content/browser/byte_stream.h - chromium/src - 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 CONTENT_BROWSER_BYTE_STREAM_H_
 #define CONTENT_BROWSER_BYTE_STREAM_H_

 #include <stddef.h>

 #include <memory>

 #include "base/callback.h"
 #include "base/memory/ref_counted.h"
 #include "base/task/post_task.h"
 #include "content/common/content_export.h"
 #include "content/public/browser/browser_task_traits.h"
 #include "net/base/io_buffer.h"

 namespace base {
 class SequencedTaskRunner;
 }

 namespace content {

 // A byte stream is a pipe to transfer bytes between a source and a
 // sink, which may be on different threads.  It is intended to be the
 // only connection between source and sink; they need have no
 // direct awareness of each other aside from the byte stream.  The source and
 // the sink have different interfaces to a byte stream, |ByteStreamWriter|
 // and |ByteStreamReader|.  A pair of connected interfaces is generated by
 // calling |CreateByteStream|.
 //
 // The source adds bytes to the bytestream via |ByteStreamWriter::Write|
 // and the sink retrieves bytes already written via |ByteStreamReader::Read|.
 //
 // When the source has no more data to add, it will call
 // |ByteStreamWriter::Close| to indicate that.  Operation status at the source
 // is indicated to the sink via an int passed to the Close() method and returned
 // from the GetStatus() method. Source and sink must agree on the interpretation
 // of this int.
 //
 // Normally the source is not managed after the relationship is setup;
 // it is expected to provide data and then close itself.  If an error
 // occurs on the sink, it is not signalled to the source via this
 // mechanism; instead, the source will write data until it exausts the
 // available space.  If the source needs to be aware of errors occuring
 // on the sink, this must be signalled in some other fashion (usually
 // through whatever controller setup the relationship).
 //
 // Callback lifetime management: No lifetime management is done in this
 // class to prevent registered callbacks from being called after any
 // objects to which they may refer have been destroyed.  It is the
 // responsibility of the callers to avoid use-after-free references.
 // This may be done by any of several mechanisms, including weak
 // pointers, scoped_refptr references, or calling the registration
 // function with a null callback from a destructor.  To enable the null
 // callback strategy, callbacks will not be stored between retrieval and
 // evaluation, so setting a null callback will guarantee that the
 // previous callback will not be executed after setting.
 //
 // Class methods are virtual to allow mocking for tests; these classes
 // aren't intended to be base classes for other classes.
 //
 // Sample usage (note that this does not show callback usage):
 //
 //    void OriginatingClass::Initialize() {
 //      // Create a stream for sending bytes from IO->FILE threads.
 //      std::unique_ptr<ByteStreamWriter> writer;
 //      std::unique_ptr<ByteStreamReader> reader;
 //      CreateByteStream(
 //          base::CreateSingleThreadTaskRunner({BrowserThread::IO}),
 //          base::CreateSequencedTaskRunner({base::MayBlock, ...}),
 //          kStreamBufferSize /* e.g. 10240.  */,
 //          &writer,
 //          &reader);         // Presumed passed to FILE thread for reading.
 //
 //      // Setup callback for writing.
 //      writer->RegisterCallback(base::BindRepeating(&SpaceAvailable, this));
 //
 //      // Do initial round of writing.
 //      SpaceAvailable();
 //    }
 //
 //    // May only be run on first argument task runner, in this case the IO
 //    // thread.
 //    void OriginatingClass::SpaceAvailable() {
 //      while (<data available>) {
 //        std::unique_ptr<net::IOBuffer> buffer;
 //        size_t buffer_length;
 //        // Create IOBuffer, fill in with data, and set buffer_length.
 //        if (!writer->Write(buffer, buffer_length)) {
 //          // No more space; return and we'll be called again
 //          // when there is space.
 //          return;
 //        }
 //      }
 //      writer->Close(<operation status>);
 //      writer.reset(NULL);
 //    }
 //
 //    // On File thread; containing class setup not shown.
 //
 //    void ReceivingClass::Initialize() {
 //      // Initialization
 //      reader->RegisterCallback(base::BindRepeating(&DataAvailable, obj));
 //    }
 //
 //    // Called whenever there's something to read.
 //    void ReceivingClass::DataAvailable() {
 //      scoped_refptr<net::IOBuffer> data;
 //      size_t length = 0;
 //
 //      while (ByteStreamReader::STREAM_HAS_DATA ==
 //             (state = reader->Read(&data, &length))) {
 //        // Process |data|.
 //      }
 //
 //      if (ByteStreamReader::STREAM_COMPLETE == state) {
 //        int status = reader->GetStatus();
 //        // Process error or successful completion in |status|.
 //      }
 //
 //      // if |state| is STREAM_EMPTY, we're done for now; we'll be called
 //      // again when there's more data.
 //    }
 class CONTENT_EXPORT ByteStreamWriter {
  public:
   // Inverse of the fraction of the stream buffer that must be full before
   // a notification is sent to paired Reader that there's more data.
   static const int kFractionBufferBeforeSending;

   virtual ~ByteStreamWriter() = 0;

   // Always adds the data passed into the ByteStream.  Returns true
   // if more data may be added without exceeding the class limit
   // on data.  Takes ownership of |buffer|.
   virtual bool Write(scoped_refptr<net::IOBuffer> buffer,
                      size_t byte_count) = 0;

   // Flushes contents buffered in this writer to the corresponding reader
   // regardless if buffer filling rate is greater than
   // kFractionBufferBeforeSending or not. Does nothing if there's no contents
   // buffered.
   virtual void Flush() = 0;

   // Signal that all data that is going to be sent, has been sent,
   // and provide a status.
   virtual void Close(int status) = 0;

   // Register a callback to be called when the stream transitions from
   // full to having space available.  The callback will always be
   // called on the task runner associated with the ByteStreamWriter.
   // This callback will only be called if a call to Write has previously
   // returned false (i.e. the ByteStream has been filled).
   // Multiple calls to this function are supported, though note that it
   // is the callers responsibility to handle races with space becoming
   // available (i.e. in the case of that race either of the before
   // or after callbacks may be called).
   // The callback will not be called after ByteStreamWriter destruction.
   virtual void RegisterCallback(
       const base::RepeatingClosure& source_callback) = 0;

   // Returns the number of bytes sent to the reader but not yet reported by
   // the reader as read.
   virtual size_t GetTotalBufferedBytes() const = 0;
 };

 class CONTENT_EXPORT ByteStreamReader {
  public:
   // Inverse of the fraction of the stream buffer that must be empty before
   // a notification is send to paired Writer that there's more room.
   static const int kFractionReadBeforeWindowUpdate;

   enum StreamState { STREAM_EMPTY, STREAM_HAS_DATA, STREAM_COMPLETE };

   virtual ~ByteStreamReader() = 0;

   // Returns STREAM_EMPTY if there is no data on the ByteStream and
   // Close() has not been called, and STREAM_COMPLETE if there
   // is no data on the ByteStream and Close() has been called.
   // If there is data on the ByteStream, returns STREAM_HAS_DATA
   // and fills in |*data| with a pointer to the data, and |*length|
   // with its length.
   virtual StreamState Read(scoped_refptr<net::IOBuffer>* data,
                            size_t* length) = 0;

   // Only valid to call if Read() has returned STREAM_COMPLETE.
   virtual int GetStatus() const = 0;

   // Register a callback to be called when data is added or the source
   // completes.  The callback will be always be called on the owning
   // task runner.  Multiple calls to this function are supported,
   // though note that it is the callers responsibility to handle races
   // with data becoming available (i.e. in the case of that race
   // either of the before or after callbacks may be called).
   // The callback will not be called after ByteStreamReader destruction.
   virtual void RegisterCallback(
       const base::RepeatingClosure& sink_callback) = 0;
 };

 CONTENT_EXPORT void CreateByteStream(
     scoped_refptr<base::SequencedTaskRunner> input_task_runner,
     scoped_refptr<base::SequencedTaskRunner> output_task_runner,
     size_t buffer_size,
     std::unique_ptr<ByteStreamWriter>* input,
     std::unique_ptr<ByteStreamReader>* output);

 }  // namespace content

 #endif  // CONTENT_BROWSER_BYTE_STREAM_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 CONTENT_BROWSER_BYTE_STREAM_H_
	#define CONTENT_BROWSER_BYTE_STREAM_H_

	#include <stddef.h>

	#include <memory>

	#include "base/callback.h"
	#include "base/memory/ref_counted.h"
	#include "base/task/post_task.h"
	#include "content/common/content_export.h"
	#include "content/public/browser/browser_task_traits.h"
	#include "net/base/io_buffer.h"

	namespace base {
	class SequencedTaskRunner;
	}

	namespace content {

	// A byte stream is a pipe to transfer bytes between a source and a
	// sink, which may be on different threads. It is intended to be the
	// only connection between source and sink; they need have no
	// direct awareness of each other aside from the byte stream. The source and
	// the sink have different interfaces to a byte stream, \|ByteStreamWriter\|
	// and \|ByteStreamReader\|. A pair of connected interfaces is generated by
	// calling \|CreateByteStream\|.
	//
	// The source adds bytes to the bytestream via \|ByteStreamWriter::Write\|
	// and the sink retrieves bytes already written via \|ByteStreamReader::Read\|.
	//
	// When the source has no more data to add, it will call
	// \|ByteStreamWriter::Close\| to indicate that. Operation status at the source
	// is indicated to the sink via an int passed to the Close() method and returned
	// from the GetStatus() method. Source and sink must agree on the interpretation
	// of this int.
	//
	// Normally the source is not managed after the relationship is setup;
	// it is expected to provide data and then close itself. If an error
	// occurs on the sink, it is not signalled to the source via this
	// mechanism; instead, the source will write data until it exausts the
	// available space. If the source needs to be aware of errors occuring
	// on the sink, this must be signalled in some other fashion (usually
	// through whatever controller setup the relationship).
	//
	// Callback lifetime management: No lifetime management is done in this
	// class to prevent registered callbacks from being called after any
	// objects to which they may refer have been destroyed. It is the
	// responsibility of the callers to avoid use-after-free references.
	// This may be done by any of several mechanisms, including weak
	// pointers, scoped_refptr references, or calling the registration
	// function with a null callback from a destructor. To enable the null
	// callback strategy, callbacks will not be stored between retrieval and
	// evaluation, so setting a null callback will guarantee that the
	// previous callback will not be executed after setting.
	//
	// Class methods are virtual to allow mocking for tests; these classes
	// aren't intended to be base classes for other classes.
	//
	// Sample usage (note that this does not show callback usage):
	//
	// void OriginatingClass::Initialize() {
	// // Create a stream for sending bytes from IO->FILE threads.
	// std::unique_ptr<ByteStreamWriter> writer;
	// std::unique_ptr<ByteStreamReader> reader;
	// CreateByteStream(
	// base::CreateSingleThreadTaskRunner({BrowserThread::IO}),
	// base::CreateSequencedTaskRunner({base::MayBlock, ...}),
	// kStreamBufferSize /* e.g. 10240. */,
	// &writer,
	// &reader); // Presumed passed to FILE thread for reading.
	//
	// // Setup callback for writing.
	// writer->RegisterCallback(base::BindRepeating(&SpaceAvailable, this));
	//
	// // Do initial round of writing.
	// SpaceAvailable();
	// }
	//
	// // May only be run on first argument task runner, in this case the IO
	// // thread.
	// void OriginatingClass::SpaceAvailable() {
	// while (<data available>) {
	// std::unique_ptr<net::IOBuffer> buffer;
	// size_t buffer_length;
	// // Create IOBuffer, fill in with data, and set buffer_length.
	// if (!writer->Write(buffer, buffer_length)) {
	// // No more space; return and we'll be called again
	// // when there is space.
	// return;
	// }
	// }
	// writer->Close(<operation status>);
	// writer.reset(NULL);
	// }
	//
	// // On File thread; containing class setup not shown.
	//
	// void ReceivingClass::Initialize() {
	// // Initialization
	// reader->RegisterCallback(base::BindRepeating(&DataAvailable, obj));
	// }
	//
	// // Called whenever there's something to read.
	// void ReceivingClass::DataAvailable() {
	// scoped_refptr<net::IOBuffer> data;
	// size_t length = 0;
	//
	// while (ByteStreamReader::STREAM_HAS_DATA ==
	// (state = reader->Read(&data, &length))) {
	// // Process \|data\|.
	// }
	//
	// if (ByteStreamReader::STREAM_COMPLETE == state) {
	// int status = reader->GetStatus();
	// // Process error or successful completion in \|status\|.
	// }
	//
	// // if \|state\| is STREAM_EMPTY, we're done for now; we'll be called
	// // again when there's more data.
	// }
	class CONTENT_EXPORT ByteStreamWriter {
	public:
	// Inverse of the fraction of the stream buffer that must be full before
	// a notification is sent to paired Reader that there's more data.
	static const int kFractionBufferBeforeSending;

	virtual ~ByteStreamWriter() = 0;

	// Always adds the data passed into the ByteStream. Returns true
	// if more data may be added without exceeding the class limit
	// on data. Takes ownership of \|buffer\|.
	virtual bool Write(scoped_refptr<net::IOBuffer> buffer,
	size_t byte_count) = 0;

	// Flushes contents buffered in this writer to the corresponding reader
	// regardless if buffer filling rate is greater than
	// kFractionBufferBeforeSending or not. Does nothing if there's no contents
	// buffered.
	virtual void Flush() = 0;

	// Signal that all data that is going to be sent, has been sent,
	// and provide a status.
	virtual void Close(int status) = 0;

	// Register a callback to be called when the stream transitions from
	// full to having space available. The callback will always be
	// called on the task runner associated with the ByteStreamWriter.
	// This callback will only be called if a call to Write has previously
	// returned false (i.e. the ByteStream has been filled).
	// Multiple calls to this function are supported, though note that it
	// is the callers responsibility to handle races with space becoming
	// available (i.e. in the case of that race either of the before
	// or after callbacks may be called).
	// The callback will not be called after ByteStreamWriter destruction.
	virtual void RegisterCallback(
	const base::RepeatingClosure& source_callback) = 0;

	// Returns the number of bytes sent to the reader but not yet reported by
	// the reader as read.
	virtual size_t GetTotalBufferedBytes() const = 0;
	};

	class CONTENT_EXPORT ByteStreamReader {
	public:
	// Inverse of the fraction of the stream buffer that must be empty before
	// a notification is send to paired Writer that there's more room.
	static const int kFractionReadBeforeWindowUpdate;

	enum StreamState { STREAM_EMPTY, STREAM_HAS_DATA, STREAM_COMPLETE };

	virtual ~ByteStreamReader() = 0;

	// Returns STREAM_EMPTY if there is no data on the ByteStream and
	// Close() has not been called, and STREAM_COMPLETE if there
	// is no data on the ByteStream and Close() has been called.
	// If there is data on the ByteStream, returns STREAM_HAS_DATA
	// and fills in \|data\| with a pointer to the data, and \|length\|
	// with its length.
	virtual StreamState Read(scoped_refptr<net::IOBuffer>* data,
	size_t* length) = 0;

	// Only valid to call if Read() has returned STREAM_COMPLETE.
	virtual int GetStatus() const = 0;

	// Register a callback to be called when data is added or the source
	// completes. The callback will be always be called on the owning
	// task runner. Multiple calls to this function are supported,
	// though note that it is the callers responsibility to handle races
	// with data becoming available (i.e. in the case of that race
	// either of the before or after callbacks may be called).
	// The callback will not be called after ByteStreamReader destruction.
	virtual void RegisterCallback(
	const base::RepeatingClosure& sink_callback) = 0;
	};

	CONTENT_EXPORT void CreateByteStream(
	scoped_refptr<base::SequencedTaskRunner> input_task_runner,
	scoped_refptr<base::SequencedTaskRunner> output_task_runner,
	size_t buffer_size,
	std::unique_ptr<ByteStreamWriter>* input,
	std::unique_ptr<ByteStreamReader>* output);

	} // namespace content

	#endif // CONTENT_BROWSER_BYTE_STREAM_H_