src/net/base/io_buffer.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_BASE_IO_BUFFER_H_
 #define NET_BASE_IO_BUFFER_H_

 #include <memory>
 #include <string>

 #include "base/memory/free_deleter.h"
 #include "base/memory/ref_counted.h"
 #include "base/pickle.h"
 #include "net/base/net_export.h"
 #include "starboard/types.h"

 namespace net {

 // IOBuffers are reference counted data buffers used for easier asynchronous
 // IO handling.
 //
 // They are often used as the destination buffers for Read() operations, or as
 // the source buffers for Write() operations.
 //
 // IMPORTANT: Never re-use an IOBuffer after cancelling the IO operation that
 //            was using it, since this may lead to memory corruption!
 //
 // -----------------------
 // Ownership of IOBuffers:
 // -----------------------
 //
 // Although IOBuffers are RefCountedThreadSafe, they are not intended to be
 // used as a shared buffer, nor should they be used simultaneously across
 // threads. The fact that they are reference counted is an implementation
 // detail for allowing them to outlive cancellation of asynchronous
 // operations.
 //
 // Instead, think of the underlying |char*| buffer contained by the IOBuffer
 // as having exactly one owner at a time.
 //
 // Whenever you call an asynchronous operation that takes an IOBuffer,
 // ownership is implicitly transferred to the called function, until the
 // operation has completed (at which point it transfers back to the caller).
 //
 //     ==> The IOBuffer's data should NOT be manipulated, destroyed, or read
 //         until the operation has completed.
 //
 //     ==> Cancellation does NOT count as completion. If an operation using
 //         an IOBuffer is cancelled, the caller should release their
 //         reference to this IOBuffer at the time of cancellation since
 //         they can no longer use it.
 //
 // For instance, if you were to call a Read() operation on some class which
 // takes an IOBuffer, and then delete that class (which generally will
 // trigger cancellation), the IOBuffer which had been passed to Read() should
 // never be re-used.
 //
 // This usage contract is assumed by any API which takes an IOBuffer, even
 // though it may not be explicitly mentioned in the function's comments.
 //
 // -----------------------
 // Motivation
 // -----------------------
 //
 // The motivation for transferring ownership during cancellation is
 // to make it easier to work with un-cancellable operations.
 //
 // For instance, let's say under the hood your API called out to the
 // operating system's synchronous ReadFile() function on a worker thread.
 // When cancelling through our asynchronous interface, we have no way of
 // actually aborting the in progress ReadFile(). We must let it keep running,
 // and hence the buffer it was reading into must remain alive. Using
 // reference counting we can add a reference to the IOBuffer and make sure
 // it is not destroyed until after the synchronous operation has completed.
 class NET_EXPORT IOBuffer : public base::RefCountedThreadSafe<IOBuffer> {
  public:
   IOBuffer();

   // TODO(eroman): Deprecated. Use the size_t flavor instead. crbug.com/488553
   explicit IOBuffer(int buffer_size);
   explicit IOBuffer(size_t buffer_size);

   char* data() const { return data_; }

  protected:
   friend class base::RefCountedThreadSafe<IOBuffer>;

   // Only allow derived classes to specify data_.
   // In all other cases, we own data_, and must delete it at destruction time.
   explicit IOBuffer(char* data);

   virtual ~IOBuffer();

   char* data_;
 };

 // This version stores the size of the buffer so that the creator of the object
 // doesn't have to keep track of that value.
 // NOTE: This doesn't mean that we want to stop sending the size as an explicit
 // argument to IO functions. Please keep using IOBuffer* for API declarations.
 class NET_EXPORT IOBufferWithSize : public IOBuffer {
  public:
   // TODO(eroman): Deprecated. Use the size_t flavor instead. crbug.com/488553
   explicit IOBufferWithSize(int size);
   explicit IOBufferWithSize(size_t size);

   int size() const { return size_; }

  protected:
   // TODO(eroman): Deprecated. Use the size_t flavor instead. crbug.com/488553
   IOBufferWithSize(char* data, int size);

   // Purpose of this constructor is to give a subclass access to the base class
   // constructor IOBuffer(char*) thus allowing subclass to use underlying
   // memory it does not own.
   IOBufferWithSize(char* data, size_t size);
   ~IOBufferWithSize() override;

   int size_;
 };

 // This is a read only IOBuffer.  The data is stored in a string and
 // the IOBuffer interface does not provide a proper way to modify it.
 class NET_EXPORT StringIOBuffer : public IOBuffer {
  public:
   explicit StringIOBuffer(const std::string& s);
   explicit StringIOBuffer(std::unique_ptr<std::string> s);

   int size() const { return static_cast<int>(string_data_.size()); }

  private:
   ~StringIOBuffer() override;

   std::string string_data_;
 };

 // This version wraps an existing IOBuffer and provides convenient functions
 // to progressively read all the data.
 //
 // DrainableIOBuffer is useful when you have an IOBuffer that contains data
 // to be written progressively, and Write() function takes an IOBuffer rather
 // than char*. DrainableIOBuffer can be used as follows:
 //
 // // payload is the IOBuffer containing the data to be written.
 // buf = base::MakeRefCounted<DrainableIOBuffer>(payload, payload_size);
 //
 // while (buf->BytesRemaining() > 0) {
 //   // Write() takes an IOBuffer. If it takes char*, we could
 //   // simply use the regular IOBuffer like payload->data() + offset.
 //   int bytes_written = Write(buf, buf->BytesRemaining());
 //   buf->DidConsume(bytes_written);
 // }
 //
 class NET_EXPORT DrainableIOBuffer : public IOBuffer {
  public:
   // TODO(eroman): Deprecated. Use the size_t flavor instead. crbug.com/488553
   DrainableIOBuffer(scoped_refptr<IOBuffer> base, int size);
   DrainableIOBuffer(scoped_refptr<IOBuffer> base, size_t size);

   // DidConsume() changes the |data_| pointer so that |data_| always points
   // to the first unconsumed byte.
   void DidConsume(int bytes);

   // Returns the number of unconsumed bytes.
   int BytesRemaining() const;

   // Returns the number of consumed bytes.
   int BytesConsumed() const;

   // Seeks to an arbitrary point in the buffer. The notion of bytes consumed
   // and remaining are updated appropriately.
   void SetOffset(int bytes);

   int size() const { return size_; }

  private:
   ~DrainableIOBuffer() override;

   scoped_refptr<IOBuffer> base_;
   int size_;
   int used_;
 };

 // This version provides a resizable buffer and a changeable offset.
 //
 // GrowableIOBuffer is useful when you read data progressively without
 // knowing the total size in advance. GrowableIOBuffer can be used as
 // follows:
 //
 // buf = base::MakeRefCounted<GrowableIOBuffer>();
 // buf->SetCapacity(1024);  // Initial capacity.
 //
 // while (!some_stream->IsEOF()) {
 //   // Double the capacity if the remaining capacity is empty.
 //   if (buf->RemainingCapacity() == 0)
 //     buf->SetCapacity(buf->capacity() * 2);
 //   int bytes_read = some_stream->Read(buf, buf->RemainingCapacity());
 //   buf->set_offset(buf->offset() + bytes_read);
 // }
 //
 class NET_EXPORT GrowableIOBuffer : public IOBuffer {
  public:
   GrowableIOBuffer();

   // realloc memory to the specified capacity.
   void SetCapacity(int capacity);
   int capacity() { return capacity_; }

   // |offset| moves the |data_| pointer, allowing "seeking" in the data.
   void set_offset(int offset);
   int offset() { return offset_; }

   int RemainingCapacity();
   char* StartOfBuffer();

  private:
   ~GrowableIOBuffer() override;

   std::unique_ptr<char, base::FreeDeleter> real_data_;
   int capacity_;
   int offset_;
 };

 // This versions allows a pickle to be used as the storage for a write-style
 // operation, avoiding an extra data copy.
 class NET_EXPORT PickledIOBuffer : public IOBuffer {
  public:
   PickledIOBuffer();

   base::Pickle* pickle() { return &pickle_; }

   // Signals that we are done writing to the pickle and we can use it for a
   // write-style IO operation.
   void Done();

  private:
   ~PickledIOBuffer() override;

   base::Pickle pickle_;
 };

 // This class allows the creation of a temporary IOBuffer that doesn't really
 // own the underlying buffer. Please use this class only as a last resort.
 // A good example is the buffer for a synchronous operation, where we can be
 // sure that nobody is keeping an extra reference to this object so the lifetime
 // of the buffer can be completely managed by its intended owner.
 class NET_EXPORT WrappedIOBuffer : public IOBuffer {
  public:
   explicit WrappedIOBuffer(const char* data);

  protected:
   ~WrappedIOBuffer() override;
 };

 }  // namespace net

 #endif  // NET_BASE_IO_BUFFER_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_BASE_IO_BUFFER_H_
	#define NET_BASE_IO_BUFFER_H_

	#include <memory>
	#include <string>

	#include "base/memory/free_deleter.h"
	#include "base/memory/ref_counted.h"
	#include "base/pickle.h"
	#include "net/base/net_export.h"
	#include "starboard/types.h"

	namespace net {

	// IOBuffers are reference counted data buffers used for easier asynchronous
	// IO handling.
	//
	// They are often used as the destination buffers for Read() operations, or as
	// the source buffers for Write() operations.
	//
	// IMPORTANT: Never re-use an IOBuffer after cancelling the IO operation that
	// was using it, since this may lead to memory corruption!
	//
	// -----------------------
	// Ownership of IOBuffers:
	// -----------------------
	//
	// Although IOBuffers are RefCountedThreadSafe, they are not intended to be
	// used as a shared buffer, nor should they be used simultaneously across
	// threads. The fact that they are reference counted is an implementation
	// detail for allowing them to outlive cancellation of asynchronous
	// operations.
	//
	// Instead, think of the underlying \|char*\| buffer contained by the IOBuffer
	// as having exactly one owner at a time.
	//
	// Whenever you call an asynchronous operation that takes an IOBuffer,
	// ownership is implicitly transferred to the called function, until the
	// operation has completed (at which point it transfers back to the caller).
	//
	// ==> The IOBuffer's data should NOT be manipulated, destroyed, or read
	// until the operation has completed.
	//
	// ==> Cancellation does NOT count as completion. If an operation using
	// an IOBuffer is cancelled, the caller should release their
	// reference to this IOBuffer at the time of cancellation since
	// they can no longer use it.
	//
	// For instance, if you were to call a Read() operation on some class which
	// takes an IOBuffer, and then delete that class (which generally will
	// trigger cancellation), the IOBuffer which had been passed to Read() should
	// never be re-used.
	//
	// This usage contract is assumed by any API which takes an IOBuffer, even
	// though it may not be explicitly mentioned in the function's comments.
	//
	// -----------------------
	// Motivation
	// -----------------------
	//
	// The motivation for transferring ownership during cancellation is
	// to make it easier to work with un-cancellable operations.
	//
	// For instance, let's say under the hood your API called out to the
	// operating system's synchronous ReadFile() function on a worker thread.
	// When cancelling through our asynchronous interface, we have no way of
	// actually aborting the in progress ReadFile(). We must let it keep running,
	// and hence the buffer it was reading into must remain alive. Using
	// reference counting we can add a reference to the IOBuffer and make sure
	// it is not destroyed until after the synchronous operation has completed.
	class NET_EXPORT IOBuffer : public base::RefCountedThreadSafe<IOBuffer> {
	public:
	IOBuffer();

	// TODO(eroman): Deprecated. Use the size_t flavor instead. crbug.com/488553
	explicit IOBuffer(int buffer_size);
	explicit IOBuffer(size_t buffer_size);

	char* data() const { return data_; }

	protected:
	friend class base::RefCountedThreadSafe<IOBuffer>;

	// Only allow derived classes to specify data_.
	// In all other cases, we own data_, and must delete it at destruction time.
	explicit IOBuffer(char* data);

	virtual ~IOBuffer();

	char* data_;
	};

	// This version stores the size of the buffer so that the creator of the object
	// doesn't have to keep track of that value.
	// NOTE: This doesn't mean that we want to stop sending the size as an explicit
	// argument to IO functions. Please keep using IOBuffer* for API declarations.
	class NET_EXPORT IOBufferWithSize : public IOBuffer {
	public:
	// TODO(eroman): Deprecated. Use the size_t flavor instead. crbug.com/488553
	explicit IOBufferWithSize(int size);
	explicit IOBufferWithSize(size_t size);

	int size() const { return size_; }

	protected:
	// TODO(eroman): Deprecated. Use the size_t flavor instead. crbug.com/488553
	IOBufferWithSize(char* data, int size);

	// Purpose of this constructor is to give a subclass access to the base class
	// constructor IOBuffer(char*) thus allowing subclass to use underlying
	// memory it does not own.
	IOBufferWithSize(char* data, size_t size);
	~IOBufferWithSize() override;

	int size_;
	};

	// This is a read only IOBuffer. The data is stored in a string and
	// the IOBuffer interface does not provide a proper way to modify it.
	class NET_EXPORT StringIOBuffer : public IOBuffer {
	public:
	explicit StringIOBuffer(const std::string& s);
	explicit StringIOBuffer(std::unique_ptr<std::string> s);

	int size() const { return static_cast<int>(string_data_.size()); }

	private:
	~StringIOBuffer() override;

	std::string string_data_;
	};

	// This version wraps an existing IOBuffer and provides convenient functions
	// to progressively read all the data.
	//
	// DrainableIOBuffer is useful when you have an IOBuffer that contains data
	// to be written progressively, and Write() function takes an IOBuffer rather
	// than char*. DrainableIOBuffer can be used as follows:
	//
	// // payload is the IOBuffer containing the data to be written.
	// buf = base::MakeRefCounted<DrainableIOBuffer>(payload, payload_size);
	//
	// while (buf->BytesRemaining() > 0) {
	// // Write() takes an IOBuffer. If it takes char*, we could
	// // simply use the regular IOBuffer like payload->data() + offset.
	// int bytes_written = Write(buf, buf->BytesRemaining());
	// buf->DidConsume(bytes_written);
	// }
	//
	class NET_EXPORT DrainableIOBuffer : public IOBuffer {
	public:
	// TODO(eroman): Deprecated. Use the size_t flavor instead. crbug.com/488553
	DrainableIOBuffer(scoped_refptr<IOBuffer> base, int size);
	DrainableIOBuffer(scoped_refptr<IOBuffer> base, size_t size);

	// DidConsume() changes the \|data_\| pointer so that \|data_\| always points
	// to the first unconsumed byte.
	void DidConsume(int bytes);

	// Returns the number of unconsumed bytes.
	int BytesRemaining() const;

	// Returns the number of consumed bytes.
	int BytesConsumed() const;

	// Seeks to an arbitrary point in the buffer. The notion of bytes consumed
	// and remaining are updated appropriately.
	void SetOffset(int bytes);

	int size() const { return size_; }

	private:
	~DrainableIOBuffer() override;

	scoped_refptr<IOBuffer> base_;
	int size_;
	int used_;
	};

	// This version provides a resizable buffer and a changeable offset.
	//
	// GrowableIOBuffer is useful when you read data progressively without
	// knowing the total size in advance. GrowableIOBuffer can be used as
	// follows:
	//
	// buf = base::MakeRefCounted<GrowableIOBuffer>();
	// buf->SetCapacity(1024); // Initial capacity.
	//
	// while (!some_stream->IsEOF()) {
	// // Double the capacity if the remaining capacity is empty.
	// if (buf->RemainingCapacity() == 0)
	// buf->SetCapacity(buf->capacity() * 2);
	// int bytes_read = some_stream->Read(buf, buf->RemainingCapacity());
	// buf->set_offset(buf->offset() + bytes_read);
	// }
	//
	class NET_EXPORT GrowableIOBuffer : public IOBuffer {
	public:
	GrowableIOBuffer();

	// realloc memory to the specified capacity.
	void SetCapacity(int capacity);
	int capacity() { return capacity_; }

	// \|offset\| moves the \|data_\| pointer, allowing "seeking" in the data.
	void set_offset(int offset);
	int offset() { return offset_; }

	int RemainingCapacity();
	char* StartOfBuffer();

	private:
	~GrowableIOBuffer() override;

	std::unique_ptr<char, base::FreeDeleter> real_data_;
	int capacity_;
	int offset_;
	};

	// This versions allows a pickle to be used as the storage for a write-style
	// operation, avoiding an extra data copy.
	class NET_EXPORT PickledIOBuffer : public IOBuffer {
	public:
	PickledIOBuffer();

	base::Pickle* pickle() { return &pickle_; }

	// Signals that we are done writing to the pickle and we can use it for a
	// write-style IO operation.
	void Done();

	private:
	~PickledIOBuffer() override;

	base::Pickle pickle_;
	};

	// This class allows the creation of a temporary IOBuffer that doesn't really
	// own the underlying buffer. Please use this class only as a last resort.
	// A good example is the buffer for a synchronous operation, where we can be
	// sure that nobody is keeping an extra reference to this object so the lifetime
	// of the buffer can be completely managed by its intended owner.
	class NET_EXPORT WrappedIOBuffer : public IOBuffer {
	public:
	explicit WrappedIOBuffer(const char* data);

	protected:
	~WrappedIOBuffer() override;
	};

	} // namespace net

	#endif // NET_BASE_IO_BUFFER_H_