// Boost.Geometry (aka GGL, Generic Geometry Library) // Copyright (c) 2007-2014 Barend Gehrels, Amsterdam, the Netherlands. // This file was modified by Oracle on 2014. // Modifications copyright (c) 2014 Oracle and/or its affiliates. // Contributed and/or modified by Menelaos Karavelas, 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_ALGORITHMS_DETAIL_OVERLAY_FOLLOW_HPP #define BOOST_GEOMETRY_ALGORITHMS_DETAIL_OVERLAY_FOLLOW_HPP #include #include #include #include #include #include #include #include #include namespace boost { namespace geometry { #ifndef DOXYGEN_NO_DETAIL namespace detail { namespace overlay { namespace following { template static inline bool is_entering(Turn const& /* TODO remove this parameter */, Operation const& op) { // (Blocked means: blocked for polygon/polygon intersection, because // they are reversed. But for polygon/line it is similar to continue) return op.operation == operation_intersection || op.operation == operation_continue || op.operation == operation_blocked ; } template < typename Turn, typename Operation, typename LineString, typename Polygon > static inline bool last_covered_by(Turn const& turn, Operation const& op, LineString const& linestring, Polygon const& polygon) { // Check any point between the this one and the first IP typedef typename geometry::point_type::type point_type; point_type point_in_between; detail::point_on_border::midpoint_helper < point_type, 0, dimension::value >::apply(point_in_between, *(::boost::begin(linestring) + op.seg_id.segment_index), turn.point); return geometry::covered_by(point_in_between, polygon); } template < typename Turn, typename Operation, typename LineString, typename Polygon > static inline bool is_leaving(Turn const& turn, Operation const& op, bool entered, bool first, LineString const& linestring, Polygon const& polygon) { if (op.operation == operation_union) { return entered || turn.method == method_crosses || (first && last_covered_by(turn, op, linestring, polygon)) ; } return false; } template < typename Turn, typename Operation, typename LineString, typename Polygon > static inline bool is_staying_inside(Turn const& turn, Operation const& op, bool entered, bool first, LineString const& linestring, Polygon const& polygon) { if (turn.method == method_crosses) { // The normal case, this is completely covered with entering/leaving // so stay out of this time consuming "covered_by" return false; } if (is_entering(turn, op)) { return entered || (first && last_covered_by(turn, op, linestring, polygon)); } return false; } template < typename Turn, typename Operation, typename Linestring, typename Polygon > static inline bool was_entered(Turn const& turn, Operation const& op, bool first, Linestring const& linestring, Polygon const& polygon) { if (first && (turn.method == method_collinear || turn.method == method_equal)) { return last_covered_by(turn, op, linestring, polygon); } return false; } // Template specialization structure to call the right actions for the right type template struct action_selector { // If you get here the overlay type is not intersection or difference // BOOST_MPL_ASSERT(false); }; // Specialization for intersection, containing the implementation template struct action_selector { template < typename OutputIterator, typename LineStringOut, typename LineString, typename Point, typename Operation, typename RobustPolicy > static inline void enter(LineStringOut& current_piece, LineString const& , segment_identifier& segment_id, signed_index_type , Point const& point, Operation const& operation, RobustPolicy const& , OutputIterator& ) { // On enter, append the intersection point and remember starting point // TODO: we don't check on spikes for linestrings (?). Consider this. detail::overlay::append_no_duplicates(current_piece, point); segment_id = operation.seg_id; } template < typename OutputIterator, typename LineStringOut, typename LineString, typename Point, typename Operation, typename RobustPolicy > static inline void leave(LineStringOut& current_piece, LineString const& linestring, segment_identifier& segment_id, signed_index_type index, Point const& point, Operation const& , RobustPolicy const& robust_policy, OutputIterator& out) { // On leave, copy all segments from starting point, append the intersection point // and add the output piece detail::copy_segments::copy_segments_linestring < false, RemoveSpikes >::apply(linestring, segment_id, index, robust_policy, current_piece); detail::overlay::append_no_duplicates(current_piece, point); if (::boost::size(current_piece) > 1) { *out++ = current_piece; } geometry::clear(current_piece); } template < typename OutputIterator, typename LineStringOut, typename LineString, typename Point, typename Operation > static inline void isolated_point(LineStringOut&, LineString const&, segment_identifier&, signed_index_type, Point const& point, Operation const& , OutputIterator& out) { LineStringOut isolated_point_ls; geometry::append(isolated_point_ls, point); #ifndef BOOST_GEOMETRY_ALLOW_ONE_POINT_LINESTRINGS geometry::append(isolated_point_ls, point); #endif // BOOST_GEOMETRY_ALLOW_ONE_POINT_LINESTRINGS *out++ = isolated_point_ls; } static inline bool is_entered(bool entered) { return entered; } template < typename Point, typename Geometry, typename RobustPolicy > static inline bool included(Point const& point, Geometry const& geometry, RobustPolicy const& ) { return geometry::covered_by(point, geometry); } }; // Specialization for difference, which reverses these actions template struct action_selector { typedef action_selector normal_action; template < typename OutputIterator, typename LineStringOut, typename LineString, typename Point, typename Operation, typename RobustPolicy > static inline void enter(LineStringOut& current_piece, LineString const& linestring, segment_identifier& segment_id, signed_index_type index, Point const& point, Operation const& operation, RobustPolicy const& robust_policy, OutputIterator& out) { normal_action::leave(current_piece, linestring, segment_id, index, point, operation, robust_policy, out); } template < typename OutputIterator, typename LineStringOut, typename LineString, typename Point, typename Operation, typename RobustPolicy > static inline void leave(LineStringOut& current_piece, LineString const& linestring, segment_identifier& segment_id, signed_index_type index, Point const& point, Operation const& operation, RobustPolicy const& robust_policy, OutputIterator& out) { normal_action::enter(current_piece, linestring, segment_id, index, point, operation, robust_policy, out); } template < typename OutputIterator, typename LineStringOut, typename LineString, typename Point, typename Operation > static inline void isolated_point(LineStringOut&, LineString const&, segment_identifier&, signed_index_type, Point const&, Operation const&, OutputIterator&) { } static inline bool is_entered(bool entered) { return ! normal_action::is_entered(entered); } template < typename Point, typename Geometry, typename RobustPolicy > static inline bool included(Point const& point, Geometry const& geometry, RobustPolicy const& robust_policy) { return ! normal_action::included(point, geometry, robust_policy); } }; } /*! \brief Follows a linestring from intersection point to intersection point, outputting which is inside, or outside, a ring or polygon \ingroup overlay */ template < typename LineStringOut, typename LineString, typename Polygon, overlay_type OverlayType, bool RemoveSpikes = true > class follow { template struct sort_on_segment { // In case of turn point at the same location, we want to have continue/blocked LAST // because that should be followed (intersection) or skipped (difference). inline int operation_order(Turn const& turn) const { operation_type const& operation = turn.operations[0].operation; switch(operation) { case operation_opposite : return 0; case operation_none : return 0; case operation_union : return 1; case operation_intersection : return 2; case operation_blocked : return 3; case operation_continue : return 4; } return -1; }; inline bool use_operation(Turn const& left, Turn const& right) const { // If they are the same, OK. return operation_order(left) < operation_order(right); } inline bool use_distance(Turn const& left, Turn const& right) const { return left.operations[0].fraction == right.operations[0].fraction ? use_operation(left, right) : left.operations[0].fraction < right.operations[0].fraction ; } inline bool operator()(Turn const& left, Turn const& right) const { segment_identifier const& sl = left.operations[0].seg_id; segment_identifier const& sr = right.operations[0].seg_id; return sl == sr ? use_distance(left, right) : sl < sr ; } }; public : template < typename Point, typename Geometry, typename RobustPolicy > static inline bool included(Point const& point, Geometry const& geometry, RobustPolicy const& robust_policy) { return following::action_selector < OverlayType, RemoveSpikes >::included(point, geometry, robust_policy); } template < typename Turns, typename OutputIterator, typename RobustPolicy > static inline OutputIterator apply(LineString const& linestring, Polygon const& polygon, detail::overlay::operation_type , // TODO: this parameter might be redundant Turns& turns, RobustPolicy const& robust_policy, OutputIterator out) { typedef typename boost::range_iterator::type turn_iterator; typedef typename boost::range_value::type turn_type; typedef typename boost::range_iterator < typename turn_type::container_type >::type turn_operation_iterator_type; typedef following::action_selector action; // Sort intersection points on segments-along-linestring, and distance // (like in enrich is done for poly/poly) std::sort(boost::begin(turns), boost::end(turns), sort_on_segment()); LineStringOut current_piece; geometry::segment_identifier current_segment_id(0, -1, -1, -1); // Iterate through all intersection points (they are ordered along the line) bool entered = false; bool first = true; for (turn_iterator it = boost::begin(turns); it != boost::end(turns); ++it) { turn_operation_iterator_type iit = boost::begin(it->operations); if (following::was_entered(*it, *iit, first, linestring, polygon)) { debug_traverse(*it, *iit, "-> Was entered"); entered = true; } if (following::is_staying_inside(*it, *iit, entered, first, linestring, polygon)) { debug_traverse(*it, *iit, "-> Staying inside"); entered = true; } else if (following::is_entering(*it, *iit)) { debug_traverse(*it, *iit, "-> Entering"); entered = true; action::enter(current_piece, linestring, current_segment_id, iit->seg_id.segment_index, it->point, *iit, robust_policy, out); } else if (following::is_leaving(*it, *iit, entered, first, linestring, polygon)) { debug_traverse(*it, *iit, "-> Leaving"); entered = false; action::leave(current_piece, linestring, current_segment_id, iit->seg_id.segment_index, it->point, *iit, robust_policy, out); } first = false; } if (action::is_entered(entered)) { detail::copy_segments::copy_segments_linestring < false, RemoveSpikes >::apply(linestring, current_segment_id, static_cast(boost::size(linestring) - 1), robust_policy, current_piece); } // Output the last one, if applicable if (::boost::size(current_piece) > 1) { *out++ = current_piece; } return out; } }; }} // namespace detail::overlay #endif // DOXYGEN_NO_DETAIL }} // namespace boost::geometry #endif // BOOST_GEOMETRY_ALGORITHMS_DETAIL_OVERLAY_FOLLOW_HPP