// Copyright (c) 2009 INRIA Sophia-Antipolis (France). // All rights reserved. // // This file is part of CGAL (www.cgal.org). // You can redistribute it and/or modify it under the terms of the GNU // General Public License as published by the Free Software Foundation, // either version 3 of the License, or (at your option) any later version. // // Licensees holding a valid commercial license may use this file in // accordance with the commercial license agreement provided with the software. // // This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE // WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. // // $URL$ // $Id$ // SPDX-License-Identifier: GPL-3.0+ // // // Author(s) : Stephane Tayeb // //****************************************************************************** // //****************************************************************************** #ifndef CGAL_MESH_3_C3T3_HELPERS_H #define CGAL_MESH_3_C3T3_HELPERS_H #include #include #include #include #include #include #include #include #include #include #include #ifdef CGAL_MESH_3_PROFILING #include #endif #include #include #include #include #include #include #include #include #include #ifdef CGAL_LINKED_WITH_TBB # include # include #endif #include #include #include namespace CGAL { namespace Mesh_3 { #ifdef CGAL_INTRUSIVE_LIST template class Intrusive_list { public: typedef Type Type_handle; typedef Type_handle& reference; typedef const Type_handle& const_reference; typedef Type_handle value_type; Intrusive_list() : f(), b(), n(0) {} ~Intrusive_list() { clear(); } Intrusive_list(const Intrusive_list& ) { CGAL_assertion(false); } #ifdef CGAL_CONSTRUCT_INTRUSIVE_LIST_RANGE_CONSTRUCTOR template Intrusive_list(IT first, IT last) : f(), b(), n(0) { if(first == last){ return; } f = *first; Type_handle ch = f; ++n; ++first; while(first != last){ if((ch != Type(*first)) && ((*first)->next_intrusive()==Type_handle())){ // not yet inserted ch->set_next_intrusive(*first); (*first)->set_previous_intrusive(ch); ch = *first; ++n; } ++first; } b = ch; b->set_next_intrusive(f); f->set_previous_intrusive(b); } #endif bool is_valid() const { if(n < 0){ std::cerr << "n < 0" << std::endl; return false; } if(n == 0){ if (f != Type_handle()){ std::cerr << "n==0, but f!= Type_handle()" << std::endl; return false; } if (b != Type_handle()){ std::cerr << "n==0, but b!= Type_handle()" << std::endl; return false; } }else{ if(f->previous_intrusive() != b){ std::cerr << "f->previous_intrusive() != b" << std::endl; return false; } if(b->next_intrusive() != f){ std::cerr << "b->next_intrusive() != f" << std::endl; return false; } Type_handle ch = f; for(std::size_t i = 1; i < n; i++){ if(ch->next_intrusive()->previous_intrusive() != ch){ std::cerr << "ch->next_intrusive()->previous_intrusive() != ch" << std::endl; return false; } ch = ch->next_intrusive(); } if(ch != b){ std::cerr << "ch!= b)" << std::endl; return false; } } return true; } void clear() { if(!empty()){ while( f!= b ){ Type_handle h = f; f=f->next_intrusive(); h->set_previous_intrusive(Type_handle()); h->set_next_intrusive(Type_handle()); } b->set_previous_intrusive(Type_handle()); b->set_next_intrusive(Type_handle()); f = b = Type_handle(); } n = 0; } std::size_t size() const { return n; } struct iterator { Type_handle pos, b; typedef Type_handle value_type; typedef const Type_handle* pointer; typedef const Type_handle& reference; typedef std::size_t size_type; typedef std::ptrdiff_t difference_type; typedef std::forward_iterator_tag iterator_category; iterator(Type_handle f, Type_handle b) : pos(f), b(b) {} iterator() : pos() {} iterator& operator++() { if(pos != Type_handle()){ if(pos == b){ pos = Type_handle(); // past the end }else { pos = pos->next_intrusive(); } } return *this; } iterator operator++(int) { iterator tmp(*this); ++(*this); return tmp; } bool operator==(const iterator& i) const { return pos == i.pos; } bool operator!=(const iterator& i) const { return !(*this == i); } reference operator*() const { return pos; } pointer operator->() const { return pos; } }; // struct iterator iterator begin() { return iterator(f,b); } iterator end() { return iterator(); } Type_handle front() const { return f; } Type_handle& front() { return f; } Type_handle back() const { return b; } Type_handle& back() { return b; } iterator insert(iterator /* position */, const Type_handle& ch) { CGAL_assertion( (ch->next_intrusive() == Type_handle() && ch->previous_intrusive() == Type_handle()) || (ch->next_intrusive() != Type_handle() && ch->previous_intrusive() != Type_handle()) ); CGAL_expensive_assertion(is_valid()); if(ch->next_intrusive() != Type_handle()){ return iterator(ch->next_intrusive()/*first*/, ch/*last*/); } else{ insert(ch); return iterator(ch->next_intrusive()/*first*/, ch/*last*/); } } void insert(Type_handle ch) { CGAL_assertion( (ch->next_intrusive() == Type_handle() && ch->previous_intrusive() == Type_handle()) || (ch->next_intrusive() != Type_handle() && ch->previous_intrusive() != Type_handle()) ); CGAL_expensive_assertion(is_valid()); if(ch->next_intrusive() != Type_handle()){ return; } if(empty()){ f = b = ch; ch->set_next_intrusive(ch); ch->set_previous_intrusive(ch); } else { ch->set_next_intrusive(f); ch->set_previous_intrusive(b); f->set_previous_intrusive(ch); b->set_next_intrusive(ch); b = ch; } n++; } void erase(Type_handle ch) { CGAL_assertion( (ch->next_intrusive() == Type_handle() && ch->previous_intrusive() == Type_handle()) || (ch->next_intrusive() != Type_handle() && ch->previous_intrusive() != Type_handle()) ); CGAL_expensive_assertion(is_valid()); if(ch->next_intrusive() == Type_handle()){ return; } if(f == b){ // only 1 element in the list CGAL_assertion(f == ch); CGAL_assertion(n == 1); f = b = Type_handle(); } else { if(f == ch){ f = f->next_intrusive(); } if(b == ch){ b = b->previous_intrusive(); } Type_handle p = ch->previous_intrusive(), n = ch->next_intrusive(); p->set_next_intrusive(n); n->set_previous_intrusive(p); } ch->set_next_intrusive(Type_handle()); ch->set_previous_intrusive(Type_handle()); CGAL_assertion(ch->next_intrusive() == Type_handle()); CGAL_assertion(ch->previous_intrusive() == Type_handle()); n--; } bool empty() const { if(f == Type_handle()){ CGAL_assertion(b == Type_handle()); CGAL_assertion(n == 0); } return f == Type_handle(); } bool contains(Type_handle th) const { if(th->next_intrusive() == Type_handle()) { CGAL_assertion(th->previous_intrusive() == Type_handle()); return true; } else return false; } void push_back(Type_handle ch) { insert(ch); } private: Type_handle f,b; std::size_t n; }; #endif // #ifdef CGAL_INTRUSIVE_LIST /************************************************ // Class C3T3_helpers_base // Two versions: sequential / parallel ************************************************/ // Sequential template class C3T3_helpers_base { protected: typedef typename Tr::Geom_traits Gt; typedef typename Tr::Bare_point Bare_point; typedef typename Tr::Weighted_point Weighted_point; typedef typename Gt::FT FT; typedef typename Tr::Vertex_handle Vertex_handle; typedef typename Tr::Cell_handle Cell_handle; typedef typename Tr::Facet Facet; typedef typename Tr::Lock_data_structure Lock_data_structure; C3T3_helpers_base(Lock_data_structure *) {} Lock_data_structure *get_lock_data_structure() const { return 0; } public: // Dummy locks/unlocks bool try_lock_point(const Weighted_point &, int = 0) const { return true; } bool try_lock_vertex(Vertex_handle, int = 0) const { return true; } bool try_lock_point_no_spin(const Weighted_point &, int = 0) const { return true; } bool try_lock_vertex_no_spin(Vertex_handle, int = 0) const { return true; } bool try_lock_element(Cell_handle, int = 0) const { return true; } bool try_lock_element(const Facet &, int = 0) const { return true; } bool is_point_locked_by_this_thread(const Weighted_point &) const { return false; } bool is_cell_locked_by_this_thread(const Cell_handle &) const { return false; } void unlock_all_elements() const {} // Dummy locks/unlocks void lock_outdated_cells() const {} void unlock_outdated_cells() const {} void lock_moving_vertices() const {} void unlock_moving_vertices() const {} void lock_vertex_to_proj() const {} void unlock_vertex_to_proj() const {} }; #ifdef CGAL_LINKED_WITH_TBB // Parallel template class C3T3_helpers_base { protected: typedef typename Tr::Geom_traits Gt; typedef typename Tr::Bare_point Bare_point; typedef typename Tr::Weighted_point Weighted_point; typedef typename Tr::Vertex_handle Vertex_handle; typedef typename Tr::Cell_handle Cell_handle; typedef typename Tr::Facet Facet; typedef typename Tr::Lock_data_structure Lock_data_structure; C3T3_helpers_base(Lock_data_structure *lock_ds) : m_lock_ds(lock_ds) {} public: // LOCKS (CONCURRENCY) /*Lock_data_structure *get_lock_data_structure() const { return m_lock_ds; }*/ bool try_lock_point(const Weighted_point &p, int lock_radius = 0) const { if (m_lock_ds) { return m_lock_ds->try_lock(p, lock_radius); } return true; } bool try_lock_vertex(Vertex_handle vh, int lock_radius = 0) const { if (m_lock_ds) { return m_lock_ds->try_lock(vh->point(), lock_radius); } return true; } bool try_lock_point_no_spin(const Weighted_point &p, int lock_radius = 0) const { if (m_lock_ds) { return m_lock_ds->template try_lock(p, lock_radius); } return true; } bool try_lock_vertex_no_spin(Vertex_handle vh, int lock_radius = 0) const { return try_lock_point_no_spin(vh->point(), lock_radius); } bool try_lock_element(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) { Vertex_handle vh = cell_handle->vertex(iVertex); success = try_lock_vertex(vh, lock_radius); } return success; } bool try_lock_element(const Facet &facet, int lock_radius = 0) const { bool success = true; // Lock the element area on the grid Cell_handle cell = facet.first; for (int iVertex = (facet.second+1)&3 ; success && iVertex != facet.second ; iVertex = (iVertex+1)&3) { Vertex_handle vh = cell->vertex(iVertex); success = try_lock_vertex(vh, lock_radius); } return success; } bool is_point_locked_by_this_thread(const Weighted_point &p) const { bool locked = true; if (m_lock_ds) { locked = m_lock_ds->is_locked_by_this_thread(p); } return locked; } 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; } void unlock_all_elements() const { if (m_lock_ds) { m_lock_ds->unlock_all_points_locked_by_this_thread(); } } void lock_outdated_cells() const { m_mut_outdated_cells.lock(); } void unlock_outdated_cells() const { m_mut_outdated_cells.unlock(); } void lock_moving_vertices() const { m_mut_moving_vertices.lock(); } void unlock_moving_vertices() const { m_mut_moving_vertices.unlock(); } void lock_vertex_to_proj() const { m_mut_vertex_to_proj.lock(); } void unlock_vertex_to_proj() const { m_mut_vertex_to_proj.unlock(); } protected: Lock_data_structure *m_lock_ds; typedef tbb::mutex Mutex_type; mutable Mutex_type m_mut_outdated_cells; mutable Mutex_type m_mut_moving_vertices; mutable Mutex_type m_mut_vertex_to_proj; }; #endif // CGAL_LINKED_WITH_TBB /************************************************ * * C3T3_helpers class * ************************************************/ template class C3T3_helpers : public C3T3_helpers_base { // ----------------------------------- // Private types // ----------------------------------- typedef C3T3_helpers Self; typedef C3T3_helpers_base Base; typedef typename C3T3::Concurrency_tag Concurrency_tag; typedef typename Base::Lock_data_structure Lock_data_structure; typedef typename C3T3::Triangulation Tr; typedef Tr Triangulation; typedef typename Tr::Geom_traits Gt; typedef typename Gt::FT FT; typedef typename Tr::Bare_point Bare_point; typedef typename Tr::Weighted_point Weighted_point; typedef typename Gt::Vector_3 Vector_3; typedef typename Gt::Plane_3 Plane_3; typedef typename Gt::Tetrahedron_3 Tetrahedron; typedef typename Tr::Vertex_handle Vertex_handle; typedef typename Tr::Facet Facet; typedef typename Tr::Cell Cell; typedef typename Tr::Cell_handle Cell_handle; typedef typename C3T3::Surface_patch_index Surface_patch_index; typedef typename C3T3::Subdomain_index Subdomain_index; typedef typename C3T3::Index Index; typedef boost::optional Surface_patch; typedef boost::optional Subdomain; typedef std::vector Cell_vector; typedef std::set Cell_set; typedef std::vector Tet_vector; typedef std::vector Facet_vector; typedef std::vector Vertex_vector; typedef CGAL::Hash_handles_with_or_without_timestamps Hash_fct; typedef boost::unordered_set Vertex_set; #ifdef CGAL_INTRUSIVE_LIST typedef Intrusive_list Outdated_cell_set; #else typedef Cell_set Outdated_cell_set; #endif //CGAL_INTRUSIVE_LIST #ifdef CGAL_INTRUSIVE_LIST typedef Intrusive_list Moving_vertices_set; #else typedef Vertex_set Moving_vertices_set; #endif //CGAL_INTRUSIVE_LIST private: typedef std::pair Ordered_edge; // Vertex_data is the dimension and Index of the third vertex of the facet. typedef std::pair Vertex_data; typedef std::pair Facet_topology_description; // Facet_boundary stores the edges, of the boundary of surface facets, with meta-data. typedef std::map Facet_boundary; typedef Triangulation_helpers Th; public: // ----------------------------------- // Public interface // ----------------------------------- typedef boost::optional Update_mesh; using Base::try_lock_point; using Base::try_lock_vertex; using Base::try_lock_point_no_spin; using Base::try_lock_vertex_no_spin; using Base::try_lock_element; using Base::is_point_locked_by_this_thread; using Base::is_cell_locked_by_this_thread; using Base::unlock_all_elements; using Base::lock_outdated_cells; using Base::unlock_outdated_cells; using Base::lock_moving_vertices; using Base::unlock_moving_vertices; using Base::lock_vertex_to_proj; using Base::unlock_vertex_to_proj; /** * Constructor */ C3T3_helpers(C3T3& c3t3, const MeshDomain& domain, Lock_data_structure *lock_ds = NULL) : Base(lock_ds) , c3t3_(c3t3) , tr_(c3t3.triangulation()) , domain_(domain) { } /** * @brief tries to move \c old_vertex to \c new_position in the mesh * @param old_vertex the old vertex * @param move the translation from the old position to the new * @param new_position the new position of \c old_vertex * @param criterion the criterion which will be used to verify the new * position is ok. c3t3 minimal value of new criterion shall not decrease. * @param modified_vertices contains the vertices incident to cells which * may have been impacted by relocation * @return a pair which contains: * - a bool which is \c true if the move has been done. * - a Vertex_handle which is always filled and may be the new vertex (if * the move is a success), or the vertex which lies at \c v's position in * the updated c3t3. */ template std::pair update_mesh(const Vertex_handle& old_vertex, const Vector_3& move, const Weighted_point& new_position, const SliverCriterion& criterion, OutputIterator modified_vertices, bool *could_lock_zone = NULL); /** @brief tries to move \c old_vertex to \c new_position in the mesh * * Same as update_mesh, but with the precondition that * Th().no_topological_change(tr_, old_vertex, new_position, * incident_cells_) return false. */ template std::pair update_mesh_topo_change(const Vertex_handle& old_vertex, const Weighted_point& new_position, const SliverCriterion& criterion, OutputIterator modified_vertices, bool *could_lock_zone = NULL); /** * Updates mesh moving vertex \c old_vertex to \c new_position. Returns the * new vertex of the triangulation. * * Insert into modified vertices the vertices which are impacted by to move. */ template Vertex_handle update_mesh(const Vertex_handle& old_vertex, const Vector_3& new_position, OutputIterator modified_vertices, bool fill_modified_vertices = true); /** * Updates mesh moving vertex \c old_vertex to \c new_position. Returns the * new vertex of the triangulation. */ Vertex_handle update_mesh(const Vertex_handle& old_vertex, const Vector_3& move) { return update_mesh(old_vertex, move, Emptyset_iterator(), false); } /** * Rebuilds restricted Delaunay */ template void rebuild_restricted_delaunay(ForwardIterator first_cell, ForwardIterator last_cell) { Moving_vertices_set mvs; return rebuild_restricted_delaunay(first_cell, last_cell, mvs); } /** * Rebuilds restricted Delaunay */ template void rebuild_restricted_delaunay(ForwardIterator first_cell, ForwardIterator last_cell, Moving_vertices_set& moving_vertices); void update_restricted_facets(); #ifdef CGAL_INTRUSIVE_LIST template void rebuild_restricted_delaunay(OutdatedCells& outdated_cells, Moving_vertices_set& moving_vertices); #endif /** * @brief Project \c p on surface, using incident facets of \c v * @param v The vertex from which p was moved * @param p The point to project * @param index The index of the surface patch where v lies, if known. * @return the projected point * * \c p is projected as follows using normal of least square fitting plane * on \c v incident surface points. If \c index is specified, only * surface points that are on the same surface patch are used to compute * the fitting plane. */ Bare_point project_on_surface(const Vertex_handle& v, const Bare_point& p, Surface_patch_index index = Surface_patch_index()) const; /** * Returns the minimum value for criterion for incident cells of \c vh */ template FT min_incident_value(const Vertex_handle& vh, const SliverCriterion& criterion) const; /** * Moves \c old_vertex to \c new_position * Stores the cells which have to be updated in \c outdated_cells * Updates the Vertex_handle old_vertex to its new value in \c moving_vertices * The second one (with the could_lock_zone param) is for the parallel version */ Vertex_handle move_point(const Vertex_handle& old_vertex, const Vector_3& move, Outdated_cell_set& outdated_cells_set, Moving_vertices_set& moving_vertices) const; Vertex_handle move_point(const Vertex_handle& old_vertex, const Vector_3& move, Outdated_cell_set& outdated_cells_set, Moving_vertices_set& moving_vertices, bool *could_lock_zone) const; /** * Try to lock the incident cells and return them in \c cells * Return value: * - false: everything is unlocked and \c cells is empty * - true: incident cells are locked and \c cells contains all of them */ bool try_lock_and_get_incident_cells(const Vertex_handle& v, Cell_vector &cells) const; /** * Try to lock ALL the incident cells and return in \c cells the ones * whose \c filter says "true". * Return value: * - false: everything is unlocked and \c cells is empty * - true: ALL incident cells are locked and \c cells is filled */ template bool try_lock_and_get_incident_cells(const Vertex_handle& v, Cell_vector &cells, const Filter &filter) const; /** * Try to lock ALL the incident cells and return in \c cells the slivers * Return value: * - false: everything is unlocked and \c cells is empty * - true: incident cells are locked and \c cells contains all slivers */ template bool try_lock_and_get_incident_slivers(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound, Cell_vector &cells) const; template void get_incident_slivers_without_using_tds_data(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound, Cell_vector &slivers) const; /** * Outputs to out the sliver (wrt \c criterion and \c sliver_bound) incident * to \c v */ template OutputIterator incident_slivers(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound, OutputIterator out) const; template OutputIterator new_incident_slivers(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound, OutputIterator out) const; /** * Returns the sliver (wrt \c criterion and \c sliver_bound) incident to \c v */ template Cell_vector incident_slivers(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound) const { Cell_vector slivers; incident_slivers(v, criterion, sliver_bound, std::back_inserter(slivers)); return slivers; } template Cell_vector new_incident_slivers(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound) const { Cell_vector slivers; new_incident_slivers(v, criterion, sliver_bound, std::back_inserter(slivers)); return slivers; } /** * Returns the number of slivers incident to \c v */ template std::size_t number_of_incident_slivers(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound) const; template bool is_sliver(const Cell_handle& ch, const SliverCriterion& criterion, const FT& sliver_bound) const; /** * Returns the minimum criterion value of cells contained in \c cells * Precondition: cells of \c cells must not be infinite. * Warning: Here we don't check if cells are in c3t3 */ template FT min_sliver_value(const Cell_vector& cells, const SliverCriterion& criterion, const bool use_cache = true) const; /** * Reset cache validity of all cells of c3t3_ */ void reset_cache() const { for(typename C3T3::Cells_in_complex_iterator it = c3t3_.cells_in_complex_begin(); it != c3t3_.cells_in_complex_end(); ++it) it->reset_cache_validity(); } private: // ----------------------------------- // Useful Functors // ----------------------------------- /** * @class Get_all_facets * * A functor which adds to an output iterator canonical facets of a cell */ template class Get_all_facets { public: Get_all_facets(const Triangulation& tr, OutputIterator out) : tr_(tr) , out_(out) {} void operator()(const Cell_handle& cell) { #ifndef CGAL_MESH_3_NEW_GET_FACETS for ( int i=0 ; i<4 ; ++i ) if ( !tr_.is_infinite(cell,i) ) *out_++ = canonical_facet(cell,i); #else // Instead of iterating over the facets we iterate over the vertices // If a vertex is infinite we report only the facet opposite to it and return // If all vertices are finite we report all facets // This approach makes less tests if vertices are infinite int i=0; for ( ; i<4 ; ++i ){ if ( tr_.is_infinite(cell->vertex(i)) ){ *out_++ = canonical_facet(cell,i); return; } } for ( i=0 ; i<4 ; ++i ){ *out_++ = canonical_facet(cell,i); } #endif } private: Facet canonical_facet(const Cell_handle& c, const int i) const { #ifndef CGAL_MESH_3_NEW_GET_FACETS Facet facet(c,i); Facet mirror = tr_.mirror_facet(facet); return ( (mirrorneighbor(i); if(c < n){ return Facet(c,i); }else{ return Facet(n,n->index(c)); } #endif } private: const Triangulation& tr_; OutputIterator out_; }; /** * @class Is_in_c3t3 * * A functor which returns true if a given handle is in c3t3 */ template class Is_in_c3t3 : public CGAL::cpp98::unary_function { public: Is_in_c3t3(const C3T3& c3t3) : c3t3_(c3t3) { } bool operator()(const Handle& h) const { return c3t3_.is_in_complex(h); } private: const C3T3& c3t3_; }; /** * @class Is_sliver * * A functor which answers true if a Cell_handle is a sliver */ template struct Is_sliver : public CGAL::cpp98::unary_function { Is_sliver(const C3T3& c3t3, const SliverCriterion& criterion, const FT& bound = 0) : c3t3_(c3t3) , criterion_(criterion) , bound_(bound) { } bool operator()(const Cell_handle& c) const { if ( c3t3_.is_in_complex(c) ) { CGAL_assertion(!c3t3_.triangulation().is_infinite(c)); if ( ! c->is_cache_valid() ) { Sliver_criterion_value sc_value(c3t3_.triangulation(), criterion_); (void) sc_value(c); // 'sc_value::operator()' updates the cache of 'c' } else { CGAL_expensive_assertion(c->sliver_value() == criterion_(c)); } if(bound_ > 0) return ( c->sliver_value() <= bound_ ); else return ( c->sliver_value() <= criterion_.sliver_bound() ); } else return false; } private: const C3T3& c3t3_; const SliverCriterion& criterion_; const FT bound_; }; /** * @class Update_c3t3 * * A functor which updates c3t3 w.r.t. the domain. */ class Update_c3t3 { public: Update_c3t3(const MeshDomain& domain, C3T3& c3t3) : domain_(domain) , c3t3_(c3t3) {} /** * @brief Updates facet \c facet in c3t3 * @param facet the facet to update * @param update if set to \c false, checking only is done * @return true if \c facet is in c3t3 */ Surface_patch operator()(const Facet& facet, const bool update = true) const { return this->operator()(facet, update, update); } /** * @brief Updates facet \c facet in c3t3 * @param facet the facet to update * @param update_c3t3 if set to \c false, checking only is done * @param update_surface_center if set to \c true, the facet surface * center is updated. * @return true if \c facet is in c3t3 * * By default, \c update_c3t3 is \c true, and \c update_surface_center * is equal to \c update_c3t3. */ Surface_patch operator()(const Facet& facet, const bool update_c3t3, const bool update_surface_center) const { typedef typename C3T3::Triangulation::Geom_traits Gt; typedef typename Gt::Segment_3 Segment_3; typedef typename Gt::Ray_3 Ray_3; typedef typename Gt::Line_3 Line_3; // Nothing to do for infinite facets if ( c3t3_.triangulation().is_infinite(facet) ) return Surface_patch(); // Functors typename Gt::Is_degenerate_3 is_degenerate = c3t3_.triangulation().geom_traits().is_degenerate_3_object(); // Get dual of facet Object dual = c3t3_.triangulation().dual(facet); // The dual is a segment, a ray or a line if ( const Segment_3* p_segment = object_cast(&dual) ) { if (is_degenerate(*p_segment)) return Surface_patch(); return dual_intersect(*p_segment,facet, update_c3t3, update_surface_center); } else if ( const Ray_3* p_ray = object_cast(&dual) ) { if (is_degenerate(*p_ray)) return Surface_patch(); return dual_intersect(*p_ray,facet,update_c3t3, update_surface_center); } else if ( const Line_3* p_line = object_cast(&dual) ) { return dual_intersect(*p_line,facet,update_c3t3, update_surface_center); } CGAL_error_msg("This should not happen"); return Surface_patch(); } /** * @brief Updates cell \c ch in c3t3 * @param ch the cell to update * @param update if set to \c false, checking only is done * @return true if \c ch is in c3t3 */ Subdomain operator()(const Cell_handle& ch, const bool update = true) const { if ( c3t3_.triangulation().is_infinite(ch) ) return Subdomain(); // treat cell const Subdomain subdomain = domain_.is_in_domain_object()(c3t3_.triangulation().dual(ch)); // function dual(cell) updates the circumcenter cache if there is one if ( subdomain && update ) { c3t3_.add_to_complex(ch,*subdomain); } else if(update) { c3t3_.remove_from_complex(ch); } return subdomain; } private: // Returns true if query intersects the surface. template Surface_patch dual_intersect(const Query& dual, const Facet& facet, const bool update_c3t3, const bool update_surface_center) const { typedef typename MeshDomain::Intersection Intersection; typename MeshDomain::Construct_intersection construct_intersection = domain_.construct_intersection_object(); #ifndef CGAL_MESH_3_NO_LONGER_CALLS_DO_INTERSECT_3 typename MeshDomain::Do_intersect_surface do_intersect_surface = domain_.do_intersect_surface_object(); Surface_patch surface = do_intersect_surface(dual); #else // CGAL_MESH_3_NO_LONGER_CALLS_DO_INTERSECT_3 Intersection intersection = construct_intersection(dual); Surface_patch surface = (CGAL::cpp0x::get<2>(intersection) == 0) ? Surface_patch() : Surface_patch( domain_.surface_patch_index(CGAL::cpp0x::get<1>(intersection))); #endif // CGAL_MESH_3_NO_LONGER_CALLS_DO_INTERSECT_3 // Update if needed if(update_c3t3) { // Update status in c3t3 if(surface != boost::none) c3t3_.add_to_complex(facet, surface.get()); else c3t3_.remove_from_complex(facet); } if(update_surface_center) { Facet facet_m = c3t3_.triangulation().mirror_facet(facet); if(surface) { #ifndef CGAL_MESH_3_NO_LONGER_CALLS_DO_INTERSECT_3 Intersection intersection = construct_intersection(dual); #endif // NOT CGAL_MESH_3_NO_LONGER_CALLS_DO_INTERSECT_3 // Update facet surface center Bare_point surface_center = CGAL::cpp0x::get<0>(intersection); facet.first->set_facet_surface_center(facet.second, surface_center); facet_m.first->set_facet_surface_center(facet_m.second, surface_center); } } return surface; } private: const MeshDomain& domain_; C3T3& c3t3_; }; //end class Update_c3t3 class Facet_updater { Vertex_set& vertex_to_proj; C3T3& c3t3_; Update_c3t3& c3t3_updater_; public: typedef Facet& reference; typedef const Facet& const_reference; Facet_updater(C3T3& c3t3, Vertex_set& vertex_to_proj, Update_c3t3& c3t3_updater_) : vertex_to_proj(vertex_to_proj), c3t3_(c3t3), c3t3_updater_(c3t3_updater_) {} void operator()(const Facet& f) { // Update facet c3t3_.remove_from_complex(f); c3t3_updater_(f); // Update vertex_to_proj if ( c3t3_.is_in_complex(f) ) { // Iterate on vertices int k = f.second; for ( int i=1 ; i<4 ; ++i ) { const Vertex_handle& v = f.first->vertex((k+i)&3); if ( c3t3_.in_dimension(v) > 2 ) { //lock_vertex_to_proj(); vertex_to_proj.insert(v); //unlock_vertex_to_proj(); } } } } }; // end class Facet_updater /** * @class Sliver_criterion_value * * A functor which returns sliver criterion value for a Cell_handle * and updates its cache value */ template class Sliver_criterion_value : public CGAL::cpp98::unary_function { public: Sliver_criterion_value(const Tr& tr, const SliverCriterion& criterion) : p_tr_(&tr) , criterion_(criterion) {} FT operator()(const Cell_handle& ch) const { CGAL_precondition(!p_tr_->is_infinite(ch)); if ( ! ch->is_cache_valid() ) { double sliver_value = criterion_(ch); ch->set_sliver_value(sliver_value); } else { CGAL_expensive_assertion(ch->sliver_value() == criterion_(ch)); } return ch->sliver_value(); } private: // '=' is used, so p_tr_ must be a pointer ... const Tr* p_tr_; SliverCriterion criterion_; }; /** * to be used by the perturber */ class Cell_from_ids { public: Cell_from_ids(const C3T3& c3t3, const Cell_handle& c) : infinite_(c3t3.triangulation().is_infinite(c)) , vertices_() , sorted_vertices_() { for(int i = 0; i < 4; ++i) { if (c3t3.triangulation().is_infinite(c->vertex(i))) continue; //the Id is set with an int by Sliver_perturber, // in initialize_vertices_id int id = static_cast(c->vertex(i)->meshing_info()); vertices_.push_back(id); } sorted_vertices_ = vertices_;//makes a copy of each element std::sort(sorted_vertices_.begin(), sorted_vertices_.end()); CGAL_assertion((infinite_ && vertices_.size() == 3) || vertices_.size() == 4); } std::size_t vertex_id(const std::size_t& i) const { CGAL_precondition(i >= 0); CGAL_precondition((infinite_ && i < 3) || i < 4); return vertices_[i]; } bool operator<(const Cell_from_ids& c) const { //std::array operator< compares lhs and rhs lexicographically return sorted_vertices_ < c.sorted_vertices_; } private: bool infinite_; // vertices IDs, not sorted, to keep the ordering of the Cell_handle id's std::vector vertices_; // vertices IDs, sorted, to be found in a std::set std::vector sorted_vertices_; }; class Cell_data_backup { public: Cell_data_backup(const C3T3& c3t3, const Cell_handle& c, const bool do_backup = true) : cell_ids_(c3t3, c) { //backup is not done when constructor is called to //convert a newly created cell (has nothing to backup) //to a Cell_data_backup if(do_backup) { if (!c3t3.triangulation().is_infinite(c)) backup_finite_cell(c); else backup_infinite_cell(c, c3t3); } } private: void backup_finite_cell(const Cell_handle& c) { if(c->is_cache_valid()) sliver_value_ = c->sliver_value(); else sliver_value_ = 0.; subdomain_index_ = c->subdomain_index(); for(std::size_t i = 0; i < 4; ++i) { const int ii = static_cast(i);//avoid warnings surface_index_table_[i] = c->surface_patch_index(ii); facet_surface_center_[i] = c->get_facet_surface_center(ii); surface_center_index_table_[i] = c->get_facet_surface_center_index(ii); } //note c->next_intrusive() and c->previous_intrusive() //are lost by 'backup' and 'restore', //because all cells are changing during the move //they are not used in update_mesh functions involving a Sliver_criterion } void backup_infinite_cell(const Cell_handle& c, const C3T3& c3t3) { for (int ii = 0; ii < 4; ++ii) { if (c3t3.triangulation().is_infinite(c->vertex(ii))) { surface_index_table_[0] = c->surface_patch_index(ii); facet_surface_center_[0] = c->get_facet_surface_center(ii); surface_center_index_table_[0] = c->get_facet_surface_center_index(ii); break; } } } public: bool operator<(const Cell_data_backup& cb) const { return cell_ids_ < cb.cell_ids_; } /** * new_cell has the same vertices as cell_ids_ * (checked before function is called) * resets new_cell's meta-data to its back-uped values */ void restore(Cell_handle new_cell, C3T3& c3t3) { if (c3t3.triangulation().is_infinite(new_cell)) return restore_infinite_cell(new_cell, c3t3); IndexMap new_to_old_indices; CGAL_assertion_code(unsigned int nbv_found = 0); for(int i = 0; i < 4; ++i) { std::size_t new_vi_index = static_cast(new_cell->vertex(i)->meshing_info()); for(std::size_t j = 0; j < 4; ++j) { if(new_vi_index == cell_ids_.vertex_id(j)) { new_to_old_indices[static_cast(i)] = j; CGAL_assertion_code(++nbv_found); break;//loop on j } }//end loop j }//end loop i CGAL_assertion(nbv_found == 4); restore(new_cell, new_to_old_indices, c3t3); } private: typedef CGAL::cpp11::array IndexMap; void restore(Cell_handle c, const IndexMap& index_map,//new_to_old_indices C3T3& c3t3) { if(sliver_value_ > 0.) c->set_sliver_value(sliver_value_); for(int i = 0; i < 4; ++i) c->reset_visited(i); //we don't need to store 'visited' information because it is //reset and used locally where it is needed //add_to_complex sets the index, and updates the cell counter //if c should be in the c3t3, add_to_complex has to be used //to increment the nb of cells and facets in c3t3 if(!( Subdomain_index() == subdomain_index_ )) c3t3.add_to_complex(c, subdomain_index_); else c3t3.remove_from_complex(c); for(int i = 0; i < 4; ++i) { std::size_t old_i = index_map.at(static_cast(i)); Surface_patch_index index = surface_index_table_[old_i]; //add_to_complex sets the index, and updates the facet counter if(!( Surface_patch_index() == index )) c3t3.add_to_complex(Facet(c, i), index); else c3t3.remove_from_complex(Facet(c,i)); c->set_facet_surface_center(i, facet_surface_center_[old_i]); const Facet mirror = c3t3.triangulation().mirror_facet(Facet(c, i)); mirror.first->set_facet_surface_center(mirror.second, facet_surface_center_[old_i]); } } void restore_infinite_cell(Cell_handle c, C3T3& c3t3) { c3t3.remove_from_complex(c);//infinite for (unsigned int i = 0; i < 4; ++i) { if (!c3t3.triangulation().is_infinite(Facet(c,i))) { Surface_patch_index index = surface_index_table_[0]; if (!( Surface_patch_index() == index )) c3t3.add_to_complex(Facet(c, i), index); else c3t3.remove_from_complex(Facet(c, i)); c->set_facet_surface_center(i, facet_surface_center_[0]); const Facet mirror = c3t3.triangulation().mirror_facet(Facet(c, i)); mirror.first->set_facet_surface_center(mirror.second, facet_surface_center_[0]); return; } } } private: typedef typename Tr::Cell::Subdomain_index Subdomain_index; typedef typename Tr::Cell::Surface_patch_index Surface_patch_index; typedef typename Tr::Cell::Index Index; Cell_from_ids cell_ids_; FT sliver_value_; Subdomain_index subdomain_index_; CGAL::cpp11::array surface_index_table_; CGAL::cpp11::array facet_surface_center_; CGAL::cpp11::array surface_center_index_table_; }; private: // ----------------------------------- // Private methods // ----------------------------------- /** * Returns the minimum criterion value of c3t3 cells contained in \c cells. */ template FT min_sliver_in_c3t3_value(const Cell_vector& cells, const SliverCriterion& criterion, const bool use_cache = true) const { // Get complex cells only Cell_vector c3t3_cells_ = c3t3_cells(cells); return min_sliver_value(c3t3_cells_, criterion, use_cache); } Cell_vector c3t3_cells(const Cell_vector& cells) const { Cell_vector c3t3_cells; std::remove_copy_if(cells.begin(), cells.end(), std::back_inserter(c3t3_cells), std::not1(Is_in_c3t3(c3t3_)) ); return c3t3_cells; } /** * Removes objects of [begin,end[ range from \c c3t3_ */ template void remove_from_c3t3(ForwardIterator begin, ForwardIterator end) const { while ( begin != end ) c3t3_.remove_from_complex(*begin++); } /** * Remove cells and facets of \c cells from c3t3 */ template < typename ForwardIterator > void remove_cells_and_facets_from_c3t3(ForwardIterator cells_begin, ForwardIterator cells_end) const { Facet_vector facets = get_facets_not_inplace(cells_begin,cells_end); remove_from_c3t3(facets.begin(), facets.end()); remove_from_c3t3(cells_begin, cells_end); } /** * Insert into \c out the vertices of range [cells_begin,cells_end[ */ template void fill_modified_vertices(InputIterator cells_begin, InputIterator cells_end, const Vertex_handle& vertex, OutputIterator out) const; /** * Backup cells meta-data to a vector of Cell_data_backup */ template void fill_cells_backup(const CellsVector& cells, CellDataSet& cells_backup) const; template void restore_from_cells_backup(const CellsVector& cells, CellDataSet& cells_backup) const; /** * Update mesh iff sliver criterion value does not decrease. */ template std::pair update_mesh_no_topo_change(const Vertex_handle& old_vertex, const Vector_3& move, const Weighted_point& new_position, const SliverCriterion& criterion, OutputIterator modified_vertices, const Cell_vector& conflict_cells); /** * Move point and returns the set of cells that are not valid anymore, and * the set of cells which have been deleted by the move process. */ template < typename OutdatedCellsOutputIterator, typename DeletedCellsOutputIterator > Vertex_handle move_point(const Vertex_handle& old_vertex, const Vector_3& move, OutdatedCellsOutputIterator outdated_cells, DeletedCellsOutputIterator deleted_cells) const; Vertex_handle move_point_topo_change(const Vertex_handle& old_vertex, const Weighted_point& new_position, Outdated_cell_set& outdated_cells_set, bool *could_lock_zone = NULL) const; template < typename OutdatedCellsOutputIterator, typename DeletedCellsOutputIterator > Vertex_handle move_point_topo_change(const Vertex_handle& old_vertex, const Weighted_point& new_position, OutdatedCellsOutputIterator outdated_cells, DeletedCellsOutputIterator deleted_cells) const; Vertex_handle move_point_topo_change(const Vertex_handle& old_vertex, const Weighted_point& new_position) const; template < typename OutdatedCellsOutputIterator > Vertex_handle move_point_no_topo_change(const Vertex_handle& old_vertex, const Vector_3& move, const Weighted_point& new_position, OutdatedCellsOutputIterator outdated_cells) const; Vertex_handle move_point_no_topo_change(const Vertex_handle& old_vertex, const Vector_3& move, const Weighted_point& new_position) const; /** * Returns the least square plane from v, using adjacent surface points */ boost::optional get_least_square_surface_plane(const Vertex_handle& v, Bare_point& ref_point, Surface_patch_index index = Surface_patch_index()) const; /** * @brief Project \c p on surface, using incident facets of \c v * @param v The vertex from which p was moved * @param p The point to project * @param index The index of the surface patch where v lies, if known. * @return a `boost::optional` with the projected point if the projection * was possible, or `boost::none`. * * \c p is projected using the normal of least square fitting plane * on \c v incident surface points. If \c index is specified, only * surface points that are on the same surface patch are used to compute * the fitting plane. */ boost::optional project_on_surface_if_possible(const Vertex_handle& v, const Bare_point& p, Surface_patch_index index = Surface_patch_index()) const; /** * @brief Returns the projection of \c p, using direction of * \c projection_vector */ Bare_point project_on_surface_aux(const Bare_point& p, const Bare_point& ref_point, const Vector_3& projection_vector) const; /** * Reverts the move from \c old_point to \c new_vertex. Returns the inserted * vertex located at \c old_point * and an output iterator on outdated cells */ template Vertex_handle revert_move(const Vertex_handle& new_vertex, const Weighted_point& old_point, OutputIterator outdated_cells) { // Move vertex Vertex_handle revert_vertex = move_point_topo_change(new_vertex, old_point, outdated_cells, CGAL::Emptyset_iterator()); //deleted cells CGAL_assertion(Vertex_handle() != revert_vertex); return revert_vertex; } /** * Returns the boundary of restricted facets of \c facets, and the list of vertices of all restricted facets, which should not contain the vertex that is moving */ Facet_boundary get_surface_boundary(const Vertex_handle& moving_vertex, const Facet_vector& facets, Vertex_set& incident_surface_vertices) const; /** * Returns the boundary of restricted facets of \c cells and the list of vertices of all restricted facets. */ Facet_boundary get_surface_boundary(const Vertex_handle& moving_vertex, const Cell_vector& cells, Vertex_set& incident_surface_vertices) const { return get_surface_boundary(moving_vertex, get_facets(cells), incident_surface_vertices); } /** * Returns false if there is a vertex belonging to one facet of \c facets * which has not his dimension < 3 */ bool check_no_inside_vertices(const Facet_vector& facets) const; /** * Returns the impacted cells when moving \c vertex to \c conflict_point */ template OutputIterator get_conflict_zone_no_topo_change(const Vertex_handle& vertex, OutputIterator conflict_cells) const; template OutputIterator get_conflict_zone_topo_change(const Vertex_handle& vertex, const Weighted_point& conflict_point, OutputIterator conflict_cells) const; template void get_conflict_zone_topo_change(const Vertex_handle& v, const Weighted_point& conflict_point, CellsOutputIterator insertion_conflict_cells, FacetsOutputIterator insertion_conflict_boundary, CellsOutputIterator removal_conflict_cells, bool *could_lock_zone = NULL) const; template < typename ConflictCellsInputIterator, typename OutdatedCellsOutputIterator, typename DeletedCellsOutputIterator > Vertex_handle move_point_topo_change_conflict_zone_known(const Vertex_handle& old_vertex, const Weighted_point& new_position, const Facet& insertion_boundary_facet, ConflictCellsInputIterator insertion_conflict_cells_begin, ConflictCellsInputIterator insertion_conflict_cells_end, ConflictCellsInputIterator removal_conflict_cells_begin, ConflictCellsInputIterator removal_conflict_cells_end, OutdatedCellsOutputIterator outdated_cells, DeletedCellsOutputIterator deleted_cells) const; /** * Updates \c boundary wrt \c edge: if edge is already in boundary we remove * it, else we add it. */ void update_boundary(Facet_boundary& boundary, const Ordered_edge& edge, const Vertex_handle third_vertex, const Surface_patch_index& surface_index) const { const typename Facet_boundary::value_type x = std::make_pair(edge, std::make_pair(surface_index, std::make_pair(c3t3_.in_dimension(third_vertex), c3t3_.index(third_vertex) ) ) ); typename Facet_boundary::iterator boundary_it = boundary.find(edge); if ( boundary_it != boundary.end() ) boundary.erase(boundary_it); else boundary.insert(x); } /** * Returns the facets of \c cells (returns each facet only once i.e. use * canonical facet) */ Facet_vector get_facets(const Cell_vector& cells) const { return get_facets(cells.begin(),cells.end()); } // TODO: write get_facets so that it uses update_facets with a FacetUpdater that calls push_back #if defined(CGAL_MESH_3_GET_FACETS_USING_INTRUSIVE_LIST) && defined(CGAL_INTRUSIVE_LIST) template Facet_vector get_facets(ForwardIterator first_cell, ForwardIterator last_cell) const { Facet_vector result; // AF: todo: resize? #ifdef CGAL_CONSTRUCT_INTRUSIVE_LIST_RANGE_CONSTRUCTOR Intrusive_list outdated_cells(first_cell, last_cell); #else Intrusive_list outdated_cells; for( ;first_cell!= last_cell; ++first_cell){ outdated_cells.insert(*first_cell); } #endif for(typename Intrusive_list::iterator it = outdated_cells.begin(); it != outdated_cells.end(); ++it){ Cell_handle cell = *it; int i=0; bool inf = false; for ( ; i<4 && (!inf) ; ++i ){ if ( tr_.is_infinite(cell->vertex(i)) ){ inf = true; Cell_handle n = cell->neighbor(i); if(n->next_intrusive() != Cell_handle()){// the neighbor is also outdated if(cell < n){ // otherwise n will report it later result.push_back(Facet(cell,i)); } } else { // report it now or never if(cell < n){ result.push_back(Facet(cell,i)); }else { result.push_back(Facet(n,n->index(cell))); } } } } if(! inf){ for ( i=0 ; i<4 ; ++i ){ Cell_handle n = cell->neighbor(i); if(n->next_intrusive() != Cell_handle()){// the neighbor is also outdated if(cell < n){ // otherwise n will report it later result.push_back(Facet(cell,i)); } } else { // report it now or never if(cell < n){ result.push_back(Facet(cell,i)); }else { result.push_back(Facet(n,n->index(cell))); } } } } } return result; } #else /** * Returns the facets of \c cells (returns each facet only once i.e. use * canonical facet) */ template Facet_vector get_facets(ForwardIterator first_cell, ForwardIterator last_cell) const { // Get all facets typedef Get_all_facets > Get_facets; Facet_vector all_facets; all_facets.reserve(64); std::for_each(first_cell, last_cell, Get_facets(tr_,std::back_inserter(all_facets))); std::sort(all_facets.begin(), all_facets.end()); // Keep one copy of each facet (maybe copy could be avoided) // typename Facet_vector::iterator all_facets_end = // std::unique(all_facets.begin(), all_facets.end()); Facet_vector facets; facets.reserve(64); std::unique_copy(all_facets.begin(), all_facets.end(), std::back_inserter(facets)); return facets; } #endif #ifdef CGAL_INTRUSIVE_LIST template void update_facets(Intrusive_list& outdated_cells, FacetUpdater updater) { # ifdef CGAL_LINKED_WITH_TBB // Parallel if (boost::is_convertible::value) { tbb::parallel_do( outdated_cells.begin(), outdated_cells.end(), Update_cell_facets(tr_, updater)); } // Sequential else # endif // CGAL_LINKED_WITH_TBB { typename Intrusive_list::iterator it; for(it = outdated_cells.begin(); it != outdated_cells.end(); ++it) { Update_cell_facets ucf(tr_, updater); ucf(*it); } } } #endif //CGAL_INTRUSIVE_LIST // Used by the parallel version template void update_facets(std::vector& outdated_cells_vector, FacetUpdater updater) { # ifdef CGAL_LINKED_WITH_TBB // Parallel if (boost::is_convertible::value) { tbb::parallel_for ( tbb::blocked_range(0, outdated_cells_vector.size()), Update_cell_facets_for_parallel_for( tr_, updater, outdated_cells_vector) ); } // Sequential else # endif // CGAL_LINKED_WITH_TBB { typename std::vector::iterator it; for(it = outdated_cells_vector.begin(); it != outdated_cells_vector.end(); ++it) { Update_cell_facets ucf(tr_, updater); ucf(*it); } } } /** * Returns the facets of \c cells (returns each facet only once i.e. use * canonical facet) */ template Facet_vector get_facets_not_inplace(ForwardIterator first_cell, ForwardIterator last_cell) const { typedef Get_all_facets > Get_facets; Facet_vector all_facets; all_facets.reserve(64); std::for_each(first_cell, last_cell, Get_facets(tr_,std::back_inserter(all_facets))); std::sort(all_facets.begin(), all_facets.end()); // Keep one copy of each facet (maybe copy could be avoided) // typename Facet_vector::iterator all_facets_end = // std::unique(all_facets.begin(), all_facets.end()); Facet_vector facets; facets.reserve(64); std::unique_copy(all_facets.begin(), all_facets.end(), std::back_inserter(facets)); CGAL_HISTOGRAM_PROFILER("|facets|", static_cast(facets.size())); return facets; } /** * Returns false iff a surface facet of `cells` has entered or left the * restricted Delaunay, or if its surface patch index has changed * * That function does not modify the c3t3, but it does update the facet * surface centers. The function is only called by * `update_mesh_no_topo_change()`. */ bool verify_surface(const Cell_vector& cells) const { // Naive implementation. // Todo: improve this (maybe we don't have to check if no facet is on surface) Facet_vector facets = get_facets(cells); Facet_vector surface_facets; // Check that nothing changed Update_c3t3 checker(domain_,c3t3_); for ( typename Facet_vector::iterator fit = facets.begin() ; fit != facets.end() ; ++fit ) { if ( c3t3_.is_in_complex(*fit) ) { surface_facets.push_back(*fit); } const Surface_patch sp = checker(*fit, false, /* do not update c3t3 */ true); /* update surface centers */ // false means "do not update the c3t3" if ( c3t3_.is_in_complex(*fit) != (bool)sp || ((bool)sp && !(c3t3_.surface_patch_index(*fit) == sp.get()) ) ) return false; } return true; } /** * Restore mesh for cells and facets of \c cells, using domain_ */ template void restore_mesh(ForwardIterator first_cell, ForwardIterator last_cell) { Facet_vector facets = get_facets(first_cell, last_cell); restore_mesh(first_cell, last_cell, facets.begin(), facets.end()); } /** * Restore mesh for cells of \c cells and facets of \c facets, using domain_ */ template void restore_mesh(CellForwardIterator first_cell, CellForwardIterator last_cell, FacetForwardIterator first_facet, FacetForwardIterator last_facet) { // Update mesh Update_c3t3 updater(domain_,c3t3_); std::for_each(first_facet, last_facet, updater); std::for_each(first_cell, last_cell, updater); } /** * Returns true if facets of \c facets have the same boundary as * \c old_boundary, and if the list of vertices has not changed. */ bool check_surface_mesh(const Vertex_handle& moving_vertex, const Facet_vector& facets, const Facet_boundary& old_boundary, const Vertex_set& old_incident_surface_vertices) const { Vertex_set incident_surface_vertices; Facet_boundary new_boundary = get_surface_boundary(moving_vertex, facets, incident_surface_vertices); return ( old_boundary.size() == new_boundary.size() && old_incident_surface_vertices == incident_surface_vertices && std::equal(new_boundary.begin(), new_boundary.end(), old_boundary.begin()) ); } void set_facet_visited(const Facet& facet) { facet.first->set_facet_visited(facet.second); const Facet mirror_facet = tr_.mirror_facet(facet); mirror_facet.first->set_facet_visited(mirror_facet.second); } /** * Orders handles \c h1, \c h2 & \c h3 */ template void order_handles(Handle& h1, Handle& h2, Handle& h3) const { // Function used in get_surface_boundary if ( h2 < h1 ) std::swap(h1,h2); if ( h3 < h2 ) { std::swap(h2,h3); if ( h2 < h1 ) // don't need to compare h2 & h1 if h2 didn't change std::swap(h1,h2); } } template void reset_sliver_cache(CellRange& cell_range) const { reset_sliver_cache(boost::begin(cell_range), boost::end(cell_range)); } template void reset_sliver_cache(CellForwardIterator cells_begin, CellForwardIterator cells_end) const { while(cells_begin != cells_end) { (*cells_begin)->reset_cache_validity(); ++cells_begin; } } template void reset_circumcenter_cache(CellRange& cell_range) const { reset_circumcenter_cache(boost::begin(cell_range), boost::end(cell_range)); } template void reset_circumcenter_cache(CellForwardIterator cells_begin, CellForwardIterator cells_end) const { while(cells_begin != cells_end) { (*cells_begin)->invalidate_weighted_circumcenter_cache(); ++cells_begin; } } private: // Functor for update_facets function (base) template class Update_cell_facets { Tr & m_tr; FacetUpdater_ & m_facet_updater; protected: void update(const Cell_handle& cell) const { Cell_handle null_cell; bool inf = false; for (int i=0 ; i<4 && (!inf) ; ++i ){ if ( m_tr.is_infinite(cell->vertex(i)) ){ inf = true; Cell_handle n = cell->neighbor(i); if(n->next_intrusive() != null_cell){// the neighbor is also outdated if(cell < n){ // otherwise n will report it later Facet f(cell,i); m_facet_updater(f); } } else { // report it now or never if(cell < n){ Facet f(cell,i); m_facet_updater(f); }else { Facet f(n,n->index(cell)); m_facet_updater(f); } } } } if(! inf){ for ( int i=0 ; i<4 ; ++i ){ Cell_handle n = cell->neighbor(i); if(n->next_intrusive() != null_cell){// the neighbor is also outdated if(cell < n){ // otherwise n will report it later Facet f(cell,i); m_facet_updater(f); } } else { // report it now or never if(cell < n){ Facet f(cell,i); m_facet_updater(f); }else { Facet f(n,n->index(cell)); m_facet_updater(f); } } } } } public: // Constructor Update_cell_facets(Tr &tr, FacetUpdater_& fu) : m_tr(tr), m_facet_updater(fu) {} // Constructor Update_cell_facets(const Update_cell_facets &uf) : m_tr(uf.m_tr), m_facet_updater(uf.m_facet_updater) {} // operator() void operator()(const Cell_handle& cell) const { update(cell); } }; #ifdef CGAL_LINKED_WITH_TBB // Same functor: special version for tbb:parallel_for template class Update_cell_facets_for_parallel_for : Update_cell_facets { typedef Update_cell_facets Base; using Base::update; const std::vector & m_outdated_cells; public: // Constructor Update_cell_facets_for_parallel_for( Tr &tr, FacetUpdater_& fu, const std::vector &oc) : Base(tr, fu), m_outdated_cells(oc) {} // Constructor Update_cell_facets_for_parallel_for( const Update_cell_facets_for_parallel_for &uf) : Base(uf), m_outdated_cells(uf.m_outdated_cells) {} // operator() void operator()(const tbb::blocked_range& r) const { for( size_t i = r.begin() ; i != r.end() ; ++i) update(m_outdated_cells[i]); } }; #endif //CGAL_LINKED_WITH_TBB // ----------------------------------- // ----------------------------------- // ----------------------------------- // Functor for rebuild_restricted_delaunay function template class Update_cell { C3T3 & m_c3t3; Update_c3t3_ & m_updater; protected: typedef typename C3T3_::Cell_handle Cell_handle; void update(const Cell_handle& cell) const { m_c3t3.remove_from_complex(cell); m_updater(cell); } public: // Constructor Update_cell(C3T3_ &c3t3, Update_c3t3_& updater) : m_c3t3(c3t3), m_updater(updater) {} // Constructor Update_cell(const Update_cell &uc) : m_c3t3(uc.m_c3t3), m_updater(uc.m_updater) {} // operator() void operator()(const Cell_handle& cell) const { update(cell); } }; #ifdef CGAL_LINKED_WITH_TBB // Same functor: special version for tbb:parallel_for template class Update_cell_for_parallel_for : Update_cell { typedef Update_cell Base; using Base::update; const std::vector & m_outdated_cells; public: // Constructor Update_cell_for_parallel_for( C3T3_ &c3t3, Update_c3t3_& updater, const std::vector &oc) : Base(c3t3, updater), m_outdated_cells(oc) {} // Constructor Update_cell_for_parallel_for( const Update_cell_for_parallel_for &uc) : Base(uc), m_outdated_cells(uc.m_outdated_cells) {} // operator() void operator()(const tbb::blocked_range& r) const { for( size_t i = r.begin() ; i != r.end() ; ++i) update(m_outdated_cells[i]); } }; #endif //CGAL_LINKED_WITH_TBB // ----------------------------------- // ----------------------------------- // ----------------------------------- // Functor for rebuild_restricted_delaunay function #ifdef CGAL_LINKED_WITH_TBB template class Update_facet { const C3T3_helpers_ & m_c3t3_helpers; C3T3_ & m_c3t3; Update_c3t3_ & m_updater; Vertex_to_proj_set_ & m_vertex_to_proj; typedef typename C3T3_::Vertex_handle Vertex_handle; typedef typename C3T3_::Cell_handle Cell_handle; typedef typename C3T3_::Facet Facet; typedef typename C3T3::Surface_patch_index Surface_patch_index; public: // Constructor Update_facet(const C3T3_helpers_ & c3t3_helpers, C3T3_ &c3t3, Update_c3t3_& updater, Vertex_to_proj_set_ &vertex_to_proj) : m_c3t3_helpers(c3t3_helpers), m_c3t3(c3t3), m_updater(updater), m_vertex_to_proj(vertex_to_proj) {} // Constructor Update_facet(const Update_facet &uc) : m_c3t3_helpers(uc.m_c3t3_helpers), m_c3t3(uc.m_c3t3), m_updater(uc.m_updater), m_vertex_to_proj(uc.m_vertex_to_proj) {} // operator() void operator()( const Facet& facet ) const { // Update facet m_c3t3.remove_from_complex(facet); m_updater(facet); // Update m_vertex_to_proj if ( m_c3t3.is_in_complex(facet) ) { // Iterate on vertices int k = facet.second; for ( int i=1 ; i<4 ; ++i ) { const Vertex_handle& v = facet.first->vertex((k+i)&3); if ( m_c3t3.in_dimension(v) > 2 ) { std::pair p = std::make_pair(v, m_c3t3.surface_patch_index(facet)); m_c3t3_helpers.lock_vertex_to_proj(); m_vertex_to_proj.insert(p); m_c3t3_helpers.unlock_vertex_to_proj(); } } } } }; #endif // ----------------------------------- // Private data // ----------------------------------- C3T3& c3t3_; Tr& tr_; const MeshDomain& domain_; }; // class C3T3_helpers template template std::pair::Vertex_handle> C3T3_helpers:: update_mesh(const Vertex_handle& old_vertex, const Vector_3& move, const Weighted_point& new_position, const SliverCriterion& criterion, OutputIterator modified_vertices, bool *could_lock_zone) { // std::cerr << "\nupdate_mesh[v1](" << (void*)(&*old_vertex) // << "=" << tr_.point(old_vertex) << ",\n" // << " " << move << ",\n" // << " " << new_position << ")\n"; if (could_lock_zone) *could_lock_zone = true; Cell_vector incident_cells_; incident_cells_.reserve(64); tr_.incident_cells(old_vertex, std::back_inserter(incident_cells_)); if ( Th().no_topological_change(tr_, old_vertex, move, new_position, incident_cells_) ) { return update_mesh_no_topo_change(old_vertex, move, new_position, criterion, modified_vertices, incident_cells_); } else { return update_mesh_topo_change(old_vertex, new_position, criterion, modified_vertices, could_lock_zone); } } template template std::pair::Vertex_handle> C3T3_helpers:: update_mesh_no_topo_change(const Vertex_handle& old_vertex, const Vector_3& move, const Weighted_point& new_position, const SliverCriterion& criterion, OutputIterator modified_vertices, const Cell_vector& conflict_cells ) { #ifdef CGAL_MESH_3_C3T3_HELPERS_VERBOSE std::cerr << "update_mesh_no_topo_change(" << (void*)(&*old_vertex) << " = " << tr_.point(old_vertex) << ",\n" << " " << move << ",\n" << " " << new_position << ")" << std::endl; #endif typename Gt::Construct_opposite_vector_3 cov = tr_.geom_traits().construct_opposite_vector_3_object(); //backup metadata std::set cells_backup; fill_cells_backup(conflict_cells, cells_backup); // Get old values criterion.before_move(c3t3_cells(conflict_cells)); Weighted_point old_position = tr_.point(old_vertex); // intentional copy // Move point reset_circumcenter_cache(conflict_cells); reset_sliver_cache(conflict_cells); move_point_no_topo_change(old_vertex, move, new_position); // Check that surface mesh is still valid // and Get new criterion value (conflict_zone did not change) // warnings : valid_move updates caches // verify_surface does not change c3t3 when returns false, // but it does change circumcenters if( verify_surface(conflict_cells) && criterion.valid_move(c3t3_cells(conflict_cells))) { fill_modified_vertices(conflict_cells.begin(), conflict_cells.end(), old_vertex, modified_vertices); return std::make_pair(true,old_vertex); } else // revert move { #ifdef CGAL_MESH_3_C3T3_HELPERS_VERBOSE std::cerr << "update_mesh_no_topo_change: revert move to " << old_position << "\n"; #endif reset_circumcenter_cache(conflict_cells); // Sliver caches have been updated by valid_move reset_sliver_cache(conflict_cells); move_point_no_topo_change(old_vertex, cov(move), old_position); // Restore meta-data (cells should have same connectivity as before move) // cells_backup does not contain infinite cells so they can be fewer CGAL_assertion(conflict_cells.size() >= cells_backup.size()); restore_from_cells_backup(conflict_cells, cells_backup); return std::make_pair(false, old_vertex); } } template template std::pair::Vertex_handle> C3T3_helpers:: update_mesh_topo_change(const Vertex_handle& old_vertex, const Weighted_point& new_position, const SliverCriterion& criterion, OutputIterator modified_vertices, bool *could_lock_zone) { #ifdef CGAL_MESH_3_C3T3_HELPERS_VERBOSE std::cerr << "update_mesh_topo_change(" << (void*)(&*old_vertex) << "=" << tr_.point(old_vertex) << " " << new_position << ",\n" << ")" << std::endl; #endif Cell_set insertion_conflict_cells; Cell_set removal_conflict_cells; Facet_vector insertion_conflict_boundary; insertion_conflict_boundary.reserve(64); get_conflict_zone_topo_change(old_vertex, new_position, std::inserter(insertion_conflict_cells,insertion_conflict_cells.end()), std::back_inserter(insertion_conflict_boundary), std::inserter(removal_conflict_cells, removal_conflict_cells.end()), could_lock_zone); if (could_lock_zone && *could_lock_zone == false) return std::make_pair(false, Vertex_handle()); if(insertion_conflict_boundary.empty()) return std::make_pair(false, old_vertex); // new_location is a vertex already Cell_vector conflict_cells; conflict_cells.reserve(insertion_conflict_cells.size()+removal_conflict_cells.size()); std::set_union(insertion_conflict_cells.begin(), insertion_conflict_cells.end(), removal_conflict_cells.begin(), removal_conflict_cells.end(), std::back_inserter(conflict_cells)); // Backup metadata std::set cells_backup; fill_cells_backup(conflict_cells, cells_backup); CGAL_assertion(conflict_cells.size() == cells_backup.size()); criterion.before_move(c3t3_cells(conflict_cells)); Weighted_point old_position = tr_.point(old_vertex); // intentional copy // Keep old boundary Vertex_set old_incident_surface_vertices; Facet_boundary old_surface_boundary = get_surface_boundary(old_vertex, conflict_cells, old_incident_surface_vertices); reset_circumcenter_cache(conflict_cells); reset_sliver_cache(conflict_cells); Cell_vector outdated_cells; outdated_cells.reserve(64); Vertex_handle new_vertex = move_point_topo_change_conflict_zone_known(old_vertex, new_position, insertion_conflict_boundary[0], insertion_conflict_cells.begin(), insertion_conflict_cells.end(), removal_conflict_cells.begin(), removal_conflict_cells.end(), std::back_inserter(outdated_cells), CGAL::Emptyset_iterator()); // If nothing changed, return if ( old_position == tr_.point(new_vertex) ) { #ifdef CGAL_MESH_3_C3T3_HELPERS_VERBOSE std::cerr << "update_mesh_topo_change: no move!\n"; #endif return std::make_pair(false,old_vertex); } restore_mesh(outdated_cells.begin(),outdated_cells.end()); // Check that surface boundary does not change. // This check ensures that vertices which are inside c3t3 stay inside. if (criterion.valid_move(c3t3_cells(outdated_cells)) && check_surface_mesh(new_vertex, get_facets(outdated_cells), old_surface_boundary, old_incident_surface_vertices) ) { fill_modified_vertices(outdated_cells.begin(), outdated_cells.end(), new_vertex, modified_vertices); return std::make_pair(true,new_vertex); } else { // Removing from c3t3 cells which will be destroyed by revert_move // is done by move_point_topo_change_conflict_zone_known, called by revert_move #ifdef CGAL_MESH_3_C3T3_HELPERS_VERBOSE std::cerr << "update_mesh_topo_change: revert move to " << old_position << "\n"; #endif //reset caches in case cells are re-used by the compact container reset_circumcenter_cache(outdated_cells); reset_sliver_cache(outdated_cells); outdated_cells.clear(); // Revert move Vertex_handle revert_vertex = revert_move(new_vertex, old_position, std::inserter(outdated_cells, outdated_cells.end())); //restore meta-data (cells should have same connectivity as before move) //cells should be the same (connectivity-wise) as before initial move CGAL_assertion(outdated_cells.size() == cells_backup.size()); restore_from_cells_backup(outdated_cells, cells_backup); return std::make_pair(false,revert_vertex); } } template template typename C3T3_helpers::Vertex_handle C3T3_helpers:: update_mesh(const Vertex_handle& old_vertex, const Vector_3& move, OutputIterator modified_vertices, bool fill_vertices) { #ifdef CGAL_MESH_3_C3T3_HELPERS_VERBOSE std::cerr << "\nupdate_mesh[v2](" << (void*)(&*old_vertex) << "=" << tr_.point(old_vertex) << ",\n" << " " << move << ")\n"; #endif Cell_vector outdated_cells; Vertex_handle new_vertex = move_point(old_vertex, move, std::back_inserter(outdated_cells), CGAL::Emptyset_iterator()); // move_point has invalidated caches restore_mesh(outdated_cells.begin(), outdated_cells.end()); // Fill modified vertices if ( fill_vertices && !(boost::is_same::value)) { fill_modified_vertices(outdated_cells.begin(), outdated_cells.end(), new_vertex, modified_vertices); } return new_vertex; } #ifdef CGAL_INTRUSIVE_LIST template template void C3T3_helpers:: rebuild_restricted_delaunay(OutdatedCells& outdated_cells, Moving_vertices_set& moving_vertices) { typename Gt::Construct_point_3 cp = tr_.geom_traits().construct_point_3_object(); typename OutdatedCells::iterator first_cell = outdated_cells.begin(); typename OutdatedCells::iterator last_cell = outdated_cells.end(); Update_c3t3 updater(domain_,c3t3_); # ifdef CGAL_MESH_3_PROFILING std::cerr << std::endl << " Updating cells..."; WallClockTimer t; size_t num_cells = c3t3_.number_of_cells_in_complex(); # endif // Updates cells // Note: ~58% of rebuild_restricted_delaunay time Vertex_set vertex_to_proj; # ifdef CGAL_LINKED_WITH_TBB // Parallel if (boost::is_convertible::value) { std::vector outdated_cells_vector; outdated_cells_vector.reserve(outdated_cells.size()); for ( ; first_cell != last_cell ; ++first_cell) { outdated_cells_vector.push_back(*first_cell); } tbb::parallel_for( tbb::blocked_range(0, outdated_cells_vector.size()), Update_cell_for_parallel_for( c3t3_, updater, outdated_cells_vector)); # ifdef CGAL_MESH_3_PROFILING std::cerr << " done in " << t.elapsed() << " seconds (#cells from " << num_cells << " to " << c3t3_.number_of_cells_in_complex() << ")." << std::endl; std::cerr << " Updating facets..."; t.reset(); # endif // Get facets (returns each canonical facet only once) // Note: ~42% of rebuild_restricted_delaunay time // Facet_vector facets; lock_vertex_to_proj(); Facet_updater facet_updater(c3t3_,vertex_to_proj, updater); unlock_vertex_to_proj(); update_facets(outdated_cells_vector, facet_updater); // now we can clear outdated_cells.clear(); } // Sequential else # endif // CGAL_LINKED_WITH_TBB { while ( first_cell != last_cell ) { Cell_handle cell = *first_cell++; c3t3_.remove_from_complex(cell); updater(cell); } # ifdef CGAL_MESH_3_PROFILING std::cerr << " done in " << t.elapsed() << " seconds (#cells from " << num_cells << " to " << c3t3_.number_of_cells_in_complex() << ")." << std::endl; std::cerr << " Updating facets..."; t.reset(); # endif // Get facets (returns each canonical facet only once) // Note: ~42% of rebuild_restricted_delaunay time // Facet_vector facets; Facet_updater facet_updater(c3t3_,vertex_to_proj, updater); update_facets(outdated_cells, facet_updater); // now we can clear outdated_cells.clear(); } # ifdef CGAL_MESH_3_PROFILING std::cerr << " done in " << t.elapsed() << " seconds (" << vertex_to_proj.size() << " vertices to project)." << std::endl; std::cerr << " Projecting interior vertices..."; t.reset(); # endif CGAL_HISTOGRAM_PROFILER("|vertex_to_proj|=", static_cast(vertex_to_proj.size())); // Project interior vertices // Note: ~0% of rebuild_restricted_delaunay time // TODO : iterate to be sure no interior vertice become on the surface // because of move ? for ( typename Vertex_set::iterator it = vertex_to_proj.begin() ; it != vertex_to_proj.end() ; ++it ) { const Weighted_point& initial_position = tr_.point(*it); boost::optional opt_new_pos = project_on_surface(*it, cp(initial_position)); if ( opt_new_pos ) { //freezing needs 'erase' to be done before the vertex is actually destroyed // Update moving vertices (it becomes new_vertex) moving_vertices.erase(*it); Vector_3 move(cp(initial_position), *opt_new_pos); Vertex_handle new_vertex = update_mesh(*it, move); c3t3_.set_dimension(new_vertex, 2); moving_vertices.insert(new_vertex); } } # ifdef CGAL_MESH_3_PROFILING std::cerr << " done in " << t.elapsed() << " seconds." << std::endl; # endif } #endif //CGAL_INTRUSIVE_LIST template template void C3T3_helpers:: rebuild_restricted_delaunay(ForwardIterator first_cell, ForwardIterator last_cell, Moving_vertices_set& moving_vertices) { typename Gt::Construct_point_3 cp = tr_.geom_traits().construct_point_3_object(); typename Gt::Construct_vector_3 vector = tr_.geom_traits().construct_vector_3_object(); typename Gt::Equal_3 equal = tr_.geom_traits().equal_3_object(); Update_c3t3 updater(domain_,c3t3_); // Get facets (returns each canonical facet only once) Facet_vector facets = get_facets(first_cell, last_cell); // Updates cells // Note: ~58% of rebuild_restricted_delaunay time #ifdef CGAL_LINKED_WITH_TBB // Parallel if (boost::is_convertible::value) { tbb::parallel_do(first_cell, last_cell, Update_cell(c3t3_, updater)); } // Sequential else #endif // CGAL_LINKED_WITH_TBB { while ( first_cell != last_cell ) { Update_cell uc(c3t3_, updater); uc(*first_cell++); } } // Updates facets typedef std::set > Vertex_to_proj_set; Vertex_to_proj_set vertex_to_proj; #ifdef CGAL_LINKED_WITH_TBB // Parallel if (boost::is_convertible::value) { tbb::parallel_do( facets.begin(), facets.end(), Update_facet( *this, c3t3_, updater, vertex_to_proj) ); } // Sequential else #endif // CGAL_LINKED_WITH_TBB { for ( typename Facet_vector::iterator fit = facets.begin() ; fit != facets.end() ; ++fit ) { // Update facet c3t3_.remove_from_complex(*fit); updater(*fit); // Update vertex_to_proj if ( c3t3_.is_in_complex(*fit) ) { // Iterate on vertices int k = fit->second; for ( int i=1 ; i<4 ; ++i ) { const Vertex_handle& v = fit->first->vertex((k+i)&3); if ( c3t3_.in_dimension(v) > 2 ) { vertex_to_proj.insert( std::make_pair(v, c3t3_.surface_patch_index(*fit))); } } } } } // Project interior vertices // TODO : iterate to be sure no interior vertice become on the surface // because of move ? typename Vertex_to_proj_set::iterator it = vertex_to_proj.begin(), end = vertex_to_proj.end(); for ( ; it != end; ++it ) { Vertex_handle vh = it->first; const Weighted_point& initial_position = tr_.point(vh); boost::optional opt_new_pos = project_on_surface(vh, cp(initial_position), it->second); if ( opt_new_pos ) { //freezing needs 'erase' to be done before the vertex is actually destroyed // Update moving vertices (it becomes new_vertex) moving_vertices.erase(vh); Vertex_handle new_vertex = update_mesh(vh, vector(cp(initial_position), *opt_new_pos)); c3t3_.set_dimension(new_vertex, 2); moving_vertices.insert(new_vertex); } } } template void C3T3_helpers:: update_restricted_facets() { Update_c3t3 updater(domain_, c3t3_); for (typename C3T3::Triangulation::Finite_facets_iterator fit = tr_.finite_facets_begin(); fit != tr_.finite_facets_end(); ++fit) updater(*fit); } template template typename C3T3_helpers::Vertex_handle C3T3_helpers:: move_point(const Vertex_handle& old_vertex, const Vector_3& move, OutdatedCellsOutputIterator outdated_cells, DeletedCellsOutputIterator deleted_cells) const { #ifdef CGAL_MESH_3_C3T3_HELPERS_VERBOSE std::cerr << "C3T3_helpers::move_point[v2](" << (void*)(&*old_vertex) << " = " << tr_.point(old_vertex) << ",\n" << " " << move << ")\n"; #endif typename Gt::Construct_translated_point_3 translate = tr_.geom_traits().construct_translated_point_3_object(); typename Gt::Construct_point_3 cp = tr_.geom_traits().construct_point_3_object(); typename Gt::Construct_weighted_point_3 cwp = tr_.geom_traits().construct_weighted_point_3_object(); Cell_vector incident_cells_; incident_cells_.reserve(64); tr_.incident_cells(old_vertex, std::back_inserter(incident_cells_)); const Weighted_point& position = tr_.point(old_vertex); const Weighted_point& new_position = cwp(translate(cp(position), move)); if ( Th().no_topological_change(tr_, old_vertex, move, new_position, incident_cells_) ) { reset_circumcenter_cache(incident_cells_); reset_sliver_cache(incident_cells_); std::copy(incident_cells_.begin(),incident_cells_.end(), outdated_cells); return move_point_no_topo_change(old_vertex, move, new_position); } else { return move_point_topo_change(old_vertex, new_position, outdated_cells, deleted_cells); } } // Sequential template typename C3T3_helpers::Vertex_handle C3T3_helpers:: move_point(const Vertex_handle& old_vertex, const Vector_3& move, Outdated_cell_set& outdated_cells_set, Moving_vertices_set& moving_vertices) const { #ifdef CGAL_MESH_3_C3T3_HELPERS_VERBOSE std::cerr << "C3T3_helpers::move_point(" << (void*)(&*old_vertex) << " = " << tr_.point(old_vertex) << ",\n" << " " << move << ")\n"; #endif typename Gt::Construct_translated_point_3 translate = tr_.geom_traits().construct_translated_point_3_object(); typename Gt::Construct_point_3 cp = tr_.geom_traits().construct_point_3_object(); typename Gt::Construct_weighted_point_3 cwp = tr_.geom_traits().construct_weighted_point_3_object(); Cell_vector incident_cells_; incident_cells_.reserve(64); tr_.incident_cells(old_vertex, std::back_inserter(incident_cells_)); const Weighted_point& position = tr_.point(old_vertex); const Weighted_point& new_position = cwp(translate(cp(position), move)); if ( Th().no_topological_change(tr_, old_vertex, move, new_position, incident_cells_) ) { reset_circumcenter_cache(incident_cells_); reset_sliver_cache(incident_cells_); std::copy(incident_cells_.begin(),incident_cells_.end(), std::inserter(outdated_cells_set, outdated_cells_set.end())); return move_point_no_topo_change(old_vertex, move, new_position); } else { moving_vertices.erase(old_vertex); Vertex_handle new_vertex = move_point_topo_change(old_vertex, new_position, outdated_cells_set); moving_vertices.insert(new_vertex); return new_vertex; } } // Parallel // In case of success (could_lock_zone = true), the zone is locked after the call // ==> the caller needs to call "unlock_all_elements" by itself // In case of failure (could_lock_zone = false), the zone is unlocked by this function template typename C3T3_helpers::Vertex_handle C3T3_helpers:: move_point(const Vertex_handle& old_vertex, const Vector_3& move, Outdated_cell_set& outdated_cells_set, Moving_vertices_set& moving_vertices, bool *could_lock_zone) const { CGAL_assertion(could_lock_zone != NULL); *could_lock_zone = true; if (!try_lock_vertex(old_vertex)) // LOCK { *could_lock_zone = false; unlock_all_elements(); return Vertex_handle(); } //======= Get incident cells ========== Cell_vector incident_cells_; incident_cells_.reserve(64); if (try_lock_and_get_incident_cells(old_vertex, incident_cells_) == false) { *could_lock_zone = false; return Vertex_handle(); } //======= /Get incident cells ========== typename Gt::Construct_translated_point_3 translate = tr_.geom_traits().construct_translated_point_3_object(); typename Gt::Construct_point_3 cp = tr_.geom_traits().construct_point_3_object(); typename Gt::Construct_weighted_point_3 cwp = tr_.geom_traits().construct_weighted_point_3_object(); const Weighted_point& position = tr_.point(old_vertex); const Weighted_point& new_position = cwp(translate(cp(position), move)); if (!try_lock_point(new_position)) // LOCK { *could_lock_zone = false; unlock_all_elements(); return Vertex_handle(); } if ( Th().no_topological_change(tr_, old_vertex, move, new_position, incident_cells_) ) { reset_circumcenter_cache(incident_cells_); reset_sliver_cache(incident_cells_); lock_outdated_cells(); std::copy(incident_cells_.begin(),incident_cells_.end(), std::inserter(outdated_cells_set, outdated_cells_set.end())); unlock_outdated_cells(); Vertex_handle new_vertex = move_point_no_topo_change(old_vertex, move, new_position); // Don't "unlock_all_elements" here, the caller may need it to do it himself return new_vertex; } else { //moving_vertices.erase(old_vertex); MOVED BELOW Vertex_handle new_vertex = move_point_topo_change(old_vertex, new_position, outdated_cells_set, could_lock_zone); if (*could_lock_zone == false) { unlock_all_elements(); return Vertex_handle(); } lock_moving_vertices(); moving_vertices.erase(old_vertex); moving_vertices.insert(new_vertex); unlock_moving_vertices(); // Don't "unlock_all_elements" here, the caller may need it to do it himself return new_vertex; } } template typename C3T3_helpers::Vertex_handle C3T3_helpers:: move_point_topo_change(const Vertex_handle& old_vertex, const Weighted_point& new_position, Outdated_cell_set& outdated_cells_set, bool *could_lock_zone) const { #ifdef CGAL_MESH_3_C3T3_HELPERS_VERBOSE std::cerr << "move_point_topo_change(" << (void*)(&*old_vertex) << "=" << tr_.point(old_vertex) << " " << new_position << ",\n" << ")" << std::endl; #endif Cell_set insertion_conflict_cells; Cell_set removal_conflict_cells; Facet_vector insertion_conflict_boundary; insertion_conflict_boundary.reserve(64); get_conflict_zone_topo_change(old_vertex, new_position, std::inserter(insertion_conflict_cells,insertion_conflict_cells.end()), std::back_inserter(insertion_conflict_boundary), std::inserter(removal_conflict_cells, removal_conflict_cells.end()), could_lock_zone); if (insertion_conflict_cells.empty()) return old_vertex;//new_position coincides with an existing vertex (not old_vertex) //and old_vertex should not be removed of the nb_vertices will change reset_circumcenter_cache(removal_conflict_cells); reset_sliver_cache(removal_conflict_cells); reset_circumcenter_cache(insertion_conflict_cells); reset_sliver_cache(insertion_conflict_cells); if (could_lock_zone && *could_lock_zone == false) return Vertex_handle(); lock_outdated_cells(); for(typename Cell_set::iterator it = insertion_conflict_cells.begin(); it != insertion_conflict_cells.end(); ++it) outdated_cells_set.erase(*it); for(typename Cell_set::iterator it = removal_conflict_cells.begin(); it != removal_conflict_cells.end(); ++it) outdated_cells_set.erase(*it); unlock_outdated_cells(); Cell_vector outdated_cells; Vertex_handle nv = move_point_topo_change_conflict_zone_known(old_vertex, new_position, insertion_conflict_boundary[0], insertion_conflict_cells.begin(), insertion_conflict_cells.end(), removal_conflict_cells.begin(), removal_conflict_cells.end(), std::back_inserter(outdated_cells), CGAL::Emptyset_iterator()); // deleted_cells lock_outdated_cells(); for(typename Cell_vector::iterator it = outdated_cells.begin(); it != outdated_cells.end(); ++it) outdated_cells_set.insert(*it); unlock_outdated_cells(); return nv; } template template typename C3T3_helpers::Vertex_handle C3T3_helpers:: move_point_topo_change(const Vertex_handle& old_vertex, const Weighted_point& new_position, OutdatedCellsOutputIterator outdated_cells, DeletedCellsOutputIterator deleted_cells) const { #ifdef CGAL_MESH_3_C3T3_HELPERS_VERBOSE std::cerr << "move_point_topo_change with delcells(" << (void*)(&*old_vertex) << "=" << tr_.point(old_vertex) << " " << new_position << ",\n" << ")" << std::endl; #endif Cell_set insertion_conflict_cells; Cell_set removal_conflict_cells; Facet_vector insertion_conflict_boundary; insertion_conflict_boundary.reserve(64); get_conflict_zone_topo_change(old_vertex, new_position, std::inserter(insertion_conflict_cells,insertion_conflict_cells.end()), std::back_inserter(insertion_conflict_boundary), std::inserter(removal_conflict_cells, removal_conflict_cells.end())); reset_circumcenter_cache(removal_conflict_cells); reset_sliver_cache(removal_conflict_cells); reset_circumcenter_cache(insertion_conflict_cells); reset_sliver_cache(insertion_conflict_cells); Vertex_handle nv = move_point_topo_change_conflict_zone_known(old_vertex, new_position, insertion_conflict_boundary[0], insertion_conflict_cells.begin(), insertion_conflict_cells.end(), removal_conflict_cells.begin(), removal_conflict_cells.end(), outdated_cells, deleted_cells); return nv; } template template < typename ConflictCellsInputIterator, typename OutdatedCellsOutputIterator, typename DeletedCellsOutputIterator > typename C3T3_helpers::Vertex_handle C3T3_helpers:: move_point_topo_change_conflict_zone_known( const Vertex_handle& old_vertex, const Weighted_point& new_position, const Facet& insertion_boundary_facet, ConflictCellsInputIterator insertion_conflict_cells_begin,//ordered ConflictCellsInputIterator insertion_conflict_cells_end, ConflictCellsInputIterator removal_conflict_cells_begin,//ordered ConflictCellsInputIterator removal_conflict_cells_end, OutdatedCellsOutputIterator outdated_cells, DeletedCellsOutputIterator deleted_cells)//warning : this should not be an iterator to Intrusive_list //o.w. deleted_cells will point to null pointer or so and crash const { Weighted_point old_position = tr_.point(old_vertex); // intentional copy // make one set with conflict zone Cell_set conflict_zone; std::set_union(insertion_conflict_cells_begin, insertion_conflict_cells_end, removal_conflict_cells_begin, removal_conflict_cells_end, std::inserter(conflict_zone, conflict_zone.end())); // Remove conflict zone cells from c3t3 (they will be deleted by insert/remove) remove_cells_and_facets_from_c3t3(conflict_zone.begin(), conflict_zone.end()); // Start Move point // Insert new_vertex, remove old_vertex int dimension = c3t3_.in_dimension(old_vertex); Index vertex_index = c3t3_.index(old_vertex); FT meshing_info = old_vertex->meshing_info(); // insert new point Vertex_handle new_vertex = tr_.insert_in_hole(new_position, insertion_conflict_cells_begin, insertion_conflict_cells_end, insertion_boundary_facet.first, insertion_boundary_facet.second); // If new_position is hidden, update what should be and return default constructed handle if ( Vertex_handle() == new_vertex ) { std::copy(conflict_zone.begin(), conflict_zone.end(), outdated_cells); return old_vertex; } // remove old point tr_.remove(old_vertex); c3t3_.set_dimension(new_vertex,dimension); c3t3_.set_index(new_vertex,vertex_index); new_vertex->set_meshing_info(meshing_info); // End Move point //// Fill outdated_cells // Get conflict zone in new triangulation and set cells outdated Cell_vector new_conflict_cells; new_conflict_cells.reserve(64); get_conflict_zone_topo_change(new_vertex, old_position, std::back_inserter(new_conflict_cells)); std::copy(new_conflict_cells.begin(),new_conflict_cells.end(),outdated_cells); // Fill deleted_cells if(! boost::is_same::value) std::copy(conflict_zone.begin(), conflict_zone.end(), deleted_cells); return new_vertex; } template typename C3T3_helpers::Vertex_handle C3T3_helpers:: move_point_topo_change(const Vertex_handle& old_vertex, const Weighted_point& new_position) const { // Insert new_vertex, remove old_vertex int dimension = c3t3_.in_dimension(old_vertex); Index vertex_index = c3t3_.index(old_vertex); FT meshing_info = old_vertex->meshing_info(); // insert new point Vertex_handle new_vertex = tr_.insert(new_position, old_vertex->cell()); // If new_position is hidden, return default constructed handle if ( Vertex_handle() == new_vertex ) { return Vertex_handle(); } // remove old point tr_.remove(old_vertex); c3t3_.set_dimension(new_vertex,dimension); c3t3_.set_index(new_vertex,vertex_index); new_vertex->set_meshing_info(meshing_info); return new_vertex; } template template typename C3T3_helpers::Vertex_handle C3T3_helpers:: move_point_no_topo_change(const Vertex_handle& old_vertex, const Vector_3& move, const Weighted_point& new_position, OutdatedCellsOutputIterator outdated_cells) const { lock_outdated_cells(); get_conflict_zone_no_topo_change(old_vertex, outdated_cells); unlock_outdated_cells(); return move_point_no_topo_change(old_vertex, move, new_position); } template typename C3T3_helpers::Vertex_handle C3T3_helpers:: move_point_no_topo_change(const Vertex_handle& old_vertex, const Vector_3& move, const Weighted_point& new_position) const { // Change vertex position tr_.set_point(old_vertex, move, new_position); CGAL_expensive_postcondition(tr_.is_valid()); return old_vertex; } /** * @brief Returns the projection of \c p, using direction of * \c projection_vector */ template typename C3T3_helpers::Bare_point C3T3_helpers:: project_on_surface_aux(const Bare_point& p, const Bare_point& ref_point, const Vector_3& projection_vector) const { typedef typename Gt::Segment_3 Segment_3; // Build a segment directed as projection_direction, typename Gt::Compute_squared_distance_3 sq_distance = tr_.geom_traits().compute_squared_distance_3_object(); typename Gt::Compute_squared_length_3 sq_length = tr_.geom_traits().compute_squared_length_3_object(); typename Gt::Construct_scaled_vector_3 scale = tr_.geom_traits().construct_scaled_vector_3_object(); typename Gt::Is_degenerate_3 is_degenerate = tr_.geom_traits().is_degenerate_3_object(); typename Gt::Construct_translated_point_3 translate = tr_.geom_traits().construct_translated_point_3_object(); typename MD::Construct_intersection construct_intersection = domain_.construct_intersection_object(); const FT sq_dist = sq_distance(p, ref_point); const FT sq_proj_length = sq_length(projection_vector); if ( CGAL_NTS is_zero(sq_proj_length) ) return ref_point; const Vector_3 projection_scaled_vector = scale(projection_vector, CGAL::sqrt(sq_dist / sq_proj_length)); const Bare_point source = translate(p, projection_scaled_vector); const Bare_point target = translate(p, - projection_scaled_vector); const Segment_3 proj_segment(source, target); if ( is_degenerate(proj_segment) ) return ref_point; #ifndef CGAL_MESH_3_NO_LONGER_CALLS_DO_INTERSECT_3 typename MD::Do_intersect_surface do_intersect = domain_.do_intersect_surface_object(); if ( do_intersect(proj_segment) ) return CGAL::cpp0x::get<0>(construct_intersection(proj_segment)); else return ref_point; #else // CGAL_MESH_3_NO_LONGER_CALLS_DO_INTERSECT_3 typedef typename MD::Intersection Intersection; Intersection intersection = construct_intersection(proj_segment); if(CGAL::cpp0x::get<2>(intersection) == 2) return CGAL::cpp0x::get<0>(intersection); else return ref_point; #endif // CGAL_MESH_3_NO_LONGER_CALLS_DO_INTERSECT_3 } template boost::optional::Plane_3> C3T3_helpers:: get_least_square_surface_plane(const Vertex_handle& v, Bare_point& reference_point, Surface_patch_index patch_index) const { typename Gt::Construct_point_3 cp = tr_.geom_traits().construct_point_3_object(); // Get incident facets Facet_vector facets; # ifdef CGAL_LINKED_WITH_TBB // Parallel if (boost::is_convertible::value) { tr_.finite_incident_facets_threadsafe(v, std::back_inserter(facets)); } // Sequential else # endif // CGAL_LINKED_WITH_TBB { tr_.finite_incident_facets(v, std::back_inserter(facets)); } const Weighted_point& position = tr_.point(v); // Get adjacent surface points std::vector surface_point_vector; typename Facet_vector::iterator fit = facets.begin(), fend = facets.end(); for ( ; fit != fend; ++fit ) { if ( c3t3_.is_in_complex(*fit) && (patch_index == Surface_patch_index() || c3t3_.surface_patch_index(*fit) == patch_index) ) { const Cell_handle cell = fit->first; const int i = fit->second; // In the case of a periodic triangulation, the incident facets of a point // do not necessarily have the same offsets. Worse, the surface centers // might not have the same offset as their facet. Thus, no solution except // calling a function 'get_closest_point(p, q)' that simply returns q // for a non-periodic triangulation, and checks all possible offsets for // periodic triangulations const Bare_point& bp = tr_.get_closest_point(cp(position), cell->get_facet_surface_center(i)); surface_point_vector.push_back(bp); } } // In some cases point is not a real surface point if ( surface_point_vector.empty() ) return boost::none; // Compute least square fitting plane Plane_3 plane; Bare_point point; CGAL::linear_least_squares_fitting_3(surface_point_vector.begin(), surface_point_vector.end(), plane, point, Dimension_tag<0>(), tr_.geom_traits(), Default_diagonalize_traits()); reference_point = surface_point_vector.front(); return plane; } template typename C3T3_helpers::Bare_point C3T3_helpers:: project_on_surface(const Vertex_handle& v, const Bare_point& p, Surface_patch_index index) const { boost::optional opt_point = project_on_surface_if_possible(v, p, index); if(opt_point) return *opt_point; else return p; } template boost::optional::Bare_point> C3T3_helpers:: project_on_surface_if_possible(const Vertex_handle& v, const Bare_point& p, Surface_patch_index index) const { // return domain_.project_on_surface(p); typename Gt::Construct_point_3 cp = tr_.geom_traits().construct_point_3_object(); typename Gt::Equal_3 equal = tr_.geom_traits().equal_3_object(); // Get plane Bare_point reference_point; boost::optional opt_plane = get_least_square_surface_plane(v, reference_point, index); if(!opt_plane) return boost::none; // Project const Weighted_point& position = tr_.point(v); if ( ! equal(p, cp(position)) ) return project_on_surface_aux(p, cp(position), opt_plane->orthogonal_vector()); else return project_on_surface_aux(p, reference_point, opt_plane->orthogonal_vector()); } template template typename C3T3_helpers::FT C3T3_helpers:: min_incident_value(const Vertex_handle& vh, const SliverCriterion& criterion) const { Cell_vector incident_cells_; tr_.finite_incident_cells(vh,std::back_inserter(incident_cells_)); return min_sliver_in_c3t3_value(incident_cells_, criterion); } template struct Filter { mutable OutputIterator out; const Fct& fct; Filter(OutputIterator out, const Fct& fct) : out(out), fct(fct) {} void operator()(CH cell_handle) const { if(fct(cell_handle)){ *out++ = cell_handle; } } }; template struct Counter { const Fct& fct; std::size_t& count; Counter(const Fct& fct, std::size_t& count) : fct(fct), count(count) {} void operator()(CH cell_handle) { if(fct(cell_handle)){ ++count; } } }; template template void C3T3_helpers:: get_incident_slivers_without_using_tds_data(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound, Cell_vector &slivers) const { typedef SliverCriterion Sc; typedef std::back_insert_iterator OutputIt; typedef Filter > F; OutputIt slivers_it = std::back_inserter(slivers); Is_sliver i_s(c3t3_, criterion, sliver_bound); F f(slivers_it, i_s); tr_.incident_cells_threadsafe(v, boost::make_function_output_iterator(f)); } // CJTODO: call tr_.try_lock_and_get_incident_cells instead? template bool C3T3_helpers:: try_lock_and_get_incident_cells(const Vertex_handle& v, Cell_vector &cells) const { // We need to lock v individually first, to be sure v->cell() is valid if (!try_lock_vertex(v)) return false; Cell_handle d = v->cell(); if (!try_lock_element(d)) // LOCK { unlock_all_elements(); 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 (!try_lock_element(next)) // LOCK { BOOST_FOREACH(Cell_handle& ch, std::make_pair(cells.begin(), cells.end())) { ch->tds_data().clear(); } cells.clear(); unlock_all_elements(); return false; } if (! next->tds_data().is_clear()) continue; cells.push_back(next); ++tail; next->tds_data().mark_in_conflict(); } ++head; } while(head != tail); BOOST_FOREACH(Cell_handle& ch, std::make_pair(cells.begin(), cells.end())) { ch->tds_data().clear(); } return true; } template template bool C3T3_helpers:: try_lock_and_get_incident_cells(const Vertex_handle& v, Cell_vector &cells, const Filter &filter) const { std::vector tmp_cells; tmp_cells.reserve(64); bool ret = try_lock_and_get_incident_cells(v, tmp_cells); if (ret) { BOOST_FOREACH(Cell_handle& ch, std::make_pair(tmp_cells.begin(), tmp_cells.end())) { if (filter(ch)) cells.push_back(ch); } } return ret; } template template bool C3T3_helpers:: try_lock_and_get_incident_slivers(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound, Cell_vector &slivers) const { Is_sliver i_s(c3t3_, criterion, sliver_bound); return try_lock_and_get_incident_cells(v, slivers, i_s); } template template OutputIterator C3T3_helpers:: incident_slivers(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound, OutputIterator out) const { typedef SliverCriterion Sc; std::vector incident_cells_; tr_.incident_cells(v, std::back_inserter(incident_cells_)); std::remove_copy_if(incident_cells_.begin(), incident_cells_.end(), out, std::not1(Is_sliver(c3t3_,criterion,sliver_bound))); return out; } template template OutputIterator C3T3_helpers:: new_incident_slivers(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound, OutputIterator out) const { typedef SliverCriterion Sc; typedef Filter > F; Is_sliver i_s(c3t3_, criterion, sliver_bound); F f(out, i_s); tr_.incident_cells(v,boost::make_function_output_iterator(f)); return f.out; } template template bool C3T3_helpers:: is_sliver(const Cell_handle& ch, const SliverCriterion& criterion, const FT& sliver_bound) const { Is_sliver iss(c3t3_,criterion,sliver_bound); return iss(ch); } template template std::size_t C3T3_helpers:: number_of_incident_slivers(const Vertex_handle& v, const SliverCriterion& criterion, const FT& sliver_bound) const { typedef SliverCriterion Sc; typedef Counter > C; std::size_t count = 0; Is_sliver is_sliver(c3t3_,criterion,sliver_bound); C c(is_sliver, count); tr_.incident_cells(v, boost::make_function_output_iterator(c)); return count; } template template typename C3T3_helpers::FT C3T3_helpers:: min_sliver_value(const Cell_vector& cells, const SliverCriterion& criterion, const bool use_cache) const { using boost::make_transform_iterator; if ( cells.empty() ) return criterion.get_max_value(); if ( ! use_cache ) { reset_sliver_cache(cells.begin(),cells.end()); } // Return min dihedral angle //Sliver_criterion_value sc_value(tr_,criterion); // //return *(std::min_element(make_transform_iterator(cells.begin(),sc_value), // make_transform_iterator(cells.end(),sc_value))); FT min_value = criterion.get_max_value(); for(typename Cell_vector::const_iterator it = cells.begin(); it != cells.end(); ++it) { min_value = (std::min)(criterion(*it), min_value); } return min_value; } template template void C3T3_helpers:: fill_modified_vertices(InputIterator cells_begin, InputIterator cells_end, const Vertex_handle& vertex, OutputIterator out) const { Vertex_set already_inserted_vertices; // Dont insert vertex in out already_inserted_vertices.insert(vertex); for ( InputIterator it = cells_begin ; it != cells_end ; ++it ) { for ( int i=0 ; i<4 ; ++i ) { // Insert vertices if not already inserted const Vertex_handle& current_vertex = (*it)->vertex(i); if ( !tr_.is_infinite(current_vertex) && already_inserted_vertices.insert(current_vertex).second ) { *out++ = current_vertex; } } } } template template void C3T3_helpers:: fill_cells_backup(const CellsVector& cells, CellDataSet& cells_backup) const { typedef typename CellDataSet::value_type Cell_data; typename CellsVector::const_iterator cit; for(cit = cells.begin(); cit != cells.end(); ++cit) { cells_backup.insert(Cell_data(c3t3_,*cit)); } } template template void C3T3_helpers:: restore_from_cells_backup(const CellsVector& cells, CellDataSet& cells_backup) const { for(typename CellsVector::const_iterator cit = cells.begin(); cit != cells.end(); ++cit) { typename CellDataSet::const_iterator cd_it = cells_backup.find(Cell_data_backup(c3t3_, *cit, false/*don't backup*/)); if(cd_it != cells_backup.end()) { typename CellDataSet::value_type cell_data = *cd_it; cell_data.restore(*cit, c3t3_); cells_backup.erase(cd_it); } else CGAL_error(); } CGAL_assertion(cells_backup.empty()); } template template OutputIterator C3T3_helpers:: get_conflict_zone_no_topo_change(const Vertex_handle& vertex, OutputIterator conflict_cells) const { return tr_.incident_cells(vertex, conflict_cells); } template template void C3T3_helpers:: get_conflict_zone_topo_change(const Vertex_handle& v, const Weighted_point& conflict_point, CellsOutputIterator insertion_conflict_cells, FacetsOutputIterator insertion_conflict_boundary, CellsOutputIterator removal_conflict_cells, bool *could_lock_zone) const { // Get triangulation_vertex incident cells : removal conflict zone // TODO: hasn't it already been computed in "perturb_vertex" (when getting the slivers)? // We don't try to lock the incident cells since they've already been locked tr_.incident_cells(v, removal_conflict_cells); // Get conflict_point conflict zone int li=0; int lj=0; typename Tr::Locate_type lt; Cell_handle cell = tr_.locate( conflict_point, lt, li, lj, v->cell(), could_lock_zone); if (could_lock_zone && *could_lock_zone == false) return; if ( lt == Tr::VERTEX ) // Vertex removal is forbidden return; // Find conflict zone tr_.find_conflicts(conflict_point, cell, insertion_conflict_boundary, insertion_conflict_cells, could_lock_zone); } template template OutputIterator C3T3_helpers:: get_conflict_zone_topo_change(const Vertex_handle& vertex, const Weighted_point& conflict_point, OutputIterator conflict_cells) const { // Get triangulation_vertex incident cells Cell_vector incident_cells_; incident_cells_.reserve(64); tr_.incident_cells(vertex, std::back_inserter(incident_cells_)); // Get conflict_point conflict zone Cell_vector deleted_cells; deleted_cells.reserve(64); // Vertex removal is forbidden int li=0; int lj=0; typename Tr::Locate_type locate_type; Cell_handle cell = tr_.locate(conflict_point, locate_type, li, lj, vertex->cell()); if ( Tr::VERTEX == locate_type ) return conflict_cells; // Find conflict zone tr_.find_conflicts(conflict_point, cell, CGAL::Emptyset_iterator(), std::back_inserter(deleted_cells), CGAL::Emptyset_iterator()); // Compute union of conflict_point conflict zone and triangulation_vertex // incident cells std::sort(deleted_cells.begin(),deleted_cells.end()); std::sort(incident_cells_.begin(),incident_cells_.end()); std::set_union(deleted_cells.begin(), deleted_cells.end(), incident_cells_.begin(), incident_cells_.end(), conflict_cells); return conflict_cells; } template typename C3T3_helpers::Facet_boundary C3T3_helpers:: get_surface_boundary(const Vertex_handle& moving_vertex, const Facet_vector& facets, Vertex_set& incident_surface_vertices) const { Facet_boundary boundary; typename Facet_vector::const_iterator fit = facets.begin(); for ( ; fit != facets.end() ; ++fit ) { if ( c3t3_.is_in_complex(*fit) ) { const Surface_patch_index surface_index = c3t3_.surface_patch_index(*fit); const int k = fit->second; Vertex_handle v1 = fit->first->vertex((k+1)&3); Vertex_handle v2 = fit->first->vertex((k+2)&3); Vertex_handle v3 = fit->first->vertex((k+3)&3); incident_surface_vertices.insert(v1); incident_surface_vertices.insert(v2); incident_surface_vertices.insert(v3); // Check that each vertex is a surface one // This is a trick to ensure that in_domain vertices stay inside if ( c3t3_.in_dimension(v1) > 2 || c3t3_.in_dimension(v2) > 2 || c3t3_.in_dimension(v3) > 2 ) { boundary.clear(); return boundary; // return an empty boundary, that cannot be equal // to a real boundary } order_handles(v1,v2,v3); CGAL_assertion(v1 bool C3T3_helpers:: check_no_inside_vertices(const Facet_vector& facets) const { typename Facet_vector::const_iterator fit = facets.begin(); for ( ; fit != facets.end() ; ++fit ) { if ( c3t3_.is_in_complex(*fit) ) { const int k = fit->second; const Vertex_handle& v1 = fit->first->vertex((k+1)&3); const Vertex_handle& v2 = fit->first->vertex((k+2)&3); const Vertex_handle& v3 = fit->first->vertex((k+3)&3); // Check that each vertex is a surface one if ( c3t3_.in_dimension(v1) > 2 || c3t3_.in_dimension(v2) > 2 || c3t3_.in_dimension(v3) > 2 ) { return false; } } } return true; } } // end namespace Mesh_3 } // end namespace CGAL #include #endif // CGAL_MESH_3_C3T3_HELPERS_H