boost/xpressive/detail/core/list.hpp
/////////////////////////////////////////////////////////////////////////////// // list.hpp // A simple implementation of std::list that allows incomplete // types, does no dynamic allocation in the default constructor, // and has a guarnteed O(1) splice. // // Copyright 2009 Eric Niebler. 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_XPRESSIVE_DETAIL_CORE_LIST_HPP_EAN_10_26_2009 #define BOOST_XPRESSIVE_DETAIL_CORE_LIST_HPP_EAN_10_26_2009 // MS compatible compilers support #pragma once #if defined(_MSC_VER) # pragma once #endif #include <cstddef> #include <iterator> #include <algorithm> #include <boost/assert.hpp> #include <boost/iterator/iterator_facade.hpp> namespace boost { namespace xpressive { namespace detail { /////////////////////////////////////////////////////////////////////////////// // list // template<typename T> struct list { private: struct node_base { node_base *_prev; node_base *_next; }; struct node : node_base { explicit node(T const &value) : _value(value) {} T _value; }; node_base _sentry; template<typename Ref = T &> struct list_iterator : boost::iterator_facade<list_iterator<Ref>, T, std::bidirectional_iterator_tag, Ref> { list_iterator(list_iterator<> const &it) : _node(it._node) {} explicit list_iterator(node_base *n = 0) : _node(n) {} private: friend struct list<T>; friend class boost::iterator_core_access; Ref dereference() const { return static_cast<node *>(_node)->_value; } void increment() { _node = _node->_next; } void decrement() { _node = _node->_prev; } bool equal(list_iterator const &it) const { return _node == it._node; } node_base *_node; }; public: typedef T *pointer; typedef T const *const_pointer; typedef T &reference; typedef T const &const_reference; typedef list_iterator<> iterator; typedef list_iterator<T const &> const_iterator; typedef std::size_t size_type; list() { _sentry._next = _sentry._prev = &_sentry; } list(list const &that) { _sentry._next = _sentry._prev = &_sentry; const_iterator it = that.begin(), e = that.end(); for( ; it != e; ++it) push_back(*it); } list &operator =(list const &that) { list(that).swap(*this); return *this; } ~list() { clear(); } void clear() { while(!empty()) pop_front(); } void swap(list &that) // throw() { list temp; temp.splice(temp.begin(), that); // move that to temp that.splice(that.begin(), *this); // move this to that splice(begin(), temp); // move temp to this } void push_front(T const &t) { node *new_node = new node(t); new_node->_next = _sentry._next; new_node->_prev = &_sentry; _sentry._next->_prev = new_node; _sentry._next = new_node; } void push_back(T const &t) { node *new_node = new node(t); new_node->_next = &_sentry; new_node->_prev = _sentry._prev; _sentry._prev->_next = new_node; _sentry._prev = new_node; } void pop_front() { BOOST_ASSERT(!empty()); node *old_node = static_cast<node *>(_sentry._next); _sentry._next = old_node->_next; _sentry._next->_prev = &_sentry; delete old_node; } void pop_back() { BOOST_ASSERT(!empty()); node *old_node = static_cast<node *>(_sentry._prev); _sentry._prev = old_node->_prev; _sentry._prev->_next = &_sentry; delete old_node; } bool empty() const { return _sentry._next == &_sentry; } void splice(iterator it, list &x) { if(x.empty()) return; x._sentry._prev->_next = it._node; x._sentry._next->_prev = it._node->_prev; it._node->_prev->_next = x._sentry._next; it._node->_prev = x._sentry._prev; x._sentry._prev = x._sentry._next = &x._sentry; } void splice(iterator it, list &, iterator xit) { xit._node->_prev->_next = xit._node->_next; xit._node->_next->_prev = xit._node->_prev; xit._node->_next = it._node; xit._node->_prev = it._node->_prev; it._node->_prev = it._node->_prev->_next = xit._node; } reference front() { BOOST_ASSERT(!empty()); return static_cast<node *>(_sentry._next)->_value; } const_reference front() const { BOOST_ASSERT(!empty()); return static_cast<node *>(_sentry._next)->_value; } reference back() { BOOST_ASSERT(!empty()); return static_cast<node *>(_sentry._prev)->_value; } const_reference back() const { BOOST_ASSERT(!empty()); return static_cast<node *>(_sentry._prev)->_value; } iterator begin() { return iterator(_sentry._next); } const_iterator begin() const { return const_iterator(_sentry._next); } iterator end() { return iterator(&_sentry); } const_iterator end() const { return const_iterator(const_cast<node_base *>(&_sentry)); } size_type size() const { return static_cast<size_type>(std::distance(begin(), end())); } }; template<typename T> void swap(list<T> &lhs, list<T> &rhs) { lhs.swap(rhs); } }}} // namespace boost::xpressive::detail #endif