EVOLUTION-MANAGER

Edit File: range.hpp

// Boost.Geometry (aka GGL, Generic Geometry Library) // Copyright (c) 2007-2012 Barend Gehrels, Amsterdam, the Netherlands. // This file was modified by Oracle on 2013, 2014, 2015, 2016, 2019. // Modifications copyright (c) 2013-2019 Oracle and/or its affiliates. // Contributed and/or modified by Adam Wulkiewicz, on behalf of Oracle // Use, modification and distribution is subject to 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_GEOMETRY_UTIL_RANGE_HPP #define BOOST_GEOMETRY_UTIL_RANGE_HPP #include <algorithm> #include <iterator> #include <boost/concept_check.hpp> #include <boost/config.hpp> #include <boost/core/addressof.hpp> #include <boost/range/concepts.hpp> #include <boost/range/begin.hpp> #include <boost/range/end.hpp> #include <boost/range/empty.hpp> #include <boost/range/difference_type.hpp> #include <boost/range/iterator.hpp> #include <boost/range/rbegin.hpp> #include <boost/range/reference.hpp> #include <boost/range/size.hpp> #include <boost/range/value_type.hpp> #include <boost/type_traits/is_convertible.hpp> #include <boost/geometry/core/assert.hpp> #include <boost/geometry/core/mutable_range.hpp> namespace boost { namespace geometry { namespace range { namespace detail { // NOTE: For SinglePassRanges pos could iterate over all elements until the i-th element was met. template <typename RandomAccessRange> struct pos { typedef typename boost::range_iterator<RandomAccessRange>::type iterator; typedef typename boost::range_size<RandomAccessRange>::type size_type; typedef typename boost::range_difference<RandomAccessRange>::type difference_type; static inline iterator apply(RandomAccessRange & rng, size_type i) { BOOST_RANGE_CONCEPT_ASSERT(( boost::RandomAccessRangeConcept<RandomAccessRange> )); return boost::begin(rng) + static_cast<difference_type>(i); } }; } // namespace detail /*! \brief Short utility to conveniently return an iterator of a RandomAccessRange. \ingroup utility */ template <typename RandomAccessRange> inline typename boost::range_iterator<RandomAccessRange const>::type pos(RandomAccessRange const& rng, typename boost::range_size<RandomAccessRange const>::type i) { BOOST_GEOMETRY_ASSERT(i <= boost::size(rng)); return detail::pos<RandomAccessRange const>::apply(rng, i); } /*! \brief Short utility to conveniently return an iterator of a RandomAccessRange. \ingroup utility */ template <typename RandomAccessRange> inline typename boost::range_iterator<RandomAccessRange>::type pos(RandomAccessRange & rng, typename boost::range_size<RandomAccessRange>::type i) { BOOST_GEOMETRY_ASSERT(i <= boost::size(rng)); return detail::pos<RandomAccessRange>::apply(rng, i); } /*! \brief Short utility to conveniently return an element of a RandomAccessRange. \ingroup utility */ template <typename RandomAccessRange> inline typename boost::range_reference<RandomAccessRange const>::type at(RandomAccessRange const& rng, typename boost::range_size<RandomAccessRange const>::type i) { BOOST_GEOMETRY_ASSERT(i < boost::size(rng)); return * detail::pos<RandomAccessRange const>::apply(rng, i); } /*! \brief Short utility to conveniently return an element of a RandomAccessRange. \ingroup utility */ template <typename RandomAccessRange> inline typename boost::range_reference<RandomAccessRange>::type at(RandomAccessRange & rng, typename boost::range_size<RandomAccessRange>::type i) { BOOST_GEOMETRY_ASSERT(i < boost::size(rng)); return * detail::pos<RandomAccessRange>::apply(rng, i); } /*! \brief Short utility to conveniently return the front element of a Range. \ingroup utility */ template <typename Range> inline typename boost::range_reference<Range const>::type front(Range const& rng) { BOOST_GEOMETRY_ASSERT(!boost::empty(rng)); return *boost::begin(rng); } /*! \brief Short utility to conveniently return the front element of a Range. \ingroup utility */ template <typename Range> inline typename boost::range_reference<Range>::type front(Range & rng) { BOOST_GEOMETRY_ASSERT(!boost::empty(rng)); return *boost::begin(rng); } // NOTE: For SinglePassRanges back() could iterate over all elements until the last element is met. /*! \brief Short utility to conveniently return the back element of a BidirectionalRange. \ingroup utility */ template <typename BidirectionalRange> inline typename boost::range_reference<BidirectionalRange const>::type back(BidirectionalRange const& rng) { BOOST_RANGE_CONCEPT_ASSERT(( boost::BidirectionalRangeConcept<BidirectionalRange const> )); BOOST_GEOMETRY_ASSERT(!boost::empty(rng)); return *(boost::rbegin(rng)); } /*! \brief Short utility to conveniently return the back element of a BidirectionalRange. \ingroup utility */ template <typename BidirectionalRange> inline typename boost::range_reference<BidirectionalRange>::type back(BidirectionalRange & rng) { BOOST_RANGE_CONCEPT_ASSERT((boost::BidirectionalRangeConcept<BidirectionalRange>)); BOOST_GEOMETRY_ASSERT(!boost::empty(rng)); return *(boost::rbegin(rng)); } /*! \brief Short utility to conveniently clear a mutable range. It uses traits::clear<>. \ingroup utility */ template <typename Range> inline void clear(Range & rng) { // NOTE: this trait is probably not needed since it could be implemented using resize() geometry::traits::clear<Range>::apply(rng); } /*! \brief Short utility to conveniently insert a new element at the end of a mutable range. It uses boost::geometry::traits::push_back<>. \ingroup utility */ template <typename Range> inline void push_back(Range & rng, typename boost::range_value<Range>::type const& value) { geometry::traits::push_back<Range>::apply(rng, value); } /*! \brief Short utility to conveniently resize a mutable range. It uses boost::geometry::traits::resize<>. \ingroup utility */ template <typename Range> inline void resize(Range & rng, typename boost::range_size<Range>::type new_size) { geometry::traits::resize<Range>::apply(rng, new_size); } /*! \brief Short utility to conveniently remove an element from the back of a mutable range. It uses resize(). \ingroup utility */ template <typename Range> inline void pop_back(Range & rng) { BOOST_GEOMETRY_ASSERT(!boost::empty(rng)); range::resize(rng, boost::size(rng) - 1); } namespace detail { #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES template <typename It, typename OutIt, bool UseMove = boost::is_convertible < typename std::iterator_traits<It>::value_type &&, typename std::iterator_traits<OutIt>::value_type >::value> struct copy_or_move_impl { static inline OutIt apply(It first, It last, OutIt out) { return std::move(first, last, out); } }; template <typename It, typename OutIt> struct copy_or_move_impl<It, OutIt, false> { static inline OutIt apply(It first, It last, OutIt out) { return std::copy(first, last, out); } }; template <typename It, typename OutIt> inline OutIt copy_or_move(It first, It last, OutIt out) { return copy_or_move_impl<It, OutIt>::apply(first, last, out); } #else template <typename It, typename OutIt> inline OutIt copy_or_move(It first, It last, OutIt out) { return std::copy(first, last, out); } #endif } // namespace detail /*! \brief Short utility to conveniently remove an element from a mutable range. It uses std::copy() and resize(). Version taking mutable iterators. \ingroup utility */ template <typename Range> inline typename boost::range_iterator<Range>::type erase(Range & rng, typename boost::range_iterator<Range>::type it) { BOOST_GEOMETRY_ASSERT(!boost::empty(rng)); BOOST_GEOMETRY_ASSERT(it != boost::end(rng)); typename boost::range_difference<Range>::type const d = std::distance(boost::begin(rng), it); typename boost::range_iterator<Range>::type next = it; ++next; detail::copy_or_move(next, boost::end(rng), it); range::resize(rng, boost::size(rng) - 1); // NOTE: In general this should be sufficient: // return it; // But in MSVC using the returned iterator causes // assertion failures when iterator debugging is enabled // Furthermore the code below should work in the case if resize() // invalidates iterators when the container is resized down. return boost::begin(rng) + d; } /*! \brief Short utility to conveniently remove an element from a mutable range. It uses std::copy() and resize(). Version taking non-mutable iterators. \ingroup utility */ template <typename Range> inline typename boost::range_iterator<Range>::type erase(Range & rng, typename boost::range_iterator<Range const>::type cit) { BOOST_RANGE_CONCEPT_ASSERT(( boost::RandomAccessRangeConcept<Range> )); typename boost::range_iterator<Range>::type it = boost::begin(rng) + std::distance(boost::const_begin(rng), cit); return range::erase(rng, it); } /*! \brief Short utility to conveniently remove a range of elements from a mutable range. It uses std::copy() and resize(). Version taking mutable iterators. \ingroup utility */ template <typename Range> inline typename boost::range_iterator<Range>::type erase(Range & rng, typename boost::range_iterator<Range>::type first, typename boost::range_iterator<Range>::type last) { typename boost::range_difference<Range>::type const diff = std::distance(first, last); BOOST_GEOMETRY_ASSERT(diff >= 0); std::size_t const count = static_cast<std::size_t>(diff); BOOST_GEOMETRY_ASSERT(count <= boost::size(rng)); if ( count > 0 ) { typename boost::range_difference<Range>::type const d = std::distance(boost::begin(rng), first); detail::copy_or_move(last, boost::end(rng), first); range::resize(rng, boost::size(rng) - count); // NOTE: In general this should be sufficient: // return first; // But in MSVC using the returned iterator causes // assertion failures when iterator debugging is enabled // Furthermore the code below should work in the case if resize() // invalidates iterators when the container is resized down. return boost::begin(rng) + d; } return first; } /*! \brief Short utility to conveniently remove a range of elements from a mutable range. It uses std::copy() and resize(). Version taking non-mutable iterators. \ingroup utility */ template <typename Range> inline typename boost::range_iterator<Range>::type erase(Range & rng, typename boost::range_iterator<Range const>::type cfirst, typename boost::range_iterator<Range const>::type clast) { BOOST_RANGE_CONCEPT_ASSERT(( boost::RandomAccessRangeConcept<Range> )); typename boost::range_iterator<Range>::type first = boost::begin(rng) + std::distance(boost::const_begin(rng), cfirst); typename boost::range_iterator<Range>::type last = boost::begin(rng) + std::distance(boost::const_begin(rng), clast); return range::erase(rng, first, last); } // back_inserter template <class Container> class back_insert_iterator { public: typedef std::output_iterator_tag iterator_category; typedef void value_type; typedef void difference_type; typedef void pointer; typedef void reference; typedef Container container_type; explicit back_insert_iterator(Container & c) : container(boost::addressof(c)) {} back_insert_iterator & operator=(typename Container::value_type const& value) { range::push_back(*container, value); return *this; } back_insert_iterator & operator* () { return *this; } back_insert_iterator & operator++ () { return *this; } back_insert_iterator operator++(int) { return *this; } private: Container * container; }; template <typename Range> inline back_insert_iterator<Range> back_inserter(Range & rng) { return back_insert_iterator<Range>(rng); } }}} // namespace boost::geometry::range #endif // BOOST_GEOMETRY_UTIL_RANGE_HPP