// Copyright (c) 2006,2007,2008,2009,2010,2011 Tel-Aviv University(Israel). // All rights reserved. // // This file is part of CGAL (www.cgal.org). // You can redistribute it and/or modify it under the terms of the GNU // General Public License as published by the Free Software Foundation, // either version 3 of the License, or (at your option) any later version. // // Licensees holding a valid commercial license may use this file in // accordance with the commercial license agreement provided with the software. // // This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE // WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. // // $URL$ // $Id$ // SPDX-License-Identifier: GPL-3.0+ // // Author(s) : Efi Fogel // Ron Wein // Dror Atariah // Waqar Khan #ifndef CGAL_ARR_POLYCURVE_TRAITS_2_H #define CGAL_ARR_POLYCURVE_TRAITS_2_H #include #include /*! \file * The traits-class for the general piece-wise (polycurve) type of curves of the * arrangement package. */ #include #include #include #include #include #include #include #include #include #include namespace CGAL { template > class Arr_polycurve_traits_2 : public Arr_polycurve_basic_traits_2 { public: typedef SubcurveTraits_2 Subcurve_traits_2; private: typedef Arr_polycurve_basic_traits_2 Base; public: /// \name Types inherited from the polycurve basic traits class. //@{ typedef typename Base::Has_left_category Has_left_category; typedef typename Base::Has_do_intersect_category Has_do_intersect_category; typedef typename Base::Left_side_category Left_side_category; typedef typename Base::Bottom_side_category Bottom_side_category; typedef typename Base::Top_side_category Top_side_category; typedef typename Base::Right_side_category Right_side_category; typedef typename Base::Are_all_sides_oblivious_tag Are_all_sides_oblivious_tag; typedef typename Base::X_monotone_subcurve_2 X_monotone_subcurve_2; typedef typename Base::Size Size; typedef typename Base::size_type size_type; typedef typename Base::Point_2 Point_2; typedef typename Base::X_monotone_curve_2 X_monotone_curve_2; typedef typename Base::Compare_x_2 Compare_x_2; typedef typename Base::Compare_xy_2 Compare_xy_2; typedef typename Base::Construct_min_vertex_2 Construct_min_vertex_2; typedef typename Base::Construct_max_vertex_2 Construct_max_vertex_2; typedef typename Base::Is_vertical_2 Is_vertical_2; typedef typename Base::Compare_y_at_x_2 Compare_y_at_x_2; typedef typename Base::Compare_y_at_x_left_2 Compare_y_at_x_left_2; typedef typename Base::Compare_y_at_x_right_2 Compare_y_at_x_right_2; typedef typename Base::Equal_2 Equal_2; typedef typename Base::Compare_endpoints_xy_2 Compare_endpoints_xy_2; typedef typename Base::Construct_opposite_2 Construct_opposite_2; typedef typename Base::Approximate_2 Approximate_2; typedef typename Base::Construct_x_monotone_curve_2 Construct_x_monotone_curve_2; typedef typename Base::Parameter_space_in_x_2 Parameter_space_in_x_2; typedef typename Base::Parameter_space_in_y_2 Parameter_space_in_y_2; typedef typename Base::Compare_x_on_boundary_2 Compare_x_on_boundary_2; typedef typename Base::Compare_x_at_limit_2 Compare_x_at_limit_2; typedef typename Base::Compare_x_near_limit_2 Compare_x_near_limit_2; typedef typename Base::Compare_y_on_boundary_2 Compare_y_on_boundary_2; typedef typename Base::Compare_y_near_boundary_2 Compare_y_near_boundary_2; typedef typename Base::Is_on_y_identification_2 Is_on_y_identification_2; typedef typename Base::Is_on_x_identification_2 Is_on_x_identification_2; typedef typename Base::Trim_2 Trim_2; //@} /// \name Types and functors inherited from the subcurve geometry traits. //@{ typedef typename Subcurve_traits_2::Has_merge_category Has_merge_category; typedef typename Subcurve_traits_2::Multiplicity Multiplicity; typedef typename Subcurve_traits_2::Curve_2 Subcurve_2; //@} // Backward compatibility: typedef Subcurve_2 Segment_2; private: typedef Arr_polycurve_traits_2 Self; public: /*! Default constructor */ Arr_polycurve_traits_2() : Base() {} /*! Constructor with given subcurve traits * \param seg_traits an already existing subcurve tarits which is passed will * be used by the class. */ Arr_polycurve_traits_2(const Subcurve_traits_2* geom_traits) : Base(geom_traits) {} /*! A polycurve represents a general continuous piecewise-linear * curve, without degenerated subcurves. */ typedef internal::Polycurve_2 Curve_2; /// \name Basic predicate functors(based on the subcurve traits). //@{ /*! \class * A functor that obtains the number of points of a polycurve. */ class Number_of_points_2 : public Base::Number_of_points_2 { public: size_type operator()(const Curve_2& cv) const { size_type num_seg = cv.number_of_subcurves(); return (num_seg == 0) ? 0 : num_seg + 1; } }; /*! Obtain a number_of_points_2 functor object. */ Number_of_points_2 number_of_points_2_object() const { return Number_of_points_2(); } ///@} /// \name Construction functors(based on the subcurve traits). //@{ #ifndef DOXYGEN_RUNNING class Push_back_2; #endif /*! \class * A functor that divides an arc into x-monotone arcs. That are, arcs that * do not cross the identification arc. */ class Make_x_monotone_2 { protected: typedef Arr_polycurve_traits_2 Polycurve_traits_2; /*! The traits (in case it has state) */ const Polycurve_traits_2& m_poly_traits; public: /*! Constructor. */ Make_x_monotone_2(const Polycurve_traits_2& traits) : m_poly_traits(traits) {} /*! Cut the given curve into x-monotone sub-curves and insert them into the * given output iterator. * * \pre if `cv` is not empty then it must be continuous and well-oriented. * \param cv The curve. * \param oi The output iterator, whose value-type is Object. The output * object is a wrapper of a X_monotone_curve_2. * \return The past-the-end iterator. */ private: template OutputIterator operator_impl(const Curve_2& cv, OutputIterator oi, Arr_all_sides_oblivious_tag) const { typedef typename Curve_2::Subcurve_const_iterator const_seg_iterator; // If the polycurve is empty, return. if (cv.number_of_subcurves() == 0) return oi; Construct_x_monotone_curve_2 ctr_x_curve = m_poly_traits.construct_x_monotone_curve_2_object(); typename Subcurve_traits_2::Make_x_monotone_2 make_seg_x_monotone = m_poly_traits.subcurve_traits_2()->make_x_monotone_2_object(); typename Subcurve_traits_2::Compare_endpoints_xy_2 cmp_seg_endpts = m_poly_traits.subcurve_traits_2()->compare_endpoints_xy_2_object(); #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT typename Subcurve_traits_2::Construct_opposite_2 ctr_seg_opposite = m_poly_traits.subcurve_traits_2()->construct_opposite_2_object(); #endif // Convert the input polycurve to a sequence of CGAL objects, such // that each Object wraps an x-monotone subcurve. std::vector x_seg_objects; const_seg_iterator it_segs; for (it_segs = cv.subcurves_begin(); it_segs != cv.subcurves_end(); ++it_segs) make_seg_x_monotone(*it_segs, std::back_inserter(x_seg_objects)); typename std::vector::iterator it = x_seg_objects.begin(); X_monotone_subcurve_2 x_seg; #if defined (CGAL_NO_ASSERTIONS) CGAL::assign(x_seg, *it); #else bool assign_res = CGAL::assign(x_seg, *it); CGAL_assertion(assign_res); #endif // If the polycurve consists of a single x-monotone subcurve, return. if (x_seg_objects.size() == 1) { #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT if (cmp_seg_endpts(x_seg) == LARGER) x_seg = ctr_seg_opposite(x_seg); #endif *oi++ = make_object(ctr_x_curve(x_seg)); x_seg_objects.clear(); return oi; } CGAL_precondition_code ( // To be used in order to verify continuity and well-orientedness // of the input curve cv. typename Subcurve_traits_2::Construct_min_vertex_2 min_seg_v = m_poly_traits.subcurve_traits_2()->construct_min_vertex_2_object(); typename Subcurve_traits_2::Construct_max_vertex_2 max_seg_v = m_poly_traits.subcurve_traits_2()->construct_max_vertex_2_object(); typename Subcurve_traits_2::Equal_2 equal = m_poly_traits.subcurve_traits_2()->equal_2_object(); Point_2 last_target = (cmp_seg_endpts(x_seg) == SMALLER) ? max_seg_v(x_seg) : min_seg_v(x_seg); Point_2 next_src; ); // The polycurve consists of at least 2 x-monotone subcurves: Push_back_2 push_back = m_poly_traits.push_back_2_object(); typename Subcurve_traits_2::Is_vertical_2 is_seg_vertical = m_poly_traits.subcurve_traits_2()->is_vertical_2_object(); bool is_start_vertical = is_seg_vertical(x_seg); Comparison_result start_dir = cmp_seg_endpts(x_seg); #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT Push_front_2 push_front = m_poly_traits.push_front_2_object(); if (cmp_seg_endpts(x_seg) == LARGER) x_seg = ctr_seg_opposite(x_seg); #endif X_monotone_curve_2 x_polycurve = ctr_x_curve(x_seg); for (++it; it != x_seg_objects.end(); ++it){ X_monotone_subcurve_2 x_seg; #if defined (CGAL_NO_ASSERTIONS) CGAL::assign(x_seg, *it); #else bool assign_res = CGAL::assign(x_seg, *it); CGAL_assertion(assign_res); #endif // Test that cv is continuous and well-oriented. CGAL_precondition_code ( next_src = (cmp_seg_endpts(x_seg) == SMALLER) ? min_seg_v(x_seg) : max_seg_v(x_seg); ); CGAL_precondition_msg ( equal(last_target, next_src), "cv must form a continuous and well oriented curve." ); CGAL_precondition_code ( last_target = (cmp_seg_endpts(x_seg) == SMALLER) ? max_seg_v(x_seg) : min_seg_v(x_seg); ); if ((cmp_seg_endpts(x_seg) != start_dir) || (is_seg_vertical(x_seg) != is_start_vertical)) { // Construct an x-monotone curve from the sub-range which was found *oi++ = make_object(x_polycurve); is_start_vertical = is_seg_vertical(x_seg); start_dir = cmp_seg_endpts(x_seg); #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT if (cmp_seg_endpts(x_seg) == LARGER) x_seg = ctr_seg_opposite(x_seg); #endif x_polycurve = ctr_x_curve(x_seg); } else { #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT if (cmp_seg_endpts(x_seg) == LARGER) { x_seg = ctr_seg_opposite(x_seg); push_front(x_polycurve, x_seg); } else push_back(x_polycurve, x_seg); #else push_back(x_polycurve, x_seg); #endif } } // for loop if (x_polycurve.number_of_subcurves() != 0) *oi++ = make_object(x_polycurve); x_seg_objects.clear(); return oi; } template OutputIterator operator_impl(const Curve_2& cv, OutputIterator oi, Arr_not_all_sides_oblivious_tag) const { typedef typename Curve_2::Subcurve_const_iterator const_seg_iterator; // If the polycurve is empty, return. if (cv.number_of_subcurves() == 0) return oi; Construct_x_monotone_curve_2 ctr_x_curve = m_poly_traits.construct_x_monotone_curve_2_object(); typename Subcurve_traits_2::Make_x_monotone_2 make_seg_x_monotone = m_poly_traits.subcurve_traits_2()->make_x_monotone_2_object(); typename Subcurve_traits_2::Compare_endpoints_xy_2 cmp_seg_endpts = m_poly_traits.subcurve_traits_2()->compare_endpoints_xy_2_object(); typename Subcurve_traits_2::Parameter_space_in_x_2 ps_x = m_poly_traits.subcurve_traits_2()->parameter_space_in_x_2_object(); typename Subcurve_traits_2::Parameter_space_in_y_2 ps_y = m_poly_traits.subcurve_traits_2()->parameter_space_in_y_2_object(); #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT typename Subcurve_traits_2::Construct_opposite_2 ctr_seg_opposite = m_poly_traits.subcurve_traits_2()->construct_opposite_2_object(); #endif // Convert the input polycurve to a sequence of CGAL objects, such // that each Object wraps an x-monotone subcurve. std::vector x_seg_objects; const_seg_iterator it_segs; for (it_segs = cv.subcurves_begin(); it_segs != cv.subcurves_end(); ++it_segs) make_seg_x_monotone(*it_segs, std::back_inserter(x_seg_objects)); typename std::vector::iterator it = x_seg_objects.begin(); X_monotone_subcurve_2 x_seg; #if defined (CGAL_NO_ASSERTIONS) CGAL::assign(x_seg, *it); #else bool assign_res = CGAL::assign(x_seg, *it); CGAL_assertion(assign_res); #endif // If the polycurve consists of a single x-monotone subcurve, return. if (x_seg_objects.size() == 1) { #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT if (cmp_seg_endpts(x_seg) == LARGER) x_seg = ctr_seg_opposite(x_seg); #endif *oi++ = make_object(ctr_x_curve(x_seg)); x_seg_objects.clear(); return oi; } CGAL_precondition_code ( // To be used in order to verify continuity and well-orientedness // of the input curve cv. typename Subcurve_traits_2::Construct_min_vertex_2 min_seg_v = m_poly_traits.subcurve_traits_2()->construct_min_vertex_2_object(); typename Subcurve_traits_2::Construct_max_vertex_2 max_seg_v = m_poly_traits.subcurve_traits_2()->construct_max_vertex_2_object(); typename Subcurve_traits_2::Equal_2 equal = m_poly_traits.subcurve_traits_2()->equal_2_object(); Point_2 last_target = (cmp_seg_endpts(x_seg) == SMALLER) ? max_seg_v(x_seg) : min_seg_v(x_seg); Point_2 next_src; ); // The polycurve consists of at least 2 x-monotone subcurves: Push_back_2 push_back = m_poly_traits.push_back_2_object(); typename Subcurve_traits_2::Is_vertical_2 is_seg_vertical = m_poly_traits.subcurve_traits_2()->is_vertical_2_object(); bool is_start_vertical = is_seg_vertical(x_seg); Comparison_result start_dir = cmp_seg_endpts(x_seg); #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT Push_front_2 push_front = m_poly_traits.push_front_2_object(); if (cmp_seg_endpts(x_seg) == LARGER) x_seg = ctr_seg_opposite(x_seg); #endif X_monotone_curve_2 x_polycurve = ctr_x_curve(x_seg); for (++it; it != x_seg_objects.end(); ++it){ X_monotone_subcurve_2 x_seg; #if defined (CGAL_NO_ASSERTIONS) CGAL::assign(x_seg, *it); #else bool assign_res = CGAL::assign(x_seg, *it); CGAL_assertion(assign_res); #endif // Test that cv is continuous and well-oriented. CGAL_precondition_code ( next_src = (cmp_seg_endpts(x_seg) == SMALLER) ? min_seg_v(x_seg) : max_seg_v(x_seg); ); CGAL_precondition_msg ( equal(last_target, next_src), "cv must form a continuous and well oriented curve." ); CGAL_precondition_code ( last_target = (cmp_seg_endpts(x_seg) == SMALLER) ? max_seg_v(x_seg) : min_seg_v(x_seg); ); Arr_curve_end polycurve_target = (cmp_seg_endpts(x_polycurve[0]) == SMALLER) ? ARR_MAX_END : ARR_MIN_END; Arr_curve_end seg_source = (cmp_seg_endpts(x_seg) == SMALLER) ? ARR_MIN_END : ARR_MAX_END; unsigned int num_segs = x_polycurve.number_of_subcurves(); if ((cmp_seg_endpts(x_seg) != start_dir) || (is_seg_vertical(x_seg) != is_start_vertical)) { // Construct an x-monotone curve from the sub-range which was found *oi++ = make_object(x_polycurve); is_start_vertical = is_seg_vertical(x_seg); start_dir = cmp_seg_endpts(x_seg); #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT if (cmp_seg_endpts(x_seg) == LARGER) x_seg = ctr_seg_opposite(x_seg); #endif x_polycurve = ctr_x_curve(x_seg); } else if (ps_x(x_polycurve[num_segs-1], polycurve_target) != ARR_INTERIOR || ps_x(x_seg, seg_source) != ARR_INTERIOR) { *oi++ = make_object(x_polycurve); #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT if (cmp_seg_endpts(x_seg) == LARGER) x_seg = ctr_seg_opposite(x_seg); #endif x_polycurve = ctr_x_curve(x_seg); } else { #ifdef CGAL_ALWAYS_LEFT_TO_RIGHT if (cmp_seg_endpts(x_seg) == LARGER) { x_seg = ctr_seg_opposite(x_seg); push_front(x_polycurve, x_seg); } else push_back(x_polycurve, x_seg); #else push_back(x_polycurve, x_seg); #endif } } // for loop if (x_polycurve.number_of_subcurves() != 0) *oi++ = make_object(x_polycurve); x_seg_objects.clear(); return oi; } public: template OutputIterator operator()(const Curve_2& cv, OutputIterator oi) const { return operator_impl(cv, oi, Are_all_sides_oblivious_tag()); } }; /*! Obtain a Make_x_monotone_2 functor object. */ Make_x_monotone_2 make_x_monotone_2_object() const { return Make_x_monotone_2(*this); } /* Functor to augment a polycurve by either adding a vertex or a subcurve * at the back. * TODO: Test all the operator()'s. (Don't forget vertical cases!) */ class Push_back_2 : public Base::Push_back_2 { protected: typedef Arr_polycurve_traits_2 Polycurve_traits_2; public: /*! Constructor. */ Push_back_2(const Polycurve_traits_2& traits) : Base::Push_back_2(traits) {} // Normally, the moment the compiler finds a name, it stops looking. In // other words, the compiler first finds the operator() in the current // class and stops looking, never finding the one in the base class. // Explicitly bring the base operator() into scope, unnecesitating the // code below. using Base::Push_back_2::operator(); // /*! Append a subcurve to an existing x-monotone polycurve at the back. // */ // void operator()(X_monotone_curve_2& xcv, // const X_monotone_subcurve_2& seg) // const // { Base::Push_back_2::operator()(xcv, seg); } /* Append a subcurve to an existing polycurve at the back. * If the polycurve is empty, the subcurve will be its only subcurve. */ void operator()(Curve_2& cv, const Subcurve_2& seg) const { cv.push_back(seg); } }; /*! Obtain a Push_back_2 functor object. */ Push_back_2 push_back_2_object() const { return Push_back_2(*this); } /* Functor to augment a polycurve by either adding a vertex or a subcurve * at the front. * TODO: Test all the operator()'s. (Don't forget vertical cases!) */ class Push_front_2 : public Base::Push_front_2 { protected: typedef Arr_polycurve_traits_2 Polycurve_traits_2; public: /*! Constructor. */ Push_front_2(const Polycurve_traits_2& traits) : Base::Push_front_2(traits) {} // Normally, the moment the compiler finds a name, it stops looking. In // other words, the compiler first finds the operator() in the current // class and stops looking, never finding the one in the base class. // Explicitly bring the base operator() into scope, unnecesitating the // code below. using Base::Push_front_2::operator(); // /*! Append a subcurve to an existing x-monotone polycurve at the front. // */ // void operator()(X_monotone_curve_2& xcv, // const X_monotone_subcurve_2& seg) // const // { Base::Push_front_2::operator()(xcv, seg); } /* Append a subcurve to an existing polycurve at the front. */ void operator()(Curve_2& cv, const Subcurve_2& seg) const { cv.push_front(seg); } }; /*! Obtain a Push_front_2 functor object. */ Push_front_2 push_front_2_object() const { return Push_front_2(*this); } class Split_2 { protected: typedef Arr_polycurve_traits_2 Polycurve_traits_2; /*! The polycurve traits (in case it has state) */ const Polycurve_traits_2& m_poly_traits; public: /*! Constructor. */ Split_2(const Polycurve_traits_2& traits) : m_poly_traits(traits) {} public: /*! Split a given x-monotone curve at a given point into two sub-curves. * \param cv The curve to split * \param p The split point. * \param c1 Output: The left resulting subcurve(p is its right endpoint). * \param c2 Output: The right resulting subcurve(p is its left endpoint). * \pre p lies on cv but is not one of its end-points. */ void operator()(const X_monotone_curve_2& xcv, const Point_2& p, X_monotone_curve_2& xcv1, X_monotone_curve_2& xcv2) const { const Subcurve_traits_2* geom_traits = m_poly_traits.subcurve_traits_2(); typename Subcurve_traits_2::Construct_min_vertex_2 min_vertex = geom_traits->construct_min_vertex_2_object(); typename Subcurve_traits_2::Construct_max_vertex_2 max_vertex = geom_traits->construct_max_vertex_2_object(); typename Subcurve_traits_2::Equal_2 equal = geom_traits->equal_2_object(); typename Subcurve_traits_2::Compare_endpoints_xy_2 cmp_seg_endpts = geom_traits->compare_endpoints_xy_2_object(); // Make sure the split point is not one of the curve endpoints. CGAL_precondition((!equal(m_poly_traits. construct_min_vertex_2_object()(xcv), p))); CGAL_precondition((!equal(m_poly_traits. construct_max_vertex_2_object()(xcv), p))); CGAL_precondition_msg(xcv.number_of_subcurves() > 0, "Cannot split a polycurve of length zero."); Comparison_result dir = cmp_seg_endpts(xcv[0]); // Locate the subcurve on the polycurve xcv that contains p. std::size_t i = m_poly_traits.locate(xcv, p); CGAL_precondition(i != Polycurve_traits_2::INVALID_INDEX); // Clear the output curves. xcv1.clear(); xcv2.clear(); // Push all subcurves labeled(0, 1, ... , i-1) into xcv1. for (std::size_t j = 0; j < i; ++j) xcv1.push_back(xcv[j]); if (dir == SMALLER){ // Check whether the split point is xcv[i]'s source or target. if (equal(max_vertex(xcv[i]), p)) { // The entire i'th subcurve belongs to xcv1: xcv1.push_back(xcv[i]); } else if (equal(min_vertex(xcv[i]), p)) { // The entire i'th subcurves belongs to xcv2: xcv2.push_back(xcv[i]); } else { // The i'th subcurve should be split: The left part(seg1) // goes to xcv1, and the right part(seg2) goes to xcv2. X_monotone_subcurve_2 seg1, seg2; m_poly_traits.subcurve_traits_2()->split_2_object()(xcv[i], p, seg1, seg2); xcv1.push_back(seg1); xcv2.push_back(seg2); } } else { if (equal(min_vertex(xcv[i]), p)) { xcv1.push_back(xcv[i]); } else if (equal(max_vertex(xcv[i]), p)) { xcv2.push_back(xcv[i]); } else { X_monotone_subcurve_2 seg1, seg2; m_poly_traits.subcurve_traits_2()-> split_2_object()(xcv[i], p, seg1, seg2); if (cmp_seg_endpts(seg2) == LARGER){ xcv1.push_back(seg2); } else { // seg2 has to be reversed seg2 = m_poly_traits.subcurve_traits_2()-> construct_opposite_2_object()(seg2); xcv1.push_back(seg2); } if (cmp_seg_endpts(seg1) == LARGER){ xcv2.push_back(seg1); } else { // seg2 has to be reversed seg1 = m_poly_traits.subcurve_traits_2()-> construct_opposite_2_object()(seg1); xcv1.push_back(seg1); } } } // Push all subcurves labeled(i+1, i+2, ... , n-1) into xcv1. std::size_t n = xcv.number_of_subcurves(); for (std::size_t j = i+1; j < n; ++j) xcv2.push_back(xcv[j]); if (dir != SMALLER) std::swap(xcv1, xcv2); } }; /*! Obtain a Split_2 functor object. */ Split_2 split_2_object() const { return Split_2(*this); } class Intersect_2 { protected: typedef Arr_polycurve_traits_2 Polycurve_traits_2; /*! The polycurve traits (in case it has state) */ const Polycurve_traits_2& m_poly_traits; public: /*! Constructor. */ Intersect_2(const Polycurve_traits_2& traits) : m_poly_traits(traits) {} /*! Find the intersections of the two given curves and insert them into the * given output iterator. As two subcurves may itersect only once, only a * single intersection will be contained in the iterator. * Note: If the intersection yields an overlap then it will be oriented * from left-to-right. * \param cv1 The first curve. * \param cv2 The second curve. * \param oi The output iterator. * \return The past-the-end iterator. */ template OutputIterator operator()(const X_monotone_curve_2& cv1, const X_monotone_curve_2& cv2, OutputIterator oi) const { const Subcurve_traits_2* geom_traits = m_poly_traits.subcurve_traits_2(); Compare_y_at_x_2 cmp_y_at_x = m_poly_traits.compare_y_at_x_2_object(); typename Subcurve_traits_2::Equal_2 equal = geom_traits->equal_2_object(); typename Subcurve_traits_2::Construct_min_vertex_2 min_vertex = geom_traits->construct_min_vertex_2_object(); typename Subcurve_traits_2::Construct_max_vertex_2 max_vertex = geom_traits->construct_max_vertex_2_object(); typename Subcurve_traits_2::Intersect_2 intersect = geom_traits->intersect_2_object(); typename Subcurve_traits_2::Compare_endpoints_xy_2 cmp_seg_endpts = geom_traits->compare_endpoints_xy_2_object(); typename Subcurve_traits_2::Construct_opposite_2 construct_opposite = geom_traits->construct_opposite_2_object(); typedef std::pair Point_2_pair; Comparison_result dir1 = cmp_seg_endpts(cv1[0]); Comparison_result dir2 = cmp_seg_endpts(cv2[0]); const std::size_t n1 = cv1.number_of_subcurves(); const std::size_t n2 = cv2.number_of_subcurves(); std::size_t i1 = (dir1 == SMALLER) ? 0 : n1-1; std::size_t i2 = (dir2 == SMALLER) ? 0 : n2-1; X_monotone_curve_2 ocv; // Used to represent overlaps. Compare_xy_2 compare_xy = m_poly_traits.compare_xy_2_object(); Comparison_result left_res = compare_xy(cv1[i1], ARR_MIN_END, cv2[i2], ARR_MIN_END); if (left_res == SMALLER) { // cv1's left endpoint is to the left of cv2's left endpoint: // Locate the index i1 of the subcurve in cv1 which contains cv2's // left endpoint. i1 = m_poly_traits.locate_impl(cv1, cv2[i2], ARR_MIN_END, Are_all_sides_oblivious_tag()); if (i1 == Polycurve_traits_2::INVALID_INDEX) return oi; if (equal(max_vertex(cv1[i1]), min_vertex(cv2[i2]))) { if (((dir1 == SMALLER) && (i1 == n1-1)) || ((dir1 == LARGER) && (i1 == 0))){ // cv1's right endpoint equals cv2's left endpoint // Thus we can return this single(!) intersection point std::pair p(max_vertex(cv1[i1]), 0); *oi++ = make_object(p); return oi; } dir1 == SMALLER ? ++i1 : (i1 != 0) ? --i1 : (std::size_t) Polycurve_traits_2::INVALID_INDEX; left_res = EQUAL; } } else if (left_res == LARGER) { // cv1's left endpoint is to the right of cv2's left endpoint: // Locate the index i2 of the subcurve in cv2 which contains cv1's // left endpoint. i2 = m_poly_traits.locate_impl(cv2, cv1[i1], ARR_MIN_END, Are_all_sides_oblivious_tag()); if (i2 == Polycurve_traits_2::INVALID_INDEX) return oi; if (equal(max_vertex(cv2[i2]), min_vertex(cv1[i1]))) { if (((dir2 == SMALLER) && (i2 == n2-1)) || ((dir2 == LARGER) && (i2 == 0))){ // cv2's right endpoint equals cv1's left endpoint // Thus we can return this single(!) intersection point std::pair p(max_vertex(cv2[i2]), 0); *oi++ = make_object(p); return oi; } dir2 == SMALLER ? ++i2 : (i2 != 0) ? --i2 : (std::size_t) Polycurve_traits_2::INVALID_INDEX; left_res = EQUAL; } } // Check if the the left endpoint lies on the other polycurve. bool left_coincides = (left_res == EQUAL); bool left_overlap = false; if (left_res == SMALLER) left_coincides = (cmp_y_at_x(cv2[i2], ARR_MIN_END, cv1[i1]) == EQUAL); else if (left_res == LARGER) left_coincides = (cmp_y_at_x(cv1[i1], ARR_MIN_END, cv2[i2]) == EQUAL); // The main loop: Go simultaneously over both polycurves. Comparison_result right_res = left_res; bool right_coincides = left_coincides; bool right_overlap = false; while (((dir1 == SMALLER) && (dir2 == SMALLER) && (i1 < n1) && (i2 < n2)) || ((dir1 != SMALLER) && (dir2 == SMALLER) && (i1 != Polycurve_traits_2::INVALID_INDEX) && (i2 < n2)) || ((dir1 == SMALLER) && (dir2 != SMALLER) && (i1 < n1) && (i2 != Polycurve_traits_2::INVALID_INDEX)) || ((dir1 != SMALLER) && (dir2 != SMALLER) && (i1 != Polycurve_traits_2::INVALID_INDEX) && (i2 != Polycurve_traits_2::INVALID_INDEX))) { right_res = compare_xy(cv1[i1], ARR_MAX_END, cv2[i2], ARR_MAX_END); right_coincides = (right_res == EQUAL); if (right_res == SMALLER) right_coincides = (cmp_y_at_x(cv1[i1], ARR_MAX_END, cv2[i2]) == EQUAL); else if (right_res == LARGER) right_coincides = (cmp_y_at_x(cv2[i2], ARR_MAX_END, cv1[i1]) == EQUAL); right_overlap = false; if (!right_coincides && !left_coincides) { // Non of the endpoints of the current subcurve of one polycurve // coincides with the curent subcurve of the other polycurve: // Output the intersection if exists. oi = intersect(cv1[i1], cv2[i2], oi); } else if (right_coincides && left_coincides) { // An overlap exists between the current subcurves of the // polycurves: Output the overlapping subcurve. right_overlap = true; std::vector int_seg; intersect(cv1[i1], cv2[i2], std::back_inserter(int_seg)); for (size_t i = 0; i < int_seg.size(); ++i) { const X_monotone_subcurve_2* x_seg = CGAL::object_cast (&(int_seg[i])); if (x_seg != NULL) { X_monotone_subcurve_2 seg = *x_seg; // If for some reason the subcurve intersection // results in left oriented curve. if ( cmp_seg_endpts(seg) == LARGER) seg = construct_opposite(seg); ocv.push_back(seg); } const Point_2_pair* p_ptr = CGAL::object_cast(&(int_seg[i])); if (p_ptr != NULL) { // Any point that is not equal to the max_vertex of the // subcurve should be inserted into oi. // The max_vertex of the current subcurve (if intersecting) // will be taken care of as the min_vertex of in the next // iteration. if (!equal(p_ptr->first, max_vertex(cv1[i1]))) *oi++ = make_object(*p_ptr); } } } else if (left_coincides && !right_coincides) { // std::cout << "Left is coinciding but right is not." << std::endl; // The left point of the current subcurve of one polycurve // coincides with the current subcurve of the other polycurve. if (left_overlap) { // An overlap occured at the previous iteration: // Output the overlapping polycurve. CGAL_assertion(ocv.number_of_subcurves() > 0); *oi++ = make_object(ocv); ocv.clear(); } else { // The left point of the current subcurve of one // polycurve coincides with the current subcurve of the // other polycurve, and no overlap occured at the // previous iteration: Output the intersection // point. The derivative of at least one of the // polycurves is not defined at this point, so we give // it multiplicity 0. if (left_res == SMALLER) { std::pair p(min_vertex(cv2[i2]), 0); *oi++ = make_object(p); } else { std::pair p(min_vertex(cv1[i1]), 0); *oi++ = make_object(p); } } } // Proceed forward. if (right_res != SMALLER) { if (dir2 == SMALLER) ++i2; else { if (i2 == 0) i2 = Polycurve_traits_2::INVALID_INDEX; else --i2; } } if (right_res != LARGER) { if (dir1 == SMALLER) ++i1; else { if (i1 == 0) i1 = Polycurve_traits_2::INVALID_INDEX; else --i1; } } left_res = (right_res == SMALLER) ? LARGER : (right_res == LARGER) ? SMALLER : EQUAL; left_coincides = right_coincides; left_overlap = right_overlap; } // END of while loop // Output the remaining overlapping polycurve, if necessary. if (ocv.number_of_subcurves() > 0) { *oi++ = make_object(ocv); } else if (right_coincides) { typedef std::pair return_point; return_point ip; if (right_res == SMALLER) { ip = (dir1 == SMALLER) ? return_point(max_vertex(cv1[i1-1]), 0) : (i1 != Polycurve_traits_2::INVALID_INDEX) ? return_point(max_vertex(cv1[i1+1]), 0) : return_point(max_vertex(cv1[0]), 0); *oi++ = make_object(ip); } else if (right_res == LARGER) { ip = (dir2 == SMALLER) ? return_point(max_vertex(cv2[i2-1]), 0) : (i2 != Polycurve_traits_2::INVALID_INDEX) ? return_point(max_vertex(cv2[i2+1]), 0) : return_point(max_vertex(cv2[0]), 0); *oi++ = make_object(ip); } else if (((i1 > 0) && (dir1 == SMALLER)) || ((i1 < n1) && (dir1 != SMALLER)) || ((i1 == Polycurve_traits_2::INVALID_INDEX) && (dir1 != SMALLER))) { ip = (dir1 == SMALLER) ? return_point(max_vertex(cv1[i1-1]), 0) : (i1 != Polycurve_traits_2::INVALID_INDEX) ? return_point(max_vertex(cv1[i1+1]), 0) : return_point(max_vertex(cv1[0]), 0); *oi++ = make_object(ip); } else { CGAL_assertion_msg((dir2 == SMALLER && i2 > 0) || (dir2 != SMALLER && i2 < n2) || (dir2 != SMALLER && ((i1 == Polycurve_traits_2::INVALID_INDEX) || (i2 == Polycurve_traits_2::INVALID_INDEX))), "Wrong index for xcv2 in Intersect_2 of " "polycurves."); ip = (dir2 == SMALLER) ? return_point(max_vertex(cv2[i2-1]), 0) : (i2 != Polycurve_traits_2::INVALID_INDEX) ? return_point(max_vertex(cv2[i2+1]), 0) : return_point(max_vertex(cv2[0]), 0); *oi++ = make_object(ip); } } return oi; } }; /*! Obtain an Intersect_2 functor object. */ Intersect_2 intersect_2_object() const { return Intersect_2(*this); } class Are_mergeable_2 { protected: typedef Arr_polycurve_traits_2 Polycurve_traits_2; /*! The polycurve traits (in case it has state) */ const Polycurve_traits_2& m_poly_traits; public: /*! Constructor. */ Are_mergeable_2(const Polycurve_traits_2& traits) : m_poly_traits(traits) {} /*! Check whether it is possible to merge two given x-monotone curves. * \param cv1 The first curve. * \param cv2 The second curve. * \return(true) if the two curves are mergeable, that is, they share a * common endpoint and the same orientation;(false) otherwise. */ bool operator()(const X_monotone_curve_2& cv1, const X_monotone_curve_2& cv2) const { const Subcurve_traits_2* geom_traits = m_poly_traits.subcurve_traits_2(); Construct_min_vertex_2 min_vertex = m_poly_traits.construct_min_vertex_2_object(); Construct_max_vertex_2 max_vertex = m_poly_traits.construct_max_vertex_2_object(); typename Subcurve_traits_2::Equal_2 equal = geom_traits->equal_2_object(); typename Subcurve_traits_2::Is_vertical_2 is_seg_vertical = geom_traits->is_vertical_2_object(); Comparison_result dir1 = m_poly_traits.compare_endpoints_xy_2_object()(cv1); Comparison_result dir2 = m_poly_traits.compare_endpoints_xy_2_object()(cv2); if (dir1 != dir2) return false; bool ver1 = is_seg_vertical(cv1[0]); bool ver2 = is_seg_vertical(cv2[0]); return (((// Both are directed from left-to-right (dir1 == SMALLER) && ((equal(max_vertex(cv1),min_vertex(cv2))) || (equal(max_vertex(cv2),min_vertex(cv1))))) || (// Both are directed from right-to-left (dir1 == LARGER) && ((equal(min_vertex(cv1),max_vertex(cv2))) || (equal(max_vertex(cv1),min_vertex(cv2)))) )) && (// Either both should be vertical or both should // be NOT vertical. (ver1 && ver2) || (!ver1 && !ver2))); } }; /*! Obtain an Are_mergeable_2 functor object. */ Are_mergeable_2 are_mergeable_2_object() const { return Are_mergeable_2(*this); } /*! \class Merge_2 * A functor that merges two x-monotone curves into one. */ /* Roadmap: Allow merging of overlapping polycurves. This means also * changing the subcurve traits class. */ class Merge_2 { protected: typedef Arr_polycurve_traits_2 Geometry_traits; /*! The traits (in case it has state) */ const Geometry_traits& m_poly_traits; public: /*! Constructor * \param traits the traits (in case it has state) */ Merge_2(const Geometry_traits& traits) : m_poly_traits(traits) {} /*! Merge two given x-monotone curves into a single curve(segment). * \param cv1 The first curve. * \param cv2 The second curve. * \param c Output: The merged curve. * \pre The two curves are mergeable. */ void operator()(const X_monotone_curve_2& cv1, const X_monotone_curve_2& cv2, X_monotone_curve_2& c) const { CGAL_precondition(m_poly_traits.are_mergeable_2_object()(cv1, cv2)); Construct_min_vertex_2 get_min_v = m_poly_traits.construct_min_vertex_2_object(); Construct_max_vertex_2 get_max_v = m_poly_traits.construct_max_vertex_2_object(); Compare_endpoints_xy_2 cmp_seg_endpts = m_poly_traits.compare_endpoints_xy_2_object(); Equal_2 equal = m_poly_traits.equal_2_object(); c.clear(); if (// Either both are left-to-right and cv2 is to the right of cv1 ((cmp_seg_endpts(cv1)==SMALLER) && (equal(get_max_v(cv1),get_min_v(cv2)))) || // or both are right-to-left and cv2 is to the left of cv1 ((cmp_seg_endpts(cv1)==LARGER) && (equal(get_min_v(cv1), get_max_v(cv2))))) { const std::size_t n1 = cv1.number_of_subcurves(); const std::size_t n2 = cv2.number_of_subcurves(); std::size_t i; // cv2 extends cv1 to the right: for (i = 0; i < n1 - 1; ++i) c.push_back(cv1[i]); // Try to merge the to contiguous line subcurves: if (m_poly_traits.subcurve_traits_2()-> are_mergeable_2_object()(cv1[n1 - 1], cv2[0])) { X_monotone_subcurve_2 seg; m_poly_traits.subcurve_traits_2()-> merge_2_object()(cv1[n1 - 1], cv2[0], seg); c.push_back(seg); } else { c.push_back(cv1[n1 - 1]); c.push_back(cv2[0]); } for (i = 1; i < n2; ++i) c.push_back(cv2[i]); } else return this->operator()(cv2,cv1,c); } }; /*! Obtain a Merge_2 functor object. */ Merge_2 merge_2_object() const { return Merge_2(*this); } ///@} /*! \class * A functor that constructs a (general) polycurve. */ class Construct_curve_2 { protected: typedef Arr_polycurve_traits_2 Polycurve_traits_2; /*! The polycurve traits (in case it has state) */ const Polycurve_traits_2& m_poly_traits; public: /*! Constructor. */ Construct_curve_2(const Polycurve_traits_2& traits) : m_poly_traits(traits) {} /*! Obtain a polycurve that consists of one given subcurve. */ Curve_2 operator()(const Subcurve_2& seg) const { return Curve_2(seg); } /* Construct a well-oriented polycurve from a range of either * `SubcurveTraits::Point_2` or `SubcurveTraits::Subcurve_2`. */ template Curve_2 operator()(ForwardIterator begin, ForwardIterator end) const { typedef typename std::iterator_traits::value_type VT; typedef typename boost::is_same::type Is_point; // Dispatch the range to the appropriate implementation. return constructor_impl(begin, end, Is_point()); } /*! Construction of a polycurve from a range of points. * \pre The range contains at least two points * \pre Consecutive points are disjoint. * \return Well-oriented polycurve connecting the given * points. The order of the vertices is determined by * their order in the range. Furthermore, the * orientation of the polycurve is induced by their * order. */ template Curve_2 constructor_impl(ForwardIterator /* begin */, ForwardIterator /* end */, boost::true_type) const { CGAL_error_msg("Cannot construct a polycurve from a range of points!"); } /*! Construction implementation from a range of subcurves. * Note that the subcurves in the range are NOT necessarily x-monotone, * thus it is impossible to test (even in precondition) whether the input * forms a continuous and well oriented polycurve. * \pre Range should contain at least one subcurve. */ template Curve_2 constructor_impl(ForwardIterator begin, ForwardIterator end, boost::false_type) const { // Range has to contain at least one subcurve CGAL_precondition(begin != end); return Curve_2(begin, end); } }; /*! Obtain a Construct_curve_2 functor object. */ Construct_curve_2 construct_curve_2_object() const { return Construct_curve_2(*this); } }; } //namespace CGAL #include #endif