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view DEPENDENCIES/generic/include/boost/geometry/index/detail/rtree/node/node.hpp @ 101:c530137014c0
Update Boost headers (1.58.0)
| author | Chris Cannam |
|---|---|
| date | Mon, 07 Sep 2015 11:12:49 +0100 |
| parents | 2665513ce2d3 |
| children |
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// Boost.Geometry Index // // R-tree nodes // // Copyright (c) 2011-2015 Adam Wulkiewicz, Lodz, Poland. // // 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_INDEX_DETAIL_RTREE_NODE_NODE_HPP #define BOOST_GEOMETRY_INDEX_DETAIL_RTREE_NODE_NODE_HPP #include <boost/container/vector.hpp> #include <boost/geometry/index/detail/varray.hpp> #include <boost/geometry/index/detail/rtree/node/concept.hpp> #include <boost/geometry/index/detail/rtree/node/pairs.hpp> #include <boost/geometry/index/detail/rtree/node/node_elements.hpp> #include <boost/geometry/index/detail/rtree/node/scoped_deallocator.hpp> //#include <boost/geometry/index/detail/rtree/node/weak_visitor.hpp> //#include <boost/geometry/index/detail/rtree/node/weak_dynamic.hpp> //#include <boost/geometry/index/detail/rtree/node/weak_static.hpp> #include <boost/geometry/index/detail/rtree/node/variant_visitor.hpp> #include <boost/geometry/index/detail/rtree/node/variant_dynamic.hpp> #include <boost/geometry/index/detail/rtree/node/variant_static.hpp> #include <boost/geometry/index/detail/rtree/node/subtree_destroyer.hpp> #include <boost/geometry/algorithms/expand.hpp> #include <boost/geometry/index/detail/rtree/visitors/is_leaf.hpp> #include <boost/geometry/index/detail/algorithms/bounds.hpp> namespace boost { namespace geometry { namespace index { namespace detail { namespace rtree { // elements box template <typename Box, typename FwdIter, typename Translator> inline Box elements_box(FwdIter first, FwdIter last, Translator const& tr) { Box result; if ( first == last ) { geometry::assign_inverse(result); return result; } detail::bounds(element_indexable(*first, tr), result); ++first; for ( ; first != last ; ++first ) geometry::expand(result, element_indexable(*first, tr)); return result; } // destroys subtree if the element is internal node's element template <typename Value, typename Options, typename Translator, typename Box, typename Allocators> struct destroy_element { typedef typename Options::parameters_type parameters_type; typedef typename rtree::internal_node<Value, parameters_type, Box, Allocators, typename Options::node_tag>::type internal_node; typedef typename rtree::leaf<Value, parameters_type, Box, Allocators, typename Options::node_tag>::type leaf; typedef rtree::subtree_destroyer<Value, Options, Translator, Box, Allocators> subtree_destroyer; inline static void apply(typename internal_node::elements_type::value_type & element, Allocators & allocators) { subtree_destroyer dummy(element.second, allocators); element.second = 0; } inline static void apply(typename leaf::elements_type::value_type &, Allocators &) {} }; // destroys stored subtrees if internal node's elements are passed template <typename Value, typename Options, typename Translator, typename Box, typename Allocators> struct destroy_elements { template <typename Range> inline static void apply(Range & elements, Allocators & allocators) { apply(boost::begin(elements), boost::end(elements), allocators); } template <typename It> inline static void apply(It first, It last, Allocators & allocators) { typedef boost::mpl::bool_< boost::is_same< Value, typename std::iterator_traits<It>::value_type >::value > is_range_of_values; apply_dispatch(first, last, allocators, is_range_of_values()); } private: template <typename It> inline static void apply_dispatch(It first, It last, Allocators & allocators, boost::mpl::bool_<false> const& /*is_range_of_values*/) { typedef rtree::subtree_destroyer<Value, Options, Translator, Box, Allocators> subtree_destroyer; for ( ; first != last ; ++first ) { subtree_destroyer dummy(first->second, allocators); first->second = 0; } } template <typename It> inline static void apply_dispatch(It /*first*/, It /*last*/, Allocators & /*allocators*/, boost::mpl::bool_<true> const& /*is_range_of_values*/) {} }; // clears node, deletes all subtrees stored in node template <typename Value, typename Options, typename Translator, typename Box, typename Allocators> struct clear_node { typedef typename Options::parameters_type parameters_type; typedef typename rtree::node<Value, parameters_type, Box, Allocators, typename Options::node_tag>::type node; typedef typename rtree::internal_node<Value, parameters_type, Box, Allocators, typename Options::node_tag>::type internal_node; typedef typename rtree::leaf<Value, parameters_type, Box, Allocators, typename Options::node_tag>::type leaf; inline static void apply(node & node, Allocators & allocators) { rtree::visitors::is_leaf<Value, Options, Box, Allocators> ilv; rtree::apply_visitor(ilv, node); if ( ilv.result ) { apply(rtree::get<leaf>(node), allocators); } else { apply(rtree::get<internal_node>(node), allocators); } } inline static void apply(internal_node & internal_node, Allocators & allocators) { destroy_elements<Value, Options, Translator, Box, Allocators>::apply(rtree::elements(internal_node), allocators); rtree::elements(internal_node).clear(); } inline static void apply(leaf & leaf, Allocators &) { rtree::elements(leaf).clear(); } }; template <typename Container, typename Iterator> void move_from_back(Container & container, Iterator it) { BOOST_GEOMETRY_INDEX_ASSERT(!container.empty(), "cannot copy from empty container"); Iterator back_it = container.end(); --back_it; if ( it != back_it ) { *it = boost::move(*back_it); // MAY THROW (copy) } } }} // namespace detail::rtree }}} // namespace boost::geometry::index #endif // BOOST_GEOMETRY_INDEX_DETAIL_RTREE_NODE_NODE_HPP