// Copyright (c) 1999-2003 INRIA Sophia-Antipolis (France). // All rights reserved. // // This file is part of CGAL (www.cgal.org). // // $URL: https://github.com/CGAL/cgal/blob/v5.1/Triangulation_3/include/CGAL/Triangulation_3.h $ // $Id: Triangulation_3.h 022b1a7 2020-07-21T15:27:49+02:00 Laurent Rineau // SPDX-License-Identifier: GPL-3.0-or-later OR LicenseRef-Commercial // // Author(s) : Monique Teillaud // Sylvain Pion // Clement Jamin #ifndef CGAL_TRIANGULATION_3_H #define CGAL_TRIANGULATION_3_H #include #include #include #ifdef CGAL_CONCURRENT_TRIANGULATION_3_PROFILING # define CGAL_PROFILE # include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifndef CGAL_TRIANGULATION_3_DONT_INSERT_RANGE_OF_POINTS_WITH_INFO #include #include #endif #ifndef CGAL_NO_STRUCTURAL_FILTERING #include #include #include #endif // no CGAL_NO_STRUCTURAL_FILTERING #ifdef CGAL_LINKED_WITH_TBB # include #endif #define CGAL_TRIANGULATION_3_USE_THE_4_POINTS_CONSTRUCTOR namespace CGAL { template < class GT, class Tds = Default, class Lock_data_structure = Default > class Triangulation_3; template < class GT, class Tds, class Lds > std::istream& operator>> (std::istream& is, Triangulation_3& tr); #ifndef CGAL_NO_STRUCTURAL_FILTERING namespace internal { // structural filtering is performed only for EPIC struct Structural_filtering_3_tag {}; struct No_structural_filtering_3_tag {}; template struct Structural_filtering_selector_3 { #ifdef FORCE_STRUCTURAL_FILTERING typedef Structural_filtering_3_tag Tag; #else typedef No_structural_filtering_3_tag Tag; #endif }; template <> struct Structural_filtering_selector_3 { typedef Structural_filtering_3_tag Tag; }; } // namespace internal #endif // no CGAL_NO_STRUCTURAL_FILTERING /************************************************ // Class Triangulation_3_base // Two versions: Sequential (no locking) / Parallel (with locking) ************************************************/ // Sequential (without locking) template class Triangulation_3_base { public: // If Lock_data_structure_ = Default => void typedef typename Default::Get< Lock_data_structure_, void>::type Lock_data_structure; protected: Triangulation_3_base() {} Triangulation_3_base(Lock_data_structure *) {} void swap(Triangulation_3_base&) {} template struct Vertex_triple_Facet_map_generator { typedef boost::unordered_map type; }; template struct Vertex_handle_unique_hash_map_generator { typedef Unique_hash_map type; }; public: bool is_parallel() const { return false; } // LOCKS (no-op functions) template bool try_lock_point(const Point_3&, int = 0) const { return true; } template bool try_lock_vertex(const Vertex_handle&, int = 0) const { return true; } template bool try_lock_cell(const Cell_handle&, int = 0) const { return true; } template bool try_lock_facet(const Facet&, int = 0) const { return true; } template bool is_point_locked_by_this_thread(const P3&) const { return false; } template bool is_cell_locked_by_this_thread(const Cell_handle&) const { return false; } void *get_lock_data_structure() const { return nullptr; } void set_lock_data_structure(void *) const {} void unlock_all_elements() const {} template void unlock_all_elements_but_one_point(const P3&) const {} const Bbox_3 *get_bbox() const { return nullptr; } }; #ifdef CGAL_LINKED_WITH_TBB // Parallel (with locking) template class Triangulation_3_base { public: // If Lock_data_structure_ = Default => use Spatial_lock_grid_3 typedef typename Default::Get< Lock_data_structure_, Spatial_lock_grid_3 >::type Lock_data_structure; protected: Triangulation_3_base() : m_lock_ds(0) { } Triangulation_3_base(Lock_data_structure *lock_ds) : m_lock_ds(lock_ds) { } void swap(Triangulation_3_base& tr) { std::swap(tr.m_lock_ds, m_lock_ds); } template struct Vertex_triple_Facet_map_generator { typedef boost::unordered_map < Vertex_triple, Facet, boost::hash, std::equal_to, tbb::scalable_allocator > > type; }; template struct Vertex_handle_unique_hash_map_generator { typedef Unique_hash_map > type; }; public: bool is_parallel() const { return m_lock_ds != nullptr; } // LOCKS template bool try_lock_point(const Point_3& p, int lock_radius = 0) const { bool locked = true; if(m_lock_ds) { locked = m_lock_ds->try_lock(p, lock_radius); } return locked; } template bool try_lock_vertex(const Vertex_handle& vh, int lock_radius = 0) const { bool locked = true; if(m_lock_ds) { locked = m_lock_ds->try_lock(vh->point(), lock_radius); } return locked; } template bool try_lock_cell(const Cell_handle& cell_handle, int lock_radius = 0) const { bool success = true; // Lock the element area on the grid for(int iVertex = 0 ; success && iVertex < 4 ; ++iVertex) { success = try_lock_vertex(cell_handle->vertex(iVertex), lock_radius); } return success; } template bool try_lock_facet(const Facet& facet, int lock_radius = 0) const { bool success = true; // Lock the element area on the grid for(int iVertex = (facet.second+1)&3 ; success && iVertex != facet.second ; iVertex = (iVertex+1)&3) { success = try_lock_vertex(facet.first->vertex(iVertex), lock_radius); } return success; } template bool is_point_locked_by_this_thread(const P3& p) const { bool locked = true; if(m_lock_ds) { locked = m_lock_ds->is_locked_by_this_thread(p); } return locked; } template bool is_cell_locked_by_this_thread(const Cell_handle& cell_handle) const { bool locked = true; if(m_lock_ds) { for(int iVertex = 0 ; locked && iVertex < 4 ; ++iVertex) { locked = m_lock_ds->is_locked_by_this_thread( cell_handle->vertex(iVertex)->point()); } } return locked; } Lock_data_structure *get_lock_data_structure() const { return m_lock_ds; } void set_lock_data_structure(Lock_data_structure *lock_ds) const { m_lock_ds = lock_ds; } void unlock_all_elements() const { if(m_lock_ds) m_lock_ds->unlock_all_points_locked_by_this_thread(); } template void unlock_all_elements_but_one_point(const P3& point) const { if(m_lock_ds) m_lock_ds->unlock_all_tls_locked_locations_but_one_point(point); } const Bbox_3 *get_bbox() const { return &m_lock_ds->get_bbox(); } protected: mutable Lock_data_structure *m_lock_ds; }; #endif // CGAL_LINKED_WITH_TBB /************************************************ * * Triangulation_3 class * ************************************************/ template < class GT, class Tds_, class Lock_data_structure_ > class Triangulation_3 : public Triangulation_3_base< // Get Concurrency_tag from TDS typename Default::Get, Triangulation_cell_base_3 > >::type::Concurrency_tag, Lock_data_structure_>, public Triangulation_utils_3 { friend std::istream& operator>> <> (std::istream& is, Triangulation_3& tr); typedef typename Default::Get, Triangulation_cell_base_3 > >::type Tds; typedef Triangulation_3 Self; typedef Triangulation_3_base Base; public: typedef typename Base::Lock_data_structure Lock_data_structure; typedef Tds Triangulation_data_structure; typedef GT Geom_traits; typedef typename GT::Segment_3 Segment; typedef typename GT::Triangle_3 Triangle; typedef typename GT::Tetrahedron_3 Tetrahedron; // point types typedef typename GT::Point_3 Point_3; typedef typename Tds::Vertex::Point Point; typedef typename Tds::Concurrency_tag Concurrency_tag; typedef typename Tds::Vertex Vertex; typedef typename Tds::Cell Cell; typedef typename Tds::Facet Facet; typedef typename Tds::Edge Edge; typedef typename Tds::size_type size_type; typedef typename Tds::difference_type difference_type; typedef typename Tds::Vertex_handle Vertex_handle; typedef typename Tds::Cell_handle Cell_handle; typedef typename Tds::Cell_circulator Cell_circulator; typedef typename Tds::Facet_circulator Facet_circulator; // Not documented, see TDS. typedef typename Tds::Face_circulator Face_circulator; typedef typename Tds::Cell_iterator Cell_iterator; typedef typename Tds::Facet_iterator Facet_iterator; typedef typename Tds::Edge_iterator Edge_iterator; typedef typename Tds::Vertex_iterator Vertex_iterator; typedef Cell_iterator All_cells_iterator; typedef Facet_iterator All_facets_iterator; typedef Edge_iterator All_edges_iterator; typedef Vertex_iterator All_vertices_iterator; typedef typename Tds::Cell_handles All_cell_handles; typedef typename Tds::Vertex_handles All_vertex_handles; typedef typename Tds::Facets All_facets; typedef typename Tds::Edges All_edges; typedef typename Tds::Simplex Simplex; typedef typename GT::Construct_point_3 Construct_point_3; private: // This class is used to generate the Finite_*_iterators. class Infinite_tester { const Self *t; public: Infinite_tester() {} Infinite_tester(const Self *tr) : t(tr) {} bool operator()(const Vertex_iterator& v) const { return t->is_infinite(v); } bool operator()(typename std::vector::const_iterator v) const { return t->is_infinite(*v); } bool operator()(const Cell_iterator& c) const { return t->is_infinite(c); } bool operator()(const Edge_iterator& e) const { return t->is_infinite(*e); } bool operator()(const Facet_iterator& f) const { return t->is_infinite(*f); } }; public: // We derive in order to add a conversion to handle. class Finite_cells_iterator : public Filter_iterator { typedef Filter_iterator Base; typedef Finite_cells_iterator Self; public: Finite_cells_iterator() : Base() {} Finite_cells_iterator(const Base& b) : Base(b) {} Self& operator++() { Base::operator++(); return *this; } Self& operator--() { Base::operator--(); return *this; } Self operator++(int) { Self tmp(*this); ++(*this); return tmp; } Self operator--(int) { Self tmp(*this); --(*this); return tmp; } operator Cell_handle() const { return Base::base(); } }; // We derive in order to add a conversion to handle. class Finite_vertices_iterator : public Filter_iterator { typedef Filter_iterator Base; typedef Finite_vertices_iterator Self; public: Finite_vertices_iterator() : Base() {} Finite_vertices_iterator(const Base& b) : Base(b) {} Self& operator++() { Base::operator++(); return *this; } Self& operator--() { Base::operator--(); return *this; } Self operator++(int) { Self tmp(*this); ++(*this); return tmp; } Self operator--(int) { Self tmp(*this); --(*this); return tmp; } operator Vertex_handle() const { return Base::base(); } }; typedef Iterator_range > Finite_cell_handles; typedef Iterator_range > Finite_vertex_handles; typedef Filter_iterator Finite_edges_iterator; typedef Filter_iterator Finite_facets_iterator; typedef Iterator_range Finite_edges; typedef Iterator_range Finite_facets; private: // Auxiliary iterators for convenience // do not use default template argument to please VC++ typedef Project_point Proj_point; public: typedef Iterator_project Point_iterator; typedef Iterator_range Points; // To have a back_inserter typedef Point value_type; typedef const value_type& const_reference; // Tag to distinguish triangulations with weighted_points typedef Tag_false Weighted_tag; // Tag to distinguish periodic triangulations from others typedef Tag_false Periodic_tag; enum Locate_type { VERTEX=0, EDGE, //1 FACET, //2 CELL, //3 OUTSIDE_CONVEX_HULL, //4 OUTSIDE_AFFINE_HULL //5 }; protected: Tds _tds; GT _gt; Vertex_handle infinite; // infinite vertex public: template // Point or Point_3 typename boost::result_of::type construct_point(const P& p) const { return geom_traits().construct_point_3_object()(p); } template // Point or Point_3 Comparison_result compare_xyz(const P& p, const P& q) const { return geom_traits().compare_xyz_3_object()(construct_point(p), construct_point(q)); } bool equal(const Point& p, const Point& q) const { return compare_xyz(p, q) == EQUAL; } template // Point or Point_3 Orientation orientation(const P& p, const P& q, const P& r, const P& s) const { return geom_traits().orientation_3_object()(construct_point(p), construct_point(q), construct_point(r), construct_point(s)); } bool coplanar(const Point& p, const Point& q, const Point& r, const Point& s) const { return orientation(p, q, r, s) == COPLANAR; } template // Point or Point_3 Orientation coplanar_orientation(const P& p, const P& q, const P& r) const { return geom_traits().coplanar_orientation_3_object()(construct_point(p), construct_point(q), construct_point(r)); } bool collinear(const Point& p, const Point& q, const Point& r) const { return coplanar_orientation(p, q, r) == COLLINEAR; } template // Point or Point_3 Segment construct_segment(const P& p, const P& q) const { return geom_traits().construct_segment_3_object()(construct_point(p), construct_point(q)); } template // Point or Point_3 Triangle construct_triangle(const P& p, const P& q, const P& r) const { return geom_traits().construct_triangle_3_object()(construct_point(p), construct_point(q), construct_point(r)); } template // Point or Point_3 Tetrahedron construct_tetrahedron(const P& p, const P& q, const P& r, const P& s) const { return geom_traits().construct_tetrahedron_3_object()(construct_point(p), construct_point(q), construct_point(r), construct_point(s)); } enum COLLINEAR_POSITION { BEFORE, SOURCE, MIDDLE, TARGET, AFTER }; COLLINEAR_POSITION collinear_position(const Point& s, const Point& p, const Point& t) const { // (s,t) defines a line, p is on that line. // Depending on the position of p wrt s and t, returns : // --------------- s ---------------- t -------------- // BEFORE SOURCE MIDDLE TARGET AFTER CGAL_triangulation_precondition(!equal(s, t)); CGAL_triangulation_precondition(collinear(s, p, t)); Comparison_result ps = compare_xyz(p, s); if(ps == EQUAL) return SOURCE; Comparison_result st = compare_xyz(s, t); if(ps == st) return BEFORE; Comparison_result pt = compare_xyz(p, t); if(pt == EQUAL) return TARGET; if(pt == st) return MIDDLE; return AFTER; } // used as functor in std::sort in Delaunay and regular triangulations struct Perturbation_order { bool operator()(const Point* p, const Point* q) const { return t->compare_xyz(*p, *q) == SMALLER; } Perturbation_order(const Self *tr) : t(tr) {} const Self *t; }; void init_tds() { infinite = _tds.insert_increase_dimension(); } void init_tds(const Point& p0, const Point& p1, const Point& p2, const Point& p3) { Vertex_handle v0, v1, v2, v3; infinite = _tds.insert_first_finite_cell(v0, v1, v2, v3, infinite); v0->set_point(p0); v1->set_point(p1); v2->set_point(p2); v3->set_point(p3); } void init_tds(const Point& p0, const Point& p1, const Point& p2, const Point& p3, Vertex_handle& vh0, Vertex_handle& vh1, Vertex_handle& vh2, Vertex_handle& vh3) { infinite = _tds.insert_first_finite_cell(vh0, vh1, vh2, vh3, infinite); vh0->set_point(p0); vh1->set_point(p1); vh2->set_point(p2); vh3->set_point(p3); } public: // CONSTRUCTORS Triangulation_3(const GT& gt = GT(), Lock_data_structure *lock_ds = nullptr) : Base(lock_ds), _tds(), _gt(gt) { init_tds(); } Triangulation_3(Lock_data_structure *lock_ds, const GT& gt = GT()) : Base(lock_ds), _tds(), _gt(gt) { init_tds(); } // copy constructor duplicates vertices and cells Triangulation_3(const Triangulation_3& tr) : Base(tr.get_lock_data_structure()), _gt(tr._gt) { infinite = _tds.copy_tds(tr._tds, tr.infinite); CGAL_triangulation_expensive_postcondition(*this == tr); } Triangulation_3(Triangulation_3&& tr) = default; ~Triangulation_3() = default; template < typename InputIterator > Triangulation_3(InputIterator first, InputIterator last, const GT& gt = GT(), Lock_data_structure *lock_ds = nullptr) : Base(lock_ds), _gt(gt) { init_tds(); insert(first, last); } // Create the 3D triangulation of p0, p1, p3 and p4 // Precondition: p0, p1, p3 and p4 MUST BE positively oriented Triangulation_3(const Point& p0, const Point& p1, const Point& p3, const Point& p4, const GT& gt = GT(), Lock_data_structure *lock_ds = nullptr) : Base(lock_ds), _gt(gt) { CGAL_triangulation_precondition(orientation(p0, p1, p3, p4) == POSITIVE); init_tds(p0, p1, p3, p4); } void clear() { _tds.clear(); init_tds(); } Triangulation_3& operator=(const Triangulation_3& tr) { Triangulation_3 copy(tr); swap(copy); return *this; } Triangulation_3& operator=(Triangulation_3&& tr) = default; // HELPING FUNCTIONS void swap(Triangulation_3& tr) noexcept { using std::swap; swap(tr._gt, _gt); swap(tr.infinite, infinite); _tds.swap(tr._tds); Base::swap(tr); } //ACCESS FUNCTIONS const GT& geom_traits() const { return _gt; } const Tds& tds() const { return _tds; } Tds& tds() { return _tds; } int dimension() const { return _tds.dimension(); } size_type number_of_finite_cells() const; size_type number_of_cells() const; size_type number_of_finite_facets() const; size_type number_of_facets() const; size_type number_of_finite_edges() const; size_type number_of_edges() const; size_type number_of_vertices() const // number of finite vertices { return _tds.number_of_vertices()-1; } Vertex_handle infinite_vertex() const { return infinite; } void set_infinite_vertex(Vertex_handle v) { infinite = v; } Cell_handle infinite_cell() const { CGAL_triangulation_assertion(infinite_vertex()->cell()->has_vertex(infinite_vertex())); return infinite_vertex()->cell(); } // GEOMETRIC ACCESS FUNCTIONS Tetrahedron tetrahedron(const Cell_handle c) const { CGAL_triangulation_precondition(dimension() == 3); CGAL_triangulation_precondition(! is_infinite(c)); return construct_tetrahedron(c->vertex(0)->point(), c->vertex(1)->point(), c->vertex(2)->point(), c->vertex(3)->point()); } template // can be 'Point' or 'Point_3' Tetrahedron tetrahedron(const Facet& f, const P& p) const { const Cell_handle c = f.first; const int index = f.second; const P& fp1 = point(c, (index + 1)&3); const P& fp2 = point(c, (index + 2)&3); const P& fp3 = point(c, (index + 3)&3); return construct_tetrahedron(construct_point(p), construct_point(fp1), construct_point(fp2), construct_point(fp3)); } Triangle triangle(const Cell_handle c, int i) const; Triangle triangle(const Facet& f) const { return triangle(f.first, f.second); } Segment segment(const Cell_handle c, int i, int j) const; Segment segment(const Edge& e) const { return segment(e.first, e.second, e.third); } void set_point(Cell_handle c, int i, const Point& p) { CGAL_triangulation_precondition(dimension() >= 0); CGAL_triangulation_precondition(i >= 0 && i <= dimension()); CGAL_triangulation_precondition(! is_infinite(c->vertex(i))); c->vertex(i)->point() = p; } const Point& point(Cell_handle c, int i) const { CGAL_triangulation_precondition(dimension() >= 0); CGAL_triangulation_precondition(i >= 0 && i <= dimension()); CGAL_triangulation_precondition(! is_infinite(c->vertex(i))); return c->vertex(i)->point(); } void set_point(Vertex_handle v, const Point& p) { CGAL_triangulation_precondition(dimension() >= 0); CGAL_triangulation_precondition(! is_infinite(v)); v->point() = p; } const Point& point(Vertex_handle v) const { CGAL_triangulation_precondition(number_of_vertices() > 0); CGAL_triangulation_precondition(! is_infinite(v)); return v->point(); } // TEST IF INFINITE FEATURES bool is_infinite(const Vertex_handle v) const { return v == infinite_vertex(); } bool is_infinite(const Cell_handle c) const { CGAL_triangulation_precondition(dimension() == 3); return c->has_vertex(infinite_vertex()); } bool is_infinite(const Cell_handle c, int i) const; bool is_infinite(const Facet& f) const { return is_infinite(f.first,f.second); } bool is_infinite(const Cell_handle c, int i, int j) const; bool is_infinite(const Edge& e) const { return is_infinite(e.first, e.second, e.third); } // QUERIES bool is_vertex(const Point& p, Vertex_handle& v) const; bool is_vertex(Vertex_handle v) const; bool is_edge(Vertex_handle u, Vertex_handle v, Cell_handle& c, int& i, int& j) const; bool is_facet(Vertex_handle u, Vertex_handle v, Vertex_handle w, Cell_handle& c, int& i, int& j, int& k) const; bool is_cell(Cell_handle c) const; bool is_cell(Vertex_handle u, Vertex_handle v, Vertex_handle w, Vertex_handle t, Cell_handle& c, int& i, int& j, int& k, int& l) const; bool is_cell(Vertex_handle u, Vertex_handle v, Vertex_handle w, Vertex_handle t, Cell_handle& c) const; bool has_vertex(const Facet& f, Vertex_handle v, int& j) const; bool has_vertex(Cell_handle c, int i, Vertex_handle v, int& j) const; bool has_vertex(const Facet& f, Vertex_handle v) const; bool has_vertex(Cell_handle c, int i, Vertex_handle v) const; bool are_equal(Cell_handle c, int i, Cell_handle n, int j) const; bool are_equal(const Facet& f, const Facet& g) const; bool are_equal(const Facet& f, Cell_handle n, int j) const; #ifdef CGAL_NO_STRUCTURAL_FILTERING Cell_handle locate(const Point& p, Locate_type& lt, int& li, int& lj, Cell_handle start = Cell_handle(), bool *could_lock_zone = nullptr) const; #else // no CGAL_NO_STRUCTURAL_FILTERING # ifndef CGAL_T3_STRUCTURAL_FILTERING_MAX_VISITED_CELLS # define CGAL_T3_STRUCTURAL_FILTERING_MAX_VISITED_CELLS 2500 # endif // no CGAL_T3_STRUCTURAL_FILTERING_MAX_VISITED_CELLS public: Cell_handle inexact_locate(const Point& p, Cell_handle start = Cell_handle(), int max_num_cells = CGAL_T3_STRUCTURAL_FILTERING_MAX_VISITED_CELLS, bool *could_lock_zone = nullptr) const; protected: Cell_handle exact_locate(const Point& p, Locate_type& lt, int& li, int& lj, Cell_handle start, bool *could_lock_zone = nullptr) const; Cell_handle generic_locate(const Point& p, Locate_type& lt, int& li, int& lj, Cell_handle start, internal::Structural_filtering_3_tag, bool *could_lock_zone = nullptr) const { Cell_handle ch = inexact_locate( p, start, CGAL_T3_STRUCTURAL_FILTERING_MAX_VISITED_CELLS, could_lock_zone); if(could_lock_zone && *could_lock_zone == false) return ch; // = Cell_handle() here else return exact_locate(p, lt, li, lj, ch, could_lock_zone); } Cell_handle generic_locate(const Point& p, Locate_type& lt, int& li, int& lj, Cell_handle start, internal::No_structural_filtering_3_tag, bool *could_lock_zone = nullptr) const { return exact_locate(p, lt, li, lj, start, could_lock_zone); } public: Orientation inexact_orientation(const Point& p, const Point& q, const Point& r, const Point& s) const { // So that this code works well with Lazy_kernel internal::Static_filters_predicates::Get_approx get_approx; const double px = to_double(get_approx(p).x()); const double py = to_double(get_approx(p).y()); const double pz = to_double(get_approx(p).z()); const double qx = to_double(get_approx(q).x()); const double qy = to_double(get_approx(q).y()); const double qz = to_double(get_approx(q).z()); const double rx = to_double(get_approx(r).x()); const double ry = to_double(get_approx(r).y()); const double rz = to_double(get_approx(r).z()); const double sx = to_double(get_approx(s).x()); const double sy = to_double(get_approx(s).y()); const double sz = to_double(get_approx(s).z()); const double pqx = qx - px; const double pqy = qy - py; const double pqz = qz - pz; const double prx = rx - px; const double pry = ry - py; const double prz = rz - pz; const double psx = sx - px; const double psy = sy - py; const double psz = sz - pz; const double det = determinant(pqx, pqy, pqz, prx, pry, prz, psx, psy, psz); if(det > 0) return POSITIVE; if(det < 0) return NEGATIVE; return ZERO; } public: Cell_handle locate(const Point& p, Locate_type& lt, int& li, int& lj, Cell_handle start = Cell_handle(), bool *could_lock_zone = nullptr) const { typedef Triangulation_structural_filtering_traits TSFT; typedef typename internal::Structural_filtering_selector_3< TSFT::Use_structural_filtering_tag::value >::Tag Should_filter_tag; return generic_locate(p, lt, li, lj, start, Should_filter_tag(), could_lock_zone); } #endif // no CGAL_NO_STRUCTURAL_FILTERING Cell_handle locate(const Point& p, Cell_handle start = Cell_handle(), bool *could_lock_zone = nullptr) const { Locate_type lt; int li, lj; return locate(p, lt, li, lj, start, could_lock_zone); } Cell_handle locate(const Point& p, Locate_type& lt, int& li, int& lj, Vertex_handle hint, bool *could_lock_zone = nullptr) const { return locate(p, lt, li, lj, hint == Vertex_handle() ? infinite_cell() : hint->cell(), could_lock_zone); } Cell_handle locate(const Point& p, Vertex_handle hint, bool *could_lock_zone = nullptr) const { return locate(p, hint == Vertex_handle() ? infinite_cell() : hint->cell(), could_lock_zone); } // PREDICATES ON POINTS ``TEMPLATED'' by the geom traits Bounded_side side_of_tetrahedron(const Point& p, const Point& p0, const Point& p1, const Point& p2, const Point& p3, Locate_type& lt, int& i, int& j) const; Bounded_side side_of_cell(const Point& p, Cell_handle c, Locate_type& lt, int& i, int& j) const; Bounded_side side_of_triangle(const Point& p, const Point& p0, const Point& p1, const Point& p2, Locate_type& lt, int& i, int& j) const; Bounded_side side_of_facet(const Point& p, Cell_handle c, Locate_type& lt, int& li, int& lj) const; Bounded_side side_of_facet(const Point& p, const Facet& f, Locate_type& lt, int& li, int& lj) const { CGAL_triangulation_precondition(f.second == 3); return side_of_facet(p, f.first, lt, li, lj); } Bounded_side side_of_segment(const Point& p, const Point& p0, const Point& p1, Locate_type& lt, int& i) const; Bounded_side side_of_edge(const Point& p, Cell_handle c, Locate_type& lt, int& li) const; Bounded_side side_of_edge(const Point& p, const Edge& e, Locate_type& lt, int& li) const { CGAL_triangulation_precondition(e.second == 0); CGAL_triangulation_precondition(e.third == 1); return side_of_edge(p, e.first, lt, li); } // Functions forwarded from TDS. int mirror_index(Cell_handle c, int i) const { return _tds.mirror_index(c, i); } Vertex_handle mirror_vertex(Cell_handle c, int i) const { return _tds.mirror_vertex(c, i); } Facet mirror_facet(Facet f) const { return _tds.mirror_facet(f);} // MODIFIERS bool flip(const Facet& f) { // Returns 'false' if the facet is not flippable // true other wise and // flips facet i of cell c // c will be replaced by one of the new cells return flip(f.first, f.second); } bool flip(Cell_handle c, int i); void flip_flippable(const Facet& f) { flip_flippable(f.first, f.second); } void flip_flippable(Cell_handle c, int i); bool flip(const Edge& e) { // returns false if the edge is not flippable // true otherwise and // flips edge i,j of cell c // c will be deleted return flip(e.first, e.second, e.third); } bool flip(Cell_handle c, int i, int j); void flip_flippable(const Edge& e) { flip_flippable(e.first, e.second, e.third); } void flip_flippable(Cell_handle c, int i, int j); //INSERTION Vertex_handle insert(const Point& p, Vertex_handle hint) { return insert(p, hint == Vertex_handle() ? infinite_cell() : hint->cell()); } Vertex_handle insert(const Point& p, Cell_handle start = Cell_handle()); Vertex_handle insert(const Point& p, Locate_type lt, Cell_handle c, int li, int lj); //protected: // internal methods template Vertex_handle insert_and_give_new_cells(const Point& p, OutputItCells fit, Cell_handle start = Cell_handle()); template Vertex_handle insert_and_give_new_cells(const Point& p, OutputItCells fit, Vertex_handle hint); template Vertex_handle insert_and_give_new_cells(const Point& p, Locate_type lt, Cell_handle c, int li, int lj, OutputItCells fit); template < class Conflict_tester, class Hidden_points_visitor > inline Vertex_handle insert_in_conflict(const Point& p, Locate_type lt, Cell_handle c, int li, int lj, const Conflict_tester& tester, Hidden_points_visitor& hider, bool *could_lock_zone = nullptr); #ifndef CGAL_TRIANGULATION_3_DONT_INSERT_RANGE_OF_POINTS_WITH_INFO template < class InputIterator > std::ptrdiff_t insert(InputIterator first, InputIterator last, typename boost::enable_if< boost::is_convertible< typename std::iterator_traits::value_type, Point > >::type* = nullptr) #else template < class InputIterator > std::ptrdiff_t insert(InputIterator first, InputIterator last) #endif //CGAL_TRIANGULATION_3_DONT_INSERT_RANGE_OF_POINTS_WITH_INFO { size_type n = number_of_vertices(); Vertex_handle hint; for(; first != last; ++first) hint = insert(*first, hint); return number_of_vertices() - n; } #ifndef CGAL_TRIANGULATION_3_DONT_INSERT_RANGE_OF_POINTS_WITH_INFO protected: //top stands for tuple-or-pair template const Point& top_get_first(const std::pair& pair) const { return pair.first; } template const Info& top_get_second(const std::pair& pair) const { return pair.second; } template const Point& top_get_first(const boost::tuple& tuple) const { return boost::get<0>(tuple); } template const Info& top_get_second(const boost::tuple& tuple) const { return boost::get<1>(tuple); } template std::ptrdiff_t insert_with_info(InputIterator first, InputIterator last) { size_type n = number_of_vertices(); std::vector indices; std::vector points; std::vector infos; for(InputIterator it=first;it!=last;++it) { Tuple_or_pair value=*it; points.push_back(top_get_first(value)); infos.push_back(top_get_second(value)); } Vertex_handle hint; for(std::size_t i=0; i < points.size(); ++i) { hint = insert(points[i], hint); if(hint != Vertex_handle()) hint->info() = infos[i]; } return number_of_vertices() - n; } public: template < class InputIterator > std::ptrdiff_t insert(InputIterator first, InputIterator last, typename boost::enable_if< boost::is_convertible< typename std::iterator_traits::value_type, std::pair::type> > >::type* =NULL) { return insert_with_info< std::pair::type> >(first,last); } template std::ptrdiff_t insert(boost::zip_iterator< boost::tuple > first, boost::zip_iterator< boost::tuple > last, typename boost::enable_if< boost::mpl::and_< boost::is_convertible< typename std::iterator_traits::value_type, Point >, boost::is_convertible< typename std::iterator_traits::value_type, typename internal::Info_check::type > > >::type* =NULL) { return insert_with_info< boost::tuple::type> >(first,last); } #endif //CGAL_TRIANGULATION_3_DONT_INSERT_RANGE_OF_POINTS_WITH_INFO Vertex_handle insert_in_cell(const Point& p, Cell_handle c); Vertex_handle insert_in_facet(const Point& p, Cell_handle c, int i); Vertex_handle insert_in_facet(const Point& p, const Facet& f) { return insert_in_facet(p, f.first, f.second); } Vertex_handle insert_in_edge(const Point& p, Cell_handle c, int i, int j); Vertex_handle insert_in_edge(const Point& p, const Edge& e) { return insert_in_edge(p, e.first, e.second, e.third); } Vertex_handle insert_outside_convex_hull(const Point& p, Cell_handle c); Vertex_handle insert_outside_affine_hull(const Point& p); template Vertex_handle insert_in_hole(const Point& p, CellIt cell_begin, CellIt cell_end, Cell_handle begin, int i) { // Some geometric preconditions should be tested... Vertex_handle v = _tds.insert_in_hole(cell_begin, cell_end, begin, i); v->set_point(p); return v; } template Vertex_handle insert_in_hole(const Point& p, CellIt cell_begin, CellIt cell_end, Cell_handle begin, int i, Vertex_handle newv) { // Some geometric preconditions should be tested... newv->set_point(p); return _tds.insert_in_hole(cell_begin, cell_end, begin, i, newv); } // Internal function, cells should already be marked. template Vertex_handle _insert_in_hole(const Point& p, CellIt cell_begin, CellIt cell_end, Cell_handle begin, int i) { // Some geometric preconditions should be tested... Vertex_handle v = _tds._insert_in_hole(cell_begin, cell_end, begin, i); v->set_point(p); return v; } // Internal function, cells should already be marked. template Vertex_handle _insert_in_small_hole(const Point& p, const Cells& cells, const Facets& facets ) { Vertex_handle v = _tds._insert_in_small_hole(cells, facets); v->set_point(p); return v; } // Internal function, cells should already be marked. template Vertex_handle _insert_in_hole(const Point& p, CellIt cell_begin, CellIt cell_end, Cell_handle begin, int i, Vertex_handle newv) { // Some geometric preconditions should be tested... newv->set_point(p); return _tds._insert_in_hole(cell_begin, cell_end, begin, i, newv); } protected: template < class InputIterator > bool does_repeat_in_range(InputIterator first, InputIterator beyond) const; template < class InputIterator > bool infinite_vertex_in_range(InputIterator first, InputIterator beyond) const; // - c is the current cell, which must be in conflict. // - tester is the function object that tests if a cell is in conflict. template Triple find_conflicts(Cell_handle d, const Conflict_test& tester, Triple it, bool *could_lock_zone = nullptr, const Facet *this_facet_must_be_in_the_cz = nullptr, bool *the_facet_is_in_its_cz = nullptr) const { CGAL_triangulation_precondition(dimension()>=2); if(the_facet_is_in_its_cz) *the_facet_is_in_its_cz = false; if(could_lock_zone) { *could_lock_zone = true; if(!this->try_lock_cell(d)) { *could_lock_zone = false; return it; } } CGAL_triangulation_precondition(tester(d)); // To store the boundary cells, in case we need to rollback typedef boost::container::small_vector SV; SV sv; std::stack cell_stack(sv); cell_stack.push(d); d->tds_data().mark_in_conflict(); *it.second++ = d; do { Cell_handle c = cell_stack.top(); cell_stack.pop(); // For each neighbor cell for(int i=0; ineighbor(i); // "test" is either in the conflict zone, // either facet-adjacent to the CZ if(test->tds_data().is_in_conflict()) { Facet f(c, i); // Internal facet. // Is it the facet where're looking for? if(this_facet_must_be_in_the_cz && the_facet_is_in_its_cz && f == *this_facet_must_be_in_the_cz) { *the_facet_is_in_its_cz = true; } if(c < test) { *it.third++ = f; } continue; // test was already in conflict. } if(test->tds_data().is_clear()) { if(tester(test)) { // "test" is in the conflict zone if(could_lock_zone) { if(!this->try_lock_cell(test)) { *could_lock_zone = false; // Unlock return it; } } Facet f(c, i); // Internal facet. // Is it the facet where're looking for? if(this_facet_must_be_in_the_cz && the_facet_is_in_its_cz && f == *this_facet_must_be_in_the_cz) { *the_facet_is_in_its_cz = true; } if(c < test) { *it.third++ = f; } cell_stack.push(test); test->tds_data().mark_in_conflict(); *it.second++ = test; continue; } test->tds_data().mark_on_boundary(); } Facet f(c, i); // Boundary facet. // Is it the facet where're looking for? if(this_facet_must_be_in_the_cz && the_facet_is_in_its_cz && (mirror_facet(f) == *this_facet_must_be_in_the_cz || f == *this_facet_must_be_in_the_cz)) { *the_facet_is_in_its_cz = true; } *it.first++ = f; } } while(!cell_stack.empty()); return it; } // This one takes a function object to recursively determine the cells in // conflict, then calls _tds._insert_in_hole(). template < class Conflict_test > Vertex_handle insert_conflict(Cell_handle c, const Conflict_test& tester) { CGAL_triangulation_precondition(dimension() >= 2); CGAL_triangulation_precondition(c != Cell_handle()); CGAL_triangulation_precondition(tester(c)); std::vector cells; cells.reserve(32); Facet facet; // Find the cells in conflict switch(dimension()) { case 3: find_conflicts(c, tester, make_triple(Oneset_iterator(facet), std::back_inserter(cells), Emptyset_iterator())); break; case 2: find_conflicts(c, tester, make_triple(Oneset_iterator(facet), std::back_inserter(cells), Emptyset_iterator())); } // Create the new cells and delete the old. return _tds._insert_in_hole(cells.begin(), cells.end(), facet.first, facet.second); } private: // Here are the conflit tester function objects passed to // insert_conflict_[23]() by insert_outside_convex_hull(). class Conflict_tester_outside_convex_hull_3 { const Point& p; const Self *t; public: Conflict_tester_outside_convex_hull_3(const Point& pt, const Self *tr) : p(pt), t(tr) {} bool operator()(const Cell_handle c) const { Locate_type loc; int i, j; return t->side_of_cell(p, c, loc, i, j) == ON_BOUNDED_SIDE; } }; class Conflict_tester_outside_convex_hull_2 { const Point& p; const Self *t; public: Conflict_tester_outside_convex_hull_2(const Point& pt, const Self *tr) : p(pt), t(tr) {} bool operator()(const Cell_handle c) const { Locate_type loc; int i, j; return t->side_of_facet(p, c, loc, i, j) == ON_BOUNDED_SIDE; } }; protected: // no point being private, we might need to test whether a displacement // decreases the dimension on others inherited triangulations bool test_dim_down(Vertex_handle v) const; bool test_dim_down_using_incident_cells_3(Vertex_handle v, std::vector& incident_cells, std::vector& adj_vertices, bool *could_lock_zone = nullptr) const; // REMOVAL template < class VertexRemover > void remove(Vertex_handle v, VertexRemover& remover); // Concurrency-safe version // Pre-condition: dimension = 3 // The return value is only meaningful if *could_lock_zone = true: // * returns true if the vertex was removed // * returns false if the vertex wasn't removed since it would decrease // the dimension => needs to be done sequentially template < class VertexRemover > bool remove(Vertex_handle v, VertexRemover& remover, bool *could_lock_zone); template < class VertexRemover, class OutputItCells > void remove_and_give_new_cells(Vertex_handle v, VertexRemover& remover, OutputItCells fit); // This function removes a batch of points at once. // If points are grouped in cluster, the performance is increased // compared to removing one by one. // For now, this function is only guaranteed for Delaunay triangulations (or Regular as Delaunay). // By doing these kind of remove followed by inserting the cluster, // we achieve fast relocations for a batch of points (in a Delaunay triangulation). template < class InputIterator, class VertexRemover > size_type remove(InputIterator first, InputIterator beyond, VertexRemover& remover); enum REMOVE_VERTEX_STATE {CLEAR, TO_REMOVE, PROCESSED, EXTREMITY}; // MOVE template < class VertexRemover, class VertexInserter > Vertex_handle move_if_no_collision(Vertex_handle v, const Point& p, VertexRemover& remover, VertexInserter& inserter); template < class VertexRemover, class VertexInserter > Vertex_handle move(Vertex_handle v, const Point& p, VertexRemover& remover, VertexInserter& inserter); // move and give new cells template < class VertexRemover, class VertexInserter, class OutputItCells > Vertex_handle move_if_no_collision_and_give_new_cells(Vertex_handle v, const Point& p, VertexRemover& remover, VertexInserter& inserter, OutputItCells fit); // This is a function better suited for tds // but because it is not required in the model of tds // at this time, it should be implemented here. void flip_2D(Cell_handle f, int i) { CGAL_triangulation_precondition(dimension()==2); Cell_handle n = f->neighbor(i); int ni = this->_tds.mirror_index(f,i); // ni = n->index(f); int cwi = (i+2)%3; int ccwi = (i+1)%3; int cwni = (ni+2)%3; int ccwni = (ni+1)%3; Vertex_handle v_cw = f->vertex(cwi); Vertex_handle v_ccw = f->vertex(ccwi); // bl == bottom left, tr == top right Cell_handle tr = f->neighbor(ccwi); int tri = this->_tds.mirror_index(f,ccwi); Cell_handle bl = n->neighbor(ccwni); int bli = this->_tds.mirror_index(n,ccwni); f->set_vertex(cwi, n->vertex(ni)); n->set_vertex(cwni, f->vertex(i)); // update the neighborhood relations this->_tds.set_adjacency(f, i, bl, bli); this->_tds.set_adjacency(f, ccwi, n, ccwni); this->_tds.set_adjacency(n, ni, tr, tri); if(v_cw->cell() == f) { v_cw->set_cell(n); } if(v_ccw->cell() == n) { v_ccw->set_cell(f); } } template < class VertexRemover, class VertexInserter > void restore_edges_after_decrease_dimension(Vertex_handle v, VertexRemover& remover, VertexInserter& inserter) { Cell_handle fkstart = v->cell(); Cell_handle start = fkstart->neighbor(fkstart->index(v)); std::list hole; make_hole_2D(v, hole, remover); fill_hole_2D(hole, remover); // make hole here will work if the link of v is a valid triangulation // the aim here is Delaunay triangulations // to make it more general one could have an internal function here // to remove v without touching its handle // This insert must be from Delaunay (or the particular trian.) // not the basic Triangulation_3. // Here we correct the recent triangulation (with decreased dimension) formed // in particular here a 2D (from 3D to 2D displacement) Vertex_handle inserted = inserter.insert(v->point(), start); // fixing pointer Cell_handle fc = inserted->cell(), done(fc); std::vector faces_pt; faces_pt.reserve(16); do { faces_pt.push_back(fc); fc = fc->neighbor((fc->index(inserted) + 1)%3); } while(fc != done); std::size_t ss = faces_pt.size(); for(std::size_t k=0; kindex(inserted); f->set_vertex(i, v); } v->set_cell(inserted->cell()); tds().delete_vertex(inserted); } private: typedef Facet Edge_2D; typedef Triple Vertex_triple; typedef typename Base::template Vertex_triple_Facet_map_generator< Vertex_triple, Facet>::type Vertex_triple_Facet_map; typedef typename Base::template Vertex_handle_unique_hash_map_generator< Vertex_handle>::type Vertex_handle_unique_hash_map; Vertex_triple make_vertex_triple(const Facet& f) const; void make_canonical_oriented_triple(Vertex_triple& t) const; template < class VertexRemover > VertexRemover& make_hole_2D(Vertex_handle v, std::list& hole, VertexRemover& remover); template < class VertexRemover > VertexRemover& make_hole_2D(Vertex_handle v, std::list& hole, VertexRemover& remover, std::set& cells_set); template < class VertexRemover > void fill_hole_2D(std::list& hole, VertexRemover& remover); void make_hole_3D(Vertex_handle v, Vertex_triple_Facet_map& outer_map, std::vector& hole); // When the incident cells are already known void make_hole_3D(Vertex_handle v, const std::vector& incident_cells, Vertex_triple_Facet_map& outer_map); template < class VertexRemover > VertexRemover& remove_dim_down(Vertex_handle v, VertexRemover& remover); template < class VertexRemover > VertexRemover& remove_1D(Vertex_handle v, VertexRemover& remover); template < class VertexRemover > VertexRemover& remove_2D(Vertex_handle v, VertexRemover& remover); template < class VertexRemover > VertexRemover& remove_3D(Vertex_handle v, VertexRemover& remover); // Version of remove_3D if the incident cells and the adjacent vertices // are already known template < class VertexRemover > VertexRemover& remove_3D(Vertex_handle v, VertexRemover& remover, const std::vector& inc_cells, std::vector& adj_vertices); template < class VertexRemover, class OutputItCells > VertexRemover& remove_dim_down(Vertex_handle v, VertexRemover& remover, OutputItCells fit); template < class VertexRemover, class OutputItCells > VertexRemover& remove_1D(Vertex_handle v, VertexRemover& remover, OutputItCells fit); template < class VertexRemover, class OutputItCells > VertexRemover& remove_2D(Vertex_handle v, VertexRemover& remover, OutputItCells fit); template < class VertexRemover, class OutputItCells > VertexRemover& remove_3D(Vertex_handle v, VertexRemover& remover, OutputItCells fit); template < class VertexRemover, class OutputItCells > void fill_hole_2D(std::list& hole, VertexRemover& remover, OutputItCells fit); // They access "Self", so need to be friend. friend class Conflict_tester_outside_convex_hull_3; friend class Conflict_tester_outside_convex_hull_2; friend class Infinite_tester; friend class Finite_vertices_iterator; friend class Finite_cells_iterator; // remove cluster template < class InputIterator > void _mark_vertices_to_remove(InputIterator first, InputIterator beyond, std::map& vstates) const { while(first != beyond) vstates[*first++] = TO_REMOVE; } bool _test_dim_down_cluster(std::map& vstates) const { // tests whether removing the cluster of vertices // marked as "to remove", decreases the dimension of the triangulation CGAL_triangulation_precondition(dimension() == 3); int k=0; Vertex_handle v[4]; for(Finite_vertices_iterator fit = finite_vertices_begin(); fit != finite_vertices_end(); ++fit) { if(vstates[fit] == TO_REMOVE) continue; v[k++] = fit; if(k == 4) { if(!coplanar(v[0]->point(), v[1]->point(), v[2]->point(), v[3]->point())) return false; k--; } } return k < 4; } template < class InputIterator, class VertexRemover > bool _remove_cluster_3D(InputIterator first, InputIterator beyond, VertexRemover& remover, std::map& vstates); void _make_big_hole_3D(Vertex_handle v, std::map& outer_map, std::vector& hole, std::vector& vertices, std::map& vstates); public: //TRAVERSING : ITERATORS AND CIRCULATORS Finite_cells_iterator finite_cells_begin() const { if(dimension() < 3) return finite_cells_end(); return CGAL::filter_iterator(cells_end(), Infinite_tester(this), cells_begin()); } Finite_cells_iterator finite_cells_end() const { return CGAL::filter_iterator(cells_end(), Infinite_tester(this)); } Finite_cell_handles finite_cell_handles() const { return make_prevent_deref_range(finite_cells_begin(), finite_cells_end()); } Cell_iterator cells_begin() const { return _tds.cells_begin(); } Cell_iterator cells_end() const { return _tds.cells_end(); } All_cells_iterator all_cells_begin() const { return _tds.cells_begin(); } All_cells_iterator all_cells_end() const { return _tds.cells_end(); } All_cell_handles all_cell_handles() const { return _tds.cell_handles(); } Finite_vertices_iterator finite_vertices_begin() const { if(number_of_vertices() <= 0) return finite_vertices_end(); return CGAL::filter_iterator(vertices_end(), Infinite_tester(this), vertices_begin()); } Finite_vertices_iterator finite_vertices_end() const { return CGAL::filter_iterator(vertices_end(), Infinite_tester(this)); } Finite_vertex_handles finite_vertex_handles() const { return make_prevent_deref_range(finite_vertices_begin(), finite_vertices_end()); } Vertex_iterator vertices_begin() const { return _tds.vertices_begin(); } Vertex_iterator vertices_end() const { return _tds.vertices_end(); } All_vertices_iterator all_vertices_begin() const { return _tds.vertices_begin(); } All_vertices_iterator all_vertices_end() const { return _tds.vertices_end(); } All_vertex_handles all_vertex_handles() const { return _tds.vertex_handles(); } Finite_edges_iterator finite_edges_begin() const { if(dimension() < 1) return finite_edges_end(); return CGAL::filter_iterator(edges_end(), Infinite_tester(this), edges_begin()); } Finite_edges_iterator finite_edges_end() const { return CGAL::filter_iterator(edges_end(), Infinite_tester(this)); } Finite_edges finite_edges() const { return Finite_edges(finite_edges_begin(),finite_edges_end()); } Edge_iterator edges_begin() const { return _tds.edges_begin(); } Edge_iterator edges_end() const { return _tds.edges_end(); } All_edges_iterator all_edges_begin() const { return _tds.edges_begin(); } All_edges_iterator all_edges_end() const { return _tds.edges_end(); } All_edges all_edges() const { return _tds.edges(); } Finite_facets_iterator finite_facets_begin() const { if(dimension() < 2) return finite_facets_end(); return CGAL::filter_iterator(facets_end(), Infinite_tester(this), facets_begin()); } Finite_facets_iterator finite_facets_end() const { return CGAL::filter_iterator(facets_end(), Infinite_tester(this)); } Finite_facets finite_facets() const { return Finite_facets(finite_facets_begin(),finite_facets_end()); } Facet_iterator facets_begin() const { return _tds.facets_begin(); } Facet_iterator facets_end() const { return _tds.facets_end(); } All_facets_iterator all_facets_begin() const { return _tds.facets_begin(); } All_facets_iterator all_facets_end() const { return _tds.facets_end(); } All_facets all_facets() const { return _tds.facets(); } Point_iterator points_begin() const { return Point_iterator(finite_vertices_begin()); } Point_iterator points_end() const { return Point_iterator(finite_vertices_end()); } Points points() const { return Points(points_begin(),points_end()); } // cells around an edge Cell_circulator incident_cells(const Edge& e) const { return _tds.incident_cells(e); } Cell_circulator incident_cells(Cell_handle c, int i, int j) const { return _tds.incident_cells(c, i, j); } Cell_circulator incident_cells(const Edge& e, Cell_handle start) const { return _tds.incident_cells(e, start); } Cell_circulator incident_cells(Cell_handle c, int i, int j, Cell_handle start) const { return _tds.incident_cells(c, i, j, start); } // facets around an edge Facet_circulator incident_facets(const Edge& e) const { return _tds.incident_facets(e); } Facet_circulator incident_facets(Cell_handle c, int i, int j) const { return _tds.incident_facets(c, i, j); } Facet_circulator incident_facets(const Edge& e, const Facet& start) const { return _tds.incident_facets(e, start); } Facet_circulator incident_facets(Cell_handle c, int i, int j, const Facet& start) const { return _tds.incident_facets(c, i, j, start); } Facet_circulator incident_facets(const Edge& e, Cell_handle start, int f) const { return _tds.incident_facets(e, start, f); } Facet_circulator incident_facets(Cell_handle c, int i, int j, Cell_handle start, int f) const { return _tds.incident_facets(c, i, j, start, f); } // around a vertex class Finite_filter { const Self* t; public: Finite_filter(const Self* _t): t(_t) {} template bool operator() (const T& e) const { return t->is_infinite(e); } }; class Finite_filter_2D { const Self* t; public: Finite_filter_2D(const Self* _t): t(_t) {} template bool operator() (const T& e) const { return t->is_infinite(e); } bool operator() (const Cell_handle c) { return t->is_infinite(c, 3); } }; template OutputIterator incident_cells(Vertex_handle v, OutputIterator cells) const { return _tds.incident_cells(v, cells); } template void incident_cells_threadsafe(Vertex_handle v, OutputIterator cells) const { _tds.incident_cells_threadsafe(v, cells); } template void incident_cells_threadsafe(Vertex_handle v, OutputIterator cells, const Filter& filter) const { _tds.incident_cells_threadsafe(v, cells, filter); } bool try_lock_and_get_incident_cells(Vertex_handle v, std::vector& cells) const { // We need to lock v individually first, to be sure v->cell() is valid if(!this->try_lock_vertex(v)) return false; Cell_handle d = v->cell(); if(!this->try_lock_cell(d)) // LOCK return false; cells.push_back(d); d->tds_data().mark_in_conflict(); int head=0; int tail=1; do { Cell_handle c = cells[head]; for(int i=0; i<4; ++i) { if(c->vertex(i) == v) continue; Cell_handle next = c->neighbor(i); if(!this->try_lock_cell(next)) // LOCK { for(Cell_handle ch : cells) { ch->tds_data().clear(); } cells.clear(); return false; } if(! next->tds_data().is_clear()) continue; cells.push_back(next); ++tail; next->tds_data().mark_in_conflict(); } ++head; } while(head != tail); for(Cell_handle ch : cells) { ch->tds_data().clear(); } return true; } template bool try_lock_and_get_adjacent_vertices_and_cells_3(Vertex_handle v, OutputIterator vertices, std::vector& cells) const { // We need to lock v individually first, to be sure v->cell() is valid if(!this->try_lock_vertex(v)) return false; Cell_handle d = v->cell(); if(!this->try_lock_cell(d)) // LOCK return false; cells.push_back(d); d->tds_data().mark_in_conflict(); int head=0; int tail=1; do { Cell_handle c = cells[head]; for(int i=0; i<4; ++i) { if(c->vertex(i) == v) continue; Cell_handle next = c->neighbor(i); if(!this->try_lock_cell(next)) // LOCK { for(Cell_handle ch : cells) { ch->tds_data().clear(); } cells.clear(); return false; } if(! next->tds_data().is_clear()) continue; cells.push_back(next); ++tail; next->tds_data().mark_in_conflict(); } ++head; } while(head != tail); std::set tmp_vertices; for(Cell_handle ch : cells) { ch->tds_data().clear(); for(int i = 0; i < 4; ++i) { Vertex_handle w = ch->vertex(i); if(w != v && tmp_vertices.insert(w).second) { *vertices = w; } } } return true; } template OutputIterator finite_incident_cells(Vertex_handle v, OutputIterator cells) const { if(dimension() == 2) return _tds.incident_cells(v, cells, Finite_filter_2D(this)); return _tds.incident_cells(v, cells, Finite_filter(this)); } template OutputIterator incident_facets(Vertex_handle v, OutputIterator facets) const { return _tds.incident_facets(v, facets); } template OutputIterator finite_incident_facets(Vertex_handle v, OutputIterator facets) const { return _tds.incident_facets(v, facets, Finite_filter(this)); } template OutputIterator incident_facets_threadsafe(Vertex_handle v, OutputIterator facets) const { return _tds.incident_facets_threadsafe(v, facets); } template OutputIterator finite_incident_facets_threadsafe(Vertex_handle v, OutputIterator facets) const { return _tds.incident_facets_threadsafe(v, facets, Finite_filter(this)); } // old name (up to CGAL 3.4) // kept for backwards compatibility but not documented template OutputIterator incident_vertices(Vertex_handle v, OutputIterator vertices) const { return _tds.adjacent_vertices(v, vertices); } // correct name template OutputIterator adjacent_vertices(Vertex_handle v, OutputIterator vertices) const { return _tds.adjacent_vertices(v, vertices); } template OutputIterator adjacent_vertices_threadsafe(Vertex_handle v, OutputIterator vertices) const { return _tds.adjacent_vertices_threadsafe(v, vertices); } template OutputIterator adjacent_vertices_and_cells_3(Vertex_handle v, OutputIterator vertices, std::vector& cells) const { return _tds.adjacent_vertices_and_cells_3(v, vertices, cells); } // old name (up to CGAL 3.4) // kept for backwards compatibility but not documented template OutputIterator finite_incident_vertices(Vertex_handle v, OutputIterator vertices) const { return _tds.adjacent_vertices(v, vertices, Finite_filter(this)); } // correct name template OutputIterator finite_adjacent_vertices(Vertex_handle v, OutputIterator vertices) const { return _tds.adjacent_vertices(v, vertices, Finite_filter(this)); } template OutputIterator incident_edges(Vertex_handle v, OutputIterator edges) const { return _tds.incident_edges(v, edges); } template OutputIterator finite_incident_edges(Vertex_handle v, OutputIterator edges) const { return _tds.incident_edges(v, edges, Finite_filter(this)); } template OutputIterator incident_edges_threadsafe(Vertex_handle v, OutputIterator edges) const { return _tds.incident_edges_threadsafe(v, edges); } template OutputIterator finite_incident_edges_threadsafe(Vertex_handle v, OutputIterator edges) const { return _tds.incident_edges_threadsafe(v, edges, Finite_filter(this)); } size_type degree(Vertex_handle v) const { return _tds.degree(v); } // CHECKING bool is_valid(bool verbose = false, int level = 0) const; bool is_valid(Cell_handle c, bool verbose = false, int level = 0) const; bool is_valid_finite(Cell_handle c, bool verbose = false, int level=0) const; //IO template std::istream& file_input(std::istream& is, ConvertVertex convert_vertex = ConvertVertex(), ConvertCell convert_cell = ConvertCell()) { // reads // the dimension // the number of finite vertices // the non combinatorial information on vertices (point, etc) // the number of cells // the cells by the indices of their vertices in the preceding list // of vertices, plus the non combinatorial information on each cell // the neighbors of each cell by their index in the preceding list of cells // when dimension < 3 : the same with faces of maximal dimension // If this is used for a TDS, the vertices are processed from 0 to n. // Else, we make V[0] the infinite vertex and work from 1 to n+1. typedef Self Triangulation; typedef typename Triangulation::Vertex_handle Vertex_handle; typedef typename Triangulation::Cell_handle Cell_handle; typedef typename Tr_src::Vertex Vertex1; typedef typename Tr_src::Cell Cell1; clear(); tds().cells().clear(); std::size_t n; int d; if(is_ascii(is)) is >> d >> n; else { read(is, d); read(is, n); } if(!is) return is; tds().set_dimension(d); std::size_t V_size = n+1; std::vector< Vertex_handle > V(V_size); // the infinite vertex is numbered 0 V[0] = infinite_vertex(); for (std::size_t i = 1; i < V_size; ++i) { Vertex1 v; if(!(is >> v)) return is; Vertex_handle vh=tds().create_vertex( convert_vertex(v) ); V[i] = vh; convert_vertex(v, *V[i]); } std::vector< Cell_handle > C; std::size_t m; tds().read_cells(is, V, m, C); for (std::size_t j=0 ; j < m; j++) { Cell1 c; if(!(is >> c)) return is; convert_cell(c, *C[j]); } CGAL_triangulation_assertion( is_valid(false) ); return is; } }; template < class GT, class Tds, class Lds > std::istream& operator>> (std::istream& is, Triangulation_3& tr) { // Reads: // - the dimension // - the number of finite vertices // - the non combinatorial information on vertices (point, etc) // - the number of cells // - the cells by the indices of their vertices in the preceding list // of vertices, plus the non combinatorial information on each cell // - the neighbors of each cell by their index in the preceding list of cells // - when dimension < 3 : the same with faces of maximal dimension typedef Triangulation_3 Triangulation; typedef typename Triangulation::Vertex_handle Vertex_handle; typedef typename Triangulation::Cell_handle Cell_handle; tr._tds.clear(); // infinite vertex deleted tr.infinite = tr._tds.create_vertex(); std::size_t n; int d; if(is_ascii(is)) { is >> d >> n; } else { read(is, d); read(is, n); } if(!is) return is; tr._tds.set_dimension(d); std::vector< Vertex_handle > V(n+1); V[0] = tr.infinite_vertex(); // the infinite vertex is numbered 0 for(std::size_t i=1; i <= n; i++) { V[i] = tr._tds.create_vertex(); if(!(is >> *V[i])) return is; } std::vector< Cell_handle > C; std::size_t m; tr._tds.read_cells(is, V, m, C); for(std::size_t j=0 ; j < m; j++) if(!(is >> *(C[j]))) return is; CGAL_triangulation_assertion(tr.is_valid(false)); return is; } template < class GT, class Tds, class Lds > std::ostream& operator<< (std::ostream& os, const Triangulation_3& tr) { // Writes: // - the dimension // - the number of finite vertices // - the non combinatorial information on vertices (point, etc) // - the number of cells // - the cells by the indices of their vertices in the preceding list // of vertices, plus the non combinatorial information on each cell // - the neighbors of each cell by their index in the preceding list of cells // - when dimension < 3 : the same with faces of maximal dimension typedef Triangulation_3 Triangulation; typedef typename Triangulation::size_type size_type; typedef typename Triangulation::Vertex_handle Vertex_handle; typedef typename Triangulation::Vertex_iterator Vertex_iterator; typedef typename Triangulation::Cell_iterator Cell_iterator; typedef typename Triangulation::Edge_iterator Edge_iterator; typedef typename Triangulation::Facet_iterator Facet_iterator; // outputs dimension and number of vertices size_type n = tr.number_of_vertices(); if(is_ascii(os)) { os << tr.dimension() << std::endl << n << std::endl; } else { write(os, tr.dimension()); write(os, n); } if(n == 0) return os; std::vector TV(n+1); size_type i = 0; // write the vertices for(Vertex_iterator it = tr.vertices_begin(), end = tr.vertices_end(); it != end; ++it) TV[i++] = it; CGAL_triangulation_assertion(i == n+1); CGAL_triangulation_assertion(tr.is_infinite(TV[0])); Unique_hash_map V; V[tr.infinite_vertex()] = 0; for(i=1; i <= n; i++) { os << *TV[i]; V[TV[i]] = i; if(is_ascii(os)) os << std::endl; } // Asks the tds for the combinatorial information tr.tds().print_cells(os, V); // Write the non combinatorial information on the cells // using the << operator of Cell. // Works because the iterator of the tds traverses the cells in the // same order as the iterator of the triangulation switch(tr.dimension()) { case 3: { for(Cell_iterator it = tr.cells_begin(), end = tr.cells_end(); it != end; ++it) { os << *it; // other information if(is_ascii(os)) os << std::endl; } break; } case 2: { for(Facet_iterator it = tr.facets_begin(), end = tr.facets_end(); it != end; ++it) { os << *((*it).first); // other information if(is_ascii(os)) os << std::endl; } break; } case 1: { for(Edge_iterator it = tr.edges_begin(), end = tr.edges_end(); it != end; ++it) { os << *((*it).first); // other information if(is_ascii(os)) os << std::endl; } break; } } return os ; } template < class GT, class Tds, class Lds > typename Triangulation_3::size_type Triangulation_3:: number_of_finite_cells() const { if(dimension() < 3) return 0; return std::distance(finite_cells_begin(), finite_cells_end()); } template < class GT, class Tds, class Lds > typename Triangulation_3::size_type Triangulation_3:: number_of_cells() const { return _tds.number_of_cells(); } template < class GT, class Tds, class Lds > typename Triangulation_3::size_type Triangulation_3:: number_of_finite_facets() const { if(dimension() < 2) return 0; return std::distance(finite_facets_begin(), finite_facets_end()); } template < class GT, class Tds, class Lds > typename Triangulation_3::size_type Triangulation_3:: number_of_facets() const { return _tds.number_of_facets(); } template < class GT, class Tds, class Lds > typename Triangulation_3::size_type Triangulation_3:: number_of_finite_edges() const { if(dimension() < 1) return 0; return std::distance(finite_edges_begin(), finite_edges_end()); } template < class GT, class Tds, class Lds > typename Triangulation_3::size_type Triangulation_3:: number_of_edges() const { return _tds.number_of_edges(); } template < class GT, class Tds, class Lds > typename Triangulation_3::Triangle Triangulation_3:: triangle(const Cell_handle c, int i) const { CGAL_triangulation_precondition(dimension() == 2 || dimension() == 3); CGAL_triangulation_precondition((dimension() == 2 && i == 3) || (dimension() == 3 && i >= 0 && i <= 3)); CGAL_triangulation_precondition(! is_infinite(Facet(c, i))); if((i&1)==0) return construct_triangle(c->vertex((i+2)&3)->point(), c->vertex((i+1)&3)->point(), c->vertex((i+3)&3)->point()); return construct_triangle(c->vertex((i+1)&3)->point(), c->vertex((i+2)&3)->point(), c->vertex((i+3)&3)->point()); } template < class GT, class Tds, class Lds > typename Triangulation_3::Segment Triangulation_3:: segment(const Cell_handle c, int i, int j) const { CGAL_triangulation_precondition(i != j); CGAL_triangulation_precondition(dimension() >= 1 && dimension() <= 3); CGAL_triangulation_precondition(i >= 0 && i <= dimension() && j >= 0 && j <= dimension()); CGAL_triangulation_precondition(! is_infinite(Edge(c, i, j))); return construct_segment(c->vertex(i)->point(), c->vertex(j)->point()); } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: is_infinite(const Cell_handle c, int i) const { CGAL_triangulation_precondition(dimension() == 2 || dimension() == 3); CGAL_triangulation_precondition((dimension() == 2 && i == 3) || (dimension() == 3 && i >= 0 && i <= 3)); return is_infinite(c->vertex(i<=0 ? 1 : 0)) || is_infinite(c->vertex(i<=1 ? 2 : 1)) || is_infinite(c->vertex(i<=2 ? 3 : 2)); } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: is_infinite(const Cell_handle c, int i, int j) const { CGAL_triangulation_precondition(i != j); CGAL_triangulation_precondition(dimension() >= 1 && dimension() <= 3); CGAL_triangulation_precondition(i >= 0 && i <= dimension() && j >= 0 && j <= dimension()); return is_infinite(c->vertex(i)) || is_infinite(c->vertex(j)); } template < class GT, class Tds, class Lds > bool Triangulation_3:: is_vertex(const Point& p, Vertex_handle& v) const { Locate_type lt; int li, lj; Cell_handle c = locate(p, lt, li, lj); if(lt != VERTEX) return false; v = c->vertex(li); return true; } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: is_vertex(Vertex_handle v) const { return _tds.is_vertex(v); } template < class GT, class Tds, class Lds > bool Triangulation_3:: is_edge(Vertex_handle u, Vertex_handle v, Cell_handle& c, int& i, int& j) const { return _tds.is_edge(u, v, c, i, j); } template < class GT, class Tds, class Lds > bool Triangulation_3:: is_facet(Vertex_handle u, Vertex_handle v, Vertex_handle w, Cell_handle& c, int& i, int& j, int& k) const { return _tds.is_facet(u, v, w, c, i, j, k); } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: is_cell(Cell_handle c) const { return _tds.is_cell(c); } template < class GT, class Tds, class Lds > bool Triangulation_3:: is_cell(Vertex_handle u, Vertex_handle v, Vertex_handle w, Vertex_handle t, Cell_handle& c, int& i, int& j, int& k, int& l) const { return _tds.is_cell(u, v, w, t, c, i, j, k, l); } template < class GT, class Tds, class Lds > bool Triangulation_3:: is_cell(Vertex_handle u, Vertex_handle v, Vertex_handle w, Vertex_handle t, Cell_handle& c) const { int i,j,k,l; return _tds.is_cell(u, v, w, t, c, i, j, k, l); } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: has_vertex(const Facet& f, Vertex_handle v, int& j) const { return _tds.has_vertex(f.first, f.second, v, j); } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: has_vertex(Cell_handle c, int i, Vertex_handle v, int& j) const { return _tds.has_vertex(c, i, v, j); } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: has_vertex(const Facet& f, Vertex_handle v) const { return _tds.has_vertex(f.first, f.second, v); } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: has_vertex(Cell_handle c, int i, Vertex_handle v) const { return _tds.has_vertex(c, i, v); } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: are_equal(Cell_handle c, int i, Cell_handle n, int j) const { return _tds.are_equal(c, i, n, j); } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: are_equal(const Facet& f, const Facet& g) const { return _tds.are_equal(f.first, f.second, g.first, g.second); } template < class GT, class Tds, class Lds > inline bool Triangulation_3:: are_equal(const Facet& f, Cell_handle n, int j) const { return _tds.are_equal(f.first, f.second, n, j); } template < class GT, class Tds, class Lds > typename Triangulation_3::Cell_handle Triangulation_3:: #ifdef CGAL_NO_STRUCTURAL_FILTERING locate(const Point& p, Locate_type& lt, int& li, int& lj, Cell_handle start, bool *could_lock_zone) const #else exact_locate(const Point& p, Locate_type& lt, int& li, int& lj, Cell_handle start, bool *could_lock_zone) const #endif { // Returns the (finite or infinite) cell p lies in. // Starts at cell "start". // If lt == OUTSIDE_CONVEX_HULL, li is the index of a facet separating p // from the rest of the triangulation // In dimension 2 : // returns a facet (Cell_handle,li) if lt == FACET // returns an edge (Cell_handle,li,lj) if lt == EDGE // returns a vertex (Cell_handle,li) if lt == VERTEX // If lt == OUTSIDE_CONVEX_HULL, li, lj gives the edge of c separating p // from the rest of the triangulation // lt = OUTSIDE_AFFINE_HULL if p is not coplanar with the triangulation CGAL_triangulation_expensive_assertion(start == Cell_handle() || tds().is_simplex(start)); if(could_lock_zone) *could_lock_zone = true; if(dimension() >= 1) { // Make sure we continue from here with a finite cell. if(start == Cell_handle()) start = infinite_cell(); int ind_inf; if(start->has_vertex(infinite, ind_inf)) start = start->neighbor(ind_inf); } boost::rand48 rng; switch(dimension()) { case 3: { CGAL_triangulation_precondition(start != Cell_handle()); CGAL_triangulation_precondition(! start->has_vertex(infinite)); // We implement the remembering visibility/stochastic walk. // Remembers the previous cell to avoid useless orientation tests. Cell_handle previous = Cell_handle(); Cell_handle c = start; if(could_lock_zone) { if(!this->try_lock_cell(c)) { *could_lock_zone = false; return Cell_handle(); } } // Stores the results of the 4 orientation tests. It will be used // at the end to decide if p lies on a face/edge/vertex/interior. Orientation o[4]; boost::uniform_smallint<> four(0, 3); boost::variate_generator > die4(rng, four); // Now treat the cell c. bool try_next_cell = true; while(try_next_cell) { try_next_cell = false; // We know that the 4 vertices of c are positively oriented. // So, in order to test if p is seen outside from one of c's facets, // we just replace the corresponding point by p in the orientation // test. We do this using the array below. const Point* pts[4] = { &(c->vertex(0)->point()), &(c->vertex(1)->point()), &(c->vertex(2)->point()), &(c->vertex(3)->point()) }; // For the remembering stochastic walk, // we need to start trying with a random index : int i = die4(); // For the remembering visibility walk (Delaunay and Regular only), we don't : // int i = 0; // for each vertex for(int j=0; !try_next_cell && j != 4; ++j, i = (i+1)&3) { Cell_handle next = c->neighbor(i); if(previous == next) { o[i] = POSITIVE; } else { // We temporarily put p at i's place in pts. const Point* backup = pts[i]; pts[i] = &p; o[i] = orientation(*pts[0], *pts[1], *pts[2], *pts[3]); if(o[i] != NEGATIVE) { pts[i] = backup; } else { if(next->has_vertex(infinite, li)) { // We are outside the convex hull. lt = OUTSIDE_CONVEX_HULL; return next; } previous = c; c = next; if(could_lock_zone) { //previous->unlock(); // DON'T do that, "c" may be in // the same locking cell as "previous" if(!this->try_lock_cell(c)) { *could_lock_zone = false; return Cell_handle(); } } try_next_cell = true; } } } // next vertex } // next cell // now p is in c or on its boundary int sum =(o[0] == COPLANAR) +(o[1] == COPLANAR) +(o[2] == COPLANAR) +(o[3] == COPLANAR); switch(sum) { case 0: { lt = CELL; break; } case 1: { lt = FACET; li = (o[0] == COPLANAR) ? 0 : (o[1] == COPLANAR) ? 1 : (o[2] == COPLANAR) ? 2 : 3; break; } case 2: { lt = EDGE; li = (o[0] != COPLANAR) ? 0 : (o[1] != COPLANAR) ? 1 : 2; lj = (o[li+1] != COPLANAR) ? li+1 : (o[li+2] != COPLANAR) ? li+2 : li+3; CGAL_triangulation_assertion(collinear(p, c->vertex(li)->point(), c->vertex(lj)->point())); break; } case 3: { lt = VERTEX; li = (o[0] != COPLANAR) ? 0 : (o[1] != COPLANAR) ? 1 : (o[2] != COPLANAR) ? 2 : 3; break; } } return c; } case 2: { CGAL_triangulation_precondition(start != Cell_handle()); CGAL_triangulation_precondition(! start->has_vertex(infinite)); Cell_handle c = start; boost::uniform_smallint<> three(0, 2); boost::variate_generator > die3(rng, three); //first tests whether p is coplanar with the current triangulation if(orientation(c->vertex(0)->point(), c->vertex(1)->point(), c->vertex(2)->point(), p) != DEGENERATE) { lt = OUTSIDE_AFFINE_HULL; li = 3; // only one facet in dimension 2 return c; } // if p is coplanar, location in the triangulation // only the facet numbered 3 exists in each cell while(1) { int inf; if(c->has_vertex(infinite, inf)) { // c must contain p in its interior lt = OUTSIDE_CONVEX_HULL; li = cw(inf); lj = ccw(inf); return c; } // else c is finite // we test its edges in a random order until we find a // neighbor to go further int i = die3(); const Point& p0 = c->vertex(i)->point(); const Point& p1 = c->vertex(ccw(i))->point(); const Point& p2 = c->vertex(cw(i))->point(); Orientation o[3]; CGAL_triangulation_assertion(coplanar_orientation(p0,p1,p2) == POSITIVE); o[0] = coplanar_orientation(p0,p1,p); if(o[0] == NEGATIVE) { c = c->neighbor(cw(i)); continue; } o[1] = coplanar_orientation(p1,p2,p); if(o[1] == NEGATIVE) { c = c->neighbor(i); continue; } o[2] = coplanar_orientation(p2,p0,p); if(o[2] == NEGATIVE) { c = c->neighbor(ccw(i)); continue; } // now p is in c or on its boundary int sum =(o[0] == COLLINEAR) +(o[1] == COLLINEAR) +(o[2] == COLLINEAR); switch(sum) { case 0: { lt = FACET; li = 3; // useless ? break; } case 1: { lt = EDGE; li = (o[0] == COLLINEAR) ? i : (o[1] == COLLINEAR) ? ccw(i) : cw(i); lj = ccw(li); break; } case 2: { lt = VERTEX; li = (o[0] != COLLINEAR) ? cw(i) : (o[1] != COLLINEAR) ? i : ccw(i); break; } } return c; } } case 1: { CGAL_triangulation_precondition(start != Cell_handle()); CGAL_triangulation_precondition(! start->has_vertex(infinite)); Cell_handle c = start; //first tests whether p is collinear with the current triangulation if(! collinear(p, c->vertex(0)->point(), c->vertex(1)->point())) { lt = OUTSIDE_AFFINE_HULL; return c; } // if p is collinear, location : while(1) { if(c->has_vertex(infinite)) { // c must contain p in its interior lt = OUTSIDE_CONVEX_HULL; return c; } // else c is finite // we test on which direction to continue the traversal switch(collinear_position(c->vertex(0)->point(), p, c->vertex(1)->point())) { case AFTER: c = c->neighbor(0); continue; case BEFORE: c = c->neighbor(1); continue; case MIDDLE: lt = EDGE; li = 0; lj = 1; return c; case SOURCE: lt = VERTEX; li = 0; return c; case TARGET: lt = VERTEX; li = 1; return c; } } } case 0: { Finite_vertices_iterator vit = finite_vertices_begin(); if(! equal(p, vit->point())) { lt = OUTSIDE_AFFINE_HULL; } else { lt = VERTEX; li = 0; } return vit->cell(); } case -1: { lt = OUTSIDE_AFFINE_HULL; return Cell_handle(); } default: { CGAL_triangulation_assertion(false); return Cell_handle(); } } } #ifndef CGAL_NO_STRUCTURAL_FILTERING template < class Gt, class Tds, class Lds > inline typename Triangulation_3::Cell_handle Triangulation_3:: inexact_locate(const Point& t, Cell_handle start, int n_of_turns, bool *could_lock_zone) const { CGAL_triangulation_expensive_assertion(start == Cell_handle() || tds().is_simplex(start)); if(could_lock_zone) *could_lock_zone = true; if(dimension() < 3) return start; // Make sure we continue from here with a finite cell. if(start == Cell_handle()) start = infinite_cell(); // CJTODO: useless? if(could_lock_zone) { if(!this->try_lock_cell(start)) { *could_lock_zone = false; return Cell_handle(); } } int ind_inf; if(start->has_vertex(infinite, ind_inf)) start = start->neighbor(ind_inf); CGAL_triangulation_precondition(start != Cell_handle()); CGAL_triangulation_precondition(! start->has_vertex(infinite)); // We implement the remembering visibility walk. // In this phase, no need to be stochastic // Remembers the previous cell to avoid useless orientation tests. Cell_handle previous = Cell_handle(); Cell_handle c = start; if(could_lock_zone) { if(!this->try_lock_cell(c)) { *could_lock_zone = false; return Cell_handle(); } } // Now treat the cell c. try_next_cell: n_of_turns--; // We know that the 4 vertices of c are positively oriented. // So, in order to test if p is seen outside from one of c's facets, // we just replace the corresponding point by p in the orientation // test. We do this using the array below. const Point* pts[4] = { &(c->vertex(0)->point()), &(c->vertex(1)->point()), &(c->vertex(2)->point()), &(c->vertex(3)->point()) }; // (non-stochastic) visibility walk for(int i=0; i != 4; ++i) { Cell_handle next = c->neighbor(i); if(previous == next) continue; // We temporarily put p at i's place in pts. const Point* backup = pts[i]; pts[i] = &t; if(inexact_orientation(*pts[0], *pts[1], *pts[2], *pts[3]) != NEGATIVE) { pts[i] = backup; continue; } if(next->has_vertex(infinite)) { // We are outside the convex hull. return next; } previous = c; c = next; if(could_lock_zone) { //previous->unlock(); // DON'T do that, "c" may be in // the same locking cell as "previous" if(!this->try_lock_cell(c)) { *could_lock_zone = false; return Cell_handle(); } } if(n_of_turns) goto try_next_cell; } return c; } #endif // no CGAL_NO_STRUCTURAL_FILTERING template < class GT, class Tds, class Lds > Bounded_side Triangulation_3:: side_of_tetrahedron(const Point& p, const Point& p0, const Point& p1, const Point& p2, const Point& p3, Locate_type& lt, int& i, int& j) const { // p0,p1,p2,p3 supposed to be non coplanar // tetrahedron p0,p1,p2,p3 is supposed to be well oriented // returns : // - ON_BOUNDED_SIDE if p lies strictly inside the tetrahedron // - ON_BOUNDARY if p lies on one of the facets // - ON_UNBOUNDED_SIDE if p lies strictly outside the tetrahedron CGAL_triangulation_precondition(orientation(p0,p1,p2,p3) == POSITIVE); Orientation o0,o1,o2,o3; if(((o0 = orientation(p,p1,p2,p3)) == NEGATIVE) || ((o1 = orientation(p0,p,p2,p3)) == NEGATIVE) || ((o2 = orientation(p0,p1,p,p3)) == NEGATIVE) || ((o3 = orientation(p0,p1,p2,p)) == NEGATIVE)) { lt = OUTSIDE_CONVEX_HULL; return ON_UNBOUNDED_SIDE; } // now all the oi's are >=0 // sum gives the number of facets p lies on int sum = ((o0 == ZERO) ? 1 : 0) + ((o1 == ZERO) ? 1 : 0) + ((o2 == ZERO) ? 1 : 0) + ((o3 == ZERO) ? 1 : 0); switch(sum) { case 0: { lt = CELL; return ON_BOUNDED_SIDE; } case 1: { lt = FACET; // i = index such that p lies on facet(i) i = (o0 == ZERO) ? 0 : (o1 == ZERO) ? 1 : (o2 == ZERO) ? 2 : 3; return ON_BOUNDARY; } case 2: { lt = EDGE; // i = smallest index such that p does not lie on facet(i) // i must be < 3 since p lies on 2 facets i = (o0 == POSITIVE) ? 0 : (o1 == POSITIVE) ? 1 : 2; // j = larger index such that p not on facet(j) // j must be > 0 since p lies on 2 facets j = (o3 == POSITIVE) ? 3 : (o2 == POSITIVE) ? 2 : 1; return ON_BOUNDARY; } case 3: { lt = VERTEX; // i = index such that p does not lie on facet(i) i = (o0 == POSITIVE) ? 0 : (o1 == POSITIVE) ? 1 : (o2 == POSITIVE) ? 2 : 3; return ON_BOUNDARY; } default: { // impossible : cannot be on 4 facets for a real tetrahedron CGAL_triangulation_assertion(false); return ON_BOUNDARY; } } } template < class GT, class Tds, class Lds > Bounded_side Triangulation_3:: side_of_cell(const Point& p, Cell_handle c, Locate_type& lt, int& i, int& j) const { // Returns // - ON_BOUNDED_SIDE if p inside the cell // (for an infinite cell this means that p lies strictly in the half space // limited by its finite facet) // - ON_BOUNDARY if p on the boundary of the cell // (for an infinite cell this means that p lies on the *finite* facet) // - ON_UNBOUNDED_SIDE if p lies outside the cell // (for an infinite cell this means that p is not in the preceding // two cases) // lt only has meaning when ON_BOUNDED_SIDE or ON_BOUNDARY CGAL_triangulation_precondition(dimension() == 3); if(! is_infinite(c)) { return side_of_tetrahedron(p, c->vertex(0)->point(), c->vertex(1)->point(), c->vertex(2)->point(), c->vertex(3)->point(), lt, i, j); } else { int inf = c->index(infinite); Orientation o; Vertex_handle v1 = c->vertex((inf+1)&3), v2 = c->vertex((inf+2)&3), v3 = c->vertex((inf+3)&3); if((inf&1) == 0) o = orientation(p, v1->point(), v2->point(), v3->point()); else o = orientation(v3->point(), p, v1->point(), v2->point()); switch(o) { case POSITIVE: { lt = CELL; return ON_BOUNDED_SIDE; } case NEGATIVE: return ON_UNBOUNDED_SIDE; case ZERO: { // location in the finite facet int i_f, j_f; Bounded_side side = side_of_triangle(p, v1->point(), v2->point(), v3->point(), lt, i_f, j_f); // lt need not be modified in most cases : switch(side) { case ON_BOUNDED_SIDE: { // lt == FACET ok i = inf; return ON_BOUNDARY; } case ON_BOUNDARY: { // lt == VERTEX OR EDGE ok i = (i_f == 0) ? ((inf+1)&3) : (i_f == 1) ? ((inf+2)&3) : ((inf+3)&3); if(lt == EDGE) { j = (j_f == 0) ? ((inf+1)&3) : (j_f == 1) ? ((inf+2)&3) : ((inf+3)&3); } return ON_BOUNDARY; } case ON_UNBOUNDED_SIDE: { // p lies on the plane defined by the finite facet // lt must be initialized return ON_UNBOUNDED_SIDE; } default: { CGAL_triangulation_assertion(false); return ON_BOUNDARY; } } // switch side } // case ZERO default: { CGAL_triangulation_assertion(false); return ON_BOUNDARY; } } // switch o } // else infinite cell } // side_of_cell template < class GT, class Tds, class Lds > Bounded_side Triangulation_3:: side_of_triangle(const Point& p, const Point& p0, const Point& p1, const Point& p2, Locate_type& lt, int& i, int& j) const { // p0,p1,p2 supposed to define a plane // p supposed to lie on plane p0,p1,p2 // triangle p0,p1,p2 defines the orientation of the plane. // Returns // - ON_BOUNDED_SIDE if p lies strictly inside the triangle // - ON_BOUNDARY if p lies on one of the edges // - ON_UNBOUNDED_SIDE if p lies strictly outside the triangle CGAL_triangulation_precondition(coplanar(p,p0,p1,p2)); Orientation o012 = coplanar_orientation(p0,p1,p2); CGAL_triangulation_precondition(o012 != COLLINEAR); Orientation o0; // edge p0 p1 Orientation o1; // edge p1 p2 Orientation o2; // edge p2 p0 if((o0 = coplanar_orientation(p0,p1,p)) == opposite(o012) || (o1 = coplanar_orientation(p1,p2,p)) == opposite(o012) || (o2 = coplanar_orientation(p2,p0,p)) == opposite(o012)) { lt = OUTSIDE_CONVEX_HULL; return ON_UNBOUNDED_SIDE; } // now all the oi's are >=0 // sum gives the number of edges p lies on int sum = ((o0 == ZERO) ? 1 : 0) + ((o1 == ZERO) ? 1 : 0) + ((o2 == ZERO) ? 1 : 0); switch(sum) { case 0: { lt = FACET; return ON_BOUNDED_SIDE; } case 1: { lt = EDGE; i = (o0 == ZERO) ? 0 : (o1 == ZERO) ? 1 : 2; if(i == 2) j=0; else j = i+1; return ON_BOUNDARY; } case 2: { lt = VERTEX; i = (o0 == o012) ? 2 : (o1 == o012) ? 0 : 1; return ON_BOUNDARY; } default: { // cannot happen CGAL_triangulation_assertion(false); return ON_BOUNDARY; } } } template < class GT, class Tds, class Lds > Bounded_side Triangulation_3:: side_of_facet(const Point& p, Cell_handle c, Locate_type& lt, int& li, int& lj) const { // Assumes dimension 2; otherwise does not work for infinite facets. // Returns : // - ON_BOUNDED_SIDE if p inside the facet // (for an infinite facet this means that p lies strictly in the half plane // limited by its finite edge) // - ON_BOUNDARY if p on the boundary of the facet // (for an infinite facet this means that p lies on the *finite* edge) // - ON_UNBOUNDED_SIDE if p lies outside the facet // (for an infinite facet this means that p is not in the // preceding two cases) // lt only has meaning when ON_BOUNDED_SIDE or ON_BOUNDARY. // When they mean anything, li and lj refer to indices in the cell c // giving the facet (c,i). CGAL_triangulation_precondition(dimension() == 2); if(! is_infinite(c,3)) { // The following precondition is useless because it is written // in side_of_facet // CGAL_triangulation_precondition(coplanar (p, // c->vertex(0)->point, // c->vertex(1)->point, // c->vertex(2)->point)); int i_t, j_t; Bounded_side side = side_of_triangle(p, c->vertex(0)->point(), c->vertex(1)->point(), c->vertex(2)->point(), lt, i_t, j_t); // We protect the following code by this test to avoid valgrind messages. if(side == ON_BOUNDARY) { // indices in the original cell : li = (i_t == 0) ? 0 : (i_t == 1) ? 1 : 2; lj = (j_t == 0) ? 0 : (j_t == 1) ? 1 : 2; } return side; } // else infinite facet int inf = c->index(infinite); // The following precondition is useless because it is written // in side_of_facet // CGAL_triangulation_precondition(coplanar (p, // c->neighbor(inf)->vertex(0)->point(), // c->neighbor(inf)->vertex(1)->point(), // c->neighbor(inf)->vertex(2)->point())); int i2 = next_around_edge(inf,3); int i1 = 3 - inf - i2; Vertex_handle v1 = c->vertex(i1), v2 = c->vertex(i2); CGAL_triangulation_assertion(coplanar_orientation(v1->point(), v2->point(), mirror_vertex(c, inf)->point()) == POSITIVE); switch(coplanar_orientation(v1->point(), v2->point(), p)) { case POSITIVE: // p lies on the same side of v1v2 as vn, so not in f return ON_UNBOUNDED_SIDE; case NEGATIVE: // p lies in f lt = FACET; li = 3; return ON_BOUNDED_SIDE; default: // case ZERO: // p collinear with v1v2 int i_e; switch(side_of_segment(p, v1->point(), v2->point(), lt, i_e)) { // computation of the indices in the original cell case ON_BOUNDED_SIDE: // lt == EDGE ok li = i1; lj = i2; return ON_BOUNDARY; case ON_BOUNDARY: // lt == VERTEX ok li =(i_e == 0) ? i1 : i2; return ON_BOUNDARY; default: // case ON_UNBOUNDED_SIDE: // p lies on the line defined by the finite edge return ON_UNBOUNDED_SIDE; } } } template < class GT, class Tds, class Lds > Bounded_side Triangulation_3:: side_of_segment(const Point& p, const Point& p0, const Point& p1, Locate_type& lt, int& i) const { // p0, p1 supposed to be different // p supposed to be collinear to p0, p1 // Returns : // - ON_BOUNDED_SIDE if p lies strictly inside the edge // - ON_BOUNDARY if p equals p0 or p1 // - ON_UNBOUNDED_SIDE if p lies strictly outside the edge CGAL_triangulation_precondition(! equal(p0, p1)); CGAL_triangulation_precondition(collinear(p, p0, p1)); switch(collinear_position(p0, p, p1)) { case MIDDLE: lt = EDGE; return ON_BOUNDED_SIDE; case SOURCE: lt = VERTEX; i = 0; return ON_BOUNDARY; case TARGET: lt = VERTEX; i = 1; return ON_BOUNDARY; default: // case BEFORE: case AFTER: lt = OUTSIDE_CONVEX_HULL; return ON_UNBOUNDED_SIDE; } } template < class GT, class Tds, class Lds > Bounded_side Triangulation_3:: side_of_edge(const Point& p, Cell_handle c, Locate_type& lt, int& li) const { // Assumes dimension 1 otherwise does not work for infinite edges. // Returns : // - ON_BOUNDED_SIDE if p inside the edge // (for an infinite edge this means that p lies in the half line // defined by the vertex) // - ON_BOUNDARY if p equals one of the vertices // - ON_UNBOUNDED_SIDE if p lies outside the edge // (for an infinite edge this means that p lies on the other half line) // lt only has meaning when ON_BOUNDED_SIDE and ON_BOUNDARY // li refer to indices in the cell c CGAL_triangulation_precondition(dimension() == 1); if(! is_infinite(c,0,1)) return side_of_segment(p, c->vertex(0)->point(), c->vertex(1)->point(), lt, li); // else infinite edge int inf = c->index(infinite); switch(collinear_position(c->vertex(1-inf)->point(), p, mirror_vertex(c, inf)->point())) { case SOURCE: lt = VERTEX; li = 1-inf; return ON_BOUNDARY; case BEFORE: lt = EDGE; return ON_BOUNDED_SIDE; default: // case MIDDLE: case AFTER: case TARGET: return ON_UNBOUNDED_SIDE; } } template < class GT, class Tds, class Lds > bool Triangulation_3:: flip(Cell_handle c, int i) { CGAL_triangulation_precondition((dimension() == 3) && (0<=i) && (i<4) && (number_of_vertices() >= 5)); Cell_handle n = c->neighbor(i); int in = n->index(c); if(is_infinite(c) || is_infinite(n)) return false; if(i%2 == 1) { if(orientation(c->vertex((i+1)&3)->point(), c->vertex((i+2)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) != POSITIVE) return false; if(orientation(c->vertex((i+2)&3)->point(), c->vertex((i+3)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) != POSITIVE) return false; if(orientation(c->vertex((i+3)&3)->point(), c->vertex((i+1)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) != POSITIVE) return false; } else { if(orientation(c->vertex((i+2)&3)->point(), c->vertex((i+1)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) != POSITIVE) return false; if(orientation(c->vertex((i+3)&3)->point(), c->vertex((i+2)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) != POSITIVE) return false; if(orientation(c->vertex((i+1)&3)->point(), c->vertex((i+3)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) != POSITIVE) return false; } _tds.flip_flippable(c, i); return true; } template < class GT, class Tds, class Lds > void Triangulation_3:: flip_flippable(Cell_handle c, int i) { CGAL_triangulation_precondition((dimension() == 3) && (0<=i) && (i<4) && (number_of_vertices() >= 5)); CGAL_triangulation_precondition_code(Cell_handle n = c->neighbor(i);); CGAL_triangulation_precondition_code(int in = n->index(c);); CGAL_triangulation_precondition((! is_infinite(c)) &&(! is_infinite(n))); if(i%2 == 1) { CGAL_triangulation_precondition(orientation(c->vertex((i+1)&3)->point(), c->vertex((i+2)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) == POSITIVE); CGAL_triangulation_precondition(orientation(c->vertex((i+2)&3)->point(), c->vertex((i+3)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) == POSITIVE); CGAL_triangulation_precondition(orientation(c->vertex((i+3)&3)->point(), c->vertex((i+1)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) == POSITIVE); } else { CGAL_triangulation_precondition(orientation(c->vertex((i+2)&3)->point(), c->vertex((i+1)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) == POSITIVE); CGAL_triangulation_precondition(orientation(c->vertex((i+3)&3)->point(), c->vertex((i+2)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) == POSITIVE); CGAL_triangulation_precondition(orientation(c->vertex((i+1)&3)->point(), c->vertex((i+3)&3)->point(), n->vertex(in)->point(), c->vertex(i)->point()) == POSITIVE); } _tds.flip_flippable(c, i); } template < class GT, class Tds, class Lds > bool Triangulation_3:: flip(Cell_handle c, int i, int j) { // Flips the edge (i,j) of cell c CGAL_triangulation_precondition((dimension() == 3) && (0<=i) && (i<4) && (0<=j) && (j<4) &&(i != j) && (number_of_vertices() >= 5)); // Checks that degree 3 and not on the convex hull int degree = 0; Cell_circulator ccir = incident_cells(c,i,j); Cell_circulator cdone = ccir; do { if(is_infinite(ccir)) return false; ++degree; ++ccir; } while(ccir != cdone); if(degree != 3) return false; // Checks that future tetrahedra are well oriented Cell_handle n = c->neighbor(next_around_edge(i,j)); int in = n->index(c->vertex(i)); int jn = n->index(c->vertex(j)); if(orientation(c->vertex(next_around_edge(i,j))->point(), c->vertex(next_around_edge(j,i))->point(), n->vertex(next_around_edge(jn,in))->point(), c->vertex(j)->point()) != POSITIVE) return false; if(orientation(c->vertex(i)->point(), c->vertex(next_around_edge(j,i))->point(), n->vertex(next_around_edge(jn,in))->point(), c->vertex(next_around_edge(i,j))->point()) != POSITIVE) return false; _tds.flip_flippable(c, i, j); return true; } template < class GT, class Tds, class Lds > void Triangulation_3:: flip_flippable(Cell_handle c, int i, int j) { // flips edge i,j of cell c #if !defined CGAL_TRIANGULATION_NO_PRECONDITIONS && \ !defined CGAL_NO_PRECONDITIONS && !defined NDEBUG CGAL_triangulation_precondition((dimension() == 3) && (0<=i) && (i<4) && (0<=j) && (j<4) && (i != j) && (number_of_vertices() >= 5)); int degree = 0; Cell_circulator ccir = incident_cells(c,i,j); Cell_circulator cdone = ccir; do { CGAL_triangulation_precondition(! is_infinite(ccir)); ++degree; ++ccir; } while(ccir != cdone); CGAL_triangulation_precondition(degree == 3); Cell_handle n = c->neighbor(next_around_edge(i, j)); int in = n->index(c->vertex(i)); int jn = n->index(c->vertex(j)); CGAL_triangulation_precondition(orientation(c->vertex(next_around_edge(i,j))->point(), c->vertex(next_around_edge(j,i))->point(), n->vertex(next_around_edge(jn,in))->point(), c->vertex(j)->point()) == POSITIVE); CGAL_triangulation_precondition(orientation(c->vertex(i)->point(), c->vertex(next_around_edge(j,i))->point(), n->vertex(next_around_edge(jn,in))->point(), c->vertex(next_around_edge(i,j))->point()) == POSITIVE); #endif _tds.flip_flippable(c, i, j); } template < class GT, class Tds, class Lds > typename Triangulation_3::Vertex_handle Triangulation_3:: insert(const Point& p, Cell_handle start) { Locate_type lt; int li, lj; Cell_handle c = locate(p, lt, li, lj, start); return insert(p, lt, c, li, lj); } template < class GT, class Tds, class Lds > typename Triangulation_3::Vertex_handle Triangulation_3:: insert(const Point& p, Locate_type lt, Cell_handle c, int li, int lj) { switch(lt) { case VERTEX: return c->vertex(li); case EDGE: return insert_in_edge(p, c, li, lj); case FACET: return insert_in_facet(p, c, li); case CELL: return insert_in_cell(p, c); case OUTSIDE_CONVEX_HULL: return insert_outside_convex_hull(p, c); case OUTSIDE_AFFINE_HULL: default: return insert_outside_affine_hull(p); } } template < class GT, class Tds, class Lds > template < class Conflict_tester, class Hidden_points_visitor > typename Triangulation_3::Vertex_handle Triangulation_3:: insert_in_conflict(const Point& p, Locate_type lt, Cell_handle c, int li, int /*lj*/, const Conflict_tester& tester, Hidden_points_visitor& hider, bool *could_lock_zone) { if(could_lock_zone) *could_lock_zone = true; switch(dimension()) { case 3: { if((lt == VERTEX) && (tester.compare_weight(c->vertex(li)->point(), p)==0)) { return c->vertex(li); } // If the new point is not in conflict with its cell, it is hidden. if(!tester.test_initial_cell(c)) { hider.hide_point(c,p); return Vertex_handle(); } // Ok, we really insert the point now. // First, find the conflict region. boost::container::small_vector cells; Facet facet; boost::container::small_vector facets; // Parallel if(could_lock_zone) { find_conflicts(c, tester, make_triple(std::back_inserter(facets), std::back_inserter(cells), Emptyset_iterator()), could_lock_zone); if(*could_lock_zone == false) { for(Cell_handle ch : cells) { ch->tds_data().clear(); } for(Facet& f : facets) { f.first->neighbor(f.second)->tds_data().clear(); } return Vertex_handle(); } } // Sequential else { find_conflicts(c, tester, make_triple( std::back_inserter(facets), std::back_inserter(cells), Emptyset_iterator())); } facet = facets.back(); // Remember the points that are hidden by the conflicting cells, // as they will be deleted during the insertion. hider.process_cells_in_conflict(cells.begin(), cells.end()); Vertex_handle v = tds().is_small_hole(facets.size()) ? _insert_in_small_hole(p, cells, facets) : _insert_in_hole(p, cells.begin(), cells.end(), facet.first, facet.second); // Store the hidden points in their new cells. hider.reinsert_vertices(v); return v; } case 2: { // This check is added compared to the 3D case if(lt == OUTSIDE_AFFINE_HULL) return insert_outside_affine_hull (p); if((lt == VERTEX) && (tester.compare_weight(c->vertex(li)->point(), p)==0)) { return c->vertex(li); } // If the new point is not in conflict with its cell, it is hidden. if(!tester.test_initial_cell(c)) { hider.hide_point(c,p); return Vertex_handle(); } // Ok, we really insert the point now. // First, find the conflict region. std::vector cells; cells.reserve(32); Facet facet; find_conflicts(c, tester, make_triple(Oneset_iterator(facet), std::back_inserter(cells), Emptyset_iterator())); // Remember the points that are hidden by the conflicting cells, // as they will be deleted during the insertion. hider.process_cells_in_conflict(cells.begin(), cells.end()); Vertex_handle v = _insert_in_hole(p, cells.begin(), cells.end(), facet.first, facet.second); // Store the hidden points in their new cells. hider.reinsert_vertices(v); return v; } default: { // dimension() <= 1 if(lt == OUTSIDE_AFFINE_HULL) return insert_outside_affine_hull (p); if(lt == VERTEX && tester.compare_weight(c->vertex(li)->point(), p) == 0) return c->vertex(li); // If the new point is not in conflict with its cell, it is hidden. if(! tester.test_initial_cell(c)) { hider.hide_point(c,p); return Vertex_handle(); } if(dimension() == 0) return hider.replace_vertex(c, li, p); // dimension() == 1; // Ok, we really insert the point now. // First, find the conflict region. std::vector cells; Facet facet; Cell_handle bound[2]; // corresponding index: bound[j]->neighbor(1-j) is in conflict. // We get all cells in conflict, // and remember the 2 external boundaries. cells.push_back(c); for(int j = 0; j<2; ++j) { Cell_handle n = c->neighbor(j); while(tester(n)) { cells.push_back(n); n = n->neighbor(j); } bound[j] = n; } // Insertion. hider.process_cells_in_conflict(cells.begin(), cells.end()); tds().delete_cells(cells.begin(), cells.end()); // We preserve the order (like the orientation in 2D-3D). Vertex_handle v = tds().create_vertex(); Cell_handle c0 = tds().create_face(v, bound[0]->vertex(0), Vertex_handle()); Cell_handle c1 = tds().create_face(bound[1]->vertex(1), v, Vertex_handle()); tds().set_adjacency(c0, 1, c1, 0); tds().set_adjacency(bound[0], 1, c0, 0); tds().set_adjacency(c1, 1, bound[1], 0); bound[0]->vertex(0)->set_cell(bound[0]); bound[1]->vertex(1)->set_cell(bound[1]); v->set_cell(c0); v->set_point (p); hider.reinsert_vertices(v); return v; } } } template < class GT, class Tds, class Lds > typename Triangulation_3::Vertex_handle Triangulation_3:: insert_in_cell(const Point& p, Cell_handle c) { CGAL_triangulation_precondition(dimension() == 3); CGAL_triangulation_precondition_code( Locate_type lt; int i; int j; ); CGAL_triangulation_precondition(side_of_tetrahedron(p, c->vertex(0)->point(), c->vertex(1)->point(), c->vertex(2)->point(), c->vertex(3)->point(), lt,i,j) == ON_BOUNDED_SIDE); Vertex_handle v = _tds.insert_in_cell(c); v->set_point(p); return v; } template < class GT, class Tds, class Lds > inline typename Triangulation_3::Vertex_handle Triangulation_3:: insert_in_facet(const Point& p, Cell_handle c, int i) { CGAL_triangulation_precondition(dimension() == 2 || dimension() == 3); CGAL_triangulation_precondition((dimension() == 2 && i == 3) || (dimension() == 3 && i >= 0 && i <= 3)); CGAL_triangulation_exactness_precondition_code( Locate_type lt; int li; int lj; ); CGAL_triangulation_exactness_precondition(coplanar(p, c->vertex((i+1)&3)->point(), c->vertex((i+2)&3)->point(), c->vertex((i+3)&3)->point()) && side_of_triangle(p, c->vertex((i+1)&3)->point(), c->vertex((i+2)&3)->point(), c->vertex((i+3)&3)->point(), lt, li, lj) == ON_BOUNDED_SIDE); Vertex_handle v = _tds.insert_in_facet(c, i); v->set_point(p); return v; } template < class GT, class Tds, class Lds > typename Triangulation_3::Vertex_handle Triangulation_3:: insert_in_edge(const Point& p, Cell_handle c, int i, int j) { CGAL_triangulation_precondition(i != j); CGAL_triangulation_precondition(dimension() >= 1 && dimension() <= 3); CGAL_triangulation_precondition(i >= 0 && i <= dimension() && j >= 0 && j <= dimension()); CGAL_triangulation_exactness_precondition_code( Locate_type lt; int li; ); switch(dimension()) { case 3: case 2: { CGAL_triangulation_precondition(! is_infinite(c, i, j)); CGAL_triangulation_exactness_precondition(collinear(c->vertex(i)->point(), p, c->vertex(j)->point()) && side_of_segment(p, c->vertex(i)->point(), c->vertex(j)->point(), lt, li) == ON_BOUNDED_SIDE); break; } case 1: { CGAL_triangulation_exactness_precondition(side_of_edge(p, c, lt, li) == ON_BOUNDED_SIDE); break; } } Vertex_handle v = _tds.insert_in_edge(c, i, j); v->set_point(p); return v; } template < class GT, class Tds, class Lds > typename Triangulation_3::Vertex_handle Triangulation_3:: insert_outside_convex_hull(const Point& p, Cell_handle c) { // c is an infinite cell containing p // p is strictly outside the convex hull // dimension 0 not allowed, use outside-affine-hull CGAL_triangulation_precondition(dimension() > 0); CGAL_triangulation_precondition(c->has_vertex(infinite)); // the precondition that p is in c is tested in each of the // insertion methods called from this method switch(dimension()) { case 1: { // // p lies in the infinite edge neighboring c // // on the other side of li // return insert_in_edge(p,c->neighbor(1-li),0,1); return insert_in_edge(p,c,0,1); } case 2: { Conflict_tester_outside_convex_hull_2 tester(p, this); Vertex_handle v = insert_conflict(c, tester); v->set_point(p); return v; } default: // case 3: { Conflict_tester_outside_convex_hull_3 tester(p, this); Vertex_handle v = insert_conflict(c, tester); v->set_point(p); return v; } } } template < class GT, class Tds, class Lds > typename Triangulation_3::Vertex_handle Triangulation_3:: insert_outside_affine_hull(const Point& p) { CGAL_triangulation_precondition(dimension() < 3); bool reorient; switch(dimension()) { case 1: { Cell_handle c = infinite_cell(); Cell_handle n = c->neighbor(c->index(infinite_vertex())); Orientation o = coplanar_orientation(n->vertex(0)->point(), n->vertex(1)->point(), p); CGAL_triangulation_precondition(o != COLLINEAR); reorient = o == NEGATIVE; break; } case 2: { Cell_handle c = infinite_cell(); Cell_handle n = c->neighbor(c->index(infinite_vertex())); Orientation o = orientation(n->vertex(0)->point(), n->vertex(1)->point(), n->vertex(2)->point(), p); CGAL_triangulation_precondition(o != COPLANAR); reorient = o == NEGATIVE; break; } default: reorient = false; } Vertex_handle v = _tds.insert_increase_dimension(infinite_vertex()); v->set_point(p); if(reorient) _tds.reorient(); return v; } template < class GT, class Tds, class Lds > template < class OutputItCells > typename Triangulation_3::Vertex_handle Triangulation_3::insert_and_give_new_cells(const Point& p, OutputItCells fit, Cell_handle start) { Vertex_handle v = insert(p, start); int dimension = this->dimension(); if(dimension == 3) this->incident_cells(v, fit); else if(dimension == 2) { Cell_handle c = v->cell(), end = c; do { *fit++ = c; int i = c->index(v); c = c->neighbor((i+1)%3); } while(c != end); } else if(dimension == 1) { Cell_handle c = v->cell(); *fit++ = c; *fit++ = c->neighbor((~(c->index(v)))&1); } else *fit++ = v->cell(); // dimension = 0 return v; } template < class GT, class Tds, class Lds > template < class OutputItCells > typename Triangulation_3::Vertex_handle Triangulation_3::insert_and_give_new_cells(const Point& p, OutputItCells fit, Vertex_handle hint) { Vertex_handle v = insert(p, hint); int dimension = this->dimension(); if(dimension == 3) { this->incident_cells(v, fit); } else if(dimension == 2) { Cell_handle c = v->cell(), end = c; do { *fit++ = c; int i = c->index(v); c = c->neighbor((i+1)%3); } while(c != end); } else if(dimension == 1) { Cell_handle c = v->cell(); *fit++ = c; *fit++ = c->neighbor((~(c->index(v)))&1); } else // dimension = 0 { *fit++ = v->cell(); } return v; } template < class GT, class Tds, class Lds > template < class OutputItCells > typename Triangulation_3::Vertex_handle Triangulation_3::insert_and_give_new_cells(const Point& p, Locate_type lt, Cell_handle c, int li, int lj, OutputItCells fit) { Vertex_handle v = insert(p, lt, c, li, lj); int dimension = this->dimension(); if(dimension == 3) this->incident_cells(v, fit); else if(dimension == 2) { Cell_handle c = v->cell(), end = c; do { *fit++ = c; int i = c->index(v); c = c->neighbor((i+1)%3); } while(c != end); } else if(dimension == 1) { Cell_handle c = v->cell(); *fit++ = c; *fit++ = c->neighbor((~(c->index(v)))&1); } else *fit++ = v->cell(); // dimension = 0 return v; } template < class Gt, class Tds, class Lds > typename Triangulation_3::Vertex_triple Triangulation_3:: make_vertex_triple(const Facet& f) const { Cell_handle ch = f.first; int i = f.second; return Vertex_triple(ch->vertex(vertex_triple_index(i,0)), ch->vertex(vertex_triple_index(i,1)), ch->vertex(vertex_triple_index(i,2))); } template < class Gt, class Tds, class Lds > void Triangulation_3:: make_canonical_oriented_triple(Vertex_triple& t) const { int i = (t.first < t.second) ? 0 : 1; if(i==0) { i = (t.first < t.third) ? 0 : 2; } else { i = (t.second < t.third) ? 1 : 2; } Vertex_handle tmp; switch(i) { case 0: return; case 1: tmp = t.first; t.first = t.second; t.second = t.third; t.third = tmp; return; default: tmp = t.first; t.first = t.third; t.third = t.second; t.second = tmp; } } template < class GT, class Tds, class Lds > bool Triangulation_3:: test_dim_down(Vertex_handle v) const { // Tests whether removing v decreases the dimension of the triangulation. // Returns true iff v is incident to all finite cells/facets // and all the other vertices are coplanar/collinear in dim3/2. CGAL_triangulation_precondition(dimension() >= 0); CGAL_triangulation_precondition(! is_infinite(v)); if(dimension() == 3) { Finite_cells_iterator cit = finite_cells_begin(); int iv; if(! cit->has_vertex(v,iv)) return false; const Point& p1=cit->vertex((iv+1)&3)->point(); const Point& p2=cit->vertex((iv+2)&3)->point(); const Point& p3=cit->vertex((iv+3)&3)->point(); ++cit; for(; cit != finite_cells_end(); ++cit) { if(! cit->has_vertex(v,iv)) return false; for(int i=1; i<4; i++) if(!coplanar(p1,p2,p3,cit->vertex((iv+i)&3)->point())) return false; } } else if(dimension() == 2) { Finite_facets_iterator cit = finite_facets_begin(); int iv; if(! cit->first->has_vertex(v,iv)) return false; const Point& p1 = cit->first->vertex(cw(iv))->point(); const Point& p2 = cit->first->vertex(ccw(iv))->point(); ++cit; for(; cit != finite_facets_end(); ++cit) { if(! cit->first->has_vertex(v,iv)) return false; if(!collinear(p1, p2, cit->first->vertex(cw(iv))->point()) || !collinear(p1, p2, cit->first->vertex(ccw(iv))->point())) return false; } } else // dimension() == 1 or 0 { return number_of_vertices() == (size_type) dimension() + 1; } return true; } template < class GT, class Tds, class Lds > bool Triangulation_3:: test_dim_down_using_incident_cells_3(Vertex_handle v, std::vector& incident_cells, std::vector& adj_vertices, bool *could_lock_zone) const { CGAL_triangulation_precondition(dimension() == 3); CGAL_triangulation_precondition(! is_infinite(v)); // Collect all vertices on the boundary // and all incident cells if(could_lock_zone) { *could_lock_zone = try_lock_and_get_adjacent_vertices_and_cells_3( v, std::back_inserter(adj_vertices), incident_cells); if(*could_lock_zone == false) return false; } else { adjacent_vertices_and_cells_3(v, std::back_inserter(adj_vertices), incident_cells); } typedef Filter_iterator< typename std::vector::const_iterator, Infinite_tester> Finite_vertex_iterator; Finite_vertex_iterator vit(adj_vertices.end(), Infinite_tester(this), adj_vertices.begin()); Finite_vertex_iterator vit_end(adj_vertices.end(), Infinite_tester(this)); const Point& p1 = (*vit++)->point(); const Point& p2 = (*vit++)->point(); const Point& p3 = (*vit++)->point(); for(; vit != vit_end ; ++vit) { if(!coplanar(p1, p2, p3, (*vit)->point())) return false; } for(typename std::vector::const_iterator it_inc_cell = incident_cells.begin() ; it_inc_cell != incident_cells.end() ; ++it_inc_cell) { if(!is_infinite(*it_inc_cell)) return is_infinite(mirror_vertex(*it_inc_cell, (*it_inc_cell)->index(v))); } return true; } template < class Gt, class Tds, class Lds > template < class VertexRemover > VertexRemover& Triangulation_3:: make_hole_2D(Vertex_handle v, std::list& hole, VertexRemover& remover) { std::vector to_delete; to_delete.reserve(32); Face_circulator fc = tds().incident_faces(v); Face_circulator done(fc); // We prepare for deleting all interior cells. // We ->set_cell() pointers to cells outside the hole. // We push the Edges_2D of the boundary (seen from outside) in "hole". do { Cell_handle f = fc; int i = f->index(v); Cell_handle fn = f->neighbor(i); int in = fn->index(f); f->vertex(cw(i))->set_cell(fn); fn->set_neighbor(in, Cell_handle()); hole.push_back(Edge_2D(fn, in)); remover.add_hidden_points(f); to_delete.push_back(f); ++fc; } while(fc != done); tds().delete_cells(to_delete.begin(), to_delete.end()); return remover; } // This method also erases a set of cells, which is useful to the move method // that outputs newly created cells template < class Gt, class Tds, class Lds > template < class VertexRemover > VertexRemover& Triangulation_3:: make_hole_2D(Vertex_handle v, std::list& hole, VertexRemover& remover, std::set& cells_set) { std::vector to_delete; to_delete.reserve(32); Face_circulator fc = tds().incident_faces(v); Face_circulator done(fc); // We prepare for deleting all interior cells. // We ->set_cell() pointers to cells outside the hole. // We push the Edges_2D of the boundary (seen from outside) in "hole". do { Cell_handle f = fc; int i = f->index(v); Cell_handle fn = f->neighbor(i); int in = fn->index(f); f->vertex(cw(i))->set_cell(fn); fn->set_neighbor(in, Cell_handle()); hole.push_back(Edge_2D(fn, in)); remover.add_hidden_points(f); to_delete.push_back(f); ++fc; } while(fc != done); for(typename std::vector::const_iterator ib = to_delete.begin(), iend = to_delete.end(); ib != iend; ib++) { cells_set.erase(*ib); } tds().delete_cells(to_delete.begin(), to_delete.end()); return remover; } template < class Gt, class Tds, class Lds > template < class VertexRemover > void Triangulation_3:: fill_hole_2D(std::list& first_hole, VertexRemover& remover) { typedef std::list Hole; std::vector hole_list; Cell_handle f, ff, fn; int i, ii, in; hole_list.push_back(first_hole); while(! hole_list.empty()) { Hole hole = hole_list.back(); hole_list.pop_back(); // If the hole has only three edges, create the triangle if(hole.size() == 3) { typename Hole::iterator hit = hole.begin(); f = (*hit).first; i = (*hit).second; ff = (* ++hit).first; ii = (*hit).second; fn = (* ++hit).first; in = (*hit).second; tds().create_face(f, i, ff, ii, fn, in); continue; } // Else find an edge with two finite vertices on the hole boundary // and the new triangle adjacent to that edge // cut the hole and push it back // First, ensure that a neighboring face // whose vertices on the hole boundary are finite // is the first of the hole while(1) { ff = (hole.front()).first; ii = (hole.front()).second; if(is_infinite(ff->vertex(cw(ii))) || is_infinite(ff->vertex(ccw(ii)))) { hole.push_back(hole.front()); hole.pop_front(); } else { break; } } // Take the first neighboring face and pop it; ff = (hole.front()).first; ii = (hole.front()).second; hole.pop_front(); Vertex_handle v0 = ff->vertex(cw(ii)); Vertex_handle v1 = ff->vertex(ccw(ii)); Vertex_handle v2 = infinite_vertex(); const Point& p0 = v0->point(); const Point& p1 = v1->point(); const Point *p2 = nullptr; // Initialize to nullptr to avoid warning. typename Hole::iterator hdone = hole.end(); typename Hole::iterator hit = hole.begin(); typename Hole::iterator cut_after(hit); // If tested vertex is c with respect to the vertex opposite to nullptr neighbor, // stop at the before last face; hdone--; for(; hit != hdone; ++hit) { fn = hit->first; in = hit->second; Vertex_handle vv = fn->vertex(ccw(in)); if(is_infinite(vv)) { if(is_infinite(v2)) cut_after = hit; } else // vv is a finite vertex { const Point& p = vv->point(); if(coplanar_orientation(p0, p1, p) == COUNTERCLOCKWISE) { if(is_infinite(v2) || remover.side_of_bounded_circle(p0, p1, *p2, p, true) == ON_BOUNDED_SIDE) { v2 = vv; p2 = &p; cut_after = hit; } } } } // Create new triangle and update adjacency relations Cell_handle newf; // Update the hole and push back in the Hole_List stack. // If v2 belongs to the neighbor following or preceding *f // the hole remains a single hole; otherwise it is split in two holes. fn = (hole.front()).first; in = (hole.front()).second; if(fn->has_vertex(v2, i) && i == ccw(in)) { newf = tds().create_face(ff, ii, fn, in); hole.pop_front(); hole.push_front(Edge_2D(newf, 1)); hole_list.push_back(hole); } else { fn = (hole.back()).first; in = (hole.back()).second; if(fn->has_vertex(v2, i) && i == cw(in)) { newf = tds().create_face(fn, in, ff, ii); hole.pop_back(); hole.push_back(Edge_2D(newf, 1)); hole_list.push_back(hole); } else { // split the hole in two holes newf = tds().create_face(ff, ii, v2); Hole new_hole; ++cut_after; while(hole.begin() != cut_after) { new_hole.push_back(hole.front()); hole.pop_front(); } hole.push_front(Edge_2D(newf, 1)); new_hole.push_front(Edge_2D(newf, 0)); hole_list.push_back(hole); hole_list.push_back(new_hole); } } } } template < class Gt, class Tds, class Lds > template < class VertexRemover, class OutputItCells > void Triangulation_3:: fill_hole_2D(std::list& first_hole, VertexRemover& remover, OutputItCells fit) { typedef std::list Hole; std::vector hole_list; Cell_handle f, ff, fn; int i, ii, in; hole_list.push_back(first_hole); while(! hole_list.empty()) { Hole hole = hole_list.back(); hole_list.pop_back(); // If the hole has only three edges, create the triangle if(hole.size() == 3) { typename Hole::iterator hit = hole.begin(); f = (*hit).first; i = (*hit).second; ff = (* ++hit).first; ii = (*hit).second; fn = (* ++hit).first; in = (*hit).second; *fit++ = tds().create_face(f, i, ff, ii, fn, in); continue; } // Else find an edge with two finite vertices on the hole boundary // and the new triangle adjacent to that edge // cut the hole and push it back // First, ensure that a neighboring face // whose vertices on the hole boundary are finite // is the first of the hole while(1) { ff = (hole.front()).first; ii = (hole.front()).second; if(is_infinite(ff->vertex(cw(ii))) || is_infinite(ff->vertex(ccw(ii)))) { hole.push_back(hole.front()); hole.pop_front(); } else { break; } } // take the first neighboring face and pop it; ff = (hole.front()).first; ii = (hole.front()).second; hole.pop_front(); Vertex_handle v0 = ff->vertex(cw(ii)); Vertex_handle v1 = ff->vertex(ccw(ii)); Vertex_handle v2 = infinite_vertex(); const Point& p0 = v0->point(); const Point& p1 = v1->point(); const Point *p2 = nullptr; // Initialize to nullptr to avoid warning. typename Hole::iterator hdone = hole.end(); typename Hole::iterator hit = hole.begin(); typename Hole::iterator cut_after(hit); // if tested vertex is c with respect to the vertex opposite // to nullptr neighbor, // stop at the before last face; hdone--; for(; hit != hdone; ++hit) { fn = hit->first; in = hit->second; Vertex_handle vv = fn->vertex(ccw(in)); if(is_infinite(vv)) { if(is_infinite(v2)) cut_after = hit; } else // vv is a finite vertex { const Point& p = vv->point(); if(coplanar_orientation(p0, p1, p) == COUNTERCLOCKWISE) { if(is_infinite(v2) || remover.side_of_bounded_circle(p0, p1, *p2, p, true) == ON_BOUNDED_SIDE) { v2 = vv; p2 = &p; cut_after = hit; } } } } // create new triangle and update adjacency relations Cell_handle newf; //update the hole and push back in the Hole_List stack // if v2 belongs to the neighbor following or preceding *f // the hole remain a single hole // otherwise it is split in two holes fn = (hole.front()).first; in = (hole.front()).second; if(fn->has_vertex(v2, i) && i == ccw(in)) { newf = tds().create_face(ff, ii, fn, in); hole.pop_front(); hole.push_front(Edge_2D(newf, 1)); hole_list.push_back(hole); } else { fn = (hole.back()).first; in = (hole.back()).second; if(fn->has_vertex(v2, i) && i == cw(in)) { newf = tds().create_face(fn, in, ff, ii); hole.pop_back(); hole.push_back(Edge_2D(newf, 1)); hole_list.push_back(hole); } else { // split the hole in two holes newf = tds().create_face(ff, ii, v2); Hole new_hole; ++cut_after; while(hole.begin() != cut_after) { new_hole.push_back(hole.front()); hole.pop_front(); } hole.push_front(Edge_2D(newf, 1)); new_hole.push_front(Edge_2D(newf, 0)); hole_list.push_back(hole); hole_list.push_back(new_hole); } } *fit++ = newf; } } template < class Gt, class Tds, class Lds > void Triangulation_3:: make_hole_3D(Vertex_handle v, Vertex_triple_Facet_map& outer_map, std::vector& hole) { CGAL_triangulation_expensive_precondition(! test_dim_down(v)); incident_cells(v, std::back_inserter(hole)); for(typename std::vector::iterator cit = hole.begin(), end = hole.end(); cit != end; ++cit) { int indv = (*cit)->index(v); Cell_handle opp_cit = (*cit)->neighbor(indv); Facet f(opp_cit, opp_cit->index(*cit)); Vertex_triple vt = make_vertex_triple(f); make_canonical_oriented_triple(vt); outer_map[vt] = f; for(int i=0; i<4; i++) { if(i != indv) (*cit)->vertex(i)->set_cell(opp_cit); } } } // When the incident cells are already known template < class Gt, class Tds, class Lds > void Triangulation_3:: make_hole_3D(Vertex_handle v, const std::vector& incident_cells, Vertex_triple_Facet_map& outer_map) { CGAL_triangulation_expensive_precondition(! test_dim_down(v)); for(typename std::vector::const_iterator cit = incident_cells.begin(), end = incident_cells.end(); cit != end; ++cit) { int indv = (*cit)->index(v); Cell_handle opp_cit = (*cit)->neighbor(indv); Facet f(opp_cit, opp_cit->index(*cit)); Vertex_triple vt = make_vertex_triple(f); make_canonical_oriented_triple(vt); outer_map[vt] = f; for(int i=0; i<4; i++) { if(i != indv) (*cit)->vertex(i)->set_cell(opp_cit); } } } template < class Gt, class Tds, class Lds > template < class VertexRemover > VertexRemover& Triangulation_3:: remove_dim_down(Vertex_handle v, VertexRemover& remover) { CGAL_triangulation_precondition (dimension() >= 0); // Collect all the hidden points. for(All_cells_iterator ci = tds().raw_cells_begin(), end = tds().raw_cells_end(); ci != end; ++ci) remover.add_hidden_points(ci); tds().remove_decrease_dimension(v, infinite_vertex()); // Now try to see if we need to re-orient. if(dimension() == 2) { Facet f = *finite_facets_begin(); if(coplanar_orientation(f.first->vertex(0)->point(), f.first->vertex(1)->point(), f.first->vertex(2)->point()) == NEGATIVE) { tds().reorient(); } } return remover; } template < class Gt, class Tds, class Lds > template < class VertexRemover > VertexRemover& Triangulation_3:: remove_1D(Vertex_handle v, VertexRemover& remover) { CGAL_triangulation_precondition (dimension() == 1); Cell_handle c1 = v->cell(); Cell_handle c2 = c1->neighbor(c1->index(v) == 0 ? 1 : 0); remover.add_hidden_points(c1); remover.add_hidden_points(c2); tds().remove_from_maximal_dimension_simplex (v); return remover; } template < class Gt, class Tds, class Lds > template < class VertexRemover > VertexRemover& Triangulation_3:: remove_2D(Vertex_handle v, VertexRemover& remover) { CGAL_triangulation_precondition(dimension() == 2); std::list hole; make_hole_2D(v, hole, remover); fill_hole_2D(hole, remover); tds().delete_vertex(v); return remover; } template < class Gt, class Tds, class Lds > template < class VertexRemover > VertexRemover& Triangulation_3:: remove_3D(Vertex_handle v, VertexRemover& remover) { std::vector hole; hole.reserve(64); // Construct the set of vertex triples on the boundary // with the facet just behind Vertex_triple_Facet_map outer_map; Vertex_triple_Facet_map inner_map; make_hole_3D(v, outer_map, hole); CGAL_assertion(remover.hidden_points_begin() == remover.hidden_points_end()); // Output the hidden points. for(typename std::vector::iterator hi = hole.begin(), hend = hole.end(); hi != hend; ++hi) { remover.add_hidden_points(*hi); } bool inf = false; // collect all vertices on the boundary std::vector vertices; vertices.reserve(64); adjacent_vertices(v, std::back_inserter(vertices)); // create a Delaunay triangulation of the points on the boundary // and make a map from the vertices in remover.tmp towards the vertices // in *this unsigned int i = 0; Vertex_handle_unique_hash_map vmap; Cell_handle ch = Cell_handle(); #ifdef CGAL_TRIANGULATION_3_USE_THE_4_POINTS_CONSTRUCTOR size_t num_vertices = vertices.size(); if(num_vertices >= 5) { for(int j = 0 ; j < 4 ; ++j) { if(is_infinite(vertices[j])) { std::swap(vertices[j], vertices[4]); break; } } Orientation o = orientation(vertices[0]->point(), vertices[1]->point(), vertices[2]->point(), vertices[3]->point()); if(o == NEGATIVE) std::swap(vertices[0], vertices[1]); if(o != ZERO) { Vertex_handle vh1, vh2, vh3, vh4; remover.tmp.init_tds(vertices[0]->point(), vertices[1]->point(), vertices[2]->point(), vertices[3]->point(), vh1, vh2, vh3, vh4); ch = vh1->cell(); vmap[vh1] = vertices[0]; vmap[vh2] = vertices[1]; vmap[vh3] = vertices[2]; vmap[vh4] = vertices[3]; i = 4; } } #endif for(; i < vertices.size(); i++) { if(! is_infinite(vertices[i])) { Vertex_handle vh = remover.tmp.insert(vertices[i]->point(), ch); ch = vh->cell(); vmap[vh] = vertices[i]; } else { inf = true; } } if(remover.tmp.dimension() == 2) { Vertex_handle fake_inf = remover.tmp.insert(v->point()); vmap[fake_inf] = infinite_vertex(); } else { vmap[remover.tmp.infinite_vertex()] = infinite_vertex(); } CGAL_triangulation_assertion(remover.tmp.dimension() == 3); // Construct the set of vertex triples of remover.tmp // We reorient the vertex triple so that it matches those from outer_map // Also note that we use the vertices of *this, not of remover.tmp if(inf) { for(All_cells_iterator it = remover.tmp.all_cells_begin(), end = remover.tmp.all_cells_end(); it != end; ++it) { for(i=0; i < 4; i++) { Facet f = std::pair(it,i); Vertex_triple vt_aux = make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first], vmap[vt_aux.third], vmap[vt_aux.second]); make_canonical_oriented_triple(vt); inner_map[vt]= f; } } } else { for(Finite_cells_iterator it = remover.tmp.finite_cells_begin(), end = remover.tmp.finite_cells_end(); it != end; ++it) { for(i=0; i < 4; i++) { Facet f = std::pair(it,i); Vertex_triple vt_aux = make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first], vmap[vt_aux.third], vmap[vt_aux.second]); make_canonical_oriented_triple(vt); inner_map[vt]= f; } } } // Grow inside the hole, by extending the surface while(! outer_map.empty()) { typename Vertex_triple_Facet_map::iterator oit = outer_map.begin(); while(is_infinite(oit->first.first) || is_infinite(oit->first.second) || is_infinite(oit->first.third)) { ++oit; // Otherwise the lookup in the inner_map fails // because the infinite vertices are different } typename Vertex_triple_Facet_map::value_type o_vt_f_pair = *oit; Cell_handle o_ch = o_vt_f_pair.second.first; unsigned int o_i = o_vt_f_pair.second.second; typename Vertex_triple_Facet_map::iterator iit = inner_map.find(o_vt_f_pair.first); CGAL_triangulation_assertion(iit != inner_map.end()); typename Vertex_triple_Facet_map::value_type i_vt_f_pair = *iit; Cell_handle i_ch = i_vt_f_pair.second.first; unsigned int i_i = i_vt_f_pair.second.second; // Create a new cell and glue it to the outer surface Cell_handle new_ch = tds().create_cell(); new_ch->set_vertices(vmap[i_ch->vertex(0)], vmap[i_ch->vertex(1)], vmap[i_ch->vertex(2)], vmap[i_ch->vertex(3)]); o_ch->set_neighbor(o_i,new_ch); new_ch->set_neighbor(i_i, o_ch); // For the other faces check, if they can also be glued for(i = 0; i < 4; i++) { if(i != i_i) { Facet f = std::pair(new_ch,i); Vertex_triple vt = make_vertex_triple(f); make_canonical_oriented_triple(vt); std::swap(vt.second,vt.third); typename Vertex_triple_Facet_map::iterator oit2 = outer_map.find(vt); if(oit2 == outer_map.end()) { std::swap(vt.second,vt.third); outer_map[vt]= f; } else { // glue the faces typename Vertex_triple_Facet_map::value_type o_vt_f_pair2 = *oit2; Cell_handle o_ch2 = o_vt_f_pair2.second.first; int o_i2 = o_vt_f_pair2.second.second; o_ch2->set_neighbor(o_i2,new_ch); new_ch->set_neighbor(i, o_ch2); outer_map.erase(oit2); } } } outer_map.erase(oit); } tds().delete_vertex(v); tds().delete_cells(hole.begin(), hole.end()); return remover; } template < class Gt, class Tds, class Lds > template < class VertexRemover > VertexRemover& Triangulation_3:: remove_3D(Vertex_handle v, VertexRemover& remover, const std::vector& inc_cells, std::vector& adj_vertices) { // Construct the set of vertex triples on the boundary with the facet just behind Vertex_triple_Facet_map outer_map; Vertex_triple_Facet_map inner_map; make_hole_3D(v, inc_cells, outer_map); CGAL_assertion(remover.hidden_points_begin() == remover.hidden_points_end()); // Output the hidden points. for(typename std::vector::const_iterator hi = inc_cells.begin(), hend = inc_cells.end(); hi != hend; ++hi) { remover.add_hidden_points(*hi); } bool inf = false; // Create a Delaunay triangulation of the points on the boundary // and make a map from the vertices in remover.tmp towards the vertices // in *this unsigned int i = 0; Vertex_handle_unique_hash_map vmap; Cell_handle ch = Cell_handle(); #ifdef CGAL_TRIANGULATION_3_USE_THE_4_POINTS_CONSTRUCTOR size_t num_vertices = adj_vertices.size(); if(num_vertices >= 5) { for(int j = 0 ; j < 4 ; ++j) { if(is_infinite(adj_vertices[j])) { std::swap(adj_vertices[j], adj_vertices[4]); break; } } Orientation o = orientation(adj_vertices[0]->point(), adj_vertices[1]->point(), adj_vertices[2]->point(), adj_vertices[3]->point()); if(o == NEGATIVE) std::swap(adj_vertices[0], adj_vertices[1]); if(o != ZERO) { Vertex_handle vh1, vh2, vh3, vh4; remover.tmp.init_tds(adj_vertices[0]->point(), adj_vertices[1]->point(), adj_vertices[2]->point(), adj_vertices[3]->point(), vh1, vh2, vh3, vh4); ch = vh1->cell(); vmap[vh1] = adj_vertices[0]; vmap[vh2] = adj_vertices[1]; vmap[vh3] = adj_vertices[2]; vmap[vh4] = adj_vertices[3]; i = 4; } } #endif for(; i < adj_vertices.size(); i++) { if(! is_infinite(adj_vertices[i])) { Vertex_handle vh = remover.tmp.insert(adj_vertices[i]->point(), ch); ch = vh->cell(); vmap[vh] = adj_vertices[i]; } else { inf = true; } } if(remover.tmp.dimension()==2) { Vertex_handle fake_inf = remover.tmp.insert(v->point()); vmap[fake_inf] = infinite_vertex(); } else { vmap[remover.tmp.infinite_vertex()] = infinite_vertex(); } CGAL_triangulation_assertion(remover.tmp.dimension() == 3); // Construct the set of vertex triples of remover.tmp // We reorient the vertex triple so that it matches those from outer_map // Also note that we use the vertices of *this, not of remover.tmp if(inf) { for(All_cells_iterator it = remover.tmp.all_cells_begin(), end = remover.tmp.all_cells_end(); it != end; ++it) { for(i=0; i < 4; i++) { Facet f = std::pair(it,i); Vertex_triple vt_aux = make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first],vmap[vt_aux.third],vmap[vt_aux.second]); make_canonical_oriented_triple(vt); inner_map[vt]= f; } } } else { for(Finite_cells_iterator it = remover.tmp.finite_cells_begin(), end = remover.tmp.finite_cells_end(); it != end; ++it) { for(i=0; i < 4; i++) { Facet f = std::pair(it,i); Vertex_triple vt_aux = make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first],vmap[vt_aux.third],vmap[vt_aux.second]); make_canonical_oriented_triple(vt); inner_map[vt]= f; } } } // Grow inside the hole, by extending the surface while(! outer_map.empty()) { typename Vertex_triple_Facet_map::iterator oit = outer_map.begin(); while(is_infinite(oit->first.first) || is_infinite(oit->first.second) || is_infinite(oit->first.third)) { ++oit; // otherwise the lookup in the inner_map fails // because the infinite vertices are different } typename Vertex_triple_Facet_map::value_type o_vt_f_pair = *oit; Cell_handle o_ch = o_vt_f_pair.second.first; unsigned int o_i = o_vt_f_pair.second.second; typename Vertex_triple_Facet_map::iterator iit = inner_map.find(o_vt_f_pair.first); CGAL_triangulation_assertion(iit != inner_map.end()); typename Vertex_triple_Facet_map::value_type i_vt_f_pair = *iit; Cell_handle i_ch = i_vt_f_pair.second.first; unsigned int i_i = i_vt_f_pair.second.second; // create a new cell and glue it to the outer surface Cell_handle new_ch = tds().create_cell(); new_ch->set_vertices(vmap[i_ch->vertex(0)], vmap[i_ch->vertex(1)], vmap[i_ch->vertex(2)], vmap[i_ch->vertex(3)]); o_ch->set_neighbor(o_i,new_ch); new_ch->set_neighbor(i_i, o_ch); // for the other faces check, if they can also be glued for(i = 0; i < 4; i++) { if(i != i_i) { Facet f = std::pair(new_ch,i); Vertex_triple vt = make_vertex_triple(f); make_canonical_oriented_triple(vt); std::swap(vt.second,vt.third); typename Vertex_triple_Facet_map::iterator oit2 = outer_map.find(vt); if(oit2 == outer_map.end()) { std::swap(vt.second,vt.third); outer_map[vt]= f; } else { // glue the faces typename Vertex_triple_Facet_map::value_type o_vt_f_pair2 = *oit2; Cell_handle o_ch2 = o_vt_f_pair2.second.first; int o_i2 = o_vt_f_pair2.second.second; o_ch2->set_neighbor(o_i2,new_ch); new_ch->set_neighbor(i, o_ch2); outer_map.erase(oit2); } } } outer_map.erase(oit); } tds().delete_vertex(v); tds().delete_cells(inc_cells.begin(), inc_cells.end()); return remover; } template < class Gt, class Tds, class Lds > template < class VertexRemover > void Triangulation_3:: remove(Vertex_handle v, VertexRemover& remover) { CGAL_triangulation_precondition(v != Vertex_handle()); CGAL_triangulation_precondition(!is_infinite(v)); CGAL_triangulation_expensive_precondition(tds().is_vertex(v)); if(test_dim_down (v)) { remove_dim_down (v, remover); } else { switch(dimension()) { case 1: remove_1D (v, remover); break; case 2: remove_2D (v, remover); break; case 3: remove_3D (v, remover); break; default: CGAL_triangulation_assertion (false); } } } template < class Gt, class Tds, class Lds > template < class VertexRemover > bool Triangulation_3:: remove(Vertex_handle v, VertexRemover& remover, bool *could_lock_zone) { // N.B.: dimension doesn't need to be atomic since the parallel removal // will never decrease the dimension (the last few removes are done // sequentially) CGAL_triangulation_precondition(v != Vertex_handle()); CGAL_triangulation_precondition(!is_infinite(v)); CGAL_triangulation_precondition(dimension() == 3); CGAL_triangulation_expensive_precondition(tds().is_vertex(v)); #ifdef CGAL_CONCURRENT_TRIANGULATION_3_PROFILING static Profile_branch_counter_3 bcounter( "early withdrawals / late withdrawals / successes [Delaunay_tri_3::remove]"); #endif bool removed = true; // Locking vertex v is a good start if(!this->try_lock_vertex(v)) { *could_lock_zone = false; #ifdef CGAL_CONCURRENT_TRIANGULATION_3_PROFILING bcounter.increment_branch_2(); // THIS is an early withdrawal! #endif } else { std::vector incident_cells; incident_cells.reserve(64); std::vector adj_vertices; adj_vertices.reserve(64); bool dim_down = test_dim_down_using_incident_cells_3( v, incident_cells, adj_vertices, could_lock_zone); if(*could_lock_zone) { if(dim_down) removed = false; else remove_3D (v, remover, incident_cells, adj_vertices); } } #ifdef CGAL_CONCURRENT_TRIANGULATION_3_PROFILING if(could_lock_zone) { if(*could_lock_zone) ++bcounter; else bcounter.increment_branch_1(); // THIS is a late withdrawal! } #endif return removed; } // The remove here uses the remover, but // no function envolving hidden points // will be used in this internal version template < class Gt, class Tds, class Lds > template < class VertexRemover, class OutputItCells > VertexRemover& Triangulation_3:: remove_dim_down(Vertex_handle v, VertexRemover& remover, OutputItCells fit) { remove_dim_down(v, remover); for(All_cells_iterator afi = tds().raw_cells_begin(); afi != tds().raw_cells_end(); afi++) { *fit++ = afi; } return remover; } template < class Gt, class Tds, class Lds > template < class VertexRemover, class OutputItCells > VertexRemover& Triangulation_3:: remove_1D(Vertex_handle v, VertexRemover& remover, OutputItCells fit) { Point p = v->point(); remove_1D(v, remover); *fit++ = locate(p); return remover; } template < class Gt, class Tds, class Lds > template < class VertexRemover, class OutputItCells > VertexRemover& Triangulation_3:: remove_2D(Vertex_handle v, VertexRemover& remover, OutputItCells fit) { CGAL_triangulation_precondition(dimension() == 2); std::list hole; make_hole_2D(v, hole, remover); fill_hole_2D(hole, remover, fit); tds().delete_vertex(v); return remover; } template < class Gt, class Tds, class Lds > template < class VertexRemover, class OutputItCells > VertexRemover& Triangulation_3:: remove_3D(Vertex_handle v, VertexRemover& remover, OutputItCells fit) { CGAL_triangulation_precondition(dimension() == 3); std::vector hole; hole.reserve(64); // Construct the set of vertex triples on the boundary // with the facet just behind Vertex_triple_Facet_map outer_map; Vertex_triple_Facet_map inner_map; make_hole_3D(v, outer_map, hole); CGAL_assertion(remover.hidden_points_begin() == remover.hidden_points_end()); // Output the hidden points. for(typename std::vector::iterator hi = hole.begin(), hend = hole.end(); hi != hend; ++hi) { remover.add_hidden_points(*hi); } bool inf = false; unsigned int i; // collect all vertices on the boundary std::vector vertices; vertices.reserve(64); adjacent_vertices(v, std::back_inserter(vertices)); // create a Delaunay triangulation of the points on the boundary // and make a map from the vertices in remover.tmp towards the vertices // in *this Vertex_handle_unique_hash_map vmap; Cell_handle ch = Cell_handle(); for(i=0; ipoint(), ch); ch = vh->cell(); vmap[vh] = vertices[i]; } else { inf = true; } } if(remover.tmp.dimension()==2) { Vertex_handle fake_inf = remover.tmp.insert(v->point()); vmap[fake_inf] = infinite_vertex(); } else { vmap[remover.tmp.infinite_vertex()] = infinite_vertex(); } CGAL_triangulation_assertion(remover.tmp.dimension() == 3); // Construct the set of vertex triples of remover.tmp // We reorient the vertex triple so that it matches those from outer_map // Also note that we use the vertices of *this, not of remover.tmp if(inf) { for(All_cells_iterator it = remover.tmp.all_cells_begin(), end = remover.tmp.all_cells_end(); it != end; ++it) { for(i=0; i < 4; i++) { Facet f = std::pair(it,i); Vertex_triple vt_aux = make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first], vmap[vt_aux.third], vmap[vt_aux.second]); make_canonical_oriented_triple(vt); inner_map[vt] = f; } } } else { for(Finite_cells_iterator it = remover.tmp.finite_cells_begin(), end = remover.tmp.finite_cells_end(); it != end; ++it) { for(i=0; i < 4; i++) { Facet f = std::pair(it,i); Vertex_triple vt_aux = make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first], vmap[vt_aux.third], vmap[vt_aux.second]); make_canonical_oriented_triple(vt); inner_map[vt] = f; } } } // Grow inside the hole, by extending the surface while(! outer_map.empty()) { typename Vertex_triple_Facet_map::iterator oit = outer_map.begin(); while(is_infinite(oit->first.first) || is_infinite(oit->first.second) || is_infinite(oit->first.third)) { ++oit; // otherwise the lookup in the inner_map fails // because the infinite vertices are different } typename Vertex_triple_Facet_map::value_type o_vt_f_pair = *oit; Cell_handle o_ch = o_vt_f_pair.second.first; unsigned int o_i = o_vt_f_pair.second.second; typename Vertex_triple_Facet_map::iterator iit = inner_map.find(o_vt_f_pair.first); CGAL_triangulation_assertion(iit != inner_map.end()); typename Vertex_triple_Facet_map::value_type i_vt_f_pair = *iit; Cell_handle i_ch = i_vt_f_pair.second.first; unsigned int i_i = i_vt_f_pair.second.second; // create a new cell and glue it to the outer surface Cell_handle new_ch = tds().create_cell(); *fit++ = new_ch; new_ch->set_vertices(vmap[i_ch->vertex(0)], vmap[i_ch->vertex(1)], vmap[i_ch->vertex(2)], vmap[i_ch->vertex(3)]); o_ch->set_neighbor(o_i,new_ch); new_ch->set_neighbor(i_i, o_ch); // for the other faces check, if they can also be glued for(i = 0; i < 4; i++) { if(i != i_i) { Facet f = std::pair(new_ch,i); Vertex_triple vt = make_vertex_triple(f); make_canonical_oriented_triple(vt); std::swap(vt.second, vt.third); typename Vertex_triple_Facet_map::iterator oit2 = outer_map.find(vt); if(oit2 == outer_map.end()) { std::swap(vt.second, vt.third); outer_map[vt]= f; } else { // glue the faces typename Vertex_triple_Facet_map::value_type o_vt_f_pair2 = *oit2; Cell_handle o_ch2 = o_vt_f_pair2.second.first; int o_i2 = o_vt_f_pair2.second.second; o_ch2->set_neighbor(o_i2, new_ch); new_ch->set_neighbor(i, o_ch2); outer_map.erase(oit2); } } } outer_map.erase(oit); } tds().delete_vertex(v); tds().delete_cells(hole.begin(), hole.end()); return remover; } template < class Gt, class Tds, class Lds > template < class VertexRemover, class OutputItCells > void Triangulation_3:: remove_and_give_new_cells(Vertex_handle v, VertexRemover& remover, OutputItCells fit) { CGAL_triangulation_precondition(v != Vertex_handle()); CGAL_triangulation_precondition(!is_infinite(v)); CGAL_triangulation_expensive_precondition(tds().is_vertex(v)); if(test_dim_down (v)) { remove_dim_down (v, remover, fit); } else { switch(dimension()) { case 1: remove_1D (v, remover, fit); break; case 2: remove_2D (v, remover, fit); break; case 3: remove_3D (v, remover, fit); break; default: CGAL_triangulation_assertion (false); } } } // The VertexInserter is needed so as to // allow us the usage of the insertion method // from the particular triangulation template < class Gt, class Tds, class Lds > template < class VertexRemover, class VertexInserter > typename Triangulation_3::Vertex_handle Triangulation_3:: move_if_no_collision(Vertex_handle v, const Point& p, VertexRemover& remover, VertexInserter& inserter) { CGAL_assertion(remover.hidden_points_begin() == remover.hidden_points_end()); CGAL_triangulation_precondition(!is_infinite(v)); if(v->point() == p) return v; const int dim = dimension(); // If displacements are known to be small, we might want to optimize by checking // whether there is a topological change or not before. // In this version, this will not be put inside this method because // it is for general purposes, and remaining Delaunay after motion // is a bit too restrictive. // // In the filtered version optimized for displacements, it will be used // as an a priori. However, a non-fully optimized but good version of // is_delaunay_after_displacement is provided as an internal method of // Delaunay_triangulation_3 (see the class for more details). Locate_type lt; int li, lj; Cell_handle loc = locate(p, lt, li, lj, v->cell()); if(lt == VERTEX) return loc->vertex(li); if(dim == 0) { v->set_point(p); return v; } size_type n_vertices = tds().number_of_vertices(); if((lt == OUTSIDE_AFFINE_HULL) && (dim == 1) && (n_vertices == 3)) { v->set_point(p); return v; } if((lt == OUTSIDE_AFFINE_HULL) && (dim == 2) && (n_vertices == 4)) { v->set_point(p); return v; } if((lt != OUTSIDE_AFFINE_HULL) && (dim == 1)) { if(loc->has_vertex(v)) { v->set_point(p); } else { Vertex_handle inserted = insert(p, lt, loc, li, lj); Cell_handle f = v->cell(); int i = f->index(v); if(i == 0) f = f->neighbor(1); CGAL_triangulation_assertion(f->index(v) == 1); Cell_handle g= f->neighbor(0); f->set_vertex(1, g->vertex(1)); f->set_neighbor(0,g->neighbor(0)); g->neighbor(0)->set_neighbor(1,f); g->vertex(1)->set_cell(f); tds().delete_cell(g); Cell_handle f_ins = inserted->cell(); i = f_ins->index(inserted); if(i == 0) f_ins = f_ins->neighbor(1); CGAL_triangulation_assertion(f_ins->index(inserted) == 1); Cell_handle g_ins = f_ins->neighbor(0); f_ins->set_vertex(1, v); g_ins->set_vertex(0, v); v->set_point(p); v->set_cell(inserted->cell()); tds().delete_vertex(inserted); } return v; } bool dim_down = test_dim_down(v); if((lt != OUTSIDE_AFFINE_HULL) && dim_down && (dim == 2)) { // verify if p and two static vertices are collinear in this case int iinf; Cell_handle finf = infinite_vertex()->cell(), fdone; fdone = finf; do { iinf = finf->index(infinite_vertex()); if(!finf->has_vertex(v)) break; finf = finf->neighbor((iinf+1)%3); } while(finf != fdone); iinf = ~iinf; if(this->collinear(finf->vertex(iinf&1)->point(), finf->vertex(iinf&2)->point(), p)) { v->set_point(p); _tds.decrease_dimension(loc, loc->index(v)); return v; } } if(((dim == 2) && (lt != OUTSIDE_AFFINE_HULL)) || ((lt == OUTSIDE_AFFINE_HULL) && (dim == 1))) { // This is insert must be from Delaunay (or the particular trian.) // not Triangulation_3 ! Vertex_handle inserted = inserter.insert(p, lt, loc, li, lj); std::list hole; make_hole_2D(v, hole, remover); fill_hole_2D(hole, remover); // fixing pointer Cell_handle fc = inserted->cell(), done(fc); std::vector faces_pt; faces_pt.reserve(16); do { faces_pt.push_back(fc); fc = fc->neighbor((fc->index(inserted) + 1)%3); } while(fc != done); std::size_t ss = faces_pt.size(); for(std::size_t k=0; kindex(inserted); f->set_vertex(i, v); } v->set_point(p); v->set_cell(inserted->cell()); tds().delete_vertex(inserted); return v; } if((lt != OUTSIDE_AFFINE_HULL) && dim_down && (dim == 3)) { // verify if p and two static vertices are collinear in this case std::vector ics; incident_cells(infinite_vertex(), std::back_inserter(ics)); std::size_t size = ics.size(); Cell_handle finf; for(std::size_t i=0; ihas_vertex(v)) break; } int iinf = finf->index(infinite_vertex()); if(remover.tmp.coplanar(finf->vertex((iinf+1)&3)->point(), finf->vertex((iinf+2)&3)->point(), finf->vertex((iinf+3)&3)->point(), p)) { v->set_point(p); _tds.decrease_dimension(loc, loc->index(v)); Facet f = *finite_facets_begin(); if(coplanar_orientation(f.first->vertex(0)->point(), f.first->vertex(1)->point(), f.first->vertex(2)->point()) == NEGATIVE) { tds().reorient(); } restore_edges_after_decrease_dimension(v, remover,inserter); return v; } } // This is insert must be from Delaunay (or the particular trian.) // not Triangulation_3 ! Vertex_handle inserted = inserter.insert(p, lt, loc, li, lj); std::vector hole; hole.reserve(64); // Construct the set of vertex triples on the boundary // with the facet just behind Vertex_triple_Facet_map outer_map; Vertex_triple_Facet_map inner_map; make_hole_3D(v, outer_map, hole); CGAL_assertion(remover.hidden_points_begin() == remover.hidden_points_end()); // Output the hidden points. for(typename std::vector::iterator hi = hole.begin(), hend = hole.end(); hi != hend; ++hi) { remover.add_hidden_points(*hi); } bool inf = false; unsigned int i; // collect all vertices on the boundary std::vector vertices; vertices.reserve(64); adjacent_vertices(v, std::back_inserter(vertices)); // create a Delaunay triangulation of the points on the boundary // and make a map from the vertices in remover.tmp towards the vertices // in *this Vertex_handle_unique_hash_map vmap; Cell_handle ch = Cell_handle(); for(i=0; i < vertices.size(); i++) { if(! is_infinite(vertices[i])) { Vertex_handle vh = remover.tmp.insert(vertices[i]->point(), ch); ch = vh->cell(); vmap[vh] = vertices[i]; } else { inf = true; } } if(remover.tmp.dimension() == 2) { Vertex_handle fake_inf = remover.tmp.insert(v->point()); vmap[fake_inf] = infinite_vertex(); } else { vmap[remover.tmp.infinite_vertex()] = infinite_vertex(); } CGAL_triangulation_assertion(remover.tmp.dimension() == 3); // Construct the set of vertex triples of remover.tmp // We reorient the vertex triple so that it matches those from outer_map // Also note that we use the vertices of *this, not of remover.tmp if(inf) { for(All_cells_iterator it = remover.tmp.all_cells_begin(), end = remover.tmp.all_cells_end(); it != end; ++it) { for(i=0; i < 4; i++) { Facet f = std::pair(it,i); Vertex_triple vt_aux = make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first],vmap[vt_aux.third],vmap[vt_aux.second]); make_canonical_oriented_triple(vt); inner_map[vt]= f; } } } else { for(Finite_cells_iterator it = remover.tmp.finite_cells_begin(), end = remover.tmp.finite_cells_end(); it != end; ++it) { for(i=0; i < 4; i++) { Facet f = std::pair(it,i); Vertex_triple vt_aux = make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first],vmap[vt_aux.third],vmap[vt_aux.second]); make_canonical_oriented_triple(vt); inner_map[vt]= f; } } } // Grow inside the hole, by extending the surface while(! outer_map.empty()) { typename Vertex_triple_Facet_map::iterator oit = outer_map.begin(); while(is_infinite(oit->first.first) || is_infinite(oit->first.second) || is_infinite(oit->first.third)) { ++oit; // otherwise the lookup in the inner_map fails // because the infinite vertices are different } typename Vertex_triple_Facet_map::value_type o_vt_f_pair = *oit; Cell_handle o_ch = o_vt_f_pair.second.first; unsigned int o_i = o_vt_f_pair.second.second; typename Vertex_triple_Facet_map::iterator iit = inner_map.find(o_vt_f_pair.first); CGAL_triangulation_assertion(iit != inner_map.end()); typename Vertex_triple_Facet_map::value_type i_vt_f_pair = *iit; Cell_handle i_ch = i_vt_f_pair.second.first; unsigned int i_i = i_vt_f_pair.second.second; // create a new cell and glue it to the outer surface Cell_handle new_ch = tds().create_cell(); new_ch->set_vertices(vmap[i_ch->vertex(0)], vmap[i_ch->vertex(1)], vmap[i_ch->vertex(2)], vmap[i_ch->vertex(3)]); o_ch->set_neighbor(o_i,new_ch); new_ch->set_neighbor(i_i, o_ch); // for the other faces check, if they can also be glued for(i = 0; i < 4; i++) { if(i != i_i) { Facet f = std::pair(new_ch,i); Vertex_triple vt = make_vertex_triple(f); make_canonical_oriented_triple(vt); std::swap(vt.second,vt.third); typename Vertex_triple_Facet_map::iterator oit2 = outer_map.find(vt); if(oit2 == outer_map.end()) { std::swap(vt.second,vt.third); outer_map[vt]= f; } else { // glue the faces typename Vertex_triple_Facet_map::value_type o_vt_f_pair2 = *oit2; Cell_handle o_ch2 = o_vt_f_pair2.second.first; int o_i2 = o_vt_f_pair2.second.second; o_ch2->set_neighbor(o_i2,new_ch); new_ch->set_neighbor(i, o_ch2); outer_map.erase(oit2); } } } outer_map.erase(oit); } // fixing pointer std::vector cells_pt; cells_pt.reserve(64); incident_cells(inserted, std::back_inserter(cells_pt)); std::size_t size = cells_pt.size(); for(std::size_t i=0; iset_vertex(c->index(inserted), v); } v->set_point(p); v->set_cell(inserted->cell()); tds().delete_vertex(inserted); tds().delete_cells(hole.begin(), hole.end()); return v; } // end of Vertex_handle template < class Gt, class Tds, class Lds > template < class VertexRemover, class VertexInserter > typename Triangulation_3::Vertex_handle Triangulation_3:: move(Vertex_handle v, const Point& p, VertexRemover& remover, VertexInserter& inserter) { CGAL_assertion(remover.hidden_points_begin() == remover.hidden_points_end()); CGAL_triangulation_precondition(!is_infinite(v)); if(v->point() == p) return v; Vertex_handle w = move_if_no_collision(v,p,remover,inserter); if(w != v) { remove(v, remover); return w; } return v; } // The VertexInserter is needed so as to allow us the usage of the insertion method // from the particular triangulation template < class Gt, class Tds, class Lds > template < class VertexRemover, class VertexInserter, class OutputItCells > typename Triangulation_3::Vertex_handle Triangulation_3:: move_if_no_collision_and_give_new_cells(Vertex_handle v, const Point& p, VertexRemover& remover, VertexInserter& inserter, OutputItCells fit) { CGAL_assertion(remover.hidden_points_begin() == remover.hidden_points_end()); CGAL_triangulation_precondition(!is_infinite(v)); if(v->point() == p) return v; const int dim = dimension(); // If displacements are known to be small, we might want to optimize by checking // whether there is a topological change or not before. // // In this version this will not be put inside this method because it is // for general purposes, and remaining Delaunay after motion is a bit // too restrictive. // // In the filtered version optimized for displacements, it will be used // as an a priori. However, a non-fully optimized but good version of // is_delaunay_after_displacement is provided as an internal method of // Delaunay_triangulation_3 (see the class for more details). Locate_type lt; int li, lj; Cell_handle loc = locate(p, lt, li, lj, v->cell()); if(lt == VERTEX) return loc->vertex(li); if(dim == 0) { v->set_point(p); return v; } int n_vertices = tds().number_of_vertices(); if((lt == OUTSIDE_AFFINE_HULL) && (dim == 1) && (n_vertices == 3)) { v->set_point(p); for(All_cells_iterator afi = tds().raw_cells_begin(); afi != tds().raw_cells_end(); afi++) { *fit++ = afi; } return v; } if((lt == OUTSIDE_AFFINE_HULL) && (dim == 2) && (n_vertices == 4)) { v->set_point(p); for(All_cells_iterator afi = tds().raw_cells_begin(); afi != tds().raw_cells_end(); afi++) { *fit++ = afi; } return v; } if((lt != OUTSIDE_AFFINE_HULL) && (dim == 1)) { if(loc->has_vertex(v)) { v->set_point(p); } else { Vertex_handle inserted = insert(p, lt, loc, li, lj); Cell_handle f = v->cell(); int i = f->index(v); if(i==0) f = f->neighbor(1); CGAL_triangulation_assertion(f->index(v) == 1); Cell_handle g = f->neighbor(0); f->set_vertex(1, g->vertex(1)); f->set_neighbor(0,g->neighbor(0)); g->neighbor(0)->set_neighbor(1,f); g->vertex(1)->set_cell(f); tds().delete_cell(g); *fit++ = f; Cell_handle f_ins = inserted->cell(); i = f_ins->index(inserted); if(i==0) f_ins = f_ins->neighbor(1); CGAL_triangulation_assertion(f_ins->index(inserted) == 1); Cell_handle g_ins = f_ins->neighbor(0); f_ins->set_vertex(1, v); g_ins->set_vertex(0, v); v->set_point(p); v->set_cell(inserted->cell()); tds().delete_vertex(inserted); } *fit++ = v->cell(); if(v->cell()->neighbor(0)->has_vertex(v)) *fit++ = v->cell()->neighbor(0); if(v->cell()->neighbor(1)->has_vertex(v)) *fit++ = v->cell()->neighbor(1); return v; } bool dim_down = test_dim_down(v); if((lt != OUTSIDE_AFFINE_HULL) && dim_down && (dim == 2)) { // Verify if p and two static vertices are collinear in this case int iinf; Cell_handle finf = infinite_vertex()->cell(), fdone; fdone = finf; do { iinf = finf->index(infinite_vertex()); if(!finf->has_vertex(v)) break; finf = finf->neighbor((iinf+1)%3); } while(finf != fdone); iinf = ~iinf; if(this->collinear(finf->vertex(iinf&1)->point(), finf->vertex(iinf&2)->point(), p)) { v->set_point(p); _tds.decrease_dimension(loc, loc->index(v)); for(All_cells_iterator afi = tds().raw_cells_begin(); afi != tds().raw_cells_end(); afi++) { *fit++ = afi; } return v; } } if(((dim == 2) && (lt != OUTSIDE_AFFINE_HULL)) || ((lt == OUTSIDE_AFFINE_HULL) && (dim == 1))) { std::set cells_set; // This is insert must be from Delaunay (or the particular trian.) // not Triangulation_3 ! Vertex_handle inserted = inserter.insert(p, lt, loc, li, lj); Cell_handle c = inserted->cell(), end = c; do { cells_set.insert(c); int i = c->index(inserted); c = c->neighbor((i+1)%3); } while(c != end); std::list hole; make_hole_2D(v, hole, remover, cells_set); fill_hole_2D(hole, remover, fit); // fixing pointer Cell_handle fc = inserted->cell(), done(fc); std::vector faces_pt; faces_pt.reserve(16); do { faces_pt.push_back(fc); fc = fc->neighbor((fc->index(inserted) + 1)%3); } while(fc != done); int ss = faces_pt.size(); for(int k=0; kindex(inserted); f->set_vertex(i, v); } v->set_point(p); v->set_cell(inserted->cell()); tds().delete_vertex(inserted); for(typename std::set::const_iterator ib = cells_set.begin(), iend = cells_set.end(); ib != iend; ib++) { *fit++ = *ib; } return v; } if((lt != OUTSIDE_AFFINE_HULL) && dim_down && (dim == 3)) { // verify if p and two static vertices are collinear in this case std::vector ics; incident_cells(infinite_vertex(), std::back_inserter(ics)); int size = ics.size(); Cell_handle finf; for(int i=0; ihas_vertex(v)) break; } int iinf = finf->index(infinite_vertex()); if(remover.tmp.coplanar(finf->vertex((iinf+1)&3)->point(), finf->vertex((iinf+2)&3)->point(), finf->vertex((iinf+3)&3)->point(), p)) { v->set_point(p); _tds.decrease_dimension(loc, loc->index(v)); Facet f = *finite_facets_begin(); if(coplanar_orientation(f.first->vertex(0)->point(), f.first->vertex(1)->point(), f.first->vertex(2)->point()) == NEGATIVE) { tds().reorient(); } restore_edges_after_decrease_dimension(v, remover,inserter); for(All_cells_iterator afi = tds().raw_cells_begin(); afi != tds().raw_cells_end(); afi++) { *fit++ = afi; } return v; } } std::set cells_set; // This is insert must be from Delaunay (or the particular trian.) // not Triangulation_3 ! Vertex_handle inserted = inserter.insert(p, lt, loc, li, lj); std::vector cells_tmp; cells_tmp.reserve(64); incident_cells(inserted, std::back_inserter(cells_tmp)); int size = cells_tmp.size(); for(int i=0; i hole; hole.reserve(64); // Construct the set of vertex triples on the boundary // with the facet just behind Vertex_triple_Facet_map outer_map; Vertex_triple_Facet_map inner_map; make_hole_3D(v, outer_map, hole); for(typename std::vector::const_iterator ib = hole.begin(), iend = hole.end(); ib != iend; ib++) { cells_set.erase(*ib); } CGAL_assertion(remover.hidden_points_begin() == remover.hidden_points_end()); // Output the hidden points. for(typename std::vector::iterator hi = hole.begin(), hend = hole.end(); hi != hend; ++hi) { remover.add_hidden_points(*hi); } bool inf = false; unsigned int i; // Collect all vertices on the boundary std::vector vertices; vertices.reserve(64); adjacent_vertices(v, std::back_inserter(vertices)); // Create a Delaunay triangulation of the points on the boundary // and make a map from the vertices in remover.tmp towards the vertices // in *this Vertex_handle_unique_hash_map vmap; Cell_handle ch = Cell_handle(); for(i=0; i < vertices.size(); i++) { if(! is_infinite(vertices[i])) { Vertex_handle vh = remover.tmp.insert(vertices[i]->point(), ch); ch = vh->cell(); vmap[vh] = vertices[i]; }else { inf = true; } } if(remover.tmp.dimension()==2) { Vertex_handle fake_inf = remover.tmp.insert(v->point()); vmap[fake_inf] = infinite_vertex(); } else { vmap[remover.tmp.infinite_vertex()] = infinite_vertex(); } CGAL_triangulation_assertion(remover.tmp.dimension() == 3); // Construct the set of vertex triples of remover.tmp // We reorient the vertex triple so that it matches those from outer_map // Also note that we use the vertices of *this, not of remover.tmp if(inf) { for(All_cells_iterator it = remover.tmp.all_cells_begin(), end = remover.tmp.all_cells_end(); it != end; ++it) { for(i=0; i < 4; i++) { Facet f = std::pair(it,i); Vertex_triple vt_aux = make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first], vmap[vt_aux.third], vmap[vt_aux.second]); make_canonical_oriented_triple(vt); inner_map[vt]= f; } } } else { for(Finite_cells_iterator it = remover.tmp.finite_cells_begin(), end = remover.tmp.finite_cells_end(); it != end; ++it) { for(i=0; i < 4; i++) { Facet f = std::pair(it,i); Vertex_triple vt_aux = make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first], vmap[vt_aux.third], vmap[vt_aux.second]); make_canonical_oriented_triple(vt); inner_map[vt]= f; } } } // Grow inside the hole, by extending the surface while(! outer_map.empty()) { typename Vertex_triple_Facet_map::iterator oit = outer_map.begin(); while(is_infinite(oit->first.first) || is_infinite(oit->first.second) || is_infinite(oit->first.third)) { ++oit; // otherwise the lookup in the inner_map fails // because the infinite vertices are different } typename Vertex_triple_Facet_map::value_type o_vt_f_pair = *oit; Cell_handle o_ch = o_vt_f_pair.second.first; unsigned int o_i = o_vt_f_pair.second.second; typename Vertex_triple_Facet_map::iterator iit = inner_map.find(o_vt_f_pair.first); CGAL_triangulation_assertion(iit != inner_map.end()); typename Vertex_triple_Facet_map::value_type i_vt_f_pair = *iit; Cell_handle i_ch = i_vt_f_pair.second.first; unsigned int i_i = i_vt_f_pair.second.second; // create a new cell and glue it to the outer surface Cell_handle new_ch = tds().create_cell(); *fit++ = new_ch; new_ch->set_vertices(vmap[i_ch->vertex(0)], vmap[i_ch->vertex(1)], vmap[i_ch->vertex(2)], vmap[i_ch->vertex(3)]); o_ch->set_neighbor(o_i,new_ch); new_ch->set_neighbor(i_i, o_ch); // for the other faces check, if they can also be glued for(i = 0; i < 4; i++) { if(i != i_i) { Facet f = std::pair(new_ch, i); Vertex_triple vt = make_vertex_triple(f); make_canonical_oriented_triple(vt); std::swap(vt.second,vt.third); typename Vertex_triple_Facet_map::iterator oit2 = outer_map.find(vt); if(oit2 == outer_map.end()) { std::swap(vt.second,vt.third); outer_map[vt] = f; } else { // glue the faces typename Vertex_triple_Facet_map::value_type o_vt_f_pair2 = *oit2; Cell_handle o_ch2 = o_vt_f_pair2.second.first; int o_i2 = o_vt_f_pair2.second.second; o_ch2->set_neighbor(o_i2,new_ch); new_ch->set_neighbor(i, o_ch2); outer_map.erase(oit2); } } } outer_map.erase(oit); } // fixing pointer std::vector cells_pt; cells_pt.reserve(64); incident_cells(inserted, std::back_inserter(cells_pt)); size = cells_pt.size(); for(int i=0; iset_vertex(c->index(inserted), v); } v->set_point(p); v->set_cell(inserted->cell()); tds().delete_vertex(inserted); tds().delete_cells(hole.begin(), hole.end()); for(typename std::set::const_iterator ib = cells_set.begin(), iend = cells_set.end(); ib != iend; ib++) { *fit++ = *ib; } return v; } template < class Gt, class Tds, class Lds > void Triangulation_3:: _make_big_hole_3D(Vertex_handle v, std::map& outer_map, std::vector& hole, std::vector& vertices, std::map& vstates) { Cell_handle start = v->cell(); start->tds_data().mark_processed(); hole.push_back(start); std::size_t i=0, n=1; while(i < n) { Cell_handle c = hole[i++]; for(int k=0; k<4; k++) { Vertex_handle v0 = c->vertex(k); const REMOVE_VERTEX_STATE vst = vstates[v0]; if(vst == CLEAR) { vstates[v0] = EXTREMITY; vertices.push_back(v0); } else if(vst == TO_REMOVE) { // we mark the vertices, so all the vertices // from the same cluster will be skipped // in the remove_cluster_3D function vstates[v0] = PROCESSED; } int i1 = vertex_triple_index(k, 0); int i2 = vertex_triple_index(k, 1); int i3 = vertex_triple_index(k, 2); Vertex_handle v1 = c->vertex(i1); Vertex_handle v2 = c->vertex(i2); Vertex_handle v3 = c->vertex(i3); Cell_handle opp_cit = c->neighbor(k); int opp_i = tds().mirror_index(c, k); Vertex_handle vm = opp_cit->vertex(opp_i); bool pb1 = false, pb2 = false, pb3 = false, pbm = false; const REMOVE_VERTEX_STATE vst1 = vstates[v1]; pb1 = vst1 == TO_REMOVE || vst1 == PROCESSED; if(!pb1) { const REMOVE_VERTEX_STATE vst2 = vstates[v2]; pb2 = vst2 == TO_REMOVE || vst2 == PROCESSED; if(!pb2) { const REMOVE_VERTEX_STATE vst3 = vstates[v3]; pb3 = vst3 == TO_REMOVE || vst3 == PROCESSED; if(!pb3) { const REMOVE_VERTEX_STATE vstm = vstates[vm]; pbm = vstm == TO_REMOVE || vstm == PROCESSED; } } } bool bad_opposite_cell = pb1 || pb2 || pb3 || pbm; // update the hole if needed // when the vertex is not to be removed if(bad_opposite_cell) { if(opp_cit->tds_data().is_clear()) { hole.push_back(opp_cit); opp_cit->tds_data().mark_processed(); n++; } continue; } Facet f(opp_cit, opp_i); Vertex_triple vt = make_vertex_triple(f); make_canonical_oriented_triple(vt); outer_map[vt] = f; v1->set_cell(opp_cit); v2->set_cell(opp_cit); v3->set_cell(opp_cit); vm->set_cell(opp_cit); } } std::size_t vsize = vertices.size(); for(std::size_t i=0; i template < class InputIterator, class VertexRemover > bool Triangulation_3:: _remove_cluster_3D(InputIterator first, InputIterator beyond, VertexRemover& remover, std::map& vstates) { InputIterator init = first; while(first != beyond) { Vertex_handle v = *first++; if(vstates[v] == PROCESSED) continue; // _make_big_hole_3D and we fill the hole for each cluster vstates[v] = PROCESSED; // here, we make the hole for the cluster with v inside typedef std::map Vertex_triple_Facet_map; std::vector hole; std::vector vertices; hole.reserve(64); vertices.reserve(32); Vertex_triple_Facet_map outer_map; _make_big_hole_3D(v, outer_map, hole, vertices, vstates); // the connectivity is totally lost, we need to rebuild if(!outer_map.size()) { std::size_t nh = hole.size(); for(std::size_t i=0; itds_data().clear(); return false; } std::size_t vsi = vertices.size(); bool inf = false; std::size_t i; Vertex_handle_unique_hash_map vmap; Cell_handle ch = Cell_handle(); if(vsi > 100) { // spatial sort if too many points std::vector vps; std::map mp_vps; for(i=0; iis_infinite(vv)) { vps.push_back(vv->point()); mp_vps[vv->point()] = vv; } else { inf = true; } } // Spatial sorting can only be applied to bare points, so we need an adaptor typedef typename Geom_traits::Construct_point_3 Construct_point_3; typedef typename boost::result_of::type Ret; typedef boost::function_property_map fpmap; typedef CGAL::Spatial_sort_traits_adapter_3 Search_traits_3; spatial_sort(vps.begin(), vps.end(), Search_traits_3( boost::make_function_property_map( geom_traits().construct_point_3_object()), geom_traits())); std::size_t svps = vps.size(); for(i=0; i < svps; i++) { Vertex_handle vv = mp_vps[vps[i]]; Vertex_handle vh = remover.tmp.insert(vv->point(), ch); ch = vh->cell(); vmap[vh] = vv; } if(remover.tmp.dimension()==2) { Vertex_handle fake_inf = remover.tmp.insert(v->point()); vmap[fake_inf] = this->infinite_vertex(); } else { vmap[remover.tmp.infinite_vertex()] = this->infinite_vertex(); } } else { for(i=0; i < vsi; i++) { if(!this->is_infinite(vertices[i])) { Vertex_handle vh = remover.tmp.insert(vertices[i]->point(), ch); ch = vh->cell(); vmap[vh] = vertices[i]; } else { inf = true; } } if(remover.tmp.dimension()==2) { Vertex_handle fake_inf = remover.tmp.insert(v->point()); vmap[fake_inf] = this->infinite_vertex(); } else { vmap[remover.tmp.infinite_vertex()] = this->infinite_vertex(); } } Vertex_triple_Facet_map inner_map; if(inf) { for(All_cells_iterator it = remover.tmp.all_cells_begin(), end = remover.tmp.all_cells_end(); it != end; ++it) { for(unsigned int index=0; index < 4; index++) { Facet f = std::pair(it,index); Vertex_triple vt_aux = this->make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first], vmap[vt_aux.third], vmap[vt_aux.second]); this->make_canonical_oriented_triple(vt); inner_map[vt]= f; } } } else { for(Finite_cells_iterator it = remover.tmp.finite_cells_begin(), end = remover.tmp.finite_cells_end(); it != end; ++it) { for(unsigned int index=0; index < 4; index++) { Facet f = std::pair(it,index); Vertex_triple vt_aux = this->make_vertex_triple(f); Vertex_triple vt(vmap[vt_aux.first], vmap[vt_aux.third], vmap[vt_aux.second]); this->make_canonical_oriented_triple(vt); inner_map[vt]= f; } } } // Grow inside the hole, by extending the surface while(! outer_map.empty()) { typename Vertex_triple_Facet_map::iterator oit = outer_map.begin(); while(this->is_infinite(oit->first.first) || this->is_infinite(oit->first.second) || this->is_infinite(oit->first.third)) { ++oit; // otherwise the lookup in the inner_map fails // because the infinite vertices are different } typename Vertex_triple_Facet_map::value_type o_vt_f_pair = *oit; Cell_handle o_ch = o_vt_f_pair.second.first; unsigned int o_i = o_vt_f_pair.second.second; typename Vertex_triple_Facet_map::iterator iit = inner_map.find(o_vt_f_pair.first); CGAL_triangulation_assertion(iit != inner_map.end()); typename Vertex_triple_Facet_map::value_type i_vt_f_pair = *iit; Cell_handle i_ch = i_vt_f_pair.second.first; unsigned int i_i = i_vt_f_pair.second.second; // create a new cell and glue it to the outer surface Cell_handle new_ch = tds().create_cell(); new_ch->set_vertices(vmap[i_ch->vertex(0)], vmap[i_ch->vertex(1)], vmap[i_ch->vertex(2)], vmap[i_ch->vertex(3)]); o_ch->set_neighbor(o_i,new_ch); new_ch->set_neighbor(i_i, o_ch); for(int j=0; j<4; j++) new_ch->vertex(j)->set_cell(new_ch); // for the other faces check, if they can also be glued for(unsigned int index = 0; index < 4; index++) { if(index != i_i) { Facet f = std::pair