// // Copyright (c) 2016-2019 Vinnie Falco (vinnie dot falco at gmail 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) // // Official repository: https://github.com/boostorg/beast // #ifndef BOOST_BEAST_FLAT_BUFFER_HPP #define BOOST_BEAST_FLAT_BUFFER_HPP #include #include #include #include #include #include #include namespace boost { namespace beast { /** A dynamic buffer providing buffer sequences of length one. A dynamic buffer encapsulates memory storage that may be automatically resized as required, where the memory is divided into two regions: readable bytes followed by writable bytes. These memory regions are internal to the dynamic buffer, but direct access to the elements is provided to permit them to be efficiently used with I/O operations. Objects of this type meet the requirements of DynamicBuffer and have the following additional properties: @li A mutable buffer sequence representing the readable bytes is returned by @ref data when `this` is non-const. @li A configurable maximum buffer size may be set upon construction. Attempts to exceed the buffer size will throw `std::length_error`. @li Buffer sequences representing the readable and writable bytes, returned by @ref data and @ref prepare, will have length one. Upon construction, a maximum size for the buffer may be specified. If this limit is exceeded, the `std::length_error` exception will be thrown. @note This class is designed for use with algorithms that take dynamic buffers as parameters, and are optimized for the case where the input sequence or output sequence is stored in a single contiguous buffer. */ template class basic_flat_buffer #if ! BOOST_BEAST_DOXYGEN : private boost::empty_value< typename detail::allocator_traits:: template rebind_alloc> #endif { template friend class basic_flat_buffer; using base_alloc_type = typename detail::allocator_traits:: template rebind_alloc; static bool constexpr default_nothrow = std::is_nothrow_default_constructible::value; using alloc_traits = beast::detail::allocator_traits; using pocma = typename alloc_traits::propagate_on_container_move_assignment; using pocca = typename alloc_traits::propagate_on_container_copy_assignment; static std::size_t dist(char const* first, char const* last) noexcept { return static_cast(last - first); } char* begin_; char* in_; char* out_; char* last_; char* end_; std::size_t max_; public: /// The type of allocator used. using allocator_type = Allocator; /// Destructor ~basic_flat_buffer(); /** Constructor After construction, @ref capacity will return zero, and @ref max_size will return the largest value which may be passed to the allocator's `allocate` function. */ basic_flat_buffer() noexcept(default_nothrow); /** Constructor After construction, @ref capacity will return zero, and @ref max_size will return the specified value of `limit`. @param limit The desired maximum size. */ explicit basic_flat_buffer( std::size_t limit) noexcept(default_nothrow); /** Constructor After construction, @ref capacity will return zero, and @ref max_size will return the largest value which may be passed to the allocator's `allocate` function. @param alloc The allocator to use for the object. @esafe No-throw guarantee. */ explicit basic_flat_buffer(Allocator const& alloc) noexcept; /** Constructor After construction, @ref capacity will return zero, and @ref max_size will return the specified value of `limit`. @param limit The desired maximum size. @param alloc The allocator to use for the object. @esafe No-throw guarantee. */ basic_flat_buffer( std::size_t limit, Allocator const& alloc) noexcept; /** Move Constructor The container is constructed with the contents of `other` using move semantics. The maximum size will be the same as the moved-from object. Buffer sequences previously obtained from `other` using @ref data or @ref prepare remain valid after the move. @param other The object to move from. After the move, the moved-from object will have zero capacity, zero readable bytes, and zero writable bytes. @esafe No-throw guarantee. */ basic_flat_buffer(basic_flat_buffer&& other) noexcept; /** Move Constructor Using `alloc` as the allocator for the new container, the contents of `other` are moved. If `alloc != other.get_allocator()`, this results in a copy. The maximum size will be the same as the moved-from object. Buffer sequences previously obtained from `other` using @ref data or @ref prepare become invalid after the move. @param other The object to move from. After the move, the moved-from object will have zero capacity, zero readable bytes, and zero writable bytes. @param alloc The allocator to use for the object. @throws std::length_error if `other.size()` exceeds the maximum allocation size of `alloc`. */ basic_flat_buffer( basic_flat_buffer&& other, Allocator const& alloc); /** Copy Constructor This container is constructed with the contents of `other` using copy semantics. The maximum size will be the same as the copied object. @param other The object to copy from. @throws std::length_error if `other.size()` exceeds the maximum allocation size of the allocator. */ basic_flat_buffer(basic_flat_buffer const& other); /** Copy Constructor This container is constructed with the contents of `other` using copy semantics and the specified allocator. The maximum size will be the same as the copied object. @param other The object to copy from. @param alloc The allocator to use for the object. @throws std::length_error if `other.size()` exceeds the maximum allocation size of `alloc`. */ basic_flat_buffer( basic_flat_buffer const& other, Allocator const& alloc); /** Copy Constructor This container is constructed with the contents of `other` using copy semantics. The maximum size will be the same as the copied object. @param other The object to copy from. @throws std::length_error if `other.size()` exceeds the maximum allocation size of the allocator. */ template basic_flat_buffer( basic_flat_buffer const& other) noexcept(default_nothrow); /** Copy Constructor This container is constructed with the contents of `other` using copy semantics. The maximum size will be the same as the copied object. @param other The object to copy from. @param alloc The allocator to use for the object. @throws std::length_error if `other.size()` exceeds the maximum allocation size of `alloc`. */ template basic_flat_buffer( basic_flat_buffer const& other, Allocator const& alloc); /** Move Assignment The container is assigned with the contents of `other` using move semantics. The maximum size will be the same as the moved-from object. Buffer sequences previously obtained from `other` using @ref data or @ref prepare remain valid after the move. @param other The object to move from. After the move, the moved-from object will have zero capacity, zero readable bytes, and zero writable bytes. @esafe No-throw guarantee. */ basic_flat_buffer& operator=(basic_flat_buffer&& other) noexcept; /** Copy Assignment The container is assigned with the contents of `other` using copy semantics. The maximum size will be the same as the copied object. After the copy, `this` will have zero writable bytes. @param other The object to copy from. @throws std::length_error if `other.size()` exceeds the maximum allocation size of the allocator. */ basic_flat_buffer& operator=(basic_flat_buffer const& other); /** Copy assignment The container is assigned with the contents of `other` using copy semantics. The maximum size will be the same as the copied object. After the copy, `this` will have zero writable bytes. @param other The object to copy from. @throws std::length_error if `other.size()` exceeds the maximum allocation size of the allocator. */ template basic_flat_buffer& operator=(basic_flat_buffer const& other); /// Returns a copy of the allocator used. allocator_type get_allocator() const { return this->get(); } /** Set the maximum allowed capacity This function changes the currently configured upper limit on capacity to the specified value. @param n The maximum number of bytes ever allowed for capacity. @esafe No-throw guarantee. */ void max_size(std::size_t n) noexcept { max_ = n; } /** Guarantee a minimum capacity This function adjusts the internal storage (if necessary) to guarantee space for at least `n` bytes. Buffer sequences previously obtained using @ref data or @ref prepare become invalid. @param n The minimum number of byte for the new capacity. If this value is greater than the maximum size, then the maximum size will be adjusted upwards to this value. @esafe Basic guarantee. @throws std::length_error if n is larger than the maximum allocation size of the allocator. */ void reserve(std::size_t n); /** Reallocate the buffer to fit the readable bytes exactly. Buffer sequences previously obtained using @ref data or @ref prepare become invalid. @esafe Strong guarantee. */ void shrink_to_fit(); /** Set the size of the readable and writable bytes to zero. This clears the buffer without changing capacity. Buffer sequences previously obtained using @ref data or @ref prepare become invalid. @esafe No-throw guarantee. */ void clear() noexcept; /// Exchange two dynamic buffers template friend void swap( basic_flat_buffer&, basic_flat_buffer&); //-------------------------------------------------------------------------- /// The ConstBufferSequence used to represent the readable bytes. using const_buffers_type = net::const_buffer; /// The MutableBufferSequence used to represent the readable bytes. using mutable_data_type = net::mutable_buffer; /// The MutableBufferSequence used to represent the writable bytes. using mutable_buffers_type = net::mutable_buffer; /// Returns the number of readable bytes. std::size_t size() const noexcept { return dist(in_, out_); } /// Return the maximum number of bytes, both readable and writable, that can ever be held. std::size_t max_size() const noexcept { return max_; } /// Return the maximum number of bytes, both readable and writable, that can be held without requiring an allocation. std::size_t capacity() const noexcept { return dist(begin_, end_); } /// Returns a constant buffer sequence representing the readable bytes const_buffers_type data() const noexcept { return {in_, dist(in_, out_)}; } /// Returns a constant buffer sequence representing the readable bytes const_buffers_type cdata() const noexcept { return data(); } /// Returns a mutable buffer sequence representing the readable bytes mutable_data_type data() noexcept { return {in_, dist(in_, out_)}; } /** Returns a mutable buffer sequence representing writable bytes. Returns a mutable buffer sequence representing the writable bytes containing exactly `n` bytes of storage. Memory may be reallocated as needed. All buffers sequences previously obtained using @ref data or @ref prepare become invalid. @param n The desired number of bytes in the returned buffer sequence. @throws std::length_error if `size() + n` exceeds either `max_size()` or the allocator's maximum allocation size. @esafe Strong guarantee. */ mutable_buffers_type prepare(std::size_t n); /** Append writable bytes to the readable bytes. Appends n bytes from the start of the writable bytes to the end of the readable bytes. The remainder of the writable bytes are discarded. If n is greater than the number of writable bytes, all writable bytes are appended to the readable bytes. All buffers sequences previously obtained using @ref data or @ref prepare become invalid. @param n The number of bytes to append. If this number is greater than the number of writable bytes, all writable bytes are appended. @esafe No-throw guarantee. */ void commit(std::size_t n) noexcept { out_ += (std::min)(n, dist(out_, last_)); } /** Remove bytes from beginning of the readable bytes. Removes n bytes from the beginning of the readable bytes. All buffers sequences previously obtained using @ref data or @ref prepare become invalid. @param n The number of bytes to remove. If this number is greater than the number of readable bytes, all readable bytes are removed. @esafe No-throw guarantee. */ void consume(std::size_t n) noexcept; private: template void copy_from(basic_flat_buffer const& other); void move_assign(basic_flat_buffer&, std::true_type); void move_assign(basic_flat_buffer&, std::false_type); void copy_assign(basic_flat_buffer const&, std::true_type); void copy_assign(basic_flat_buffer const&, std::false_type); void swap(basic_flat_buffer&); void swap(basic_flat_buffer&, std::true_type); void swap(basic_flat_buffer&, std::false_type); char* alloc(std::size_t n); }; /// A flat buffer which uses the default allocator. using flat_buffer = basic_flat_buffer>; } // beast } // boost #include #endif