boost/asio/buffers_iterator.hpp
// // buffers_iterator.hpp // ~~~~~~~~~~~~~~~~~~~~ // // Copyright (c) 2003-2008 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 BOOST_ASIO_BUFFERS_ITERATOR_HPP #define BOOST_ASIO_BUFFERS_ITERATOR_HPP #if defined(_MSC_VER) && (_MSC_VER >= 1200) # pragma once #endif // defined(_MSC_VER) && (_MSC_VER >= 1200) #include <boost/asio/detail/push_options.hpp> #include <boost/asio/detail/push_options.hpp> #include <cstddef> #include <boost/assert.hpp> #include <boost/config.hpp> #include <boost/detail/workaround.hpp> #include <boost/iterator/iterator_facade.hpp> #include <boost/type_traits/is_convertible.hpp> #include <boost/type_traits/add_const.hpp> #include <boost/asio/detail/pop_options.hpp> #include <boost/asio/buffer.hpp> namespace boost { namespace asio { namespace detail { template <bool IsMutable> struct buffers_iterator_types_helper; template <> struct buffers_iterator_types_helper<false> { typedef const_buffer buffer_type; template <typename ByteType> struct byte_type { typedef typename boost::add_const<ByteType>::type type; }; }; template <> struct buffers_iterator_types_helper<true> { typedef mutable_buffer buffer_type; template <typename ByteType> struct byte_type { typedef ByteType type; }; }; template <typename BufferSequence, typename ByteType> struct buffers_iterator_types { enum { is_mutable = boost::is_convertible< typename BufferSequence::value_type, mutable_buffer>::value }; typedef buffers_iterator_types_helper<is_mutable> helper; typedef typename helper::buffer_type buffer_type; typedef typename helper::template byte_type<ByteType>::type byte_type; }; } /// A random access iterator over the bytes in a buffer sequence. template <typename BufferSequence, typename ByteType = char> class buffers_iterator : public boost::iterator_facade< buffers_iterator<BufferSequence, ByteType>, typename detail::buffers_iterator_types< BufferSequence, ByteType>::byte_type, boost::random_access_traversal_tag> { private: typedef typename detail::buffers_iterator_types< BufferSequence, ByteType>::buffer_type buffer_type; typedef typename detail::buffers_iterator_types< BufferSequence, ByteType>::byte_type byte_type; public: /// Default constructor. Creates an iterator in an undefined state. buffers_iterator() : current_buffer_(), current_buffer_position_(0), begin_(), current_(), end_(), position_(0) { } /// Construct an iterator representing the beginning of the buffers' data. static buffers_iterator begin(const BufferSequence& buffers) #if BOOST_WORKAROUND(__GNUC__, == 4) && BOOST_WORKAROUND(__GNUC_MINOR__, == 3) __attribute__ ((noinline)) #endif { buffers_iterator new_iter; new_iter.begin_ = buffers.begin(); new_iter.current_ = buffers.begin(); new_iter.end_ = buffers.end(); while (new_iter.current_ != new_iter.end_) { new_iter.current_buffer_ = *new_iter.current_; if (boost::asio::buffer_size(new_iter.current_buffer_) > 0) break; ++new_iter.current_; } return new_iter; } /// Construct an iterator representing the end of the buffers' data. static buffers_iterator end(const BufferSequence& buffers) #if BOOST_WORKAROUND(__GNUC__, == 4) && BOOST_WORKAROUND(__GNUC_MINOR__, == 3) __attribute__ ((noinline)) #endif { buffers_iterator new_iter; new_iter.begin_ = buffers.begin(); new_iter.current_ = buffers.begin(); new_iter.end_ = buffers.end(); while (new_iter.current_ != new_iter.end_) { buffer_type buffer = *new_iter.current_; new_iter.position_ += boost::asio::buffer_size(buffer); ++new_iter.current_; } return new_iter; } private: friend class boost::iterator_core_access; // Dereference the iterator. byte_type& dereference() const { return buffer_cast<byte_type*>(current_buffer_)[current_buffer_position_]; } // Compare two iterators for equality. bool equal(const buffers_iterator& other) const { return position_ == other.position_; } // Increment the iterator. void increment() { BOOST_ASSERT(current_ != end_ && "iterator out of bounds"); ++position_; // Check if the increment can be satisfied by the current buffer. ++current_buffer_position_; if (current_buffer_position_ != boost::asio::buffer_size(current_buffer_)) return; // Find the next non-empty buffer. ++current_; current_buffer_position_ = 0; while (current_ != end_) { current_buffer_ = *current_; if (boost::asio::buffer_size(current_buffer_) > 0) return; ++current_; } } // Decrement the iterator. void decrement() { BOOST_ASSERT(position_ > 0 && "iterator out of bounds"); --position_; // Check if the decrement can be satisfied by the current buffer. if (current_buffer_position_ != 0) { --current_buffer_position_; return; } // Find the previous non-empty buffer. typename BufferSequence::const_iterator iter = current_; while (iter != begin_) { --iter; buffer_type buffer = *iter; std::size_t buffer_size = boost::asio::buffer_size(buffer); if (buffer_size > 0) { current_ = iter; current_buffer_ = buffer; current_buffer_position_ = buffer_size - 1; return; } } } // Advance the iterator by the specified distance. void advance(std::ptrdiff_t n) { if (n > 0) { BOOST_ASSERT(current_ != end_ && "iterator out of bounds"); for (;;) { std::ptrdiff_t current_buffer_balance = boost::asio::buffer_size(current_buffer_) - current_buffer_position_; // Check if the advance can be satisfied by the current buffer. if (current_buffer_balance > n) { position_ += n; current_buffer_position_ += n; return; } // Update position. n -= current_buffer_balance; position_ += current_buffer_balance; // Move to next buffer. If it is empty then it will be skipped on the // next iteration of this loop. if (++current_ == end_) { BOOST_ASSERT(n == 0 && "iterator out of bounds"); current_buffer_ = buffer_type(); current_buffer_position_ = 0; return; } current_buffer_ = *current_; current_buffer_position_ = 0; } } else if (n < 0) { std::size_t abs_n = -n; BOOST_ASSERT(position_ >= abs_n && "iterator out of bounds"); for (;;) { // Check if the advance can be satisfied by the current buffer. if (current_buffer_position_ >= abs_n) { position_ -= abs_n; current_buffer_position_ -= abs_n; return; } // Update position. abs_n -= current_buffer_position_; position_ -= current_buffer_position_; // Check if we've reached the beginning of the buffers. if (current_ == begin_) { BOOST_ASSERT(abs_n == 0 && "iterator out of bounds"); current_buffer_position_ = 0; return; } // Find the previous non-empty buffer. typename BufferSequence::const_iterator iter = current_; while (iter != begin_) { --iter; buffer_type buffer = *iter; std::size_t buffer_size = boost::asio::buffer_size(buffer); if (buffer_size > 0) { current_ = iter; current_buffer_ = buffer; current_buffer_position_ = buffer_size; break; } } } } } // Determine the distance between two iterators. std::ptrdiff_t distance_to(const buffers_iterator& other) const { return other.position_ - position_; } buffer_type current_buffer_; std::size_t current_buffer_position_; typename BufferSequence::const_iterator begin_; typename BufferSequence::const_iterator current_; typename BufferSequence::const_iterator end_; std::size_t position_; }; /// Construct an iterator representing the beginning of the buffers' data. template <typename BufferSequence> inline buffers_iterator<BufferSequence> buffers_begin( const BufferSequence& buffers) { return buffers_iterator<BufferSequence>::begin(buffers); } /// Construct an iterator representing the end of the buffers' data. template <typename BufferSequence> inline buffers_iterator<BufferSequence> buffers_end( const BufferSequence& buffers) { return buffers_iterator<BufferSequence>::end(buffers); } } // namespace asio } // namespace boost #include <boost/asio/detail/pop_options.hpp> #endif // BOOST_ASIO_BUFFERS_ITERATOR_HPP