// // buffer.hpp // ~~~~~~~~~~ // // Copyright (c) 2003-2015 Christopher M. Kohlhoff (chris at kohlhoff dot com) // // Distributed under the Boost Software License, Version 1.0. (See accompanying // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) // #ifndef ASIO_BUFFER_HPP #define ASIO_BUFFER_HPP #include "asio/detail/config.hpp" #include #include #include #include #include "asio/detail/array_fwd.hpp" #if defined(__GNUC__) # if defined(_GLIBCXX_DEBUG) # endif // defined(_GLIBCXX_DEBUG) #endif // defined(__GNUC__) #if defined(ASIO_ENABLE_ARRAY_BUFFER_WORKAROUND) # include "asio/detail/type_traits.hpp" #endif // defined(ASIO_ENABLE_ARRAY_BUFFER_WORKAROUND) #include "asio/detail/push_options.hpp" namespace asio { class mutable_buffer; class const_buffer; namespace detail { void* buffer_cast_helper(const mutable_buffer&); const void* buffer_cast_helper(const const_buffer&); std::size_t buffer_size_helper(const mutable_buffer&); std::size_t buffer_size_helper(const const_buffer&); } // namespace detail /// Holds a buffer that can be modified. /** * The mutable_buffer class provides a safe representation of a buffer that can * be modified. It does not own the underlying data, and so is cheap to copy or * assign. * * @par Accessing Buffer Contents * * The contents of a buffer may be accessed using the @ref buffer_size * and @ref buffer_cast functions: * * @code asio::mutable_buffer b1 = ...; * std::size_t s1 = asio::buffer_size(b1); * unsigned char* p1 = asio::buffer_cast(b1); * @endcode * * The asio::buffer_cast function permits violations of type safety, so * uses of it in application code should be carefully considered. */ class mutable_buffer { public: /// Construct an empty buffer. mutable_buffer() : data_(0), size_(0) { } /// Construct a buffer to represent a given memory range. mutable_buffer(void* data, std::size_t size) : data_(data), size_(size) { } private: friend void* asio::detail::buffer_cast_helper( const mutable_buffer& b); friend std::size_t asio::detail::buffer_size_helper( const mutable_buffer& b); void* data_; std::size_t size_; }; namespace detail { inline void* buffer_cast_helper(const mutable_buffer& b) { return b.data_; } inline std::size_t buffer_size_helper(const mutable_buffer& b) { return b.size_; } } // namespace detail /// Adapts a single modifiable buffer so that it meets the requirements of the /// MutableBufferSequence concept. class mutable_buffers_1 : public mutable_buffer { public: /// The type for each element in the list of buffers. typedef mutable_buffer value_type; /// A random-access iterator type that may be used to read elements. typedef const mutable_buffer* const_iterator; /// Construct to represent a given memory range. mutable_buffers_1(void* data, std::size_t size) : mutable_buffer(data, size) { } /// Construct to represent a single modifiable buffer. explicit mutable_buffers_1(const mutable_buffer& b) : mutable_buffer(b) { } /// Get a random-access iterator to the first element. const_iterator begin() const { return this; } /// Get a random-access iterator for one past the last element. const_iterator end() const { return begin() + 1; } }; /// Holds a buffer that cannot be modified. /** * The const_buffer class provides a safe representation of a buffer that cannot * be modified. It does not own the underlying data, and so is cheap to copy or * assign. * * @par Accessing Buffer Contents * * The contents of a buffer may be accessed using the @ref buffer_size * and @ref buffer_cast functions: * * @code asio::const_buffer b1 = ...; * std::size_t s1 = asio::buffer_size(b1); * const unsigned char* p1 = asio::buffer_cast(b1); * @endcode * * The asio::buffer_cast function permits violations of type safety, so * uses of it in application code should be carefully considered. */ class const_buffer { public: /// Construct an empty buffer. const_buffer() : data_(0), size_(0) { } /// Construct a buffer to represent a given memory range. const_buffer(const void* data, std::size_t size) : data_(data), size_(size) { } /// Construct a non-modifiable buffer from a modifiable one. const_buffer(const mutable_buffer& b) : data_(asio::detail::buffer_cast_helper(b)), size_(asio::detail::buffer_size_helper(b)) { } private: friend const void* asio::detail::buffer_cast_helper( const const_buffer& b); friend std::size_t asio::detail::buffer_size_helper( const const_buffer& b); const void* data_; std::size_t size_; }; namespace detail { inline const void* buffer_cast_helper(const const_buffer& b) { return b.data_; } inline std::size_t buffer_size_helper(const const_buffer& b) { return b.size_; } } // namespace detail /// Adapts a single non-modifiable buffer so that it meets the requirements of /// the ConstBufferSequence concept. class const_buffers_1 : public const_buffer { public: /// The type for each element in the list of buffers. typedef const_buffer value_type; /// A random-access iterator type that may be used to read elements. typedef const const_buffer* const_iterator; /// Construct to represent a given memory range. const_buffers_1(const void* data, std::size_t size) : const_buffer(data, size) { } /// Construct to represent a single non-modifiable buffer. explicit const_buffers_1(const const_buffer& b) : const_buffer(b) { } /// Get a random-access iterator to the first element. const_iterator begin() const { return this; } /// Get a random-access iterator for one past the last element. const_iterator end() const { return begin() + 1; } }; /// An implementation of both the ConstBufferSequence and MutableBufferSequence /// concepts to represent a null buffer sequence. class null_buffers { public: /// The type for each element in the list of buffers. typedef mutable_buffer value_type; /// A random-access iterator type that may be used to read elements. typedef const mutable_buffer* const_iterator; /// Get a random-access iterator to the first element. const_iterator begin() const { return &buf_; } /// Get a random-access iterator for one past the last element. const_iterator end() const { return &buf_; } private: mutable_buffer buf_; }; /** @defgroup buffer_size asio::buffer_size * * @brief The asio::buffer_size function determines the total number of * bytes in a buffer or buffer sequence. */ /*@{*/ /// Get the number of bytes in a modifiable buffer. inline std::size_t buffer_size(const mutable_buffer& b) { return detail::buffer_size_helper(b); } /// Get the number of bytes in a modifiable buffer. inline std::size_t buffer_size(const mutable_buffers_1& b) { return detail::buffer_size_helper(b); } /// Get the number of bytes in a non-modifiable buffer. inline std::size_t buffer_size(const const_buffer& b) { return detail::buffer_size_helper(b); } /// Get the number of bytes in a non-modifiable buffer. inline std::size_t buffer_size(const const_buffers_1& b) { return detail::buffer_size_helper(b); } /// Get the total number of bytes in a buffer sequence. /** * The @c BufferSequence template parameter may meet either of the @c * ConstBufferSequence or @c MutableBufferSequence type requirements. */ template inline std::size_t buffer_size(const BufferSequence& b) { std::size_t total_buffer_size = 0; typename BufferSequence::const_iterator iter = b.begin(); typename BufferSequence::const_iterator end = b.end(); for (; iter != end; ++iter) total_buffer_size += detail::buffer_size_helper(*iter); return total_buffer_size; } /*@}*/ /** @defgroup buffer_cast asio::buffer_cast * * @brief The asio::buffer_cast function is used to obtain a pointer to * the underlying memory region associated with a buffer. * * @par Examples: * * To access the memory of a non-modifiable buffer, use: * @code asio::const_buffer b1 = ...; * const unsigned char* p1 = asio::buffer_cast(b1); * @endcode * * To access the memory of a modifiable buffer, use: * @code asio::mutable_buffer b2 = ...; * unsigned char* p2 = asio::buffer_cast(b2); * @endcode * * The asio::buffer_cast function permits violations of type safety, so * uses of it in application code should be carefully considered. */ /*@{*/ /// Cast a non-modifiable buffer to a specified pointer to POD type. template inline PointerToPodType buffer_cast(const mutable_buffer& b) { return static_cast(detail::buffer_cast_helper(b)); } /// Cast a non-modifiable buffer to a specified pointer to POD type. template inline PointerToPodType buffer_cast(const const_buffer& b) { return static_cast(detail::buffer_cast_helper(b)); } /*@}*/ /// Create a new modifiable buffer that is offset from the start of another. /** * @relates mutable_buffer */ inline mutable_buffer operator+(const mutable_buffer& b, std::size_t start) { if (start > buffer_size(b)) return mutable_buffer(); char* new_data = buffer_cast(b) + start; std::size_t new_size = buffer_size(b) - start; return mutable_buffer(new_data, new_size ); } /// Create a new modifiable buffer that is offset from the start of another. /** * @relates mutable_buffer */ inline mutable_buffer operator+(std::size_t start, const mutable_buffer& b) { if (start > buffer_size(b)) return mutable_buffer(); char* new_data = buffer_cast(b) + start; std::size_t new_size = buffer_size(b) - start; return mutable_buffer(new_data, new_size ); } /// Create a new non-modifiable buffer that is offset from the start of another. /** * @relates const_buffer */ inline const_buffer operator+(const const_buffer& b, std::size_t start) { if (start > buffer_size(b)) return const_buffer(); const char* new_data = buffer_cast(b) + start; std::size_t new_size = buffer_size(b) - start; return const_buffer(new_data, new_size ); } /// Create a new non-modifiable buffer that is offset from the start of another. /** * @relates const_buffer */ inline const_buffer operator+(std::size_t start, const const_buffer& b) { if (start > buffer_size(b)) return const_buffer(); const char* new_data = buffer_cast(b) + start; std::size_t new_size = buffer_size(b) - start; return const_buffer(new_data, new_size ); } /** @defgroup buffer asio::buffer * * @brief The asio::buffer function is used to create a buffer object to * represent raw memory, an array of POD elements, a vector of POD elements, * or a std::string. * * A buffer object represents a contiguous region of memory as a 2-tuple * consisting of a pointer and size in bytes. A tuple of the form {void*, * size_t} specifies a mutable (modifiable) region of memory. Similarly, a * tuple of the form {const void*, size_t} specifies a const * (non-modifiable) region of memory. These two forms correspond to the classes * mutable_buffer and const_buffer, respectively. To mirror C++'s conversion * rules, a mutable_buffer is implicitly convertible to a const_buffer, and the * opposite conversion is not permitted. * * The simplest use case involves reading or writing a single buffer of a * specified size: * * @code sock.send(asio::buffer(data, size)); @endcode * * In the above example, the return value of asio::buffer meets the * requirements of the ConstBufferSequence concept so that it may be directly * passed to the socket's write function. A buffer created for modifiable * memory also meets the requirements of the MutableBufferSequence concept. * * An individual buffer may be created from a builtin array, std::vector, * std::array or boost::array of POD elements. This helps prevent buffer * overruns by automatically determining the size of the buffer: * * @code char d1[128]; * size_t bytes_transferred = sock.receive(asio::buffer(d1)); * * std::vector d2(128); * bytes_transferred = sock.receive(asio::buffer(d2)); * * std::array d3; * bytes_transferred = sock.receive(asio::buffer(d3)); * * boost::array d4; * bytes_transferred = sock.receive(asio::buffer(d4)); @endcode * * In all three cases above, the buffers created are exactly 128 bytes long. * Note that a vector is @e never automatically resized when creating or using * a buffer. The buffer size is determined using the vector's size() * member function, and not its capacity. * * @par Accessing Buffer Contents * * The contents of a buffer may be accessed using the @ref buffer_size and * @ref buffer_cast functions: * * @code asio::mutable_buffer b1 = ...; * std::size_t s1 = asio::buffer_size(b1); * unsigned char* p1 = asio::buffer_cast(b1); * * asio::const_buffer b2 = ...; * std::size_t s2 = asio::buffer_size(b2); * const void* p2 = asio::buffer_cast(b2); @endcode * * The asio::buffer_cast function permits violations of type safety, so * uses of it in application code should be carefully considered. * * For convenience, the @ref buffer_size function also works on buffer * sequences (that is, types meeting the ConstBufferSequence or * MutableBufferSequence type requirements). In this case, the function returns * the total size of all buffers in the sequence. * * @par Buffer Copying * * The @ref buffer_copy function may be used to copy raw bytes between * individual buffers and buffer sequences. * * In particular, when used with the @ref buffer_size, the @ref buffer_copy * function can be used to linearise a sequence of buffers. For example: * * @code vector buffers = ...; * * vector data(asio::buffer_size(buffers)); * asio::buffer_copy(asio::buffer(data), buffers); @endcode * * Note that @ref buffer_copy is implemented in terms of @c memcpy, and * consequently it cannot be used to copy between overlapping memory regions. * * @par Buffer Invalidation * * A buffer object does not have any ownership of the memory it refers to. It * is the responsibility of the application to ensure the memory region remains * valid until it is no longer required for an I/O operation. When the memory * is no longer available, the buffer is said to have been invalidated. * * For the asio::buffer overloads that accept an argument of type * std::vector, the buffer objects returned are invalidated by any vector * operation that also invalidates all references, pointers and iterators * referring to the elements in the sequence (C++ Std, 23.2.4) * * For the asio::buffer overloads that accept an argument of type * std::basic_string, the buffer objects returned are invalidated according to * the rules defined for invalidation of references, pointers and iterators * referring to elements of the sequence (C++ Std, 21.3). * * @par Buffer Arithmetic * * Buffer objects may be manipulated using simple arithmetic in a safe way * which helps prevent buffer overruns. Consider an array initialised as * follows: * * @code boost::array a = { 'a', 'b', 'c', 'd', 'e' }; @endcode * * A buffer object @c b1 created using: * * @code b1 = asio::buffer(a); @endcode * * represents the entire array, { 'a', 'b', 'c', 'd', 'e' }. An * optional second argument to the asio::buffer function may be used to * limit the size, in bytes, of the buffer: * * @code b2 = asio::buffer(a, 3); @endcode * * such that @c b2 represents the data { 'a', 'b', 'c' }. Even if the * size argument exceeds the actual size of the array, the size of the buffer * object created will be limited to the array size. * * An offset may be applied to an existing buffer to create a new one: * * @code b3 = b1 + 2; @endcode * * where @c b3 will set to represent { 'c', 'd', 'e' }. If the offset * exceeds the size of the existing buffer, the newly created buffer will be * empty. * * Both an offset and size may be specified to create a buffer that corresponds * to a specific range of bytes within an existing buffer: * * @code b4 = asio::buffer(b1 + 1, 3); @endcode * * so that @c b4 will refer to the bytes { 'b', 'c', 'd' }. * * @par Buffers and Scatter-Gather I/O * * To read or write using multiple buffers (i.e. scatter-gather I/O), multiple * buffer objects may be assigned into a container that supports the * MutableBufferSequence (for read) or ConstBufferSequence (for write) concepts: * * @code * char d1[128]; * std::vector d2(128); * boost::array d3; * * boost::array bufs1 = { * asio::buffer(d1), * asio::buffer(d2), * asio::buffer(d3) }; * bytes_transferred = sock.receive(bufs1); * * std::vector bufs2; * bufs2.push_back(asio::buffer(d1)); * bufs2.push_back(asio::buffer(d2)); * bufs2.push_back(asio::buffer(d3)); * bytes_transferred = sock.send(bufs2); @endcode */ /*@{*/ /// Create a new modifiable buffer from an existing buffer. /** * @returns mutable_buffers_1(b). */ inline mutable_buffers_1 buffer(const mutable_buffer& b) { return mutable_buffers_1(b); } /// Create a new modifiable buffer from an existing buffer. /** * @returns A mutable_buffers_1 value equivalent to: * @code mutable_buffers_1( * buffer_cast(b), * min(buffer_size(b), max_size_in_bytes)); @endcode */ inline mutable_buffers_1 buffer(const mutable_buffer& b, std::size_t max_size_in_bytes) { return mutable_buffers_1( mutable_buffer(buffer_cast(b), buffer_size(b) < max_size_in_bytes ? buffer_size(b) : max_size_in_bytes )); } /// Create a new non-modifiable buffer from an existing buffer. /** * @returns const_buffers_1(b). */ inline const_buffers_1 buffer(const const_buffer& b) { return const_buffers_1(b); } /// Create a new non-modifiable buffer from an existing buffer. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * buffer_cast(b), * min(buffer_size(b), max_size_in_bytes)); @endcode */ inline const_buffers_1 buffer(const const_buffer& b, std::size_t max_size_in_bytes) { return const_buffers_1( const_buffer(buffer_cast(b), buffer_size(b) < max_size_in_bytes ? buffer_size(b) : max_size_in_bytes )); } /// Create a new modifiable buffer that represents the given memory range. /** * @returns mutable_buffers_1(data, size_in_bytes). */ inline mutable_buffers_1 buffer(void* data, std::size_t size_in_bytes) { return mutable_buffers_1(mutable_buffer(data, size_in_bytes)); } /// Create a new non-modifiable buffer that represents the given memory range. /** * @returns const_buffers_1(data, size_in_bytes). */ inline const_buffers_1 buffer(const void* data, std::size_t size_in_bytes) { return const_buffers_1(const_buffer(data, size_in_bytes)); } /// Create a new modifiable buffer that represents the given POD array. /** * @returns A mutable_buffers_1 value equivalent to: * @code mutable_buffers_1( * static_cast(data), * N * sizeof(PodType)); @endcode */ template inline mutable_buffers_1 buffer(PodType (&data)[N]) { return mutable_buffers_1(mutable_buffer(data, N * sizeof(PodType))); } /// Create a new modifiable buffer that represents the given POD array. /** * @returns A mutable_buffers_1 value equivalent to: * @code mutable_buffers_1( * static_cast(data), * min(N * sizeof(PodType), max_size_in_bytes)); @endcode */ template inline mutable_buffers_1 buffer(PodType (&data)[N], std::size_t max_size_in_bytes) { return mutable_buffers_1( mutable_buffer(data, N * sizeof(PodType) < max_size_in_bytes ? N * sizeof(PodType) : max_size_in_bytes)); } /// Create a new non-modifiable buffer that represents the given POD array. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * static_cast(data), * N * sizeof(PodType)); @endcode */ template inline const_buffers_1 buffer(const PodType (&data)[N]) { return const_buffers_1(const_buffer(data, N * sizeof(PodType))); } /// Create a new non-modifiable buffer that represents the given POD array. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * static_cast(data), * min(N * sizeof(PodType), max_size_in_bytes)); @endcode */ template inline const_buffers_1 buffer(const PodType (&data)[N], std::size_t max_size_in_bytes) { return const_buffers_1( const_buffer(data, N * sizeof(PodType) < max_size_in_bytes ? N * sizeof(PodType) : max_size_in_bytes)); } #if defined(ASIO_ENABLE_ARRAY_BUFFER_WORKAROUND) // Borland C++ and Sun Studio think the overloads: // // unspecified buffer(boost::array& array ...); // // and // // unspecified buffer(boost::array& array ...); // // are ambiguous. This will be worked around by using a buffer_types traits // class that contains typedefs for the appropriate buffer and container // classes, based on whether PodType is const or non-const. namespace detail { template struct buffer_types_base; template <> struct buffer_types_base { typedef mutable_buffer buffer_type; typedef mutable_buffers_1 container_type; }; template <> struct buffer_types_base { typedef const_buffer buffer_type; typedef const_buffers_1 container_type; }; template struct buffer_types : public buffer_types_base::value> { }; } // namespace detail template inline typename detail::buffer_types::container_type buffer(boost::array& data) { typedef typename asio::detail::buffer_types::buffer_type buffer_type; typedef typename asio::detail::buffer_types::container_type container_type; return container_type( buffer_type(data.c_array(), data.size() * sizeof(PodType))); } template inline typename detail::buffer_types::container_type buffer(boost::array& data, std::size_t max_size_in_bytes) { typedef typename asio::detail::buffer_types::buffer_type buffer_type; typedef typename asio::detail::buffer_types::container_type container_type; return container_type( buffer_type(data.c_array(), data.size() * sizeof(PodType) < max_size_in_bytes ? data.size() * sizeof(PodType) : max_size_in_bytes)); } #else // defined(ASIO_ENABLE_ARRAY_BUFFER_WORKAROUND) /// Create a new modifiable buffer that represents the given POD array. /** * @returns A mutable_buffers_1 value equivalent to: * @code mutable_buffers_1( * data.data(), * data.size() * sizeof(PodType)); @endcode */ template inline mutable_buffers_1 buffer(boost::array& data) { return mutable_buffers_1( mutable_buffer(data.c_array(), data.size() * sizeof(PodType))); } /// Create a new modifiable buffer that represents the given POD array. /** * @returns A mutable_buffers_1 value equivalent to: * @code mutable_buffers_1( * data.data(), * min(data.size() * sizeof(PodType), max_size_in_bytes)); @endcode */ template inline mutable_buffers_1 buffer(boost::array& data, std::size_t max_size_in_bytes) { return mutable_buffers_1( mutable_buffer(data.c_array(), data.size() * sizeof(PodType) < max_size_in_bytes ? data.size() * sizeof(PodType) : max_size_in_bytes)); } /// Create a new non-modifiable buffer that represents the given POD array. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.data(), * data.size() * sizeof(PodType)); @endcode */ template inline const_buffers_1 buffer(boost::array& data) { return const_buffers_1( const_buffer(data.data(), data.size() * sizeof(PodType))); } /// Create a new non-modifiable buffer that represents the given POD array. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.data(), * min(data.size() * sizeof(PodType), max_size_in_bytes)); @endcode */ template inline const_buffers_1 buffer(boost::array& data, std::size_t max_size_in_bytes) { return const_buffers_1( const_buffer(data.data(), data.size() * sizeof(PodType) < max_size_in_bytes ? data.size() * sizeof(PodType) : max_size_in_bytes)); } #endif // defined(ASIO_ENABLE_ARRAY_BUFFER_WORKAROUND) /// Create a new non-modifiable buffer that represents the given POD array. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.data(), * data.size() * sizeof(PodType)); @endcode */ template inline const_buffers_1 buffer(const boost::array& data) { return const_buffers_1( const_buffer(data.data(), data.size() * sizeof(PodType))); } /// Create a new non-modifiable buffer that represents the given POD array. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.data(), * min(data.size() * sizeof(PodType), max_size_in_bytes)); @endcode */ template inline const_buffers_1 buffer(const boost::array& data, std::size_t max_size_in_bytes) { return const_buffers_1( const_buffer(data.data(), data.size() * sizeof(PodType) < max_size_in_bytes ? data.size() * sizeof(PodType) : max_size_in_bytes)); } /// Create a new modifiable buffer that represents the given POD array. /** * @returns A mutable_buffers_1 value equivalent to: * @code mutable_buffers_1( * data.data(), * data.size() * sizeof(PodType)); @endcode */ template inline mutable_buffers_1 buffer(std::array& data) { return mutable_buffers_1( mutable_buffer(data.data(), data.size() * sizeof(PodType))); } /// Create a new modifiable buffer that represents the given POD array. /** * @returns A mutable_buffers_1 value equivalent to: * @code mutable_buffers_1( * data.data(), * min(data.size() * sizeof(PodType), max_size_in_bytes)); @endcode */ template inline mutable_buffers_1 buffer(std::array& data, std::size_t max_size_in_bytes) { return mutable_buffers_1( mutable_buffer(data.data(), data.size() * sizeof(PodType) < max_size_in_bytes ? data.size() * sizeof(PodType) : max_size_in_bytes)); } /// Create a new non-modifiable buffer that represents the given POD array. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.data(), * data.size() * sizeof(PodType)); @endcode */ template inline const_buffers_1 buffer(std::array& data) { return const_buffers_1( const_buffer(data.data(), data.size() * sizeof(PodType))); } /// Create a new non-modifiable buffer that represents the given POD array. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.data(), * min(data.size() * sizeof(PodType), max_size_in_bytes)); @endcode */ template inline const_buffers_1 buffer(std::array& data, std::size_t max_size_in_bytes) { return const_buffers_1( const_buffer(data.data(), data.size() * sizeof(PodType) < max_size_in_bytes ? data.size() * sizeof(PodType) : max_size_in_bytes)); } /// Create a new non-modifiable buffer that represents the given POD array. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.data(), * data.size() * sizeof(PodType)); @endcode */ template inline const_buffers_1 buffer(const std::array& data) { return const_buffers_1( const_buffer(data.data(), data.size() * sizeof(PodType))); } /// Create a new non-modifiable buffer that represents the given POD array. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.data(), * min(data.size() * sizeof(PodType), max_size_in_bytes)); @endcode */ template inline const_buffers_1 buffer(const std::array& data, std::size_t max_size_in_bytes) { return const_buffers_1( const_buffer(data.data(), data.size() * sizeof(PodType) < max_size_in_bytes ? data.size() * sizeof(PodType) : max_size_in_bytes)); } /// Create a new modifiable buffer that represents the given POD vector. /** * @returns A mutable_buffers_1 value equivalent to: * @code mutable_buffers_1( * data.size() ? &data[0] : 0, * data.size() * sizeof(PodType)); @endcode * * @note The buffer is invalidated by any vector operation that would also * invalidate iterators. */ template inline mutable_buffers_1 buffer(std::vector& data) { return mutable_buffers_1( mutable_buffer(data.size() ? &data[0] : 0, data.size() * sizeof(PodType) )); } /// Create a new modifiable buffer that represents the given POD vector. /** * @returns A mutable_buffers_1 value equivalent to: * @code mutable_buffers_1( * data.size() ? &data[0] : 0, * min(data.size() * sizeof(PodType), max_size_in_bytes)); @endcode * * @note The buffer is invalidated by any vector operation that would also * invalidate iterators. */ template inline mutable_buffers_1 buffer(std::vector& data, std::size_t max_size_in_bytes) { return mutable_buffers_1( mutable_buffer(data.size() ? &data[0] : 0, data.size() * sizeof(PodType) < max_size_in_bytes ? data.size() * sizeof(PodType) : max_size_in_bytes )); } /// Create a new non-modifiable buffer that represents the given POD vector. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.size() ? &data[0] : 0, * data.size() * sizeof(PodType)); @endcode * * @note The buffer is invalidated by any vector operation that would also * invalidate iterators. */ template inline const_buffers_1 buffer( const std::vector& data) { return const_buffers_1( const_buffer(data.size() ? &data[0] : 0, data.size() * sizeof(PodType) )); } /// Create a new non-modifiable buffer that represents the given POD vector. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.size() ? &data[0] : 0, * min(data.size() * sizeof(PodType), max_size_in_bytes)); @endcode * * @note The buffer is invalidated by any vector operation that would also * invalidate iterators. */ template inline const_buffers_1 buffer( const std::vector& data, std::size_t max_size_in_bytes) { return const_buffers_1( const_buffer(data.size() ? &data[0] : 0, data.size() * sizeof(PodType) < max_size_in_bytes ? data.size() * sizeof(PodType) : max_size_in_bytes )); } /// Create a new non-modifiable buffer that represents the given string. /** * @returns const_buffers_1(data.data(), data.size() * sizeof(Elem)). * * @note The buffer is invalidated by any non-const operation called on the * given string object. */ template inline const_buffers_1 buffer( const std::basic_string& data) { return const_buffers_1(const_buffer(data.data(), data.size() * sizeof(Elem) )); } /// Create a new non-modifiable buffer that represents the given string. /** * @returns A const_buffers_1 value equivalent to: * @code const_buffers_1( * data.data(), * min(data.size() * sizeof(Elem), max_size_in_bytes)); @endcode * * @note The buffer is invalidated by any non-const operation called on the * given string object. */ template inline const_buffers_1 buffer( const std::basic_string& data, std::size_t max_size_in_bytes) { return const_buffers_1( const_buffer(data.data(), data.size() * sizeof(Elem) < max_size_in_bytes ? data.size() * sizeof(Elem) : max_size_in_bytes )); } /*@}*/ /** @defgroup buffer_copy asio::buffer_copy * * @brief The asio::buffer_copy function is used to copy bytes from a * source buffer (or buffer sequence) to a target buffer (or buffer sequence). * * The @c buffer_copy function is available in two forms: * * @li A 2-argument form: @c buffer_copy(target, source) * * @li A 3-argument form: @c buffer_copy(target, source, max_bytes_to_copy) * Both forms return the number of bytes actually copied. The number of bytes * copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c If specified, @c max_bytes_to_copy. * * This prevents buffer overflow, regardless of the buffer sizes used in the * copy operation. * * Note that @ref buffer_copy is implemented in terms of @c memcpy, and * consequently it cannot be used to copy between overlapping memory regions. */ /*@{*/ /// Copies bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffer& target, const const_buffer& source) { using namespace std; // For memcpy. std::size_t target_size = buffer_size(target); std::size_t source_size = buffer_size(source); std::size_t n = target_size < source_size ? target_size : source_size; memcpy(buffer_cast(target), buffer_cast(source), n); return n; } /// Copies bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffer& target, const const_buffers_1& source) { return buffer_copy(target, static_cast(source)); } /// Copies bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffer& target, const mutable_buffer& source) { return buffer_copy(target, const_buffer(source)); } /// Copies bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffer& target, const mutable_buffers_1& source) { return buffer_copy(target, const_buffer(source)); } /// Copies bytes from a source buffer sequence to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer sequence representing the memory * regions from which the bytes will be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template std::size_t buffer_copy(const mutable_buffer& target, const ConstBufferSequence& source) { std::size_t total_bytes_copied = 0; typename ConstBufferSequence::const_iterator source_iter = source.begin(); typename ConstBufferSequence::const_iterator source_end = source.end(); for (mutable_buffer target_buffer(target); buffer_size(target_buffer) && source_iter != source_end; ++source_iter) { const_buffer source_buffer(*source_iter); std::size_t bytes_copied = buffer_copy(target_buffer, source_buffer); total_bytes_copied += bytes_copied; target_buffer = target_buffer + bytes_copied; } return total_bytes_copied; } /// Copies bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffers_1& target, const const_buffer& source) { return buffer_copy(static_cast(target), source); } /// Copies bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffers_1& target, const const_buffers_1& source) { return buffer_copy(static_cast(target), static_cast(source)); } /// Copies bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffers_1& target, const mutable_buffer& source) { return buffer_copy(static_cast(target), const_buffer(source)); } /// Copies bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffers_1& target, const mutable_buffers_1& source) { return buffer_copy(static_cast(target), const_buffer(source)); } /// Copies bytes from a source buffer sequence to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer sequence representing the memory * regions from which the bytes will be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template inline std::size_t buffer_copy(const mutable_buffers_1& target, const ConstBufferSequence& source) { return buffer_copy(static_cast(target), source); } /// Copies bytes from a source buffer to a target buffer sequence. /** * @param target A modifiable buffer sequence representing the memory regions to * which the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template std::size_t buffer_copy(const MutableBufferSequence& target, const const_buffer& source) { std::size_t total_bytes_copied = 0; typename MutableBufferSequence::const_iterator target_iter = target.begin(); typename MutableBufferSequence::const_iterator target_end = target.end(); for (const_buffer source_buffer(source); buffer_size(source_buffer) && target_iter != target_end; ++target_iter) { mutable_buffer target_buffer(*target_iter); std::size_t bytes_copied = buffer_copy(target_buffer, source_buffer); total_bytes_copied += bytes_copied; source_buffer = source_buffer + bytes_copied; } return total_bytes_copied; } /// Copies bytes from a source buffer to a target buffer sequence. /** * @param target A modifiable buffer sequence representing the memory regions to * which the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template inline std::size_t buffer_copy(const MutableBufferSequence& target, const const_buffers_1& source) { return buffer_copy(target, static_cast(source)); } /// Copies bytes from a source buffer to a target buffer sequence. /** * @param target A modifiable buffer sequence representing the memory regions to * which the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template inline std::size_t buffer_copy(const MutableBufferSequence& target, const mutable_buffer& source) { return buffer_copy(target, const_buffer(source)); } /// Copies bytes from a source buffer to a target buffer sequence. /** * @param target A modifiable buffer sequence representing the memory regions to * which the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template inline std::size_t buffer_copy(const MutableBufferSequence& target, const mutable_buffers_1& source) { return buffer_copy(target, const_buffer(source)); } /// Copies bytes from a source buffer sequence to a target buffer sequence. /** * @param target A modifiable buffer sequence representing the memory regions to * which the bytes will be copied. * * @param source A non-modifiable buffer sequence representing the memory * regions from which the bytes will be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template std::size_t buffer_copy(const MutableBufferSequence& target, const ConstBufferSequence& source) { std::size_t total_bytes_copied = 0; typename MutableBufferSequence::const_iterator target_iter = target.begin(); typename MutableBufferSequence::const_iterator target_end = target.end(); std::size_t target_buffer_offset = 0; typename ConstBufferSequence::const_iterator source_iter = source.begin(); typename ConstBufferSequence::const_iterator source_end = source.end(); std::size_t source_buffer_offset = 0; while (target_iter != target_end && source_iter != source_end) { mutable_buffer target_buffer = mutable_buffer(*target_iter) + target_buffer_offset; const_buffer source_buffer = const_buffer(*source_iter) + source_buffer_offset; std::size_t bytes_copied = buffer_copy(target_buffer, source_buffer); total_bytes_copied += bytes_copied; if (bytes_copied == buffer_size(target_buffer)) { ++target_iter; target_buffer_offset = 0; } else target_buffer_offset += bytes_copied; if (bytes_copied == buffer_size(source_buffer)) { ++source_iter; source_buffer_offset = 0; } else source_buffer_offset += bytes_copied; } return total_bytes_copied; } /// Copies a limited number of bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffer& target, const const_buffer& source, std::size_t max_bytes_to_copy) { return buffer_copy(buffer(target, max_bytes_to_copy), source); } /// Copies a limited number of bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffer& target, const const_buffers_1& source, std::size_t max_bytes_to_copy) { return buffer_copy(buffer(target, max_bytes_to_copy), source); } /// Copies a limited number of bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffer& target, const mutable_buffer& source, std::size_t max_bytes_to_copy) { return buffer_copy(buffer(target, max_bytes_to_copy), source); } /// Copies a limited number of bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffer& target, const mutable_buffers_1& source, std::size_t max_bytes_to_copy) { return buffer_copy(buffer(target, max_bytes_to_copy), source); } /// Copies a limited number of bytes from a source buffer sequence to a target /// buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer sequence representing the memory * regions from which the bytes will be copied. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template inline std::size_t buffer_copy(const mutable_buffer& target, const ConstBufferSequence& source, std::size_t max_bytes_to_copy) { return buffer_copy(buffer(target, max_bytes_to_copy), source); } /// Copies a limited number of bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffers_1& target, const const_buffer& source, std::size_t max_bytes_to_copy) { return buffer_copy(buffer(target, max_bytes_to_copy), source); } /// Copies a limited number of bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffers_1& target, const const_buffers_1& source, std::size_t max_bytes_to_copy) { return buffer_copy(buffer(target, max_bytes_to_copy), source); } /// Copies a limited number of bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffers_1& target, const mutable_buffer& source, std::size_t max_bytes_to_copy) { return buffer_copy(buffer(target, max_bytes_to_copy), source); } /// Copies a limited number of bytes from a source buffer to a target buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ inline std::size_t buffer_copy(const mutable_buffers_1& target, const mutable_buffers_1& source, std::size_t max_bytes_to_copy) { return buffer_copy(buffer(target, max_bytes_to_copy), source); } /// Copies a limited number of bytes from a source buffer sequence to a target /// buffer. /** * @param target A modifiable buffer representing the memory region to which * the bytes will be copied. * * @param source A non-modifiable buffer sequence representing the memory * regions from which the bytes will be copied. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template inline std::size_t buffer_copy(const mutable_buffers_1& target, const ConstBufferSequence& source, std::size_t max_bytes_to_copy) { return buffer_copy(buffer(target, max_bytes_to_copy), source); } /// Copies a limited number of bytes from a source buffer to a target buffer /// sequence. /** * @param target A modifiable buffer sequence representing the memory regions to * which the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template inline std::size_t buffer_copy(const MutableBufferSequence& target, const const_buffer& source, std::size_t max_bytes_to_copy) { return buffer_copy(target, buffer(source, max_bytes_to_copy)); } /// Copies a limited number of bytes from a source buffer to a target buffer /// sequence. /** * @param target A modifiable buffer sequence representing the memory regions to * which the bytes will be copied. * * @param source A non-modifiable buffer representing the memory region from * which the bytes will be copied. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template inline std::size_t buffer_copy(const MutableBufferSequence& target, const const_buffers_1& source, std::size_t max_bytes_to_copy) { return buffer_copy(target, buffer(source, max_bytes_to_copy)); } /// Copies a limited number of bytes from a source buffer to a target buffer /// sequence. /** * @param target A modifiable buffer sequence representing the memory regions to * which the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template inline std::size_t buffer_copy(const MutableBufferSequence& target, const mutable_buffer& source, std::size_t max_bytes_to_copy) { return buffer_copy(target, buffer(source, max_bytes_to_copy)); } /// Copies a limited number of bytes from a source buffer to a target buffer /// sequence. /** * @param target A modifiable buffer sequence representing the memory regions to * which the bytes will be copied. * * @param source A modifiable buffer representing the memory region from which * the bytes will be copied. The contents of the source buffer will not be * modified. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template inline std::size_t buffer_copy(const MutableBufferSequence& target, const mutable_buffers_1& source, std::size_t max_bytes_to_copy) { return buffer_copy(target, buffer(source, max_bytes_to_copy)); } /// Copies a limited number of bytes from a source buffer sequence to a target /// buffer sequence. /** * @param target A modifiable buffer sequence representing the memory regions to * which the bytes will be copied. * * @param source A non-modifiable buffer sequence representing the memory * regions from which the bytes will be copied. * * @param max_bytes_to_copy The maximum number of bytes to be copied. * * @returns The number of bytes copied. * * @note The number of bytes copied is the lesser of: * * @li @c buffer_size(target) * * @li @c buffer_size(source) * * @li @c max_bytes_to_copy * * This function is implemented in terms of @c memcpy, and consequently it * cannot be used to copy between overlapping memory regions. */ template std::size_t buffer_copy(const MutableBufferSequence& target, const ConstBufferSequence& source, std::size_t max_bytes_to_copy) { std::size_t total_bytes_copied = 0; typename MutableBufferSequence::const_iterator target_iter = target.begin(); typename MutableBufferSequence::const_iterator target_end = target.end(); std::size_t target_buffer_offset = 0; typename ConstBufferSequence::const_iterator source_iter = source.begin(); typename ConstBufferSequence::const_iterator source_end = source.end(); std::size_t source_buffer_offset = 0; while (total_bytes_copied != max_bytes_to_copy && target_iter != target_end && source_iter != source_end) { mutable_buffer target_buffer = mutable_buffer(*target_iter) + target_buffer_offset; const_buffer source_buffer = const_buffer(*source_iter) + source_buffer_offset; std::size_t bytes_copied = buffer_copy(target_buffer, source_buffer, max_bytes_to_copy - total_bytes_copied); total_bytes_copied += bytes_copied; if (bytes_copied == buffer_size(target_buffer)) { ++target_iter; target_buffer_offset = 0; } else target_buffer_offset += bytes_copied; if (bytes_copied == buffer_size(source_buffer)) { ++source_iter; source_buffer_offset = 0; } else source_buffer_offset += bytes_copied; } return total_bytes_copied; } /*@}*/ } // namespace asio #include "asio/detail/pop_options.hpp" #endif // ASIO_BUFFER_HPP