

   // Runs the actual operation on the background thread.
   void ExecuteOperation();

   // Callback implementation.
   void OnIOComplete(int result);

   // Returns true if this operation is directed to an entry (vs. the backend).
   bool IsEntryOperation();

   net::CompletionCallback* callback() { return callback_; }

   // Grabs an extra reference of entry_.
   void ReferenceEntry();

   // Returns the time that has passed since the operation was created.
   base::TimeDelta ElapsedTime() const;

   // The operations we proxy:
   void Init();
   void OpenEntry(const std::string& key, Entry** entry);
   void CreateEntry(const std::string& key, Entry** entry);
   void DoomEntry(const std::string& key);
   void DoomAllEntries();
   void DoomEntriesBetween(const base::Time initial_time,
                           const base::Time end_time);
   void DoomEntriesSince(const base::Time initial_time);
   void OpenNextEntry(void** iter, Entry** next_entry);
   void OpenPrevEntry(void** iter, Entry** prev_entry);
   void EndEnumeration(void* iterator);
   void CloseEntryImpl(EntryImpl* entry);
   void DoomEntryImpl(EntryImpl* entry);
   void FlushQueue();  // Dummy operation.
   void RunTask(Task* task);
   void ReadData(EntryImpl* entry, int index, int offset, net::IOBuffer* buf,
                 int buf_len);
   void WriteData(EntryImpl* entry, int index, int offset, net::IOBuffer* buf,
                  int buf_len, bool truncate);
   void ReadSparseData(EntryImpl* entry, int64 offset, net::IOBuffer* buf,
                       int buf_len);
   void WriteSparseData(EntryImpl* entry, int64 offset, net::IOBuffer* buf,
                        int buf_len);
   void GetAvailableRange(EntryImpl* entry, int64 offset, int len, int64* start);
   void CancelSparseIO(EntryImpl* entry);
   void ReadyForSparseIO(EntryImpl* entry);

  private:
   // There are two types of operations to proxy: regular backend operations are
   // executed sequentially (queued by the message loop). On the other hand,
   // operations targeted to a given entry can be long lived and support multiple
   // simultaneous users (multiple reads or writes to the same entry), and they
   // are subject to throttling, so we keep an explicit queue.
   enum Operation {
     OP_NONE = 0,
     OP_INIT,
     OP_OPEN,
     OP_CREATE,
     OP_DOOM,
     OP_DOOM_ALL,
     OP_DOOM_BETWEEN,
     OP_DOOM_SINCE,
     OP_OPEN_NEXT,
     OP_OPEN_PREV,
     OP_END_ENUMERATION,
     OP_CLOSE_ENTRY,
     OP_DOOM_ENTRY,
     OP_FLUSH_QUEUE,
     OP_RUN_TASK,
     OP_MAX_BACKEND,
     OP_READ,
     OP_WRITE,
     OP_READ_SPARSE,
     OP_WRITE_SPARSE,
     OP_GET_RANGE,
     OP_CANCEL_IO,
     OP_IS_READY
   };

   ~BackendIO();

   void ExecuteBackendOperation();
   void ExecuteEntryOperation();

   BackendImpl* backend_;
   net::CompletionCallback* callback_;
   Operation operation_;
   net::CompletionCallbackImpl<BackendIO> my_callback_;

   // The arguments of all the operations we proxy:
   std::string key_;
   Entry** entry_ptr_;
   base::Time initial_time_;
   base::Time end_time_;
   void** iter_ptr_;
   void* iter_;
   EntryImpl* entry_;
   int index_;
   int offset_;
   scoped_refptr<net::IOBuffer> buf_;
   int buf_len_;
   bool truncate_;
   int64 offset64_;
   int64* start_;
   base::TimeTicks start_time_;
   Task* task_;

   DISALLOW_COPY_AND_ASSIGN(BackendIO);
 };

 // The specialized controller that keeps track of current operations.
 class InFlightBackendIO : public InFlightIO {
  public:
   InFlightBackendIO(BackendImpl* backend,
                     base::MessageLoopProxy* background_thread);
   ~InFlightBackendIO();

   // The operations we proxy:
   void Init(net::CompletionCallback* callback);
   void OpenEntry(const std::string& key, Entry** entry,
                  net::CompletionCallback* callback);
   void CreateEntry(const std::string& key, Entry** entry,
                    net::CompletionCallback* callback);
   void DoomEntry(const std::string& key, net::CompletionCallback* callback);
   void DoomAllEntries(net::CompletionCallback* callback);
   void DoomEntriesBetween(const base::Time initial_time,
                           const base::Time end_time,
                           net::CompletionCallback* callback);
   void DoomEntriesSince(const base::Time initial_time,
                         net::CompletionCallback* callback);
   void OpenNextEntry(void** iter, Entry** next_entry,
                      net::CompletionCallback* callback);
   void OpenPrevEntry(void** iter, Entry** prev_entry,
                      net::CompletionCallback* callback);
   void EndEnumeration(void* iterator);
   void CloseEntryImpl(EntryImpl* entry);
   void DoomEntryImpl(EntryImpl* entry);
   void FlushQueue(net::CompletionCallback* callback);
   void RunTask(Task* task, net::CompletionCallback* callback);
   void ReadData(EntryImpl* entry, int index, int offset, net::IOBuffer* buf,
                 int buf_len, net::CompletionCallback* callback);
   void WriteData(EntryImpl* entry, int index, int offset, net::IOBuffer* buf,
                  int buf_len, bool truncate, net::CompletionCallback* callback);
   void ReadSparseData(EntryImpl* entry, int64 offset, net::IOBuffer* buf,
                       int buf_len, net::CompletionCallback* callback);
   void WriteSparseData(EntryImpl* entry, int64 offset, net::IOBuffer* buf,
                        int buf_len, net::CompletionCallback* callback);
   void GetAvailableRange(EntryImpl* entry, int64 offset, int len, int64* start,
                          net::CompletionCallback* callback);
   void CancelSparseIO(EntryImpl* entry);
   void ReadyForSparseIO(EntryImpl* entry, net::CompletionCallback* callback);

   // Blocks until all operations are cancelled or completed.
   void WaitForPendingIO();

   scoped_refptr<base::MessageLoopProxy> background_thread() {
     return background_thread_;
   }

   // Returns true if the current thread is the background thread.
   bool BackgroundIsCurrentThread() {
     return background_thread_->BelongsToCurrentThread();
   }

  protected:
   virtual void OnOperationComplete(BackgroundIO* operation, bool cancel);

  private:
   void PostOperation(BackendIO* operation);

   BackendImpl* backend_;
   scoped_refptr<base::MessageLoopProxy> background_thread_;

   DISALLOW_COPY_AND_ASSIGN(InFlightBackendIO);
 };

 }  // namespace disk_cache

 #endif  // NET_DISK_CACHE_IN_FLIGHT_BACKEND_IO_H_
	// Copyright (c) 2010 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_IN_FLIGHT_BACKEND_IO_H_
	#define NET_DISK_CACHE_IN_FLIGHT_BACKEND_IO_H_
	#pragma once

	#include <list>
	#include <string>

	#include "base/message_loop_proxy.h"
	#include "base/time.h"
	#include "net/base/completion_callback.h"
	#include "net/base/io_buffer.h"
	#include "net/disk_cache/in_flight_io.h"

	namespace disk_cache {

	class BackendImpl;
	class Entry;
	class EntryImpl;

	// This class represents a single asynchronous disk cache IO operation while it
	// is being bounced between threads.
	class BackendIO : public BackgroundIO {
	public:
	BackendIO(InFlightIO* controller, BackendImpl* backend,
	net::CompletionCallback* callback);

	// Runs the actual operation on the background thread.
	void ExecuteOperation();

	// Callback implementation.
	void OnIOComplete(int result);

	// Returns true if this operation is directed to an entry (vs. the backend).
	bool IsEntryOperation();

	net::CompletionCallback* callback() { return callback_; }

	// Grabs an extra reference of entry_.
	void ReferenceEntry();

	// Returns the time that has passed since the operation was created.
	base::TimeDelta ElapsedTime() const;

	// The operations we proxy:
	void Init();
	void OpenEntry(const std::string& key, Entry** entry);
	void CreateEntry(const std::string& key, Entry** entry);
	void DoomEntry(const std::string& key);
	void DoomAllEntries();
	void DoomEntriesBetween(const base::Time initial_time,
	const base::Time end_time);
	void DoomEntriesSince(const base::Time initial_time);
	void OpenNextEntry(void iter, Entry next_entry);
	void OpenPrevEntry(void iter, Entry prev_entry);
	void EndEnumeration(void* iterator);
	void CloseEntryImpl(EntryImpl* entry);
	void DoomEntryImpl(EntryImpl* entry);
	void FlushQueue(); // Dummy operation.
	void RunTask(Task* task);
	void ReadData(EntryImpl* entry, int index, int offset, net::IOBuffer* buf,
	int buf_len);
	void WriteData(EntryImpl* entry, int index, int offset, net::IOBuffer* buf,
	int buf_len, bool truncate);
	void ReadSparseData(EntryImpl* entry, int64 offset, net::IOBuffer* buf,
	int buf_len);
	void WriteSparseData(EntryImpl* entry, int64 offset, net::IOBuffer* buf,
	int buf_len);
	void GetAvailableRange(EntryImpl* entry, int64 offset, int len, int64* start);
	void CancelSparseIO(EntryImpl* entry);
	void ReadyForSparseIO(EntryImpl* entry);

	private:
	// There are two types of operations to proxy: regular backend operations are
	// executed sequentially (queued by the message loop). On the other hand,
	// operations targeted to a given entry can be long lived and support multiple
	// simultaneous users (multiple reads or writes to the same entry), and they
	// are subject to throttling, so we keep an explicit queue.
	enum Operation {
	OP_NONE = 0,
	OP_INIT,
	OP_OPEN,
	OP_CREATE,
	OP_DOOM,
	OP_DOOM_ALL,
	OP_DOOM_BETWEEN,
	OP_DOOM_SINCE,
	OP_OPEN_NEXT,
	OP_OPEN_PREV,
	OP_END_ENUMERATION,
	OP_CLOSE_ENTRY,
	OP_DOOM_ENTRY,
	OP_FLUSH_QUEUE,
	OP_RUN_TASK,
	OP_MAX_BACKEND,
	OP_READ,
	OP_WRITE,
	OP_READ_SPARSE,
	OP_WRITE_SPARSE,
	OP_GET_RANGE,
	OP_CANCEL_IO,
	OP_IS_READY
	};

	~BackendIO();

	void ExecuteBackendOperation();
	void ExecuteEntryOperation();

	BackendImpl* backend_;
	net::CompletionCallback* callback_;
	Operation operation_;
	net::CompletionCallbackImpl<BackendIO> my_callback_;

	// The arguments of all the operations we proxy:
	std::string key_;
	Entry** entry_ptr_;
	base::Time initial_time_;
	base::Time end_time_;
	void** iter_ptr_;
	void* iter_;
	EntryImpl* entry_;
	int index_;
	int offset_;
	scoped_refptr<net::IOBuffer> buf_;
	int buf_len_;
	bool truncate_;
	int64 offset64_;
	int64* start_;
	base::TimeTicks start_time_;
	Task* task_;

	DISALLOW_COPY_AND_ASSIGN(BackendIO);
	};

	// The specialized controller that keeps track of current operations.
	class InFlightBackendIO : public InFlightIO {
	public:
	InFlightBackendIO(BackendImpl* backend,
	base::MessageLoopProxy* background_thread);
	~InFlightBackendIO();

	// The operations we proxy:
	void Init(net::CompletionCallback* callback);
	void OpenEntry(const std::string& key, Entry** entry,
	net::CompletionCallback* callback);
	void CreateEntry(const std::string& key, Entry** entry,
	net::CompletionCallback* callback);
	void DoomEntry(const std::string& key, net::CompletionCallback* callback);
	void DoomAllEntries(net::CompletionCallback* callback);
	void DoomEntriesBetween(const base::Time initial_time,
	const base::Time end_time,
	net::CompletionCallback* callback);
	void DoomEntriesSince(const base::Time initial_time,
	net::CompletionCallback* callback);
	void OpenNextEntry(void iter, Entry next_entry,
	net::CompletionCallback* callback);
	void OpenPrevEntry(void iter, Entry prev_entry,
	net::CompletionCallback* callback);
	void EndEnumeration(void* iterator);
	void CloseEntryImpl(EntryImpl* entry);
	void DoomEntryImpl(EntryImpl* entry);
	void FlushQueue(net::CompletionCallback* callback);
	void RunTask(Task* task, net::CompletionCallback* callback);
	void ReadData(EntryImpl* entry, int index, int offset, net::IOBuffer* buf,
	int buf_len, net::CompletionCallback* callback);
	void WriteData(EntryImpl* entry, int index, int offset, net::IOBuffer* buf,
	int buf_len, bool truncate, net::CompletionCallback* callback);
	void ReadSparseData(EntryImpl* entry, int64 offset, net::IOBuffer* buf,
	int buf_len, net::CompletionCallback* callback);
	void WriteSparseData(EntryImpl* entry, int64 offset, net::IOBuffer* buf,
	int buf_len, net::CompletionCallback* callback);
	void GetAvailableRange(EntryImpl* entry, int64 offset, int len, int64* start,
	net::CompletionCallback* callback);
	void CancelSparseIO(EntryImpl* entry);
	void ReadyForSparseIO(EntryImpl* entry, net::CompletionCallback* callback);

	// Blocks until all operations are cancelled or completed.
	void WaitForPendingIO();

	scoped_refptr<base::MessageLoopProxy> background_thread() {
	return background_thread_;
	}

	// Returns true if the current thread is the background thread.
	bool BackgroundIsCurrentThread() {
	return background_thread_->BelongsToCurrentThread();
	}

	protected:
	virtual void OnOperationComplete(BackgroundIO* operation, bool cancel);

	private:
	void PostOperation(BackendIO* operation);

	BackendImpl* backend_;
	scoped_refptr<base::MessageLoopProxy> background_thread_;

	DISALLOW_COPY_AND_ASSIGN(InFlightBackendIO);
	};

	} // namespace disk_cache

	#endif // NET_DISK_CACHE_IN_FLIGHT_BACKEND_IO_H_