webrtc/base/buffer.h - platform/external/webrtc - Git at Google

 /*
  *  Copyright 2004 The WebRTC Project Authors. All rights reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #ifndef WEBRTC_BASE_BUFFER_H_
 #define WEBRTC_BASE_BUFFER_H_

 #include <algorithm>  // std::swap (pre-C++11)
 #include <cassert>
 #include <cstring>
 #include <utility>  // std::swap (C++11 and later)
 #include "webrtc/base/scoped_ptr.h"

 namespace rtc {

 namespace internal {

 // (Internal; please don't use outside this file.) ByteType<T>::t is int if T
 // is uint8_t, int8_t, or char; otherwise, it's a compilation error. Use like
 // this:
 //
 //   template <typename T, typename ByteType<T>::t = 0>
 //   void foo(T* x);
 //
 // to let foo<T> be defined only for byte-sized integers.
 template <typename T>
 struct ByteType {
  private:
   static int F(uint8_t*);
   static int F(int8_t*);
   static int F(char*);

  public:
   using t = decltype(F(static_cast<T*>(nullptr)));
 };

 }  // namespace internal

 // Basic buffer class, can be grown and shrunk dynamically.
 // Unlike std::string/vector, does not initialize data when expanding capacity.
 class Buffer final {
  public:
   Buffer();                   // An empty buffer.
   Buffer(const Buffer& buf);  // Copy size and contents of an existing buffer.
   Buffer(Buffer&& buf);       // Move contents from an existing buffer.

   // Construct a buffer with the specified number of uninitialized bytes.
   explicit Buffer(size_t size);
   Buffer(size_t size, size_t capacity);

   // Construct a buffer and copy the specified number of bytes into it. The
   // source array may be (const) uint8_t*, int8_t*, or char*.
   template <typename T, typename internal::ByteType<T>::t = 0>
   Buffer(const T* data, size_t size)
       : Buffer(data, size, size) {}
   template <typename T, typename internal::ByteType<T>::t = 0>
   Buffer(const T* data, size_t size, size_t capacity)
       : Buffer(size, capacity) {
     std::memcpy(data_.get(), data, size);
   }

   // Construct a buffer from the contents of an array.
   template <typename T, size_t N, typename internal::ByteType<T>::t = 0>
   Buffer(const T(&array)[N])
       : Buffer(array, N) {}

   ~Buffer();

   // Get a pointer to the data. Just .data() will give you a (const) uint8_t*,
   // but you may also use .data<int8_t>() and .data<char>().
   template <typename T = uint8_t, typename internal::ByteType<T>::t = 0>
   const T* data() const {
     assert(IsConsistent());
     return reinterpret_cast<T*>(data_.get());
   }
   template <typename T = uint8_t, typename internal::ByteType<T>::t = 0>
   T* data() {
     assert(IsConsistent());
     return reinterpret_cast<T*>(data_.get());
   }

   size_t size() const {
     assert(IsConsistent());
     return size_;
   }
   size_t capacity() const {
     assert(IsConsistent());
     return capacity_;
   }

   Buffer& operator=(const Buffer& buf) {
     if (&buf != this)
       SetData(buf.data(), buf.size());
     return *this;
   }
   Buffer& operator=(Buffer&& buf) {
     assert(IsConsistent());
     assert(buf.IsConsistent());
     size_ = buf.size_;
     capacity_ = buf.capacity_;
     data_ = buf.data_.Pass();
     buf.OnMovedFrom();
     return *this;
   }

   bool operator==(const Buffer& buf) const {
     assert(IsConsistent());
     return size_ == buf.size() && memcmp(data_.get(), buf.data(), size_) == 0;
   }

   bool operator!=(const Buffer& buf) const { return !(*this == buf); }

   // Replace the contents of the buffer. Accepts the same types as the
   // constructors.
   template <typename T, typename internal::ByteType<T>::t = 0>
   void SetData(const T* data, size_t size) {
     assert(IsConsistent());
     size_ = 0;
     AppendData(data, size);
   }
   template <typename T, size_t N, typename internal::ByteType<T>::t = 0>
   void SetData(const T(&array)[N]) {
     SetData(array, N);
   }
   void SetData(const Buffer& buf) { SetData(buf.data(), buf.size()); }

   // Append data to the buffer. Accepts the same types as the constructors.
   template <typename T, typename internal::ByteType<T>::t = 0>
   void AppendData(const T* data, size_t size) {
     assert(IsConsistent());
     const size_t new_size = size_ + size;
     EnsureCapacity(new_size);
     std::memcpy(data_.get() + size_, data, size);
     size_ = new_size;
     assert(IsConsistent());
   }
   template <typename T, size_t N, typename internal::ByteType<T>::t = 0>
   void AppendData(const T(&array)[N]) {
     AppendData(array, N);
   }
   void AppendData(const Buffer& buf) { AppendData(buf.data(), buf.size()); }

   // Sets the size of the buffer. If the new size is smaller than the old, the
   // buffer contents will be kept but truncated; if the new size is greater,
   // the existing contents will be kept and the new space will be
   // uninitialized.
   void SetSize(size_t size) {
     EnsureCapacity(size);
     size_ = size;
   }

   // Ensure that the buffer size can be increased to at least capacity without
   // further reallocation. (Of course, this operation might need to reallocate
   // the buffer.)
   void EnsureCapacity(size_t capacity) {
     assert(IsConsistent());
     if (capacity <= capacity_)
       return;
     scoped_ptr<uint8_t[]> new_data(new uint8_t[capacity]);
     std::memcpy(new_data.get(), data_.get(), size_);
     data_ = new_data.Pass();
     capacity_ = capacity;
     assert(IsConsistent());
   }

   // We can't call std::move(b), so call b.Pass() instead to do the same job.
   Buffer&& Pass() {
     assert(IsConsistent());
     return static_cast<Buffer&&>(*this);
   }

   // Resets the buffer to zero size and capacity. Works even if the buffer has
   // been moved from.
   void Clear() {
     data_.reset();
     size_ = 0;
     capacity_ = 0;
     assert(IsConsistent());
   }

   // Swaps two buffers. Also works for buffers that have been moved from.
   friend void swap(Buffer& a, Buffer& b) {
     using std::swap;
     swap(a.size_, b.size_);
     swap(a.capacity_, b.capacity_);
     swap(a.data_, b.data_);
   }

  private:
   // Precondition for all methods except Clear and the destructor.
   // Postcondition for all methods except move construction and move
   // assignment, which leave the moved-from object in a possibly inconsistent
   // state.
   bool IsConsistent() const {
     return (data_ || capacity_ == 0) && capacity_ >= size_;
   }

   // Called when *this has been moved from. Conceptually it's a no-op, but we
   // can mutate the state slightly to help subsequent sanity checks catch bugs.
   void OnMovedFrom() {
 #ifdef NDEBUG
     // Make *this consistent and empty. Shouldn't be necessary, but better safe
     // than sorry.
     size_ = 0;
     capacity_ = 0;
 #else
     // Ensure that *this is always inconsistent, to provoke bugs.
     size_ = 1;
     capacity_ = 0;
 #endif
   }

   size_t size_;
   size_t capacity_;
   scoped_ptr<uint8_t[]> data_;
 };

 }  // namespace rtc

 #endif  // WEBRTC_BASE_BUFFER_H_
	/*
	* Copyright 2004 The WebRTC Project Authors. All rights reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#ifndef WEBRTC_BASE_BUFFER_H_
	#define WEBRTC_BASE_BUFFER_H_

	#include <algorithm> // std::swap (pre-C++11)
	#include <cassert>
	#include <cstring>
	#include <utility> // std::swap (C++11 and later)
	#include "webrtc/base/scoped_ptr.h"

	namespace rtc {

	namespace internal {

	// (Internal; please don't use outside this file.) ByteType<T>::t is int if T
	// is uint8_t, int8_t, or char; otherwise, it's a compilation error. Use like
	// this:
	//
	// template <typename T, typename ByteType<T>::t = 0>
	// void foo(T* x);
	//
	// to let foo<T> be defined only for byte-sized integers.
	template <typename T>
	struct ByteType {
	private:
	static int F(uint8_t*);
	static int F(int8_t*);
	static int F(char*);

	public:
	using t = decltype(F(static_cast<T*>(nullptr)));
	};

	} // namespace internal

	// Basic buffer class, can be grown and shrunk dynamically.
	// Unlike std::string/vector, does not initialize data when expanding capacity.
	class Buffer final {
	public:
	Buffer(); // An empty buffer.
	Buffer(const Buffer& buf); // Copy size and contents of an existing buffer.
	Buffer(Buffer&& buf); // Move contents from an existing buffer.

	// Construct a buffer with the specified number of uninitialized bytes.
	explicit Buffer(size_t size);
	Buffer(size_t size, size_t capacity);

	// Construct a buffer and copy the specified number of bytes into it. The
	// source array may be (const) uint8_t, int8_t, or char*.
	template <typename T, typename internal::ByteType<T>::t = 0>
	Buffer(const T* data, size_t size)
	: Buffer(data, size, size) {}
	template <typename T, typename internal::ByteType<T>::t = 0>
	Buffer(const T* data, size_t size, size_t capacity)
	: Buffer(size, capacity) {
	std::memcpy(data_.get(), data, size);
	}

	// Construct a buffer from the contents of an array.
	template <typename T, size_t N, typename internal::ByteType<T>::t = 0>
	Buffer(const T(&array)[N])
	: Buffer(array, N) {}

	~Buffer();

	// Get a pointer to the data. Just .data() will give you a (const) uint8_t*,
	// but you may also use .data<int8_t>() and .data<char>().
	template <typename T = uint8_t, typename internal::ByteType<T>::t = 0>
	const T* data() const {
	assert(IsConsistent());
	return reinterpret_cast<T*>(data_.get());
	}
	template <typename T = uint8_t, typename internal::ByteType<T>::t = 0>
	T* data() {
	assert(IsConsistent());
	return reinterpret_cast<T*>(data_.get());
	}

	size_t size() const {
	assert(IsConsistent());
	return size_;
	}
	size_t capacity() const {
	assert(IsConsistent());
	return capacity_;
	}

	Buffer& operator=(const Buffer& buf) {
	if (&buf != this)
	SetData(buf.data(), buf.size());
	return *this;
	}
	Buffer& operator=(Buffer&& buf) {
	assert(IsConsistent());
	assert(buf.IsConsistent());
	size_ = buf.size_;
	capacity_ = buf.capacity_;
	data_ = buf.data_.Pass();
	buf.OnMovedFrom();
	return *this;
	}

	bool operator==(const Buffer& buf) const {
	assert(IsConsistent());
	return size_ == buf.size() && memcmp(data_.get(), buf.data(), size_) == 0;
	}

	bool operator!=(const Buffer& buf) const { return !(*this == buf); }

	// Replace the contents of the buffer. Accepts the same types as the
	// constructors.
	template <typename T, typename internal::ByteType<T>::t = 0>
	void SetData(const T* data, size_t size) {
	assert(IsConsistent());
	size_ = 0;
	AppendData(data, size);
	}
	template <typename T, size_t N, typename internal::ByteType<T>::t = 0>
	void SetData(const T(&array)[N]) {
	SetData(array, N);
	}
	void SetData(const Buffer& buf) { SetData(buf.data(), buf.size()); }

	// Append data to the buffer. Accepts the same types as the constructors.
	template <typename T, typename internal::ByteType<T>::t = 0>
	void AppendData(const T* data, size_t size) {
	assert(IsConsistent());
	const size_t new_size = size_ + size;
	EnsureCapacity(new_size);
	std::memcpy(data_.get() + size_, data, size);
	size_ = new_size;
	assert(IsConsistent());
	}
	template <typename T, size_t N, typename internal::ByteType<T>::t = 0>
	void AppendData(const T(&array)[N]) {
	AppendData(array, N);
	}
	void AppendData(const Buffer& buf) { AppendData(buf.data(), buf.size()); }

	// Sets the size of the buffer. If the new size is smaller than the old, the
	// buffer contents will be kept but truncated; if the new size is greater,
	// the existing contents will be kept and the new space will be
	// uninitialized.
	void SetSize(size_t size) {
	EnsureCapacity(size);
	size_ = size;
	}

	// Ensure that the buffer size can be increased to at least capacity without
	// further reallocation. (Of course, this operation might need to reallocate
	// the buffer.)
	void EnsureCapacity(size_t capacity) {
	assert(IsConsistent());
	if (capacity <= capacity_)
	return;
	scoped_ptr<uint8_t[]> new_data(new uint8_t[capacity]);
	std::memcpy(new_data.get(), data_.get(), size_);
	data_ = new_data.Pass();
	capacity_ = capacity;
	assert(IsConsistent());
	}

	// We can't call std::move(b), so call b.Pass() instead to do the same job.
	Buffer&& Pass() {
	assert(IsConsistent());
	return static_cast<Buffer&&>(*this);
	}

	// Resets the buffer to zero size and capacity. Works even if the buffer has
	// been moved from.
	void Clear() {
	data_.reset();
	size_ = 0;
	capacity_ = 0;
	assert(IsConsistent());
	}

	// Swaps two buffers. Also works for buffers that have been moved from.
	friend void swap(Buffer& a, Buffer& b) {
	using std::swap;
	swap(a.size_, b.size_);
	swap(a.capacity_, b.capacity_);
	swap(a.data_, b.data_);
	}

	private:
	// Precondition for all methods except Clear and the destructor.
	// Postcondition for all methods except move construction and move
	// assignment, which leave the moved-from object in a possibly inconsistent
	// state.
	bool IsConsistent() const {
	return (data_ \|\| capacity_ == 0) && capacity_ >= size_;
	}

	// Called when *this has been moved from. Conceptually it's a no-op, but we
	// can mutate the state slightly to help subsequent sanity checks catch bugs.
	void OnMovedFrom() {
	#ifdef NDEBUG
	// Make *this consistent and empty. Shouldn't be necessary, but better safe
	// than sorry.
	size_ = 0;
	capacity_ = 0;
	#else
	// Ensure that *this is always inconsistent, to provoke bugs.
	size_ = 1;
	capacity_ = 0;
	#endif
	}

	size_t size_;
	size_t capacity_;
	scoped_ptr<uint8_t[]> data_;
	};

	} // namespace rtc

	#endif // WEBRTC_BASE_BUFFER_H_