// Boost.Geometry (aka GGL, Generic Geometry Library) // Copyright (c) 2007-2012 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_GEOMETRY_POLICIES_RELATE_INTERSECTION_POINTS_HPP #define BOOST_GEOMETRY_GEOMETRY_POLICIES_RELATE_INTERSECTION_POINTS_HPP #include #include #include #include #include #include #include #include #include namespace boost { namespace geometry { namespace policies { namespace relate { template struct segments_intersection_points { typedef ReturnType return_type; typedef S1 segment_type1; typedef S2 segment_type2; typedef typename select_calculation_type < S1, S2, CalculationType >::type coordinate_type; template static inline return_type segments_intersect(side_info const&, R const& r, coordinate_type const& dx1, coordinate_type const& dy1, coordinate_type const& dx2, coordinate_type const& dy2, S1 const& s1, S2 const& s2) { typedef typename geometry::coordinate_type < typename return_type::point_type >::type return_coordinate_type; coordinate_type const s1x = get<0, 0>(s1); coordinate_type const s1y = get<0, 1>(s1); return_type result; result.count = 1; set<0>(result.intersections[0], boost::numeric_cast(R(s1x) + r * R(dx1))); set<1>(result.intersections[0], boost::numeric_cast(R(s1y) + r * R(dy1))); return result; } static inline return_type collinear_touch(coordinate_type const& x, coordinate_type const& y, int, int) { return_type result; result.count = 1; set<0>(result.intersections[0], x); set<1>(result.intersections[0], y); return result; } template static inline return_type collinear_inside(S const& s, int index1 = 0, int index2 = 1) { return_type result; result.count = 2; set<0>(result.intersections[index1], get<0, 0>(s)); set<1>(result.intersections[index1], get<0, 1>(s)); set<0>(result.intersections[index2], get<1, 0>(s)); set<1>(result.intersections[index2], get<1, 1>(s)); return result; } template static inline return_type collinear_interior_boundary_intersect(S const& s, bool a_in_b, int, int, bool opposite) { int index1 = opposite && ! a_in_b ? 1 : 0; return collinear_inside(s, index1, 1 - index1); } static inline return_type collinear_a_in_b(S1 const& s, bool) { return collinear_inside(s); } static inline return_type collinear_b_in_a(S2 const& s, bool opposite) { int index1 = opposite ? 1 : 0; return collinear_inside(s, index1, 1 - index1); } static inline return_type collinear_overlaps( coordinate_type const& x1, coordinate_type const& y1, coordinate_type const& x2, coordinate_type const& y2, int, int, bool) { return_type result; result.count = 2; set<0>(result.intersections[0], x1); set<1>(result.intersections[0], y1); set<0>(result.intersections[1], x2); set<1>(result.intersections[1], y2); return result; } static inline return_type segment_equal(S1 const& s, bool) { return_type result; result.count = 2; // TODO: order of IP's set<0>(result.intersections[0], get<0, 0>(s)); set<1>(result.intersections[0], get<0, 1>(s)); set<0>(result.intersections[1], get<1, 0>(s)); set<1>(result.intersections[1], get<1, 1>(s)); return result; } static inline return_type disjoint() { return return_type(); } static inline return_type error(std::string const&) { return return_type(); } static inline return_type collinear_disjoint() { return return_type(); } static inline return_type degenerate(S1 const& s, bool) { return_type result; result.count = 1; set<0>(result.intersections[0], get<0, 0>(s)); set<1>(result.intersections[0], get<0, 1>(s)); return result; } }; }} // namespace policies::relate }} // namespace boost::geometry #endif // BOOST_GEOMETRY_GEOMETRY_POLICIES_RELATE_INTERSECTION_POINTS_HPP