EVOLUTION-MANAGER

Edit File: implementation.hpp

// Boost.Geometry (aka GGL, Generic Geometry Library) // Copyright (c) 2007-2015 Barend Gehrels, Amsterdam, the Netherlands. // Copyright (c) 2008-2015 Bruno Lalande, Paris, France. // Copyright (c) 2009-2015 Mateusz Loskot, London, UK. // Copyright (c) 2013-2015 Adam Wulkiewicz, Lodz, Poland. // This file was modified by Oracle on 2013, 2014, 2015, 2017, 2019. // Modifications copyright (c) 2013-2019, Oracle and/or its affiliates. // Contributed and/or modified by Adam Wulkiewicz, on behalf of Oracle // Parts of Boost.Geometry are redesigned from Geodan's Geographic Library // (geolib/GGL), copyright (c) 1995-2010 Geodan, 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_TOUCHES_IMPLEMENTATION_HPP #define BOOST_GEOMETRY_ALGORITHMS_DETAIL_TOUCHES_IMPLEMENTATION_HPP #include <boost/geometry/algorithms/detail/for_each_range.hpp> #include <boost/geometry/algorithms/detail/overlay/overlay.hpp> #include <boost/geometry/algorithms/detail/overlay/self_turn_points.hpp> #include <boost/geometry/algorithms/detail/sub_range.hpp> #include <boost/geometry/algorithms/detail/relate/relate_impl.hpp> #include <boost/geometry/algorithms/detail/touches/interface.hpp> #include <boost/geometry/algorithms/disjoint.hpp> #include <boost/geometry/algorithms/intersects.hpp> #include <boost/geometry/algorithms/num_geometries.hpp> #include <boost/geometry/algorithms/relate.hpp> #include <boost/geometry/policies/robustness/no_rescale_policy.hpp> namespace boost { namespace geometry { #ifndef DOXYGEN_NO_DETAIL namespace detail { namespace touches { // Box/Box template < std::size_t Dimension, std::size_t DimensionCount > struct box_box_loop { template <typename Box1, typename Box2> static inline bool apply(Box1 const& b1, Box2 const& b2, bool & touch) { typedef typename coordinate_type<Box1>::type coordinate_type1; typedef typename coordinate_type<Box2>::type coordinate_type2; coordinate_type1 const& min1 = get<min_corner, Dimension>(b1); coordinate_type1 const& max1 = get<max_corner, Dimension>(b1); coordinate_type2 const& min2 = get<min_corner, Dimension>(b2); coordinate_type2 const& max2 = get<max_corner, Dimension>(b2); // TODO assert or exception? //BOOST_GEOMETRY_ASSERT(min1 <= max1 && min2 <= max2); if (max1 < min2 || max2 < min1) { return false; } if (max1 == min2 || max2 == min1) { touch = true; } return box_box_loop < Dimension + 1, DimensionCount >::apply(b1, b2, touch); } }; template < std::size_t DimensionCount > struct box_box_loop<DimensionCount, DimensionCount> { template <typename Box1, typename Box2> static inline bool apply(Box1 const& , Box2 const&, bool &) { return true; } }; struct box_box { template <typename Box1, typename Box2, typename Strategy> static inline bool apply(Box1 const& b1, Box2 const& b2, Strategy const& /*strategy*/) { BOOST_STATIC_ASSERT((boost::is_same < typename geometry::coordinate_system<Box1>::type, typename geometry::coordinate_system<Box2>::type >::value )); assert_dimension_equal<Box1, Box2>(); bool touches = false; bool ok = box_box_loop < 0, dimension<Box1>::type::value >::apply(b1, b2, touches); return ok && touches; } }; // Areal/Areal struct areal_interrupt_policy { static bool const enabled = true; bool found_touch; bool found_not_touch; // dummy variable required by self_get_turn_points::get_turns static bool const has_intersections = false; inline bool result() { return found_touch && !found_not_touch; } inline areal_interrupt_policy() : found_touch(false), found_not_touch(false) {} template <typename Range> inline bool apply(Range const& range) { // if already rejected (temp workaround?) if ( found_not_touch ) return true; typedef typename boost::range_iterator<Range const>::type iterator; for ( iterator it = boost::begin(range) ; it != boost::end(range) ; ++it ) { if ( it->has(overlay::operation_intersection) ) { found_not_touch = true; return true; } switch(it->method) { case overlay::method_crosses: found_not_touch = true; return true; case overlay::method_equal: // Segment spatially equal means: at the right side // the polygon internally overlaps. So return false. found_not_touch = true; return true; case overlay::method_touch: case overlay::method_touch_interior: case overlay::method_collinear: if ( ok_for_touch(*it) ) { found_touch = true; } else { found_not_touch = true; return true; } break; case overlay::method_none : case overlay::method_disjoint : case overlay::method_error : break; } } return false; } template <typename Turn> inline bool ok_for_touch(Turn const& turn) { return turn.both(overlay::operation_union) || turn.both(overlay::operation_blocked) || turn.combination(overlay::operation_union, overlay::operation_blocked) ; } }; template<typename Geometry, typename PointInRingStrategy> struct check_each_ring_for_within { bool has_within; Geometry const& m_geometry; PointInRingStrategy const& m_strategy; inline check_each_ring_for_within(Geometry const& g, PointInRingStrategy const& strategy) : has_within(false) , m_geometry(g) , m_strategy(strategy) {} template <typename Range> inline void apply(Range const& range) { typename geometry::point_type<Range>::type p; geometry::point_on_border(p, range); if ( !has_within && geometry::within(p, m_geometry, m_strategy) ) { has_within = true; } } }; template <typename FirstGeometry, typename SecondGeometry, typename IntersectionStrategy> inline bool rings_containing(FirstGeometry const& geometry1, SecondGeometry const& geometry2, IntersectionStrategy const& strategy) { // NOTE: This strategy could be defined inside IntersectionStrategy typedef typename IntersectionStrategy::template point_in_geometry_strategy < FirstGeometry, SecondGeometry >::type point_in_ring_strategy_type; point_in_ring_strategy_type point_in_ring_strategy = strategy.template get_point_in_geometry_strategy<FirstGeometry, SecondGeometry>(); check_each_ring_for_within < FirstGeometry, point_in_ring_strategy_type > checker(geometry1, point_in_ring_strategy); geometry::detail::for_each_range(geometry2, checker); return checker.has_within; } template <typename Geometry1, typename Geometry2> struct areal_areal { template <typename IntersectionStrategy> static inline bool apply(Geometry1 const& geometry1, Geometry2 const& geometry2, IntersectionStrategy const& strategy) { typedef typename geometry::point_type<Geometry1>::type point_type; typedef detail::overlay::turn_info<point_type> turn_info; std::deque<turn_info> turns; detail::touches::areal_interrupt_policy policy; boost::geometry::get_turns < detail::overlay::do_reverse<geometry::point_order<Geometry1>::value>::value, detail::overlay::do_reverse<geometry::point_order<Geometry2>::value>::value, detail::overlay::assign_null_policy >(geometry1, geometry2, strategy, detail::no_rescale_policy(), turns, policy); return policy.result() && ! geometry::detail::touches::rings_containing(geometry1, geometry2, strategy) && ! geometry::detail::touches::rings_containing(geometry2, geometry1, strategy); } }; // P/* struct use_point_in_geometry { template <typename Point, typename Geometry, typename Strategy> static inline bool apply(Point const& point, Geometry const& geometry, Strategy const& strategy) { return detail::within::point_in_geometry(point, geometry, strategy) == 0; } }; }} #endif // DOXYGEN_NO_DETAIL #ifndef DOXYGEN_NO_DISPATCH namespace dispatch { // P/P template <typename Geometry1, typename Geometry2> struct touches<Geometry1, Geometry2, point_tag, point_tag, pointlike_tag, pointlike_tag, false> { template <typename Strategy> static inline bool apply(Geometry1 const& , Geometry2 const& , Strategy const&) { return false; } }; template <typename Geometry1, typename Geometry2> struct touches<Geometry1, Geometry2, point_tag, multi_point_tag, pointlike_tag, pointlike_tag, false> { template <typename Strategy> static inline bool apply(Geometry1 const& , Geometry2 const& , Strategy const&) { return false; } }; template <typename Geometry1, typename Geometry2> struct touches<Geometry1, Geometry2, multi_point_tag, multi_point_tag, pointlike_tag, pointlike_tag, false> { template <typename Strategy> static inline bool apply(Geometry1 const&, Geometry2 const&, Strategy const&) { return false; } }; // P/L P/A template <typename Point, typename Geometry, typename Tag2, typename CastedTag2> struct touches<Point, Geometry, point_tag, Tag2, pointlike_tag, CastedTag2, false> : detail::touches::use_point_in_geometry {}; template <typename MultiPoint, typename MultiGeometry, typename Tag2, typename CastedTag2> struct touches<MultiPoint, MultiGeometry, multi_point_tag, Tag2, pointlike_tag, CastedTag2, false> : detail::relate::relate_impl < detail::de9im::static_mask_touches_type, MultiPoint, MultiGeometry > {}; // L/P A/P template <typename Geometry, typename MultiPoint, typename Tag1, typename CastedTag1> struct touches<Geometry, MultiPoint, Tag1, multi_point_tag, CastedTag1, pointlike_tag, false> : detail::relate::relate_impl < detail::de9im::static_mask_touches_type, Geometry, MultiPoint > {}; // Box/Box template <typename Box1, typename Box2, typename CastedTag1, typename CastedTag2> struct touches<Box1, Box2, box_tag, box_tag, CastedTag1, CastedTag2, false> : detail::touches::box_box {}; template <typename Box1, typename Box2> struct touches<Box1, Box2, box_tag, box_tag, areal_tag, areal_tag, false> : detail::touches::box_box {}; // L/L template <typename Linear1, typename Linear2, typename Tag1, typename Tag2> struct touches<Linear1, Linear2, Tag1, Tag2, linear_tag, linear_tag, false> : detail::relate::relate_impl < detail::de9im::static_mask_touches_type, Linear1, Linear2 > {}; // L/A template <typename Linear, typename Areal, typename Tag1, typename Tag2> struct touches<Linear, Areal, Tag1, Tag2, linear_tag, areal_tag, false> : detail::relate::relate_impl < detail::de9im::static_mask_touches_type, Linear, Areal > {}; // A/L template <typename Linear, typename Areal, typename Tag1, typename Tag2> struct touches<Areal, Linear, Tag1, Tag2, areal_tag, linear_tag, false> : detail::relate::relate_impl < detail::de9im::static_mask_touches_type, Areal, Linear > {}; // A/A template <typename Areal1, typename Areal2, typename Tag1, typename Tag2> struct touches<Areal1, Areal2, Tag1, Tag2, areal_tag, areal_tag, false> : detail::relate::relate_impl < detail::de9im::static_mask_touches_type, Areal1, Areal2 > {}; template <typename Areal1, typename Areal2> struct touches<Areal1, Areal2, ring_tag, ring_tag, areal_tag, areal_tag, false> : detail::touches::areal_areal<Areal1, Areal2> {}; } // namespace dispatch #endif // DOXYGEN_NO_DISPATCH namespace resolve_variant { template <typename Geometry> struct self_touches { static bool apply(Geometry const& geometry) { concepts::check<Geometry const>(); typedef typename strategy::relate::services::default_strategy < Geometry, Geometry >::type strategy_type; typedef typename geometry::point_type<Geometry>::type point_type; typedef detail::overlay::turn_info<point_type> turn_info; typedef detail::overlay::get_turn_info < detail::overlay::assign_null_policy > policy_type; std::deque<turn_info> turns; detail::touches::areal_interrupt_policy policy; strategy_type strategy; // TODO: skip_adjacent should be set to false detail::self_get_turn_points::get_turns < false, policy_type >::apply(geometry, strategy, detail::no_rescale_policy(), turns, policy, 0, true); return policy.result(); } }; } }} // namespace boost::geometry #endif // BOOST_GEOMETRY_ALGORITHMS_DETAIL_TOUCHES_IMPLEMENTATION_HPP