// Boost.Geometry (aka GGL, Generic Geometry Library) // Copyright (c) 2007-2012 Barend Gehrels, Amsterdam, the Netherlands. // Copyright (c) 2017 Adam Wulkiewicz, Lodz, Poland. // This file was modified by Oracle on 2015, 2017, 2018, 2019. // Modifications copyright (c) 2015-2019 Oracle and/or its affiliates. // Contributed and/or modified by Adam Wulkiewicz, 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_GET_TURN_INFO_HPP #define BOOST_GEOMETRY_ALGORITHMS_DETAIL_OVERLAY_GET_TURN_INFO_HPP #include #include #include #include #include #include #include #include #include #include #include #include // Silence warning C4127: conditional expression is constant #if defined(_MSC_VER) #pragma warning(push) #pragma warning(disable : 4127) #endif namespace boost { namespace geometry { #if ! defined(BOOST_GEOMETRY_OVERLAY_NO_THROW) class turn_info_exception : public geometry::exception { std::string message; public: // NOTE: "char" will be replaced by enum in future version inline turn_info_exception(char const method) { message = "Boost.Geometry Turn exception: "; message += method; } virtual ~turn_info_exception() throw() {} virtual char const* what() const throw() { return message.c_str(); } }; #endif #ifndef DOXYGEN_NO_DETAIL namespace detail { namespace overlay { struct base_turn_handler { // Returns true if both sides are opposite static inline bool opposite(int side1, int side2) { // We cannot state side1 == -side2, because 0 == -0 // So either side1*side2==-1 or side1==-side2 && side1 != 0 return side1 * side2 == -1; } // Same side of a segment (not being 0) static inline bool same(int side1, int side2) { return side1 * side2 == 1; } // Both get the same operation template static inline void both(TurnInfo& ti, operation_type const op) { ti.operations[0].operation = op; ti.operations[1].operation = op; } // If condition, first union/second intersection, else vice versa template static inline void ui_else_iu(bool condition, TurnInfo& ti) { ti.operations[0].operation = condition ? operation_union : operation_intersection; ti.operations[1].operation = condition ? operation_intersection : operation_union; } // If condition, both union, else both intersection template static inline void uu_else_ii(bool condition, TurnInfo& ti) { both(ti, condition ? operation_union : operation_intersection); } template static inline void assign_point(TurnInfo& ti, method_type method, IntersectionInfo const& info, unsigned int index) { ti.method = method; BOOST_GEOMETRY_ASSERT(index < info.count); geometry::convert(info.intersections[index], ti.point); ti.operations[0].fraction = info.fractions[index].robust_ra; ti.operations[1].fraction = info.fractions[index].robust_rb; } template static inline unsigned int non_opposite_to_index(IntersectionInfo const& info) { return info.fractions[0].robust_rb < info.fractions[1].robust_rb ? 1 : 0; } template static inline typename geometry::coordinate_type::type distance_measure(Point1 const& a, Point2 const& b) { // TODO: use comparable distance for point-point instead - but that // causes currently cycling include problems typedef typename geometry::coordinate_type::type ctype; ctype const dx = get<0>(a) - get<0>(b); ctype const dy = get<1>(a) - get<1>(b); return dx * dx + dy * dy; } template < std::size_t IndexP, std::size_t IndexQ, typename UniqueSubRange1, typename UniqueSubRange2, typename UmbrellaStrategy, typename TurnInfo > static inline void both_collinear( UniqueSubRange1 const& range_p, UniqueSubRange2 const& range_q, UmbrellaStrategy const&, std::size_t index_p, std::size_t index_q, TurnInfo& ti) { boost::ignore_unused(range_p, range_q); BOOST_GEOMETRY_ASSERT(IndexP + IndexQ == 1); BOOST_GEOMETRY_ASSERT(index_p > 0 && index_p <= 2); BOOST_GEOMETRY_ASSERT(index_q > 0 && index_q <= 2); #if ! defined(BOOST_GEOMETRY_USE_RESCALING) ti.operations[IndexP].remaining_distance = distance_measure(ti.point, range_p.at(index_p)); ti.operations[IndexQ].remaining_distance = distance_measure(ti.point, range_q.at(index_q)); // pk/q2 is considered as collinear, but there might be // a tiny measurable difference. If so, use that. // Calculate pk // qj-qk typedef detail::distance_measure < typename select_coordinate_type < typename UniqueSubRange1::point_type, typename UniqueSubRange2::point_type >::type > dm_type; const bool p_closer = ti.operations[IndexP].remaining_distance < ti.operations[IndexQ].remaining_distance; dm_type const dm = p_closer ? get_distance_measure(range_q.at(index_q - 1), range_q.at(index_q), range_p.at(index_p)) : get_distance_measure(range_p.at(index_p - 1), range_p.at(index_p), range_q.at(index_q)); if (! dm.is_zero()) { // Not truely collinear, distinguish for union/intersection // If p goes left (positive), take that for a union bool p_left = p_closer ? dm.is_positive() : dm.is_negative(); ti.operations[IndexP].operation = p_left ? operation_union : operation_intersection; ti.operations[IndexQ].operation = p_left ? operation_intersection : operation_union; return; } #endif both(ti, operation_continue); } }; template < typename TurnInfo > struct touch_interior : public base_turn_handler { // Index: 0, P is the interior, Q is touching and vice versa template < unsigned int Index, typename UniqueSubRange1, typename UniqueSubRange2, typename IntersectionInfo, typename DirInfo, typename SidePolicy, typename UmbrellaStrategy > static inline void apply(UniqueSubRange1 const& range_p, UniqueSubRange2 const& range_q, TurnInfo& ti, IntersectionInfo const& intersection_info, DirInfo const& dir_info, SidePolicy const& side, UmbrellaStrategy const& umbrella_strategy) { assign_point(ti, method_touch_interior, intersection_info, 0); // Both segments of q touch segment p somewhere in its interior // 1) We know: if q comes from LEFT or RIGHT // (i.e. dir_info.sides.get() == 1 or -1) // 2) Important is: if q_k goes to LEFT, RIGHT, COLLINEAR // and, if LEFT/COLL, if it is lying LEFT or RIGHT w.r.t. q_i BOOST_STATIC_ASSERT(Index <= 1); static unsigned int const index_p = Index; static unsigned int const index_q = 1 - Index; bool const has_pk = ! range_p.is_last_segment(); bool const has_qk = ! range_q.is_last_segment(); int const side_qi_p = dir_info.sides.template get(); int const side_qk_p = has_qk ? side.qk_wrt_p1() : 0; if (side_qi_p == -side_qk_p) { // Q crosses P from left->right or from right->left (test "ML1") // Union: folow P (left->right) or Q (right->left) // Intersection: other turn unsigned int index = side_qk_p == -1 ? index_p : index_q; ti.operations[index].operation = operation_union; ti.operations[1 - index].operation = operation_intersection; return; } int const side_qk_q = has_qk ? side.qk_wrt_q1() : 0; // Only necessary if rescaling is turned off: int const side_pj_q2 = has_qk ? side.pj_wrt_q2() : 0; if (side_qi_p == -1 && side_qk_p == -1 && side_qk_q == 1) { // Q turns left on the right side of P (test "MR3") // Both directions for "intersection" both(ti, operation_intersection); ti.touch_only = true; } else if (side_qi_p == 1 && side_qk_p == 1 && side_qk_q == -1) { if (has_qk && side_pj_q2 == -1) { // Q turns right on the left side of P (test "ML3") // Union: take both operations // Intersection: skip both(ti, operation_union); } else { // q2 is collinear with p1, so it does not turn back. This // can happen in floating point precision. In this case, // block one of the operations to avoid taking that path. ti.operations[index_p].operation = operation_union; ti.operations[index_q].operation = operation_blocked; } ti.touch_only = true; } else if (side_qi_p == side_qk_p && side_qi_p == side_qk_q) { // Q turns left on the left side of P (test "ML2") // or Q turns right on the right side of P (test "MR2") // Union: take left turn (Q if Q turns left, P if Q turns right) // Intersection: other turn unsigned int index = side_qk_q == 1 ? index_q : index_p; if (has_qk && side_pj_q2 == 0) { // Even though sides xk w.r.t. 1 are distinct, pj is collinear // with q. Therefore swap the path index = 1 - index; } if (has_pk && has_qk && opposite(side_pj_q2, side_qi_p)) { // Without rescaling, floating point requires extra measures int const side_qj_p1 = side.qj_wrt_p1(); int const side_qj_p2 = side.qj_wrt_p2(); if (same(side_qj_p1, side_qj_p2)) { int const side_pj_q1 = side.pj_wrt_q1(); if (opposite(side_pj_q1, side_pj_q2)) { index = 1 - index; } } } ti.operations[index].operation = operation_union; ti.operations[1 - index].operation = operation_intersection; ti.touch_only = true; } else if (side_qk_p == 0) { // Q intersects on interior of P and continues collinearly if (side_qk_q == side_qi_p) { both_collinear(range_p, range_q, umbrella_strategy, 1, 2, ti); return; } else { // Opposite direction, which is never travelled. // If Q turns left, P continues for intersection // If Q turns right, P continues for union ti.operations[index_p].operation = side_qk_q == 1 ? operation_intersection : operation_union; ti.operations[index_q].operation = operation_blocked; } } else { // Should not occur! ti.method = method_error; } } }; template < typename TurnInfo > struct touch : public base_turn_handler { static inline bool between(int side1, int side2, int turn) { return side1 == side2 && ! opposite(side1, turn); } /*static inline void block_second(bool block, TurnInfo& ti) { if (block) { ti.operations[1].operation = operation_blocked; } }*/ template < typename UniqueSubRange1, typename UniqueSubRange2, typename IntersectionInfo, typename DirInfo, typename SideCalculator, typename UmbrellaStrategy > static inline void apply(UniqueSubRange1 const& range_p, UniqueSubRange2 const& range_q, TurnInfo& ti, IntersectionInfo const& intersection_info, DirInfo const& dir_info, SideCalculator const& side, UmbrellaStrategy const& umbrella_strategy) { assign_point(ti, method_touch, intersection_info, 0); bool const has_pk = ! range_p.is_last_segment(); bool const has_qk = ! range_q.is_last_segment(); int const side_qi_p1 = dir_info.sides.template get<1, 0>(); int const side_qk_p1 = has_qk ? side.qk_wrt_p1() : 0; // If Qi and Qk are both at same side of Pi-Pj, // or collinear (so: not opposite sides) if (! opposite(side_qi_p1, side_qk_p1)) { int const side_pk_q2 = has_pk && has_qk ? side.pk_wrt_q2() : 0; int const side_pk_p = has_pk ? side.pk_wrt_p1() : 0; int const side_qk_q = has_qk ? side.qk_wrt_q1() : 0; bool const q_turns_left = side_qk_q == 1; bool const block_q = side_qk_p1 == 0 && ! same(side_qi_p1, side_qk_q) ; // If Pk at same side as Qi/Qk // (the "or" is for collinear case) // or Q is fully collinear && P turns not to left if (side_pk_p == side_qi_p1 || side_pk_p == side_qk_p1 || (side_qi_p1 == 0 && side_qk_p1 == 0 && side_pk_p != -1) ) { // Collinear -> lines join, continue // (#BRL2) if (side_pk_q2 == 0 && ! block_q) { both_collinear<0, 1>(range_p, range_q, umbrella_strategy, 2, 2, ti); return; } int const side_pk_q1 = has_pk && has_qk ? side.pk_wrt_q1() : 0; // Collinear opposite case -> block P // (#BRL4, #BLR8) if (side_pk_q1 == 0) { ti.operations[0].operation = operation_blocked; // Q turns right -> union (both independent), // Q turns left -> intersection ti.operations[1].operation = block_q ? operation_blocked : q_turns_left ? operation_intersection : operation_union; return; } // Pk between Qi and Qk // (#BRL3, #BRL7) if (between(side_pk_q1, side_pk_q2, side_qk_q)) { ui_else_iu(q_turns_left, ti); if (block_q) { ti.operations[1].operation = operation_blocked; } //block_second(block_q, ti); return; } // Pk between Qk and P, so left of Qk (if Q turns right) and vv // (#BRL1) if (side_pk_q2 == -side_qk_q) { ui_else_iu(! q_turns_left, ti); ti.touch_only = true; return; } // // (#BRL5, #BRL9) if (side_pk_q1 == -side_qk_q) { uu_else_ii(! q_turns_left, ti); if (block_q) { ti.operations[1].operation = operation_blocked; } else { ti.touch_only = true; } //block_second(block_q, ti); return; } } else { // Pk at other side than Qi/Pk ti.operations[0].operation = q_turns_left ? operation_intersection : operation_union; ti.operations[1].operation = block_q ? operation_blocked : side_qi_p1 == 1 || side_qk_p1 == 1 ? operation_union : operation_intersection; if (! block_q) { ti.touch_only = true; } return; } } else { // From left to right or from right to left int const side_pk_p = has_pk ? side.pk_wrt_p1() : 0; bool const right_to_left = side_qk_p1 == 1; // If p turns into direction of qi (1,2) if (side_pk_p == side_qi_p1) { int const side_pk_q1 = has_pk ? side.pk_wrt_q1() : 0; // Collinear opposite case -> block P if (side_pk_q1 == 0) { ti.operations[0].operation = operation_blocked; ti.operations[1].operation = right_to_left ? operation_union : operation_intersection; return; } if (side_pk_q1 == side_qk_p1) { uu_else_ii(right_to_left, ti); ti.touch_only = true; return; } } // If p turns into direction of qk (4,5) if (side_pk_p == side_qk_p1) { int const side_pk_q2 = has_pk ? side.pk_wrt_q2() : 0; // Collinear case -> lines join, continue if (side_pk_q2 == 0) { both(ti, operation_continue); return; } if (side_pk_q2 == side_qk_p1) { ui_else_iu(right_to_left, ti); ti.touch_only = true; return; } } // otherwise (3) ui_else_iu(! right_to_left, ti); return; } } }; template < typename TurnInfo > struct equal : public base_turn_handler { template < typename UniqueSubRange1, typename UniqueSubRange2, typename IntersectionInfo, typename DirInfo, typename SideCalculator, typename UmbrellaStrategy > static inline void apply(UniqueSubRange1 const& range_p, UniqueSubRange2 const& range_q, TurnInfo& ti, IntersectionInfo const& info, DirInfo const& , SideCalculator const& side, UmbrellaStrategy const& umbrella_strategy) { // Copy the intersection point in TO direction assign_point(ti, method_equal, info, non_opposite_to_index(info)); bool const has_pk = ! range_p.is_last_segment(); bool const has_qk = ! range_q.is_last_segment(); int const side_pk_q2 = has_pk && has_qk ? side.pk_wrt_q2() : 0; int const side_pk_p = has_pk ? side.pk_wrt_p1() : 0; int const side_qk_p = has_qk ? side.qk_wrt_p1() : 0; #if ! defined(BOOST_GEOMETRY_USE_RESCALING) if (has_pk && has_qk && side_pk_p == side_qk_p) { // They turn to the same side, or continue both collinearly // Without rescaling, to check for union/intersection, // try to check side values (without any thresholds) typedef typename select_coordinate_type < typename UniqueSubRange1::point_type, typename UniqueSubRange2::point_type >::type coordinate_type; typedef detail::distance_measure dm_type; dm_type const dm_qk_p = get_distance_measure(range_q.at(1), range_q.at(2), range_p.at(2)); dm_type const dm_pk_q = get_distance_measure(range_p.at(1), range_p.at(2), range_q.at(2)); if (dm_pk_q.measure != dm_qk_p.measure) { // A (possibly very small) difference is detected, which // can be used to distinguish between union/intersection ui_else_iu(dm_pk_q.measure < dm_qk_p.measure, ti); return; } } #endif // If pk is collinear with qj-qk, they continue collinearly. // This can be on either side of p1 (== q1), or collinear // The second condition checks if they do not continue // oppositely if (side_pk_q2 == 0 && side_pk_p == side_qk_p) { both_collinear<0, 1>(range_p, range_q, umbrella_strategy, 2, 2, ti); return; } // If they turn to same side (not opposite sides) if (! opposite(side_pk_p, side_qk_p)) { // If pk is left of q2 or collinear: p: union, q: intersection ui_else_iu(side_pk_q2 != -1, ti); } else { // They turn opposite sides. If p turns left (or collinear), // p: union, q: intersection ui_else_iu(side_pk_p != -1, ti); } } }; template < typename TurnInfo, typename AssignPolicy > struct equal_opposite : public base_turn_handler { template < typename UniqueSubRange1, typename UniqueSubRange2, typename OutputIterator, typename IntersectionInfo > static inline void apply( UniqueSubRange1 const& /*range_p*/, UniqueSubRange2 const& /*range_q*/, /* by value: */ TurnInfo tp, OutputIterator& out, IntersectionInfo const& intersection_info) { // For equal-opposite segments, normally don't do anything. if (AssignPolicy::include_opposite) { tp.method = method_equal; for (unsigned int i = 0; i < 2; i++) { tp.operations[i].operation = operation_opposite; } for (unsigned int i = 0; i < intersection_info.i_info().count; i++) { assign_point(tp, method_none, intersection_info.i_info(), i); *out++ = tp; } } } }; template < typename TurnInfo > struct collinear : public base_turn_handler { /* arrival P pk//p1 qk//q1 product* case result 1 1 1 CLL1 ui -1 1 -1 CLL2 iu 1 1 1 CLR1 ui -1 -1 1 CLR2 ui 1 -1 -1 CRL1 iu -1 1 -1 CRL2 iu 1 -1 -1 CRR1 iu -1 -1 1 CRR2 ui 1 0 0 CC1 cc -1 0 0 CC2 cc *product = arrival * (pk//p1 or qk//q1) Stated otherwise: - if P arrives: look at turn P - if Q arrives: look at turn Q - if P arrives and P turns left: union for P - if P arrives and P turns right: intersection for P - if Q arrives and Q turns left: union for Q (=intersection for P) - if Q arrives and Q turns right: intersection for Q (=union for P) ROBUSTNESS: p and q are collinear, so you would expect that side qk//p1 == pk//q1. But that is not always the case in near-epsilon ranges. Then decision logic is different. If p arrives, q is further, so the angle qk//p1 is (normally) more precise than pk//p1 */ template < typename UniqueSubRange1, typename UniqueSubRange2, typename IntersectionInfo, typename DirInfo, typename SidePolicy > static inline void apply( UniqueSubRange1 const& range_p, UniqueSubRange2 const& range_q, TurnInfo& ti, IntersectionInfo const& info, DirInfo const& dir_info, SidePolicy const& side) { // Copy the intersection point in TO direction assign_point(ti, method_collinear, info, non_opposite_to_index(info)); int const arrival = dir_info.arrival[0]; // Should not be 0, this is checked before BOOST_GEOMETRY_ASSERT(arrival != 0); bool const has_pk = ! range_p.is_last_segment(); bool const has_qk = ! range_q.is_last_segment(); int const side_p = has_pk ? side.pk_wrt_p1() : 0; int const side_q = has_qk ? side.qk_wrt_q1() : 0; // If p arrives, use p, else use q int const side_p_or_q = arrival == 1 ? side_p : side_q ; // See comments above, // resulting in a strange sort of mathematic rule here: // The arrival-info multiplied by the relevant side // delivers a consistent result. int const product = arrival * side_p_or_q; if(product == 0) { both(ti, operation_continue); } else { ui_else_iu(product == 1, ti); } // Calculate remaining distance. If it continues collinearly it is // measured until the end of the next segment ti.operations[0].remaining_distance = side_p == 0 && has_pk ? distance_measure(ti.point, range_p.at(2)) : distance_measure(ti.point, range_p.at(1)); ti.operations[1].remaining_distance = side_q == 0 && has_qk ? distance_measure(ti.point, range_q.at(2)) : distance_measure(ti.point, range_q.at(1)); } }; template < typename TurnInfo, typename AssignPolicy > struct collinear_opposite : public base_turn_handler { private : /* arrival P arrival Q pk//p1 qk//q1 case result2 result -------------------------------------------------------------- 1 1 1 -1 CLO1 ix xu 1 1 1 0 CLO2 ix (xx) 1 1 1 1 CLO3 ix xi 1 1 0 -1 CCO1 (xx) xu 1 1 0 0 CCO2 (xx) (xx) 1 1 0 1 CCO3 (xx) xi 1 1 -1 -1 CRO1 ux xu 1 1 -1 0 CRO2 ux (xx) 1 1 -1 1 CRO3 ux xi -1 1 -1 CXO1 xu -1 1 0 CXO2 (xx) -1 1 1 CXO3 xi 1 -1 1 CXO1 ix 1 -1 0 CXO2 (xx) 1 -1 -1 CXO3 ux */ template < unsigned int Index, typename IntersectionInfo > static inline bool set_tp(int side_rk_r, bool handle_robustness, int side_rk_s, TurnInfo& tp, IntersectionInfo const& intersection_info) { BOOST_STATIC_ASSERT(Index <= 1); boost::ignore_unused(handle_robustness, side_rk_s); operation_type blocked = operation_blocked; switch(side_rk_r) { case 1 : // Turning left on opposite collinear: intersection tp.operations[Index].operation = operation_intersection; break; case -1 : // Turning right on opposite collinear: union tp.operations[Index].operation = operation_union; break; case 0 : // No turn on opposite collinear: block, do not traverse // But this "xx" is usually ignored, it is useless to include // two operations blocked, so the whole point does not need // to be generated. // So return false to indicate nothing is to be done. if (AssignPolicy::include_opposite) { tp.operations[Index].operation = operation_opposite; blocked = operation_opposite; } else { return false; } break; } // The other direction is always blocked when collinear opposite tp.operations[1 - Index].operation = blocked; // If P arrives within Q, set info on P (which is done above, index=0), // this turn-info belongs to the second intersection point, index=1 // (see e.g. figure CLO1) assign_point(tp, method_collinear, intersection_info, 1 - Index); return true; } public: static inline void empty_transformer(TurnInfo &) {} template < typename UniqueSubRange1, typename UniqueSubRange2, typename OutputIterator, typename IntersectionInfo, typename SidePolicy > static inline void apply( UniqueSubRange1 const& range_p, UniqueSubRange2 const& range_q, // Opposite collinear can deliver 2 intersection points, TurnInfo const& tp_model, OutputIterator& out, IntersectionInfo const& intersection_info, SidePolicy const& side) { apply(range_p, range_q, tp_model, out, intersection_info, side, empty_transformer); } public: template < typename UniqueSubRange1, typename UniqueSubRange2, typename OutputIterator, typename IntersectionInfo, typename SidePolicy, typename TurnTransformer > static inline void apply( UniqueSubRange1 const& range_p, UniqueSubRange2 const& range_q, // Opposite collinear can deliver 2 intersection points, TurnInfo const& tp_model, OutputIterator& out, IntersectionInfo const& info, SidePolicy const& side, TurnTransformer turn_transformer) { TurnInfo tp = tp_model; int const p_arrival = info.d_info().arrival[0]; int const q_arrival = info.d_info().arrival[1]; // If P arrives within Q, there is a turn dependent on P if ( p_arrival == 1 && ! range_p.is_last_segment() && set_tp<0>(side.pk_wrt_p1(), true, side.pk_wrt_q1(), tp, info.i_info()) ) { turn_transformer(tp); *out++ = tp; } // If Q arrives within P, there is a turn dependent on Q if ( q_arrival == 1 && ! range_q.is_last_segment() && set_tp<1>(side.qk_wrt_q1(), false, side.qk_wrt_p1(), tp, info.i_info()) ) { turn_transformer(tp); *out++ = tp; } if (AssignPolicy::include_opposite) { // Handle cases not yet handled above if ((q_arrival == -1 && p_arrival == 0) || (p_arrival == -1 && q_arrival == 0)) { for (unsigned int i = 0; i < 2; i++) { tp.operations[i].operation = operation_opposite; } for (unsigned int i = 0; i < info.i_info().count; i++) { assign_point(tp, method_collinear, info.i_info(), i); *out++ = tp; } } } } }; template < typename TurnInfo > struct crosses : public base_turn_handler { template static inline void apply(TurnInfo& ti, IntersectionInfo const& intersection_info, DirInfo const& dir_info) { assign_point(ti, method_crosses, intersection_info, 0); // In all cases: // If Q crosses P from left to right // Union: take P // Intersection: take Q // Otherwise: vice versa int const side_qi_p1 = dir_info.sides.template get<1, 0>(); unsigned int const index = side_qi_p1 == 1 ? 0 : 1; ti.operations[index].operation = operation_union; ti.operations[1 - index].operation = operation_intersection; } }; struct only_convert : public base_turn_handler { template static inline void apply(TurnInfo& ti, IntersectionInfo const& intersection_info) { assign_point(ti, method_none, intersection_info, 0); // was collinear ti.operations[0].operation = operation_continue; ti.operations[1].operation = operation_continue; } }; /*! \brief Policy doing nothing \details get_turn_info can have an optional policy include extra truns. By default it does not, and this class is that default. */ struct assign_null_policy { static bool const include_no_turn = false; static bool const include_degenerate = false; static bool const include_opposite = false; }; /*! \brief Turn information: intersection point, method, and turn information \details Information necessary for traversal phase (a phase of the overlay process). The information is gathered during the get_turns (segment intersection) phase. \tparam AssignPolicy policy to assign extra info, e.g. to calculate distance from segment's first points to intersection points. It also defines if a certain class of points (degenerate, non-turns) should be included. */ template struct get_turn_info { // Intersect a segment p with a segment q // Both p and q are modelled as sub_ranges to provide more points // to be able to give more information about the turn (left/right) template < typename UniqueSubRange1, typename UniqueSubRange2, typename TurnInfo, typename UmbrellaStrategy, typename RobustPolicy, typename OutputIterator > static inline OutputIterator apply( UniqueSubRange1 const& range_p, UniqueSubRange2 const& range_q, TurnInfo const& tp_model, UmbrellaStrategy const& umbrella_strategy, RobustPolicy const& robust_policy, OutputIterator out) { typedef intersection_info < UniqueSubRange1, UniqueSubRange2, typename TurnInfo::point_type, UmbrellaStrategy, RobustPolicy > inters_info; inters_info inters(range_p, range_q, umbrella_strategy, robust_policy); char const method = inters.d_info().how; // Copy, to copy possibly extended fields TurnInfo tp = tp_model; bool do_only_convert = false; // Select method and apply switch(method) { case 'a' : // "angle" case 'f' : // "from" case 's' : // "start" do_only_convert = true; break; case 'd' : // disjoint: never do anything break; case 'm' : { typedef touch_interior < TurnInfo > handler; // If Q (1) arrives (1) if ( inters.d_info().arrival[1] == 1 ) { handler::template apply<0>(range_p, range_q, tp, inters.i_info(), inters.d_info(), inters.sides(), umbrella_strategy); } else { // Swap p/q handler::template apply<1>(range_q, range_p, tp, inters.i_info(), inters.d_info(), inters.get_swapped_sides(), umbrella_strategy); } *out++ = tp; } break; case 'i' : { crosses::apply(tp, inters.i_info(), inters.d_info()); *out++ = tp; } break; case 't' : { // Both touch (both arrive there) touch::apply(range_p, range_q, tp, inters.i_info(), inters.d_info(), inters.sides(), umbrella_strategy); *out++ = tp; } break; case 'e': { if ( ! inters.d_info().opposite ) { // Both equal // or collinear-and-ending at intersection point equal::apply(range_p, range_q, tp, inters.i_info(), inters.d_info(), inters.sides(), umbrella_strategy); *out++ = tp; } else { equal_opposite < TurnInfo, AssignPolicy >::apply(range_p, range_q, tp, out, inters); } } break; case 'c' : { // Collinear if ( ! inters.d_info().opposite ) { if ( inters.d_info().arrival[0] == 0 ) { // Collinear, but similar thus handled as equal equal::apply(range_p, range_q, tp, inters.i_info(), inters.d_info(), inters.sides(), umbrella_strategy); // override assigned method tp.method = method_collinear; } else { collinear::apply(range_p, range_q, tp, inters.i_info(), inters.d_info(), inters.sides()); } *out++ = tp; } else { collinear_opposite < TurnInfo, AssignPolicy >::apply(range_p, range_q, tp, out, inters, inters.sides()); } } break; case '0' : { // degenerate points if (AssignPolicy::include_degenerate) { only_convert::apply(tp, inters.i_info()); *out++ = tp; } } break; default : { #if defined(BOOST_GEOMETRY_DEBUG_ROBUSTNESS) std::cout << "TURN: Unknown method: " << method << std::endl; #endif #if ! defined(BOOST_GEOMETRY_OVERLAY_NO_THROW) BOOST_THROW_EXCEPTION(turn_info_exception(method)); #endif } break; } if (do_only_convert && AssignPolicy::include_no_turn && inters.i_info().count > 0) { only_convert::apply(tp, inters.i_info()); *out++ = tp; } return out; } }; }} // namespace detail::overlay #endif //DOXYGEN_NO_DETAIL }} // namespace boost::geometry #if defined(_MSC_VER) #pragma warning(pop) #endif #endif // BOOST_GEOMETRY_ALGORITHMS_DETAIL_OVERLAY_GET_TURN_INFO_HPP