rtc_base/buffer.h - src - 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 RTC_BASE_BUFFER_H_
 #define RTC_BASE_BUFFER_H_

 #include <stdint.h>

 #include <algorithm>
 #include <cstring>
 #include <memory>
 #include <type_traits>
 #include <utility>

 #include "api/array_view.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/type_traits.h"
 #include "rtc_base/zero_memory.h"

 namespace rtc {

 namespace internal {

 // (Internal; please don't use outside this file.) Determines if elements of
 // type U are compatible with a BufferT<T>. For most types, we just ignore
 // top-level const and forbid top-level volatile and require T and U to be
 // otherwise equal, but all byte-sized integers (notably char, int8_t, and
 // uint8_t) are compatible with each other. (Note: We aim to get rid of this
 // behavior, and treat all types the same.)
 template <typename T, typename U>
 struct BufferCompat {
   static constexpr bool value =
       !std::is_volatile<U>::value &&
       ((std::is_integral<T>::value && sizeof(T) == 1)
            ? (std::is_integral<U>::value && sizeof(U) == 1)
            : (std::is_same<T, typename std::remove_const<U>::type>::value));
 };

 }  // namespace internal

 // Basic buffer class, can be grown and shrunk dynamically.
 // Unlike std::string/vector, does not initialize data when increasing size.
 // If "ZeroOnFree" is true, any memory is explicitly cleared before releasing.
 // The type alias "ZeroOnFreeBuffer" below should be used instead of setting
 // "ZeroOnFree" in the template manually to "true".
 template <typename T, bool ZeroOnFree = false>
 class BufferT {
   // We want T's destructor and default constructor to be trivial, i.e. perform
   // no action, so that we don't have to touch the memory we allocate and
   // deallocate. And we want T to be trivially copyable, so that we can copy T
   // instances with std::memcpy. This is precisely the definition of a trivial
   // type.
   static_assert(std::is_trivial<T>::value, "T must be a trivial type.");

   // This class relies heavily on being able to mutate its data.
   static_assert(!std::is_const<T>::value, "T may not be const");

  public:
   using value_type = T;
   using const_iterator = const T*;

   // An empty BufferT.
   BufferT() : size_(0), capacity_(0), data_(nullptr) {
     RTC_DCHECK(IsConsistent());
   }

   // Disable copy construction and copy assignment, since copying a buffer is
   // expensive enough that we want to force the user to be explicit about it.
   BufferT(const BufferT&) = delete;
   BufferT& operator=(const BufferT&) = delete;

   BufferT(BufferT&& buf)
       : size_(buf.size()),
         capacity_(buf.capacity()),
         data_(std::move(buf.data_)) {
     RTC_DCHECK(IsConsistent());
     buf.OnMovedFrom();
   }

   // Construct a buffer with the specified number of uninitialized elements.
   explicit BufferT(size_t size) : BufferT(size, size) {}

   BufferT(size_t size, size_t capacity)
       : size_(size),
         capacity_(std::max(size, capacity)),
         data_(capacity_ > 0 ? new T[capacity_] : nullptr) {
     RTC_DCHECK(IsConsistent());
   }

   // Construct a buffer and copy the specified number of elements into it.
   template <typename U,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   BufferT(const U* data, size_t size) : BufferT(data, size, size) {}

   template <typename U,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   BufferT(U* data, size_t size, size_t capacity) : BufferT(size, capacity) {
     static_assert(sizeof(T) == sizeof(U), "");
     std::memcpy(data_.get(), data, size * sizeof(U));
   }

   // Construct a buffer from the contents of an array.
   template <typename U,
             size_t N,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   BufferT(U (&array)[N]) : BufferT(array, N) {}

   ~BufferT() { MaybeZeroCompleteBuffer(); }

   // Get a pointer to the data. Just .data() will give you a (const) T*, but if
   // T is a byte-sized integer, you may also use .data<U>() for any other
   // byte-sized integer U.
   template <typename U = T,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   const U* data() const {
     RTC_DCHECK(IsConsistent());
     return reinterpret_cast<U*>(data_.get());
   }

   template <typename U = T,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   U* data() {
     RTC_DCHECK(IsConsistent());
     return reinterpret_cast<U*>(data_.get());
   }

   bool empty() const {
     RTC_DCHECK(IsConsistent());
     return size_ == 0;
   }

   size_t size() const {
     RTC_DCHECK(IsConsistent());
     return size_;
   }

   size_t capacity() const {
     RTC_DCHECK(IsConsistent());
     return capacity_;
   }

   BufferT& operator=(BufferT&& buf) {
     RTC_DCHECK(buf.IsConsistent());
     MaybeZeroCompleteBuffer();
     size_ = buf.size_;
     capacity_ = buf.capacity_;
     using std::swap;
     swap(data_, buf.data_);
     buf.data_.reset();
     buf.OnMovedFrom();
     return *this;
   }

   bool operator==(const BufferT& buf) const {
     RTC_DCHECK(IsConsistent());
     if (size_ != buf.size_) {
       return false;
     }
     if (std::is_integral<T>::value) {
       // Optimization.
       return std::memcmp(data_.get(), buf.data_.get(), size_ * sizeof(T)) == 0;
     }
     for (size_t i = 0; i < size_; ++i) {
       if (data_[i] != buf.data_[i]) {
         return false;
       }
     }
     return true;
   }

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

   T& operator[](size_t index) {
     RTC_DCHECK_LT(index, size_);
     return data()[index];
   }

   T operator[](size_t index) const {
     RTC_DCHECK_LT(index, size_);
     return data()[index];
   }

   T* begin() { return data(); }
   T* end() { return data() + size(); }
   const T* begin() const { return data(); }
   const T* end() const { return data() + size(); }
   const T* cbegin() const { return data(); }
   const T* cend() const { return data() + size(); }

   // The SetData functions replace the contents of the buffer. They accept the
   // same input types as the constructors.
   template <typename U,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   void SetData(const U* data, size_t size) {
     RTC_DCHECK(IsConsistent());
     const size_t old_size = size_;
     size_ = 0;
     AppendData(data, size);
     if (ZeroOnFree && size_ < old_size) {
       ZeroTrailingData(old_size - size_);
     }
   }

   template <typename U,
             size_t N,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   void SetData(const U (&array)[N]) {
     SetData(array, N);
   }

   template <typename W,
             typename std::enable_if<
                 HasDataAndSize<const W, const T>::value>::type* = nullptr>
   void SetData(const W& w) {
     SetData(w.data(), w.size());
   }

   // Replaces the data in the buffer with at most |max_elements| of data, using
   // the function |setter|, which should have the following signature:
   //
   //   size_t setter(ArrayView<U> view)
   //
   // |setter| is given an appropriately typed ArrayView of length exactly
   // |max_elements| that describes the area where it should write the data; it
   // should return the number of elements actually written. (If it doesn't fill
   // the whole ArrayView, it should leave the unused space at the end.)
   template <typename U = T,
             typename F,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   size_t SetData(size_t max_elements, F&& setter) {
     RTC_DCHECK(IsConsistent());
     const size_t old_size = size_;
     size_ = 0;
     const size_t written = AppendData<U>(max_elements, std::forward<F>(setter));
     if (ZeroOnFree && size_ < old_size) {
       ZeroTrailingData(old_size - size_);
     }
     return written;
   }

   // The AppendData functions add data to the end of the buffer. They accept
   // the same input types as the constructors.
   template <typename U,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   void AppendData(const U* data, size_t size) {
     RTC_DCHECK(IsConsistent());
     const size_t new_size = size_ + size;
     EnsureCapacityWithHeadroom(new_size, true);
     static_assert(sizeof(T) == sizeof(U), "");
     std::memcpy(data_.get() + size_, data, size * sizeof(U));
     size_ = new_size;
     RTC_DCHECK(IsConsistent());
   }

   template <typename U,
             size_t N,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   void AppendData(const U (&array)[N]) {
     AppendData(array, N);
   }

   template <typename W,
             typename std::enable_if<
                 HasDataAndSize<const W, const T>::value>::type* = nullptr>
   void AppendData(const W& w) {
     AppendData(w.data(), w.size());
   }

   template <typename U,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   void AppendData(const U& item) {
     AppendData(&item, 1);
   }

   // Appends at most |max_elements| to the end of the buffer, using the function
   // |setter|, which should have the following signature:
   //
   //   size_t setter(ArrayView<U> view)
   //
   // |setter| is given an appropriately typed ArrayView of length exactly
   // |max_elements| that describes the area where it should write the data; it
   // should return the number of elements actually written. (If it doesn't fill
   // the whole ArrayView, it should leave the unused space at the end.)
   template <typename U = T,
             typename F,
             typename std::enable_if<
                 internal::BufferCompat<T, U>::value>::type* = nullptr>
   size_t AppendData(size_t max_elements, F&& setter) {
     RTC_DCHECK(IsConsistent());
     const size_t old_size = size_;
     SetSize(old_size + max_elements);
     U* base_ptr = data<U>() + old_size;
     size_t written_elements = setter(rtc::ArrayView<U>(base_ptr, max_elements));

     RTC_CHECK_LE(written_elements, max_elements);
     size_ = old_size + written_elements;
     RTC_DCHECK(IsConsistent());
     return written_elements;
   }

   // 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) {
     const size_t old_size = size_;
     EnsureCapacityWithHeadroom(size, true);
     size_ = size;
     if (ZeroOnFree && size_ < old_size) {
       ZeroTrailingData(old_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) {
     // Don't allocate extra headroom, since the user is asking for a specific
     // capacity.
     EnsureCapacityWithHeadroom(capacity, false);
   }

   // Resets the buffer to zero size without altering capacity. Works even if the
   // buffer has been moved from.
   void Clear() {
     MaybeZeroCompleteBuffer();
     size_ = 0;
     RTC_DCHECK(IsConsistent());
   }

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

  private:
   void EnsureCapacityWithHeadroom(size_t capacity, bool extra_headroom) {
     RTC_DCHECK(IsConsistent());
     if (capacity <= capacity_)
       return;

     // If the caller asks for extra headroom, ensure that the new capacity is
     // >= 1.5 times the old capacity. Any constant > 1 is sufficient to prevent
     // quadratic behavior; as to why we pick 1.5 in particular, see
     // https://github.com/facebook/folly/blob/master/folly/docs/FBVector.md and
     // http://www.gahcep.com/cpp-internals-stl-vector-part-1/.
     const size_t new_capacity =
         extra_headroom ? std::max(capacity, capacity_ + capacity_ / 2)
                        : capacity;

     std::unique_ptr<T[]> new_data(new T[new_capacity]);
     if (data_ != nullptr) {
       std::memcpy(new_data.get(), data_.get(), size_ * sizeof(T));
     }
     MaybeZeroCompleteBuffer();
     data_ = std::move(new_data);
     capacity_ = new_capacity;
     RTC_DCHECK(IsConsistent());
   }

   // Zero the complete buffer if template argument "ZeroOnFree" is true.
   void MaybeZeroCompleteBuffer() {
     if (ZeroOnFree && capacity_ > 0) {
       // It would be sufficient to only zero "size_" elements, as all other
       // methods already ensure that the unused capacity contains no sensitive
       // data---but better safe than sorry.
       ExplicitZeroMemory(data_.get(), capacity_ * sizeof(T));
     }
   }

   // Zero the first "count" elements of unused capacity.
   void ZeroTrailingData(size_t count) {
     RTC_DCHECK(IsConsistent());
     RTC_DCHECK_LE(count, capacity_ - size_);
     ExplicitZeroMemory(data_.get() + size_, count * sizeof(T));
   }

   // Precondition for all methods except Clear, operator= 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() {
     RTC_DCHECK(!data_);  // Our heap block should have been stolen.
 #if RTC_DCHECK_IS_ON
     // Ensure that *this is always inconsistent, to provoke bugs.
     size_ = 1;
     capacity_ = 0;
 #else
     // Make *this consistent and empty. Shouldn't be necessary, but better safe
     // than sorry.
     size_ = 0;
     capacity_ = 0;
 #endif
   }

   size_t size_;
   size_t capacity_;
   std::unique_ptr<T[]> data_;
 };

 // By far the most common sort of buffer.
 using Buffer = BufferT<uint8_t>;

 // A buffer that zeros memory before releasing it.
 template <typename T>
 using ZeroOnFreeBuffer = BufferT<T, true>;

 }  // namespace rtc

 #endif  // RTC_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 RTC_BASE_BUFFER_H_
	#define RTC_BASE_BUFFER_H_

	#include <stdint.h>

	#include <algorithm>
	#include <cstring>
	#include <memory>
	#include <type_traits>
	#include <utility>

	#include "api/array_view.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/type_traits.h"
	#include "rtc_base/zero_memory.h"

	namespace rtc {

	namespace internal {

	// (Internal; please don't use outside this file.) Determines if elements of
	// type U are compatible with a BufferT<T>. For most types, we just ignore
	// top-level const and forbid top-level volatile and require T and U to be
	// otherwise equal, but all byte-sized integers (notably char, int8_t, and
	// uint8_t) are compatible with each other. (Note: We aim to get rid of this
	// behavior, and treat all types the same.)
	template <typename T, typename U>
	struct BufferCompat {
	static constexpr bool value =
	!std::is_volatile<U>::value &&
	((std::is_integral<T>::value && sizeof(T) == 1)
	? (std::is_integral<U>::value && sizeof(U) == 1)
	: (std::is_same<T, typename std::remove_const<U>::type>::value));
	};

	} // namespace internal

	// Basic buffer class, can be grown and shrunk dynamically.
	// Unlike std::string/vector, does not initialize data when increasing size.
	// If "ZeroOnFree" is true, any memory is explicitly cleared before releasing.
	// The type alias "ZeroOnFreeBuffer" below should be used instead of setting
	// "ZeroOnFree" in the template manually to "true".
	template <typename T, bool ZeroOnFree = false>
	class BufferT {
	// We want T's destructor and default constructor to be trivial, i.e. perform
	// no action, so that we don't have to touch the memory we allocate and
	// deallocate. And we want T to be trivially copyable, so that we can copy T
	// instances with std::memcpy. This is precisely the definition of a trivial
	// type.
	static_assert(std::is_trivial<T>::value, "T must be a trivial type.");

	// This class relies heavily on being able to mutate its data.
	static_assert(!std::is_const<T>::value, "T may not be const");

	public:
	using value_type = T;
	using const_iterator = const T*;

	// An empty BufferT.
	BufferT() : size_(0), capacity_(0), data_(nullptr) {
	RTC_DCHECK(IsConsistent());
	}

	// Disable copy construction and copy assignment, since copying a buffer is
	// expensive enough that we want to force the user to be explicit about it.
	BufferT(const BufferT&) = delete;
	BufferT& operator=(const BufferT&) = delete;

	BufferT(BufferT&& buf)
	: size_(buf.size()),
	capacity_(buf.capacity()),
	data_(std::move(buf.data_)) {
	RTC_DCHECK(IsConsistent());
	buf.OnMovedFrom();
	}

	// Construct a buffer with the specified number of uninitialized elements.
	explicit BufferT(size_t size) : BufferT(size, size) {}

	BufferT(size_t size, size_t capacity)
	: size_(size),
	capacity_(std::max(size, capacity)),
	data_(capacity_ > 0 ? new T[capacity_] : nullptr) {
	RTC_DCHECK(IsConsistent());
	}

	// Construct a buffer and copy the specified number of elements into it.
	template <typename U,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	BufferT(const U* data, size_t size) : BufferT(data, size, size) {}

	template <typename U,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	BufferT(U* data, size_t size, size_t capacity) : BufferT(size, capacity) {
	static_assert(sizeof(T) == sizeof(U), "");
	std::memcpy(data_.get(), data, size * sizeof(U));
	}

	// Construct a buffer from the contents of an array.
	template <typename U,
	size_t N,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	BufferT(U (&array)[N]) : BufferT(array, N) {}

	~BufferT() { MaybeZeroCompleteBuffer(); }

	// Get a pointer to the data. Just .data() will give you a (const) T*, but if
	// T is a byte-sized integer, you may also use .data<U>() for any other
	// byte-sized integer U.
	template <typename U = T,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	const U* data() const {
	RTC_DCHECK(IsConsistent());
	return reinterpret_cast<U*>(data_.get());
	}

	template <typename U = T,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	U* data() {
	RTC_DCHECK(IsConsistent());
	return reinterpret_cast<U*>(data_.get());
	}

	bool empty() const {
	RTC_DCHECK(IsConsistent());
	return size_ == 0;
	}

	size_t size() const {
	RTC_DCHECK(IsConsistent());
	return size_;
	}

	size_t capacity() const {
	RTC_DCHECK(IsConsistent());
	return capacity_;
	}

	BufferT& operator=(BufferT&& buf) {
	RTC_DCHECK(buf.IsConsistent());
	MaybeZeroCompleteBuffer();
	size_ = buf.size_;
	capacity_ = buf.capacity_;
	using std::swap;
	swap(data_, buf.data_);
	buf.data_.reset();
	buf.OnMovedFrom();
	return *this;
	}

	bool operator==(const BufferT& buf) const {
	RTC_DCHECK(IsConsistent());
	if (size_ != buf.size_) {
	return false;
	}
	if (std::is_integral<T>::value) {
	// Optimization.
	return std::memcmp(data_.get(), buf.data_.get(), size_ * sizeof(T)) == 0;
	}
	for (size_t i = 0; i < size_; ++i) {
	if (data_[i] != buf.data_[i]) {
	return false;
	}
	}
	return true;
	}

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

	T& operator[](size_t index) {
	RTC_DCHECK_LT(index, size_);
	return data()[index];
	}

	T operator[](size_t index) const {
	RTC_DCHECK_LT(index, size_);
	return data()[index];
	}

	T* begin() { return data(); }
	T* end() { return data() + size(); }
	const T* begin() const { return data(); }
	const T* end() const { return data() + size(); }
	const T* cbegin() const { return data(); }
	const T* cend() const { return data() + size(); }

	// The SetData functions replace the contents of the buffer. They accept the
	// same input types as the constructors.
	template <typename U,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	void SetData(const U* data, size_t size) {
	RTC_DCHECK(IsConsistent());
	const size_t old_size = size_;
	size_ = 0;
	AppendData(data, size);
	if (ZeroOnFree && size_ < old_size) {
	ZeroTrailingData(old_size - size_);
	}
	}

	template <typename U,
	size_t N,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	void SetData(const U (&array)[N]) {
	SetData(array, N);
	}

	template <typename W,
	typename std::enable_if<
	HasDataAndSize<const W, const T>::value>::type* = nullptr>
	void SetData(const W& w) {
	SetData(w.data(), w.size());
	}

	// Replaces the data in the buffer with at most \|max_elements\| of data, using
	// the function \|setter\|, which should have the following signature:
	//
	// size_t setter(ArrayView<U> view)
	//
	// \|setter\| is given an appropriately typed ArrayView of length exactly
	// \|max_elements\| that describes the area where it should write the data; it
	// should return the number of elements actually written. (If it doesn't fill
	// the whole ArrayView, it should leave the unused space at the end.)
	template <typename U = T,
	typename F,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	size_t SetData(size_t max_elements, F&& setter) {
	RTC_DCHECK(IsConsistent());
	const size_t old_size = size_;
	size_ = 0;
	const size_t written = AppendData<U>(max_elements, std::forward<F>(setter));
	if (ZeroOnFree && size_ < old_size) {
	ZeroTrailingData(old_size - size_);
	}
	return written;
	}

	// The AppendData functions add data to the end of the buffer. They accept
	// the same input types as the constructors.
	template <typename U,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	void AppendData(const U* data, size_t size) {
	RTC_DCHECK(IsConsistent());
	const size_t new_size = size_ + size;
	EnsureCapacityWithHeadroom(new_size, true);
	static_assert(sizeof(T) == sizeof(U), "");
	std::memcpy(data_.get() + size_, data, size * sizeof(U));
	size_ = new_size;
	RTC_DCHECK(IsConsistent());
	}

	template <typename U,
	size_t N,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	void AppendData(const U (&array)[N]) {
	AppendData(array, N);
	}

	template <typename W,
	typename std::enable_if<
	HasDataAndSize<const W, const T>::value>::type* = nullptr>
	void AppendData(const W& w) {
	AppendData(w.data(), w.size());
	}

	template <typename U,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	void AppendData(const U& item) {
	AppendData(&item, 1);
	}

	// Appends at most \|max_elements\| to the end of the buffer, using the function
	// \|setter\|, which should have the following signature:
	//
	// size_t setter(ArrayView<U> view)
	//
	// \|setter\| is given an appropriately typed ArrayView of length exactly
	// \|max_elements\| that describes the area where it should write the data; it
	// should return the number of elements actually written. (If it doesn't fill
	// the whole ArrayView, it should leave the unused space at the end.)
	template <typename U = T,
	typename F,
	typename std::enable_if<
	internal::BufferCompat<T, U>::value>::type* = nullptr>
	size_t AppendData(size_t max_elements, F&& setter) {
	RTC_DCHECK(IsConsistent());
	const size_t old_size = size_;
	SetSize(old_size + max_elements);
	U* base_ptr = data<U>() + old_size;
	size_t written_elements = setter(rtc::ArrayView<U>(base_ptr, max_elements));

	RTC_CHECK_LE(written_elements, max_elements);
	size_ = old_size + written_elements;
	RTC_DCHECK(IsConsistent());
	return written_elements;
	}

	// 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) {
	const size_t old_size = size_;
	EnsureCapacityWithHeadroom(size, true);
	size_ = size;
	if (ZeroOnFree && size_ < old_size) {
	ZeroTrailingData(old_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) {
	// Don't allocate extra headroom, since the user is asking for a specific
	// capacity.
	EnsureCapacityWithHeadroom(capacity, false);
	}

	// Resets the buffer to zero size without altering capacity. Works even if the
	// buffer has been moved from.
	void Clear() {
	MaybeZeroCompleteBuffer();
	size_ = 0;
	RTC_DCHECK(IsConsistent());
	}

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

	private:
	void EnsureCapacityWithHeadroom(size_t capacity, bool extra_headroom) {
	RTC_DCHECK(IsConsistent());
	if (capacity <= capacity_)
	return;

	// If the caller asks for extra headroom, ensure that the new capacity is
	// >= 1.5 times the old capacity. Any constant > 1 is sufficient to prevent
	// quadratic behavior; as to why we pick 1.5 in particular, see
	// https://github.com/facebook/folly/blob/master/folly/docs/FBVector.md and
	// http://www.gahcep.com/cpp-internals-stl-vector-part-1/.
	const size_t new_capacity =
	extra_headroom ? std::max(capacity, capacity_ + capacity_ / 2)
	: capacity;

	std::unique_ptr<T[]> new_data(new T[new_capacity]);
	if (data_ != nullptr) {
	std::memcpy(new_data.get(), data_.get(), size_ * sizeof(T));
	}
	MaybeZeroCompleteBuffer();
	data_ = std::move(new_data);
	capacity_ = new_capacity;
	RTC_DCHECK(IsConsistent());
	}

	// Zero the complete buffer if template argument "ZeroOnFree" is true.
	void MaybeZeroCompleteBuffer() {
	if (ZeroOnFree && capacity_ > 0) {
	// It would be sufficient to only zero "size_" elements, as all other
	// methods already ensure that the unused capacity contains no sensitive
	// data---but better safe than sorry.
	ExplicitZeroMemory(data_.get(), capacity_ * sizeof(T));
	}
	}

	// Zero the first "count" elements of unused capacity.
	void ZeroTrailingData(size_t count) {
	RTC_DCHECK(IsConsistent());
	RTC_DCHECK_LE(count, capacity_ - size_);
	ExplicitZeroMemory(data_.get() + size_, count * sizeof(T));
	}

	// Precondition for all methods except Clear, operator= 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() {
	RTC_DCHECK(!data_); // Our heap block should have been stolen.
	#if RTC_DCHECK_IS_ON
	// Ensure that *this is always inconsistent, to provoke bugs.
	size_ = 1;
	capacity_ = 0;
	#else
	// Make *this consistent and empty. Shouldn't be necessary, but better safe
	// than sorry.
	size_ = 0;
	capacity_ = 0;
	#endif
	}

	size_t size_;
	size_t capacity_;
	std::unique_ptr<T[]> data_;
	};

	// By far the most common sort of buffer.
	using Buffer = BufferT<uint8_t>;

	// A buffer that zeros memory before releasing it.
	template <typename T>
	using ZeroOnFreeBuffer = BufferT<T, true>;

	} // namespace rtc

	#endif // RTC_BASE_BUFFER_H_