// 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. // Modifications copyright (c) 2013-2014 Oracle and/or its affiliates. // 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) // Contributed and/or modified by Adam Wulkiewicz, on behalf of Oracle #ifndef BOOST_GEOMETRY_ALGORITHMS_DETAIL_RELATE_FOLLOW_HELPERS_HPP #define BOOST_GEOMETRY_ALGORITHMS_DETAIL_RELATE_FOLLOW_HELPERS_HPP #include //#include namespace boost { namespace geometry { #ifndef DOXYGEN_NO_DETAIL namespace detail { namespace relate { // NOTE: This iterates through single geometries for which turns were not generated. // It doesn't mean that the geometry is disjoint, only that no turns were detected. template ::type, bool IsMulti = boost::is_base_of::value > struct for_each_disjoint_geometry_if : public not_implemented {}; template struct for_each_disjoint_geometry_if { template static inline bool apply(TurnIt first, TurnIt last, Geometry const& geometry, Pred & pred) { if ( first != last ) return false; pred(geometry); return true; } }; template struct for_each_disjoint_geometry_if { template static inline bool apply(TurnIt first, TurnIt last, Geometry const& geometry, Pred & pred) { if ( first != last ) return for_turns(first, last, geometry, pred); else return for_empty(geometry, pred); } template static inline bool for_empty(Geometry const& geometry, Pred & pred) { typedef typename boost::range_iterator::type iterator; // O(N) // check predicate for each contained geometry without generated turn for ( iterator it = boost::begin(geometry) ; it != boost::end(geometry) ; ++it ) { bool cont = pred(*it); if ( !cont ) break; } return !boost::empty(geometry); } template static inline bool for_turns(TurnIt first, TurnIt last, Geometry const& geometry, Pred & pred) { BOOST_ASSERT(first != last); const std::size_t count = boost::size(geometry); boost::ignore_unused_variable_warning(count); // O(I) // gather info about turns generated for contained geometries std::vector detected_intersections(count, false); for ( TurnIt it = first ; it != last ; ++it ) { int multi_index = it->operations[OpId].seg_id.multi_index; BOOST_ASSERT(multi_index >= 0); std::size_t index = static_cast(multi_index); BOOST_ASSERT(index < count); detected_intersections[index] = true; } bool found = false; // O(N) // check predicate for each contained geometry without generated turn for ( std::vector::iterator it = detected_intersections.begin() ; it != detected_intersections.end() ; ++it ) { // if there were no intersections for this multi_index if ( *it == false ) { found = true; bool cont = pred(range::at(geometry, std::distance(detected_intersections.begin(), it))); if ( !cont ) break; } } return found; } }; // WARNING! This class stores pointers! // Passing a reference to local variable will result in undefined behavior! template class point_info { public: point_info() : sid_ptr(NULL), pt_ptr(NULL) {} point_info(Point const& pt, segment_identifier const& sid) : sid_ptr(boost::addressof(sid)) , pt_ptr(boost::addressof(pt)) {} segment_identifier const& seg_id() const { BOOST_ASSERT(sid_ptr); return *sid_ptr; } Point const& point() const { BOOST_ASSERT(pt_ptr); return *pt_ptr; } //friend bool operator==(point_identifier const& l, point_identifier const& r) //{ // return l.seg_id() == r.seg_id() // && detail::equals::equals_point_point(l.point(), r.point()); //} private: const segment_identifier * sid_ptr; const Point * pt_ptr; }; // WARNING! This class stores pointers! // Passing a reference to local variable will result in undefined behavior! class same_single { public: same_single(segment_identifier const& sid) : sid_ptr(boost::addressof(sid)) {} bool operator()(segment_identifier const& sid) const { return sid.multi_index == sid_ptr->multi_index; } template bool operator()(point_info const& pid) const { return operator()(pid.seg_id()); } private: const segment_identifier * sid_ptr; }; class same_ring { public: same_ring(segment_identifier const& sid) : sid_ptr(boost::addressof(sid)) {} bool operator()(segment_identifier const& sid) const { return sid.multi_index == sid_ptr->multi_index && sid.ring_index == sid_ptr->ring_index; } private: const segment_identifier * sid_ptr; }; // WARNING! This class stores pointers! // Passing a reference to local variable will result in undefined behavior! template class segment_watcher { public: segment_watcher() : m_seg_id_ptr(NULL) {} bool update(segment_identifier const& seg_id) { bool result = m_seg_id_ptr == 0 || !SameRange(*m_seg_id_ptr)(seg_id); m_seg_id_ptr = boost::addressof(seg_id); return result; } private: const segment_identifier * m_seg_id_ptr; }; // WARNING! This class stores pointers! // Passing a reference to local variable will result in undefined behavior! template class exit_watcher { static const std::size_t op_id = OpId; static const std::size_t other_op_id = (OpId + 1) % 2; typedef typename TurnInfo::point_type point_type; typedef detail::relate::point_info point_info; public: exit_watcher() : m_exit_operation(overlay::operation_none) , m_exit_turn_ptr(NULL) {} void enter(TurnInfo const& turn) { m_other_entry_points.push_back( point_info(turn.point, turn.operations[other_op_id].seg_id) ); } // TODO: exit_per_geometry parameter looks not very safe // wrong value may be easily passed void exit(TurnInfo const& turn, bool exit_per_geometry = true) { //segment_identifier const& seg_id = turn.operations[op_id].seg_id; segment_identifier const& other_id = turn.operations[other_op_id].seg_id; overlay::operation_type exit_op = turn.operations[op_id].operation; typedef typename std::vector::iterator point_iterator; // search for the entry point in the same range of other geometry point_iterator entry_it = std::find_if(m_other_entry_points.begin(), m_other_entry_points.end(), same_single(other_id)); // this end point has corresponding entry point if ( entry_it != m_other_entry_points.end() ) { // erase the corresponding entry point m_other_entry_points.erase(entry_it); if ( exit_per_geometry || m_other_entry_points.empty() ) { // here we know that we possibly left LS // we must still check if we didn't get back on the same point m_exit_operation = exit_op; m_exit_turn_ptr = boost::addressof(turn); } } } bool is_outside() const { // if we didn't entered anything in the past, we're outside return m_other_entry_points.empty(); } bool is_outside(TurnInfo const& turn) const { return m_other_entry_points.empty() || std::find_if(m_other_entry_points.begin(), m_other_entry_points.end(), same_single( turn.operations[other_op_id].seg_id)) == m_other_entry_points.end(); } overlay::operation_type get_exit_operation() const { return m_exit_operation; } point_type const& get_exit_point() const { BOOST_ASSERT(m_exit_operation != overlay::operation_none); BOOST_ASSERT(m_exit_turn_ptr); return m_exit_turn_ptr->point; } TurnInfo const& get_exit_turn() const { BOOST_ASSERT(m_exit_operation != overlay::operation_none); BOOST_ASSERT(m_exit_turn_ptr); return *m_exit_turn_ptr; } void reset_detected_exit() { m_exit_operation = overlay::operation_none; } void reset() { m_exit_operation = overlay::operation_none; m_other_entry_points.clear(); } private: overlay::operation_type m_exit_operation; const TurnInfo * m_exit_turn_ptr; std::vector m_other_entry_points; // TODO: use map here or sorted vector? }; template inline bool turn_on_the_same_ip(Turn const& prev_turn, Turn const& curr_turn) { segment_identifier const& prev_seg_id = prev_turn.operations[OpId].seg_id; segment_identifier const& curr_seg_id = curr_turn.operations[OpId].seg_id; if ( prev_seg_id.multi_index != curr_seg_id.multi_index || prev_seg_id.ring_index != curr_seg_id.ring_index ) { return false; } // TODO: will this work if between segments there will be some number of degenerated ones? if ( prev_seg_id.segment_index != curr_seg_id.segment_index && ( ! curr_turn.operations[OpId].fraction.is_zero() || prev_seg_id.segment_index + 1 != curr_seg_id.segment_index ) ) { return false; } return detail::equals::equals_point_point(prev_turn.point, curr_turn.point); } template static inline bool is_endpoint_on_boundary(Point const& pt, BoundaryChecker & boundary_checker) { return boundary_checker.template is_endpoint_boundary(pt); } template static inline bool is_ip_on_boundary(IntersectionPoint const& ip, OperationInfo const& operation_info, BoundaryChecker & boundary_checker, segment_identifier const& seg_id) { boost::ignore_unused_variable_warning(seg_id); bool res = false; // IP on the last point of the linestring if ( (BoundaryQuery == boundary_back || BoundaryQuery == boundary_any) && operation_info.position == overlay::position_back ) { // check if this point is a boundary res = boundary_checker.template is_endpoint_boundary(ip); } // IP on the last point of the linestring else if ( (BoundaryQuery == boundary_front || BoundaryQuery == boundary_any) && operation_info.position == overlay::position_front ) { // check if this point is a boundary res = boundary_checker.template is_endpoint_boundary(ip); } return res; } }} // namespace detail::relate #endif // DOXYGEN_NO_DETAIL }} // namespace boost::geometry #endif // BOOST_GEOMETRY_ALGORITHMS_DETAIL_RELATE_FOLLOW_HELPERS_HPP