// Boost.Geometry (aka GGL, Generic Geometry Library) // Copyright (c) 2011-2014 Barend Gehrels, Amsterdam, the Netherlands. // 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_ALGORITHMS_DETAIL_PARTITION_HPP #define BOOST_GEOMETRY_ALGORITHMS_DETAIL_PARTITION_HPP #include #include #include #include #include namespace boost { namespace geometry { namespace detail { namespace partition { typedef std::vector index_vector_type; template void divide_box(Box const& box, Box& lower_box, Box& upper_box) { typedef typename coordinate_type::type ctype; // Divide input box into two parts, e.g. left/right ctype two = 2; ctype mid = (geometry::get(box) + geometry::get(box)) / two; lower_box = box; upper_box = box; geometry::set(lower_box, mid); geometry::set(upper_box, mid); } // Divide collection into three subsets: lower, upper and oversized // (not-fitting) // (lower == left or bottom, upper == right or top) template inline void divide_into_subsets(Box const& lower_box, Box const& upper_box, InputCollection const& collection, index_vector_type const& input, index_vector_type& lower, index_vector_type& upper, index_vector_type& exceeding) { typedef boost::range_iterator < index_vector_type const >::type index_iterator_type; for(index_iterator_type it = boost::begin(input); it != boost::end(input); ++it) { bool const lower_overlapping = OverlapsPolicy::apply(lower_box, collection[*it]); bool const upper_overlapping = OverlapsPolicy::apply(upper_box, collection[*it]); if (lower_overlapping && upper_overlapping) { exceeding.push_back(*it); } else if (lower_overlapping) { lower.push_back(*it); } else if (upper_overlapping) { upper.push_back(*it); } else { // Is nowhere! Should not occur! BOOST_ASSERT(false); } } } // Match collection with itself template inline void handle_one(InputCollection const& collection, index_vector_type const& input, Policy& policy) { typedef boost::range_iterator::type index_iterator_type; // Quadratic behaviour at lowest level (lowest quad, or all exceeding) for(index_iterator_type it1 = boost::begin(input); it1 != boost::end(input); ++it1) { index_iterator_type it2 = it1; for(++it2; it2 != boost::end(input); ++it2) { policy.apply(collection[*it1], collection[*it2]); } } } // Match collection 1 with collection 2 template < typename InputCollection1, typename InputCollection2, typename Policy > inline void handle_two( InputCollection1 const& collection1, index_vector_type const& input1, InputCollection2 const& collection2, index_vector_type const& input2, Policy& policy) { typedef boost::range_iterator < index_vector_type const >::type index_iterator_type; for(index_iterator_type it1 = boost::begin(input1); it1 != boost::end(input1); ++it1) { for(index_iterator_type it2 = boost::begin(input2); it2 != boost::end(input2); ++it2) { policy.apply(collection1[*it1], collection2[*it2]); } } } template < int Dimension, typename Box, typename OverlapsPolicy, typename VisitBoxPolicy > class partition_one_collection { typedef std::vector index_vector_type; typedef typename coordinate_type::type ctype; typedef partition_one_collection < 1 - Dimension, Box, OverlapsPolicy, VisitBoxPolicy > sub_divide; template static inline void next_level(Box const& box, InputCollection const& collection, index_vector_type const& input, int level, std::size_t min_elements, Policy& policy, VisitBoxPolicy& box_policy) { if (boost::size(input) > 0) { if (std::size_t(boost::size(input)) > min_elements && level < 100) { sub_divide::apply(box, collection, input, level + 1, min_elements, policy, box_policy); } else { handle_one(collection, input, policy); } } } public : template static inline void apply(Box const& box, InputCollection const& collection, index_vector_type const& input, int level, std::size_t min_elements, Policy& policy, VisitBoxPolicy& box_policy) { box_policy.apply(box, level); Box lower_box, upper_box; divide_box(box, lower_box, upper_box); index_vector_type lower, upper, exceeding; divide_into_subsets(lower_box, upper_box, collection, input, lower, upper, exceeding); if (boost::size(exceeding) > 0) { // All what is not fitting a partition should be combined // with each other, and with all which is fitting. handle_one(collection, exceeding, policy); handle_two(collection, exceeding, collection, lower, policy); handle_two(collection, exceeding, collection, upper, policy); } // Recursively call operation both parts next_level(lower_box, collection, lower, level, min_elements, policy, box_policy); next_level(upper_box, collection, upper, level, min_elements, policy, box_policy); } }; template < int Dimension, typename Box, typename OverlapsPolicy1, typename OverlapsPolicy2, typename VisitBoxPolicy > class partition_two_collections { typedef std::vector index_vector_type; typedef typename coordinate_type::type ctype; typedef partition_two_collections < 1 - Dimension, Box, OverlapsPolicy1, OverlapsPolicy2, VisitBoxPolicy > sub_divide; template < typename InputCollection1, typename InputCollection2, typename Policy > static inline void next_level(Box const& box, InputCollection1 const& collection1, index_vector_type const& input1, InputCollection2 const& collection2, index_vector_type const& input2, int level, std::size_t min_elements, Policy& policy, VisitBoxPolicy& box_policy) { if (boost::size(input1) > 0 && boost::size(input2) > 0) { if (std::size_t(boost::size(input1)) > min_elements && std::size_t(boost::size(input2)) > min_elements && level < 100) { sub_divide::apply(box, collection1, input1, collection2, input2, level + 1, min_elements, policy, box_policy); } else { box_policy.apply(box, level + 1); handle_two(collection1, input1, collection2, input2, policy); } } } public : template < typename InputCollection1, typename InputCollection2, typename Policy > static inline void apply(Box const& box, InputCollection1 const& collection1, index_vector_type const& input1, InputCollection2 const& collection2, index_vector_type const& input2, int level, std::size_t min_elements, Policy& policy, VisitBoxPolicy& box_policy) { box_policy.apply(box, level); Box lower_box, upper_box; divide_box(box, lower_box, upper_box); index_vector_type lower1, upper1, exceeding1; index_vector_type lower2, upper2, exceeding2; divide_into_subsets(lower_box, upper_box, collection1, input1, lower1, upper1, exceeding1); divide_into_subsets(lower_box, upper_box, collection2, input2, lower2, upper2, exceeding2); if (boost::size(exceeding1) > 0) { // All exceeding from 1 with 2: handle_two(collection1, exceeding1, collection2, exceeding2, policy); // All exceeding from 1 with lower and upper of 2: handle_two(collection1, exceeding1, collection2, lower2, policy); handle_two(collection1, exceeding1, collection2, upper2, policy); } if (boost::size(exceeding2) > 0) { // All exceeding from 2 with lower and upper of 1: handle_two(collection1, lower1, collection2, exceeding2, policy); handle_two(collection1, upper1, collection2, exceeding2, policy); } next_level(lower_box, collection1, lower1, collection2, lower2, level, min_elements, policy, box_policy); next_level(upper_box, collection1, upper1, collection2, upper2, level, min_elements, policy, box_policy); } }; }} // namespace detail::partition struct visit_no_policy { template static inline void apply(Box const&, int ) {} }; template < typename Box, typename ExpandPolicy1, typename OverlapsPolicy1, typename ExpandPolicy2 = ExpandPolicy1, typename OverlapsPolicy2 = OverlapsPolicy1, typename VisitBoxPolicy = visit_no_policy > class partition { typedef std::vector index_vector_type; template static inline void expand_to_collection(InputCollection const& collection, Box& total, index_vector_type& index_vector) { std::size_t index = 0; for(typename boost::range_iterator::type it = boost::begin(collection); it != boost::end(collection); ++it, ++index) { ExpandPolicy::apply(total, *it); index_vector.push_back(index); } } public : template static inline void apply(InputCollection const& collection, VisitPolicy& visitor, std::size_t min_elements = 16, VisitBoxPolicy box_visitor = visit_no_policy() ) { if (std::size_t(boost::size(collection)) > min_elements) { index_vector_type index_vector; Box total; assign_inverse(total); expand_to_collection(collection, total, index_vector); detail::partition::partition_one_collection < 0, Box, OverlapsPolicy1, VisitBoxPolicy >::apply(total, collection, index_vector, 0, min_elements, visitor, box_visitor); } else { typedef typename boost::range_iterator < InputCollection const >::type iterator_type; for(iterator_type it1 = boost::begin(collection); it1 != boost::end(collection); ++it1) { iterator_type it2 = it1; for(++it2; it2 != boost::end(collection); ++it2) { visitor.apply(*it1, *it2); } } } } template < typename InputCollection1, typename InputCollection2, typename VisitPolicy > static inline void apply(InputCollection1 const& collection1, InputCollection2 const& collection2, VisitPolicy& visitor, std::size_t min_elements = 16, VisitBoxPolicy box_visitor = visit_no_policy() ) { if (std::size_t(boost::size(collection1)) > min_elements && std::size_t(boost::size(collection2)) > min_elements) { index_vector_type index_vector1, index_vector2; Box total; assign_inverse(total); expand_to_collection(collection1, total, index_vector1); expand_to_collection(collection2, total, index_vector2); detail::partition::partition_two_collections < 0, Box, OverlapsPolicy1, OverlapsPolicy2, VisitBoxPolicy >::apply(total, collection1, index_vector1, collection2, index_vector2, 0, min_elements, visitor, box_visitor); } else { typedef typename boost::range_iterator < InputCollection1 const >::type iterator_type1; typedef typename boost::range_iterator < InputCollection2 const >::type iterator_type2; for(iterator_type1 it1 = boost::begin(collection1); it1 != boost::end(collection1); ++it1) { for(iterator_type2 it2 = boost::begin(collection2); it2 != boost::end(collection2); ++it2) { visitor.apply(*it1, *it2); } } } } }; }} // namespace boost::geometry #endif // BOOST_GEOMETRY_ALGORITHMS_DETAIL_PARTITION_HPP