// Copyright (c) 2010-2011 CNRS and LIRIS' Establishments (France). // All rights reserved. // // This file is part of CGAL (www.cgal.org) // // $URL: https://github.com/CGAL/cgal/blob/v5.1/Combinatorial_map/include/CGAL/Combinatorial_map.h $ // $Id: Combinatorial_map.h e6536aa 2020-06-09T20:15:16+02:00 Laurent Rineau // SPDX-License-Identifier: LGPL-3.0-or-later OR LicenseRef-Commercial // // Author(s) : Guillaume Damiand // #ifndef CGAL_COMBINATORIAL_MAP_H #define CGAL_COMBINATORIAL_MAP_H 1 #include #include #include #include #include #include #include #include #include #include #include #include #if defined(CGAL_CMAP_DART_DEPRECATED) && !defined(CGAL_NO_DEPRECATED_CODE) #include #else #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #if defined( __INTEL_COMPILER ) // Workarounf for warning in function basic_link_beta_0 #pragma warning disable 1017 #endif #include #if (BOOST_GCC >= 40900) _Pragma("GCC diagnostic push") _Pragma("GCC diagnostic ignored \"-Warray-bounds\"") #endif namespace CGAL { // functions to allow the call to next/opposite by ADL template auto CM_ADL_next(Desc&& d, G&& g) { return next(std::forward(d), std::forward(g)); } template auto CM_ADL_opposite(Desc&& d, G&& g) { return opposite(std::forward(d), std::forward(g)); } /** @file Combinatorial_map.h * Definition of generic dD Combinatorial map. */ struct Combinatorial_map_tag {}; struct Generalized_map_tag; /** Generic definition of combinatorial map in dD. * The Combinatorial_map class describes an dD combinatorial map. It allows * mainly to create darts, to use marks onto these darts, to get and set * the beta links, and to manage enabled attributes. */ template < unsigned int d_, class Refs_, class Items_, class Alloc_, class Storage_ > class Combinatorial_map_base: public Storage_ { template friend struct CGAL::internal::Call_merge_functor; template friend struct CGAL::internal::Call_split_functor; template friend struct Remove_cell_functor; template friend struct Contract_cell_functor; template friend struct internal::Reverse_orientation_of_map_functor; template friend struct internal::Reverse_orientation_of_connected_component_functor; template friend struct internal::Init_attribute_functor; template friend struct Swap_attributes_functor; public: template < unsigned int A, class B, class I, class D, class S > friend class Combinatorial_map_base; typedef Combinatorial_map_tag Combinatorial_data_structure; /// Types definition typedef Storage_ Storage; typedef Storage Base; typedef Combinatorial_map_base Self; typedef Refs_ Refs; typedef typename Base::Dart Dart; typedef typename Base::Dart_handle Dart_handle; typedef typename Base::Dart_const_handle Dart_const_handle; typedef typename Base::Dart_container Dart_container; typedef typename Base::size_type size_type; typedef typename Base::Helper Helper; typedef typename Base::Attributes Attributes; typedef typename Base::Items Items; typedef typename Base::Alloc Alloc; typedef typename Base::Use_index Use_index; static const size_type NB_MARKS = Base::NB_MARKS; static const size_type INVALID_MARK = NB_MARKS; static const unsigned int dimension = Base::dimension; typedef typename Base::Null_handle_type Null_handle_type; using Base::null_handle; using Base::null_dart_handle; using Base::mdarts; using Base::get_beta; using Base::is_free; using Base::set_dart_mark; using Base::get_dart_mark; using Base::flip_dart_mark; using Base::set_dart_marks; using Base::get_dart_marks; using Base::dart_link_beta; using Base::dart_unlink_beta; using Base::attribute; using Base::mattribute_containers; using Base::dart_of_attribute; using Base::set_dart_of_attribute; using Base::info_of_attribute; using Base::info; using Base::dart; /// Typedef for Dart_range, a range through all the darts of the map. typedef Dart_container Dart_range; typedef const Dart_container Dart_const_range; /// Typedef for attributes template struct Attribute_type: public Base::template Attribute_type {}; template struct Attribute_handle: public Base::template Attribute_handle {}; template struct Attribute_const_handle: public Base::template Attribute_const_handle {}; template struct Attribute_range: public Base::template Attribute_range {}; template struct Attribute_const_range: public Base::template Attribute_const_range {}; class Exception_no_more_available_mark {}; public: /** Default Combinatorial_map constructor. * The map is empty. */ Combinatorial_map_base() { #if defined(CGAL_CMAP_DART_DEPRECATED) && !defined(CGAL_NO_DEPRECATED_CODE) CGAL_static_assertion_msg(Dart::dimension==dimension, "Dimension of dart different from dimension of map"); #endif CGAL_static_assertion_msg(Helper::nb_attribs<=dimension+1, "Too many attributes in the tuple Attributes_enabled"); this->init_storage(); this->mnb_used_marks = 0; this->mmask_marks.reset(); for ( size_type i = 0; i < NB_MARKS; ++i) { this->mfree_marks_stack[i] = i; this->mindex_marks[i] = i; this->mnb_marked_darts[i] = 0; this->mnb_times_reserved_marks[i] = 0; } this->automatic_attributes_management = true; init_dart(null_dart_handle); CGAL_assertion(number_of_darts()==0); } /** Copy the given combinatorial map 'amap' into *this. * Note that both CMap can have different dimensions and/or non void attributes. * Here CMap2 is necessarily non const; while Dart_handle_2 can be a const or non const handle. * This is the "generic" method, called by the different variants below. * Marks reserved and automatic attributes management are not updated. * @param amap the combinatorial map to copy. * @param origin_to_copy associative array from original darts to copy darts * @param origin_to_copy associative array from copy darts to original darts * @param converters tuple of functors, one per attribute, to transform original attributes into copies * @param dartinfoconverter functor to transform original information of darts into information of copies * @param pointconverter functor to transform points in original map into points of copies. * @param copy_perforated_darts true to copy also darts marked perforated (if any) * @param mark_perforated_darts true to mark darts wich are copies of perforated darts (if any) * @post *this is valid. */ template void generic_copy(CMap2& amap, boost::unordered_map* origin_to_copy, boost::unordered_map* copy_to_origin, const Converters& converters, const DartInfoConverter& dartinfoconverter, const PointConverter& pointconverter, bool copy_perforated_darts=false, size_type mark_perforated=INVALID_MARK) { this->clear(); /*this->mnb_used_marks = amap.mnb_used_marks; this->mmask_marks = amap.mmask_marks; this->automatic_attributes_management = amap.automatic_attributes_management; for (size_type i = 0; i < NB_MARKS; ++i) { this->mfree_marks_stack[i] = amap.mfree_marks_stack[i]; this->mused_marks_stack[i] = amap.mused_marks_stack[i]; this->mindex_marks[i] = amap.mindex_marks[i]; this->mnb_marked_darts[i] = amap.mnb_marked_darts[i]; this->mnb_times_reserved_marks[i] = amap.mnb_times_reserved_marks[i]; } init_dart(null_dart_handle, amap.get_marks(amap.null_dart_handle));*/ // Create an mapping between darts of the two maps (originals->copies). // (here we cannot use CGAL::Unique_hash_map because it does not provide // iterators... boost::unordered_map local_dartmap; if (origin_to_copy==NULL) // Use local_dartmap if user does not provides its own unordered_map { origin_to_copy=&local_dartmap; } Dart_handle new_dart; for (typename CMap2::Dart_range::iterator it=amap.darts().begin(), itend=amap.darts().end(); it!=itend; ++it) { if (copy_perforated_darts || !amap.is_perforated(it)) { new_dart=mdarts.emplace(); init_dart(new_dart); // , amap.get_marks(it)); if (mark_perforated!=INVALID_MARK && amap.is_perforated(it)) { mark(new_dart, mark_perforated); } (*origin_to_copy)[it]=new_dart; if (copy_to_origin!=NULL) { (*copy_to_origin)[new_dart]=it; } internal::Copy_dart_info_functor ::run (static_cast(amap), static_cast(*this), it, new_dart, dartinfoconverter); } } unsigned int min_dim=(dimension::iterator dartmap_iter, dartmap_iter_end=origin_to_copy->end(); for (dartmap_iter=origin_to_copy->begin(); dartmap_iter!=dartmap_iter_end; ++dartmap_iter) { for (unsigned int i=0; i<=min_dim; i++) { if (!amap.is_free(dartmap_iter->first,i) && is_free(dartmap_iter->second,i)) { basic_link_beta(dartmap_iter->second, (*origin_to_copy)[amap.beta(dartmap_iter->first,i)], i); } } } /** Copy attributes */ for (dartmap_iter=origin_to_copy->begin(); dartmap_iter!=dartmap_iter_end; ++dartmap_iter) { Helper::template Foreach_enabled_attributes < internal::Copy_attributes_functor >:: run(static_cast(amap), static_cast(*this), dartmap_iter->first, dartmap_iter->second, converters, pointconverter); } CGAL_assertion (is_valid()); } // (1a) copy(amap, converters, dartinfoconverter, pointconverter) template void copy(CMap2& amap, boost::unordered_map * origin_to_copy, boost::unordered_map * copy_to_origin, const Converters& converters, const DartInfoConverter& dartinfoconverter, const PointConverter& pointconverter, bool copy_perforated_darts=false, size_type mark_perforated=INVALID_MARK) { generic_copy (amap, origin_to_copy, copy_to_origin, converters, dartinfoconverter, pointconverter, copy_perforated_darts, mark_perforated); } // (1b) copy_from_const(const amap, converters, dartinfoconverter, pointconverter) template void copy_from_const(const CMap2& amap, boost::unordered_map * origin_to_copy, boost::unordered_map * copy_to_origin, const Converters& converters, const DartInfoConverter& dartinfoconverter, const PointConverter& pointconverter, bool copy_perforated_darts=false, size_type mark_perforated=INVALID_MARK) { generic_copy (const_cast(amap), origin_to_copy, copy_to_origin, converters, dartinfoconverter, pointconverter, copy_perforated_darts, mark_perforated); } // (2a) copy(amap, converters, dartinfoconverter) template void copy(CMap2& amap, boost::unordered_map * origin_to_copy, boost::unordered_map * copy_to_origin, const Converters& converters, const DartInfoConverter& dartinfoconverter, bool copy_perforated_darts=false, size_type mark_perforated=INVALID_MARK) { Default_converter_cmap_0attributes_with_point pointconverter; copy(amap, origin_to_copy, copy_to_origin, converters, dartinfoconverter, pointconverter, copy_perforated_darts, mark_perforated); } // (2b) copy_from_const(const amap, converters, dartinfoconverter) template void copy_from_const(const CMap2& amap, boost::unordered_map * origin_to_copy, boost::unordered_map * copy_to_origin, const Converters& converters, const DartInfoConverter& dartinfoconverter, bool copy_perforated_darts=false, size_type mark_perforated=INVALID_MARK) { Default_converter_cmap_0attributes_with_point pointconverter; copy_from_const(amap, origin_to_copy, copy_to_origin, converters, dartinfoconverter, pointconverter, copy_perforated_darts, mark_perforated); } // (3a) copy(amap, converters) template void copy(CMap2& amap, boost::unordered_map * origin_to_copy, boost::unordered_map * copy_to_origin, const Converters& converters, bool copy_perforated_darts=false, size_type mark_perforated=INVALID_MARK) { Default_converter_dart_info dartinfoconverter; copy(amap, origin_to_copy, copy_to_origin, converters, dartinfoconverter, copy_perforated_darts, mark_perforated); } // (3b) copy_from_const(const amap, converters) template void copy_from_const(const CMap2& amap, boost::unordered_map * origin_to_copy, boost::unordered_map * copy_to_origin, const Converters& converters, bool copy_perforated_darts=false, size_type mark_perforated=INVALID_MARK) { Default_converter_dart_info dartinfoconverter; copy_from_const(amap, origin_to_copy, copy_to_origin, converters, dartinfoconverter, copy_perforated_darts, mark_perforated); } // (4a) copy(amap) template void copy(CMap2& amap, boost::unordered_map * origin_to_copy=nullptr, boost::unordered_map * copy_to_origin=nullptr, bool copy_perforated_darts=false, size_type mark_perforated=INVALID_MARK) { std::tuple<> converters; copy(amap, origin_to_copy, copy_to_origin, converters, copy_perforated_darts, mark_perforated); } // (4b) copy_from_const(const amap) template void copy_from_const(const CMap2& amap, boost::unordered_map * origin_to_copy=nullptr, boost::unordered_map * copy_to_origin=nullptr, bool copy_perforated_darts=false, size_type mark_perforated=INVALID_MARK) { std::tuple<> converters; copy_from_const(amap, origin_to_copy, copy_to_origin, converters, copy_perforated_darts, mark_perforated); } // Copy constructor from a map having exactly the same type. Combinatorial_map_base (const Self & amap): Combinatorial_map_base() { copy_from_const(amap); } // "Copy constructor" from a map having different type. template Combinatorial_map_base(const Combinatorial_map_base& amap): Combinatorial_map_base() { copy_from_const(amap); } // "Copy constructor" from a map having different type. template Combinatorial_map_base(const Combinatorial_map_base& amap, const Converters& converters): Combinatorial_map_base() { copy_from_const(amap, nullptr, nullptr, converters); } // "Copy constructor" from a map having different type. template Combinatorial_map_base(const Combinatorial_map_base& amap, const Converters& converters, const DartInfoConverter& dartinfoconverter): Combinatorial_map_base() { copy_from_const(amap, nullptr, nullptr, converters, dartinfoconverter); } // "Copy constructor" from a map having different type. template Combinatorial_map_base(const Combinatorial_map_base& amap, const Converters& converters, const DartInfoConverter& dartinfoconverter, const PointConverter& pointconverter): Combinatorial_map_base() { copy_from_const(amap, nullptr, nullptr, converters, dartinfoconverter, pointconverter); } /** Affectation operation. Copies one map to the other. * @param amap a combinatorial map. * @return A copy of that combinatorial map. */ Self & operator=(const Self & amap) { if (this!=&amap) { Self tmp(amap); this->swap(tmp); } return *this; } /** Swap this combinatorial map with amap, a second combinatorial map. * Note that the two maps have exactly the same type. * @param amap a combinatorial map. */ void swap(Self & amap) { if (this!=&amap) { mdarts.swap(amap.mdarts); Helper::template Foreach_enabled_attributes < internal::Swap_attributes_functor >::run(*this, amap); std::swap_ranges(mnb_times_reserved_marks, mnb_times_reserved_marks+NB_MARKS, amap.mnb_times_reserved_marks); std::swap(mmask_marks,amap.mmask_marks); std::swap(mnb_used_marks, amap.mnb_used_marks); std::swap_ranges(mindex_marks,mindex_marks+NB_MARKS, amap.mindex_marks); std::swap_ranges(mfree_marks_stack, mfree_marks_stack+NB_MARKS, amap.mfree_marks_stack); std::swap_ranges(mused_marks_stack,mused_marks_stack+NB_MARKS, amap.mused_marks_stack); std::swap_ranges(mnb_marked_darts,mnb_marked_darts+NB_MARKS, amap.mnb_marked_darts); std::swap(null_dart_handle, amap.null_dart_handle); this->mnull_dart_container.swap(amap.mnull_dart_container); std::swap(automatic_attributes_management, amap.automatic_attributes_management); } } /** Import the given hds which should be a model of an halfedge graph. */ template void import_from_halfedge_graph(const HEG& heg, boost::unordered_map ::halfedge_descriptor, Dart_handle>* origin_to_copy=NULL, boost::unordered_map ::halfedge_descriptor>* copy_to_origin=NULL, bool copy_perforated_darts=false, size_type mark_perforated=INVALID_MARK) { // Create an mapping between darts of the two maps (originals->copies). // (here we cannot use CGAL::Unique_hash_map because it does not provide // iterators... boost::unordered_map ::halfedge_descriptor, Dart_handle> local_dartmap; if (origin_to_copy==NULL) // Used local_dartmap if user does not provides its own unordered_map { origin_to_copy=&local_dartmap; } Dart_handle new_dart; for (typename boost::graph_traits::halfedge_iterator it=halfedges(heg).begin(), itend=halfedges(heg).end(); it!=itend; ++it) { if (copy_perforated_darts || !CGAL::is_border(*it, heg)) { new_dart=mdarts.emplace(); if (mark_perforated!=INVALID_MARK && CGAL::is_border(*it, heg)) { mark(new_dart, mark_perforated); } (*origin_to_copy)[*it]=new_dart; if (copy_to_origin!=NULL) { (*copy_to_origin)[new_dart]=*it; } } } typename boost::unordered_map ::halfedge_descriptor, Dart_handle>::iterator dartmap_iter, dartmap_iter_end=origin_to_copy->end(); for (dartmap_iter=origin_to_copy->begin(); dartmap_iter!=dartmap_iter_end; ++dartmap_iter) { basic_link_beta(dartmap_iter->second, (*origin_to_copy)[CM_ADL_next(dartmap_iter->first, heg)], 1); if ((copy_perforated_darts || !CGAL::is_border(CM_ADL_opposite(dartmap_iter->first, heg), heg)) && (dartmap_iter->first)first, heg)) { basic_link_beta(dartmap_iter->second, (*origin_to_copy) [CM_ADL_opposite(dartmap_iter->first, heg)], 2); } } CGAL_assertion (is_valid()); } /** Clear the combinatorial map. Remove all darts and all attributes. * Note that reserved marks are not free. */ void clear() { mdarts.clear(); for ( size_type i = 0; i < NB_MARKS; ++i) this->mnb_marked_darts[i] = 0; internal::Clear_all::run(mattribute_containers); this->init_storage(); init_dart(null_dart_handle); } /** Test if the map is empty. * @return true iff the map is empty. */ bool is_empty() const { return mdarts.empty(); } friend std::ostream& operator<< (std::ostream& os, const Self& amap) { save_combinatorial_map(amap, os); return os; } friend std::ifstream& operator>> (std::ifstream& is, Self& amap) { load_combinatorial_map(is, amap); return is; } /** Create a new dart and add it to the map. * The marks of the darts are initialised with mmask_marks, i.e. the dart * is unmarked for all the marks. * @return a Dart_handle on the new dart. */ template < typename... Args > Dart_handle create_dart(const Args&... args) { Dart_handle res=mdarts.emplace(args...); init_dart(res); return res; } /** Erase a dart from the list of darts. * @param adart the dart to erase. */ void erase_dart(Dart_handle adart) { // 1) We update the number of marked darts. for ( size_type i = 0; i < mnb_used_marks; ++i) { if (is_marked(adart, mused_marks_stack[i])) --mnb_marked_darts[mused_marks_stack[i]]; } // 2) We update the attribute_ref_counting. Helper::template Foreach_enabled_attributes >::run(*this,adart); // 3) We erase the dart. mdarts.erase(adart); } /** Erase a dart from the list of darts. Restricted version * which do not delete attribute having no more dart associated. * @param adart the dart to erase. */ void restricted_erase_dart(Dart_handle adart) { // 1) We update the number of marked darts. for ( size_type i = 0; i < mnb_used_marks; ++i) { if (is_marked(adart, mused_marks_stack[i])) --mnb_marked_darts[mused_marks_stack[i]]; } // 2) We update the attribute_ref_counting. Helper::template Foreach_enabled_attributes >::run(*this,adart); // 3) We erase the dart. mdarts.erase(adart); } /// @return true if dh points to a used dart (i.e. valid). bool is_dart_used(Dart_const_handle dh) const { return mdarts.is_used(dh); } /// @return a Dart_range (range through all the darts of the map). Dart_range& darts() { return mdarts;} Dart_const_range& darts() const { return mdarts; } /** Get the first dart of this map. * @return the first dart. */ Dart_handle first_dart() { if (darts().begin() == darts().end()) return null_handle; return mdarts.begin(); } Dart_const_handle first_dart() const { if (darts().begin() == darts().end()) return null_handle; return mdarts.begin(); } /// @return the Dart_handle corresponding to the given dart. Dart_handle dart_handle(Dart& adart) { return mdarts.iterator_to(adart); } Dart_const_handle dart_handle(const Dart& adart) const { return mdarts.iterator_to(adart); } Dart_handle dart_handle(size_type i) { CGAL_assertion(darts().is_used(i)); return mdarts.iterator_to(darts()[i]); } Dart_const_handle dart_handle(size_type i) const { CGAL_assertion(darts().is_used(i)); return mdarts.iterator_to(darts()[i]); } /** Return the highest dimension for which dh is not free. * @param dh a dart handle * @return the dimension d such that dh is not d-free but k-free for * all k>d. -1 if the dart is free for all d in {0..n} */ int highest_nonfree_dimension(Dart_const_handle dh) const { for (int i=(int)dimension; i>=0; --i) { if ( !is_free(dh, i) ) return i; } return -1; } /** Return a dart belonging to the same edge and to the second vertex * of the current edge (nullptr if such a dart does not exist). * @return An handle to the opposite dart. */ Dart_handle opposite(Dart_handle dh) { for (unsigned int i = 2; i <= dimension; ++i) if (!is_free(dh, i)) return beta(dh, i); return null_handle; } Dart_const_handle opposite(Dart_const_handle dh) const { for (unsigned int i = 2; i <= dimension; ++i) if (!is_free(dh, i)) return beta(dh, i); return null_handle; } /** Return a dart incident to the other extremity of the current edge, * but contrary to opposite, non necessary to the same edge * (nullptr if such a dart does not exist). * @return An handle to the opposite dart. */ Dart_handle other_extremity(Dart_handle dh) { for (unsigned int i = 1; i <= dimension; ++i) if (!is_free(dh, i)) return beta(dh, i); return null_handle; } Dart_const_handle other_extremity(Dart_const_handle dh) const { for (unsigned int i = 1; i <= dimension; ++i) if (!is_free(dh, i)) return beta(dh, i); return null_handle; } // Set the handle on the i th attribute // Restricted version which do not use delete attributes when their ref // counting become null, nor that update the dart of attribute. template void restricted_set_dart_attribute(Dart_handle dh, typename Attribute_handle::type ah) { CGAL_static_assertion_msg(Helper::template Dimension_index::value>=0, "set_dart_attribute called but i-attributes are disabled."); if ( this->template attribute(dh)==ah ) return; if ( this->template attribute(dh)!=null_handle ) { this->template dec_attribute_ref_counting(this->template attribute(dh)); } Base::template basic_set_dart_attribute(dh, ah); if ( ah!=null_handle ) { this->template inc_attribute_ref_counting(ah); } } // Set the handle on the i th attribute template void set_dart_attribute(Dart_handle dh, typename Attribute_handle::type ah) { CGAL_static_assertion_msg(Helper::template Dimension_index::value>=0, "set_dart_attribute called but i-attributes are disabled."); if ( this->template attribute(dh)==ah ) return; if ( this->template attribute(dh)!=null_handle ) { this->template dec_attribute_ref_counting(this->template attribute(dh)); if ( this->are_attributes_automatically_managed() && this->template get_attribute_ref_counting (this->template attribute(dh))==0 ) this->template erase_attribute(this->template attribute(dh)); } this->template basic_set_dart_attribute(dh, ah); if ( ah!=null_handle ) { this->template set_dart_of_attribute(ah, dh); this->template inc_attribute_ref_counting(ah); } } protected: /// Marks can be modified even for const handle; otherwise it is not /// possible to iterate through const combinatorial maps. // Initialize a given dart: all beta to null_dart_handle and all // attributes to null, all marks unmarked. void init_dart(Dart_handle adart) { set_dart_marks(adart, mmask_marks); for (unsigned int i = 0; i <= dimension; ++i) dart_unlink_beta(adart, i); Helper::template Foreach_enabled_attributes >::run(*this, adart); internal::Init_id::run(mdarts, adart); } // Initialize a given dart: all beta to null_dart_handle and all // attributes to null, marks are given. void init_dart(Dart_handle adart, const std::bitset& amarks) { set_marks(adart, amarks); for (unsigned int i = 0; i <= dimension; ++i) dart_unlink_beta(adart, i); Helper::template Foreach_enabled_attributes >::run(*this, adart); internal::Init_id::run(mdarts, adart); } public: /// @return the betas of ADart (beta are used in the same order than /// they are given as parameters) template Dart_handle beta(Dart_handle ADart, Betas... betas) { return CGAL::internal::Beta_functor:: run(*this, ADart, betas...); } template Dart_const_handle beta(Dart_const_handle ADart, Betas... betas) const { return CGAL::internal::Beta_functor:: run(*this, ADart, betas...); } template Dart_handle beta(Dart_handle ADart) { return CGAL::internal::Beta_functor_static:: run(*this, ADart); } template Dart_const_handle beta(Dart_const_handle ADart) const { return CGAL::internal::Beta_functor_static:: run(*this, ADart); } // Generic function to iterate on CMap or GMap in a generic way bool is_previous_exist(Dart_const_handle ADart) const { return !this->template is_free<0>(ADart); } bool is_next_exist(Dart_const_handle ADart) const { return !this->template is_free<1>(ADart); } template bool is_opposite_exist(Dart_const_handle ADart) const { return !this->template is_free(ADart); } Dart_handle previous(Dart_handle ADart) { return this->template beta<0>(ADart); } Dart_const_handle previous(Dart_const_handle ADart) const { return this->template beta<0>(ADart); } Dart_handle next(Dart_handle ADart) { return this->template beta<1>(ADart); } Dart_const_handle next(Dart_const_handle ADart) const { return this->template beta<1>(ADart); } Dart_handle opposite2(Dart_handle ADart) { return this->template beta<2>(ADart); } Dart_const_handle opposite2(Dart_const_handle ADart) const { return this->template beta<2>(ADart); } template Dart_handle opposite(Dart_handle ADart) { return this->template beta(ADart); } template Dart_const_handle opposite(Dart_const_handle ADart) const { return this->template beta(ADart); } void set_next(Dart_handle dh1, Dart_handle dh2) { this->link_beta<1>(dh1, dh2); } template void set_opposite(Dart_handle dh1, Dart_handle dh2) { this->link_beta(dh1, dh2); } Dart_handle other_orientation(Dart_handle ADart) { return ADart; } Dart_const_handle other_orientation(Dart_const_handle ADart) const { return ADart; } size_type number_of_halfedges() const { return number_of_darts(); } bool are_all_faces_closed() const { for (typename Dart_const_range::const_iterator it(darts().begin()), itend(darts().end()); it!=itend; ++it) { if (this->template is_free<1>(it)) return false; } return true; } /** Count the number of used marks. * @return the number of used marks. */ size_type number_of_used_marks() const { return mnb_used_marks; } /** Test if a given mark is reserved. * @return true iff the mark is reserved (ie in used). */ bool is_reserved(size_type amark) const { CGAL_assertion(amark1 ) { --mnb_times_reserved_marks[amark]; return; } unmark_all(amark); // 1) We remove amark from the array mused_marks_stack by // replacing it with the last mark in this array. mused_marks_stack[mindex_marks[amark]] = mused_marks_stack[--mnb_used_marks]; mindex_marks[mused_marks_stack[mnb_used_marks]] = mindex_marks[amark]; // 2) We add amark in the array mfree_marks_stack and update its index. mfree_marks_stack[ mnb_used_marks ] = amark; mindex_marks[amark] = mnb_used_marks; mnb_times_reserved_marks[amark]=0; } template bool belong_to_same_cell(Dart_const_handle adart1, Dart_const_handle adart2) const { return CGAL::belong_to_same_cell(*this, adart1, adart2); } template bool is_whole_cell_unmarked(Dart_const_handle adart, size_type amark) const { return CGAL::is_whole_cell_unmarked(*this, adart, amark); } template bool is_whole_cell_marked(Dart_const_handle adart, size_type amark) const { return CGAL::is_whole_cell_marked(*this, adart, amark); } template size_type mark_cell(Dart_const_handle adart, size_type amark) const { return CGAL::mark_cell(*this, adart, amark); } template size_type unmark_cell(Dart_const_handle adart, size_type amark) const { return CGAL::unmark_cell(*this, adart, amark); } template size_type mark_oriented_cell(Dart_const_handle adart, size_type amark, size_type amark2=INVALID_MARK) const { return CGAL::mark_oriented_cell(*this, adart, amark, amark2); } template size_type unmark_oriented_cell(Dart_const_handle adart, size_type amark, size_type amark2=INVALID_MARK) const { return CGAL::unmark_oriented_cell(*this, adart, amark, amark2); } std::size_t orient(size_type amark) const { negate_mark(amark); return number_of_darts(); } /** Test if this map is without boundary for a given dimension. * @param i the dimension. * @return true iff all the darts are not i-free. * @pre 1<=i<=n */ bool is_without_boundary(unsigned int i) const { CGAL_assertion(1<=i && i<=dimension); for ( typename Dart_const_range::const_iterator it(darts().begin()), itend(darts().end()); it!=itend; ++it) if (is_free(it, i)) return false; return true; } /** Test if this map is without boundary for all the dimensions. * @return true iff all the darts are non free. */ bool is_without_boundary() const { for ( typename Dart_const_range::const_iterator it(darts().begin()), itend(darts().end()); it!=itend; ++it) for ( unsigned int i = 1; i<=dimension; ++i) if (is_free(it, i)) return false; return true; } /** Close the combinatorial map for a given dimension. * @param i the dimension to close * @return the number of new darts. * @pre 2<=i<=n (TODO case i==1) */ template unsigned int close() { CGAL_assertion( 2<=i && i<=dimension ); unsigned int res = 0; Dart_handle d, d2; for ( typename Dart_range::iterator it(darts().begin()); it!=darts().end(); ++it) { if ( this->template is_free(it) ) { d = create_dart(); ++res; link_beta_for_involution(it, d); if (i>2) { // Special cases for 0 and 1 if ( !this->template is_free<1>(it) && !this->template is_free(beta<1>(it)) ) link_beta<1>(beta<1,i>(it),d); if ( !this->template is_free<0>(it) && !this->template is_free(beta<0>(it)) ) link_beta<0>(beta<0,i>(it),d); } // General case for 2...dimension for ( unsigned int j=2; j<=dimension; ++j) { if ( j+1!=i && j!=i && j!=i+1 && !is_free(it, j) && !this->template is_free(beta(it, j)) ) { basic_link_beta_for_involution(beta(it, j, i), d, j); } } d2 = beta(it); while (d2!=null_dart_handle && !this->template is_free(beta(d2))) { d2 = beta(d2); } if (d2!=null_dart_handle && !this->template is_free(d2)) { if (i==2) basic_link_beta<1>(beta<2>(d2), d); else basic_link_beta_for_involution(beta(d2), d); } if (i==2) // We perhaps need also to link beta0 { d2 = beta<0>(it); while (d2!=null_dart_handle && !this->template is_free<0>(beta<2>(d2))) { d2 = beta<2, 0>(d2); } if (d2!=null_dart_handle && !this->template is_free<2>(d2)) { basic_link_beta<0>(beta<2>(d2), d); } } } } return res; } /** Test if the map is valid. * @return true iff the map is valid. */ bool is_valid(bool show_errors=true) const { bool valid = true; unsigned int i = 0, j = 0; std::vector marks(dimension+1); for ( i=0; i<=dimension; ++i) marks[i] = INVALID_MARK; Helper::template Foreach_enabled_attributes >:: run(*this, marks); for ( typename Dart_range::const_iterator it(darts().begin()), itend(darts().end()); it!=itend; ++it) { if ( !valid ) { // We continue the traversal to mark all the darts. for ( i=0; i<=dimension; ++i) if (marks[i]!=INVALID_MARK) { mark(it,marks[i]); } } else { // beta0 must be the inverse of beta1 if ((!is_free(it, 0) && beta(it, 0, 1)!=it) || (!is_free(it, 1) && beta(it, 1, 0)!=it )) { if (show_errors) { std::cerr << "Map not valid: beta(0) " "is not the inverse of beta(1) for dart " <=2) must be an involution for ( i = 2; i <= dimension; ++i) if (!is_free(it, i) && beta(it, i, i)!=it) { if (show_errors) { std::cerr << "Map not valid: beta(" << i << ") is not an involution for dart " <=3) must be involutions if (!is_free(it, 0)) { for ( i = 3; i <= dimension; ++i) if ((is_free(it, i) != is_free(beta(it, 0), i)) || (!is_free(it, i) && beta(it, 0, i)!=beta(it, i, 1))) { if (show_errors) { std::cerr << "Map not valid: beta(0) o beta(" << i << ") is not an involution for dart " <=2) o beta(j>=i+2) must be an involution for ( i = 2; i <= dimension; ++i) { if (!is_free(it, i)) { for ( j = i + 2; j <= dimension; ++j) if ((is_free(it, j)!=is_free(beta(it, i), j)) || (!is_free(it, j) && beta(it, i, j)!=beta(it, j, i))) { if (show_errors) { std::cerr << "Map not valid: beta(" << i << ") o beta(" << j << ") is not an involution for dart " << darts().index(it)<< std::endl; } valid = false; } } } Helper::template Foreach_enabled_attributes >:: run(*this, it, marks, valid); } } for ( i=0; i<=dimension; ++i) if ( marks[i]!=INVALID_MARK ) { CGAL_assertion( is_whole_map_marked(marks[i]) ); free_mark(marks[i]); } return valid; } /// correct invalid attributes in the map void correct_invalid_attributes() { std::vector marks(dimension+1); for ( unsigned int i=0; i<=dimension; ++i) marks[i] = INVALID_MARK; Helper::template Foreach_enabled_attributes >:: run(*this, marks); for ( typename Dart_range::iterator it(darts().begin()), itend(darts().end()); it!=itend; ++it) { Helper::template Foreach_enabled_attributes >:: run(*this, it, marks); } for ( unsigned int i=0; i<=dimension; ++i) if ( marks[i]!=INVALID_MARK ) { CGAL_assertion( is_whole_map_marked(marks[i]) ); free_mark(marks[i]); } Helper::template Foreach_enabled_attributes >:: run(*this); } /// @return the number of darts. size_type number_of_darts() const { return mdarts.size(); } /// @return an estimation of the bytes used by the combinatorial map. size_type bytes() const { return mdarts.capacity() * sizeof(Dart) + internal::Count_bytes_all_attributes_functor::run(*this); } /** Write the content of the map: each dart and each beta links. * @param os the ostream. * @return the ostream. */ std::ostream& display_darts(std::ostream & os, bool attribs=false) const { unsigned int nb = 0; for ( typename Dart_range::const_iterator it=darts().begin(); it!=darts().end(); ++it) { os << " dart " << darts().index(it)<<"; beta[i]="; for ( unsigned int i=0; i<=dimension; ++i) { if (is_free(it, i)) os << " - \t"; else os << darts().index(beta(it, i)) << ",\t"; } if ( attribs ) { Helper::template Foreach_enabled_attributes >::run(*this, it); } os << std::endl; ++nb; } os << "Number of darts: " << nb <<"(sizeofdarts=" < std::ostream& display_orbits(std::ostream & aos) const { CGAL_static_assertion( (boost::is_same::value) ); unsigned int nb = 0; size_type amark = get_new_mark(); for ( typename Dart_range::const_iterator it1(darts().begin()), itend(darts().end()); it1!=itend; ++it1) { if ( !is_marked(it1, amark) ) { ++nb; for ( Ite it2(*this, it1, amark); it2.cont(); ++it2 ) { aos << darts().index(it2) << " - " << std::flush; mark(it2, amark); } aos << std::endl; } } CGAL_assertion( is_whole_map_marked(amark) ); free_mark(amark); aos << "Number of orbits: " << nb << std::endl; return aos; } /** Write the content of each i-cell of the map. * @param aos the ostream. * @return the ostream. */ template < unsigned int i > std::ostream& display_cells(std::ostream & aos) const { return display_orbits > (aos); } /** Write the number of darts and cells of the map into a given ostream. * @param os the ostream. * @return the ostream. */ std::ostream& display_characteristics(std::ostream & os) const { std::vector cells(dimension+2); for ( unsigned int i=0; i<=dimension+1; ++i) { cells[i]=i; } std::vector res = count_cells(cells); os << "#Darts=" << number_of_darts(); for ( unsigned int i=0; i<=dimension; ++i) os<<", #"< but i-attributes are disabled"); typename Attribute_handle::type res= std::get::value> (mattribute_containers).emplace(args...); // Reinitialize the ref counting of the new attribute. This is normally // not required except if create_attribute is used as "copy contructor". this->template init_attribute_ref_counting(res); internal::Init_id::type>::run (this->template attributes(), res); return res; } /// Erase an attribute. /// @param h a handle to the attribute to erase. template void erase_attribute(typename Attribute_handle::type h) { CGAL_static_assertion_msg(Helper::template Dimension_index::value>=0, "erase_attribute but i-attributes are disabled"); std::get::value> (mattribute_containers).erase(h); } /// @return true if ah points to a used i-attribute (i.e. valid). template bool is_attribute_used(typename Attribute_const_handle< i >::type ah) const { CGAL_static_assertion_msg(Helper::template Dimension_index::value>=0, "is_attribute_used but i-attributes are disabled"); return std::get::value> (mattribute_containers).is_used(ah); } /// @return the number of attributes. template size_type number_of_attributes() const { CGAL_static_assertion_msg(Helper::template Dimension_index::value>=0, "number_of_attributes but i-attributes are disabled"); return std::get::value> (mattribute_containers).size(); } /** Set the i th attribute of all the darts of a given i-cell. * @param adart a dart of the i-cell. * @param ah the vertex to set. */ template void set_attribute(Dart_handle dh, typename Attribute_handle::type ah) { CGAL_static_assertion(i<=dimension); CGAL_static_assertion_msg(Helper::template Dimension_index::value>=0, "set_attribute but i-attributes are disabled"); for ( typename Dart_of_cell_range::iterator it(*this, dh); it.cont(); ++it) { this->template set_dart_attribute(it, ah); } } /// @return a Attributes_range (range through all the /// attributes of the map). template typename Attribute_range::type & attributes() { CGAL_static_assertion_msg(Helper::template Dimension_index::value>=0, "attributes but i-attributes are disabled"); return std::get::value> (mattribute_containers); } template typename Attribute_const_range::type & attributes() const { CGAL_static_assertion_msg(Helper::template Dimension_index::value>=0, "attributes but i-attributes are disabled"); return std::get::value> (mattribute_containers); } // Get the ith dynamic onsplit functor (by reference so that we can // modify it directly). template boost::function::type&, typename Attribute_type::type&)>& onsplit_functor() { CGAL_static_assertion_msg (Helper::template Dimension_index::value>=0, "onsplit_functor but " "i-attributes are disabled"); return std::get::value> (m_onsplit_functors); } // Get the ith dynamic onsplit functor (by reference so that we can // modify it directly). template const boost::function::type&, typename Attribute_type::type&)>& onsplit_functor() const { CGAL_static_assertion_msg (Helper::template Dimension_index::value>=0, "onsplit_functor but " "i-attributes are disabled"); return std::get::value> (m_onsplit_functors); } // Get the ith dynamic onmerge functor (by reference so that we can // modify it directly). template boost::function::type&, typename Attribute_type::type&)>& onmerge_functor() { CGAL_static_assertion_msg (Helper::template Dimension_index::value>=0, "onsplit_functor but " "i-attributes are disabled"); return std::get::value> (m_onmerge_functors); } // Get the ith dynamic onmerge functor (by reference so that we can // modify it directly). template const boost::function::type&, typename Attribute_type::type&)>& onmerge_functor() const { CGAL_static_assertion_msg (Helper::template Dimension_index::value>=0, "onsplit_functor but " "i-attributes are disabled"); return std::get::value> (m_onmerge_functors); } /** Double link a dart with beta 0 to a second dart. * \em adart1 is 0-linked to \em adart2 and \em adart2 is 1-linked * with \em adart1. Attributes are not updated, thus we can obtain * a non-valid map with darts belonging to a same orbit and having * different attributes. * @param adart1 a first dart. * @param adart2 a second dart. */ void basic_link_beta_0(Dart_handle adart1, Dart_handle adart2) { // Intel warning #1017: name following "template" must be a template this->template dart_link_beta<0>(adart1, adart2); this->template dart_link_beta<1>(adart2, adart1); } /** Double link a dart with beta 0 to a second dart. * \em adart1 is 0-linked to \em adart2 and \em adart2 is 1-linked * with \em adart1. Attributes are not updated, thus we can obtain * a non-valid map with darts belonging to a same orbit and having * different attributes. * @param adart1 a first dart. * @param adart2 a second dart. */ void basic_link_beta_1(Dart_handle adart1, Dart_handle adart2) { this->template dart_link_beta<1>(adart1, adart2); this->template dart_link_beta<0>(adart2, adart1); } /** Double link a dart with beta i to a second dart, when i>=2. * \em adart1 is i-linked to \em adart2 and \em adart2 is i-linked * with \em adart1. Attributes are not updated, thus we can obtain * a non-valid map with darts belonging to a same orbit and having * different attributes. * @param adart1 a first dart. * @param adart2 a second dart. * @param i the dimension of the beta. */ template void basic_link_beta_for_involution(Dart_handle adart1, Dart_handle adart2) { CGAL_assertion( i>=2 && i<=dimension ); this->template dart_link_beta(adart1, adart2); this->template dart_link_beta(adart2, adart1); } void basic_link_beta_for_involution(Dart_handle adart1, Dart_handle adart2, unsigned int i) { CGAL_assertion( i>=2 && i<=dimension ); CGAL_assertion( i>=2 && i<=dimension ); dart_link_beta(adart1, adart2, i); dart_link_beta(adart2, adart1, i); } /** Double link a dart with betai to a second dart. * \em adart1 is i-linked to \em adart2 and \em adart2 is i^-1-linked * with \em adart1. Attributes are not updated, thus we can obtain * a non-valid map with darts belonging to a same orbit and having * different attributes. * @param adart1 a first dart. * @param adart2 a second dart. */ template void basic_link_beta(Dart_handle adart1, Dart_handle adart2) { if ( i==0 ) basic_link_beta_0(adart1, adart2); else if ( i==1 ) basic_link_beta_1(adart1, adart2); else basic_link_beta_for_involution(adart1, adart2); } void basic_link_beta(Dart_handle adart1, Dart_handle adart2, unsigned int i) { if ( i==0 ) basic_link_beta_0(adart1, adart2); else if ( i==1 ) basic_link_beta_1(adart1, adart2); else basic_link_beta_for_involution(adart1, adart2, i); } /** Double link two darts, and update the nullptr attributes. * \em adart1 is 0-linked to \em adart2 and \em adart2 is 1-linked * with \em adart1. The nullptr attributes of \em adart1 are updated to * non nullptr attributes associated to \em adart2, and vice-versa. * If both darts have an attribute, the attribute of adart1 is * associated to adart2. * We can obtain a non-valid map with darts belonging to a same cell * and having different attributes. * @param adart1 a first dart. * @param adart2 a second dart. */ void link_beta_0(Dart_handle adart1, Dart_handle adart2) { Helper::template Foreach_enabled_attributes_except , 1>:: run(*this,adart1,adart2); this->template dart_link_beta<0>(adart1, adart2); this->template dart_link_beta<1>(adart2, adart1); } /** Double link two darts, and update the nullptr attributes. * \em adart1 is 1-linked to \em adart2 and \em adart2 is 0-linked * with \em adart1. The nullptr attributes of \em adart1 are updated to * non nullptr attributes associated to \em adart2, and vice-versa. * If both darts have an attribute, the attribute of adart1 is * associated to adart2. * We can obtain a non-valid map with darts belonging to a same cell * and having different attributes. * @param adart1 a first dart. * @param adart2 a second dart. */ void link_beta_1(Dart_handle adart1, Dart_handle adart2) { Helper::template Foreach_enabled_attributes_except , 1>:: run(*this,adart1,adart2); this->template dart_link_beta<1>(adart1, adart2); this->template dart_link_beta<0>(adart2, adart1); } /** Double link two darts, and update the nullptr attributes. * \em adart1 is i-linked to \em adart2 and \em adart2 is i^-1-linked * with \em adart1. The nullptr attributes of \em adart1 are updated to * non nullptr attributes associated to \em adart2, and vice-versa. * If both darts have an attribute, the attribute of adart1 is * associated to adart2. * We can obtain a non-valid map with darts belonging to a same cell * and having different attributes. * @param adart1 a first dart. * @param adart2 a second dart. * @param i the dimension of the beta. * @pre 2<=i<=dimension. */ template void link_beta_for_involution(Dart_handle adart1, Dart_handle adart2) { CGAL_assertion( 2<=i && i<=dimension ); Helper::template Foreach_enabled_attributes_except , i>:: run(*this,adart1,adart2); this->template dart_link_beta(adart1, adart2); this->template dart_link_beta(adart2, adart1); } /** Double link two darts, and update the nullptr attributes. * \em adart1 is i-linked to \em adart2 and \em adart2 is i^-1-linked * with \em adart1. The nullptr attributes of \em adart1 are updated to * non nullptr attributes associated to \em adart2, and vice-versa. * If both darts have an attribute, the attribute of adart1 is * associated to adart2. * We can obtain a non-valid map with darts belonging to a same cell * and having different attributes. * @param adart1 a first dart. * @param adart2 a second dart. */ template void link_beta(Dart_handle adart1, Dart_handle adart2) { if ( are_attributes_automatically_managed() ) { if ( i==0 ) link_beta_0(adart1, adart2); else if ( i==1 ) link_beta_1(adart1, adart2); else link_beta_for_involution(adart1, adart2); } else basic_link_beta(adart1, adart2); } /** Double link a dart with betai to a second dart. * \em adart1 is i-linked to \em adart2 and \em adart2 is i^-1-linked * with \em adart1. The nullptr attributes of \em adart1 are updated to * non nullptr attributes associated to \em adart2, and vice-versa, * if both darts have an attribute, the attribute of adart1 is * associated to adart2 (only if update_attributes==true). * @param adart1 a first dart. * @param adart2 a second dart. * @param update_attributes a boolean to update the enabled attributes. * (deprecated, now we use are_attributes_automatically_managed()) */ template void link_beta(Dart_handle adart1, Dart_handle adart2, bool update_attributes) { if ( update_attributes ) link_beta(adart1, adart2); else basic_link_beta(adart1, adart2); } /** Double unlink a dart with beta 0. * beta0(\em adart) is 1-unlinked and \em adart is 0-unlinked. * The attributes are not updated, thus we can obtain a non-valid map * with darts belonging to different orbits and having the same * attributes. * @param adart a dart. */ void unlink_beta_0(Dart_handle adart) { CGAL_assertion(!this->template is_free<0>(adart)); this->template dart_unlink_beta<1>(beta<0>(adart)); this->template dart_unlink_beta<0>(adart); } /** Double unlink a dart with beta 1. * beta1(\em adart) is 0-unlinked and \em adart is 1-unlinked. * The attributes are not updated, thus we can obtain a non-valid map * with darts belonging to different orbits and having the same * attributes. * @param adart a dart. */ void unlink_beta_1(Dart_handle adart) { CGAL_assertion(!this->template is_free<1>(adart)); this->template dart_unlink_beta<0>(beta<1>(adart)); this->template dart_unlink_beta<1>(adart); } /** Double unlink a dart with beta i, for i>=2. * betai(\em adart) is i-unlinked and \em adart is i-unlinked. * The attributes are not updated, thus we can obtain a non-valid map * with darts belonging to different orbits and having the same * attributes. * @param adart a dart. * @param i the dimension of the beta. */ template void unlink_beta_for_involution(Dart_handle adart) { CGAL_assertion(!this->template is_free(adart)); CGAL_assertion(2<=i && i<=dimension); this->template dart_unlink_beta(beta(adart)); this->template dart_unlink_beta(adart); } void unlink_beta_for_involution(Dart_handle adart, unsigned int i) { CGAL_assertion(!is_free(adart,i)); CGAL_assertion(2<=i && i<=dimension); dart_unlink_beta(beta(adart, i), i); dart_unlink_beta(adart, i); } /** Double unlink a dart with beta i. * betai(\em adart) is i-1-unlinked and \em adart is i-unlinked. * The attributes are not updated, thus we can obtain a non-valid map * with darts belonging to different orbits and having the same * attributes. * @param adart a dart. * @param i the dimension of the beta. */ template void unlink_beta(Dart_handle adart) { if ( i==0 ) unlink_beta_0(adart); else if ( i==1 ) unlink_beta_1(adart); else unlink_beta_for_involution(adart); } void unlink_beta(Dart_handle adart, unsigned int i) { if ( i==0 ) unlink_beta_0(adart); else if ( i==1 ) unlink_beta_1(adart); else unlink_beta_for_involution(adart, i); } /** Test if it is possible to sew by betai the two given darts * @param adart1 the first dart. * @param adart2 the second dart. * @return true iff \em adart1 can be i-sewn with \em adart2. */ template bool is_sewable(Dart_const_handle adart1, Dart_const_handle adart2) const { return CGAL::internal:: Is_sewable_functor::run(this, adart1, adart2); } /** Topological sew by beta1 the two given darts plus all the required darts * to satisfy the combinatorial map validity: but do not update attributes * thus the map can be non valid. * @param adart1 the first dart. * @param adart2 the second dart. * @pre is_sewable<1>(adart1, adart2). */ void topo_sew_1(Dart_handle adart1, Dart_handle adart2) { CGAL_assertion( (is_sewable<1>(adart1,adart2)) ); if ( adart1==adart2 ) { for ( CGAL::CMap_dart_iterator_of_involution it(*this, adart1); it.cont(); ++it ) { basic_link_beta_1(it, it); } } else { size_type m = get_new_mark(); std::deque dartv; for ( CGAL::CMap_dart_iterator_basic_of_cell it(*this, adart1, m); it.cont(); ++it ) { mark(it,m); dartv.push_back(it); } CGAL::CMap_dart_iterator_of_involution I1(*this, adart1); CGAL::CMap_dart_iterator_of_involution_inv I2(*this, adart2); for ( ; I1.cont(); ++I1, ++I2 ) { if ( is_marked(I1,m) ) basic_link_beta_1(I1, I2); else basic_link_beta_0(I1, I2); } for ( typename std::deque::iterator it=dartv.begin(); it!=dartv.end(); ++it) { unmark(*it,m); } CGAL_assertion( is_whole_map_unmarked(m) ); free_mark(m); } } /** Topological sew by beta0 two given darts plus all the required darts * to satisfy the combinatorial map validity: but do not update attributes * thus the map can be non valid. * @param adart1 the first dart. * @param adart2 the second dart. * @pre is_sewable<0>(adart1, adart2). */ void topo_sew_0(Dart_handle adart1, Dart_handle adart2) { topo_sew_1(adart2, adart1); } /** Topological sew by betai two given darts plus all the required darts * to satisfy the combinatorial map validity: but do not update attributes * thus the map can be non valid. * @param adart1 the first dart. * @param adart2 the second dart. * @pre 2<=i<=dimension. * @pre is_sewable(adart1, adart2). */ template void topo_sew_for_involution(Dart_handle adart1, Dart_handle adart2) { CGAL_assertion( 2<=i && i<=Self::dimension ); CGAL_assertion( (is_sewable(adart1,adart2)) ); CGAL::CMap_dart_iterator_of_involution I1(*this, adart1); CGAL::CMap_dart_iterator_of_involution_inv I2(*this, adart2); for ( ; I1.cont(); ++I1, ++I2 ) { basic_link_beta_for_involution(I1, I2); } } /** Topological sew by betai two given darts plus all the required darts * to satisfy the combinatorial map validity: but do not update attributes * thus the map can be non valid. * @param adart1 the first dart. * @param adart2 the second dart. * @pre is_sewable(adart1, adart2). */ template void topo_sew(Dart_handle adart1, Dart_handle adart2) { if ( i==0 ) topo_sew_1(adart2, adart1); else if ( i==1 ) topo_sew_1(adart1, adart2); else topo_sew_for_involution(adart1, adart2); } /** Sew by beta0 the two given darts plus all the required darts * to satisfy the combinatorial map validity, and updates enabled * attributes when necessary so that the final map is valid. * @param adart1 the first dart. * @param adart2 the second dart. * @pre is_sewable<0>(adart1, adart2). * @post is_valid() */ void sew_0(Dart_handle adart1, Dart_handle adart2) { CGAL_assertion( (is_sewable<0>(adart1,adart2)) ); if ( adart1==adart2 ) { for ( CGAL::CMap_dart_iterator_of_involution it(*this, adart1); it.cont(); ++it ) { basic_link_beta_1(it, it); } return; } size_type m = get_new_mark(); std::deque dartv; for ( CGAL::CMap_dart_iterator_basic_of_cell it(*this, adart1, m); it.cont(); ++it ) { mark(it,m); dartv.push_back(it); } size_type mark = get_new_mark(); CGAL::CMap_dart_iterator_basic_of_involution I1(*this, adart1, mark); CGAL::CMap_dart_iterator_basic_of_involution_inv I2(*this, adart2, mark); // This first loop do not modify the map, but only the attributes // (by calling when required the onmerge functors). for ( ; I1.cont(); ++I1, ++I2 ) { if ( is_marked(I1,m) ) Helper::template Foreach_enabled_attributes_except , 1>:: run(*this, I1, I2); else Helper::template Foreach_enabled_attributes_except , 1>:: run(*this, I1, I2); } // Now we update the beta links. negate_mark( mark ); for ( I1.rewind(), I2.rewind(); I1.cont(); ++I1, ++I2 ) { if ( is_marked(I1,m) ) basic_link_beta_0(I1, I2); else basic_link_beta_1(I1, I2); } for ( typename std::deque::iterator it=dartv.begin(); it!=dartv.end(); ++it ) { unmark(*it,m); } CGAL_assertion( is_whole_map_unmarked(m) ); free_mark(m); negate_mark( mark ); CGAL_assertion( is_whole_map_unmarked(mark) ); free_mark(mark); } /** Sew by beta1 the two given darts plus all the required darts * to satisfy the combinatorial map validity, and updates enabled * attributes when necessary so that the final map is valid. * @param adart1 the first dart. * @param adart2 the second dart. * @pre is_sewable<1>(adart1, adart2). * @post is_valid() */ void sew_1(Dart_handle adart1, Dart_handle adart2) { CGAL_assertion( (is_sewable<1>(adart1,adart2)) ); if ( adart1==adart2 ) { for ( CGAL::CMap_dart_iterator_of_involution it(*this, adart1); it.cont(); ++it ) { basic_link_beta_1(it, it); } return; } size_type m = get_new_mark(); std::deque dartv; for ( CGAL::CMap_dart_iterator_basic_of_cell it(*this, adart1, m); it.cont(); ++it ) { mark(it,m); dartv.push_back(it); } size_type mark = get_new_mark(); CGAL::CMap_dart_iterator_basic_of_involution I1(*this, adart1, mark); CGAL::CMap_dart_iterator_basic_of_involution_inv I2(*this, adart2, mark); // This first loop do not modify the map, but only the attributes // (by calling when required the onmerge functors). for ( ; I1.cont(); ++I1, ++I2 ) { CGAL_assertion( I2.cont() ); if ( is_marked(I1,m) ) Helper::template Foreach_enabled_attributes_except , 1>:: run(*this, I1, I2); else Helper::template Foreach_enabled_attributes_except , 1>:: run(*this, I1, I2); } // Now we update the beta links. negate_mark( mark ); for ( I1.rewind(), I2.rewind(); I1.cont(); ++I1, ++I2 ) { if ( is_marked(I1,m) ) basic_link_beta_1(I1, I2); else basic_link_beta_0(I1, I2); } for ( typename std::deque::iterator it=dartv.begin(); it!=dartv.end(); ++it ) { unmark(*it,m); } CGAL_assertion( is_whole_map_unmarked(m) ); free_mark(m); negate_mark( mark ); CGAL_assertion( is_whole_map_unmarked(mark) ); free_mark(mark); } /** Sew by betai the two given darts plus all the required darts * to satisfy the combinatorial map validity, and updates enabled * attributes when necessary so that the final map is valid. * @param adart1 the first dart. * @param adart2 the second dart. * @pre is_sewable(adart1, adart2). * @pre 2<=i<=dimension. * @post is_valid() */ template void sew_for_involution(Dart_handle adart1, Dart_handle adart2) { CGAL_assertion( 2<=i && i<=dimension ); CGAL_assertion( (is_sewable(adart1,adart2)) ); size_type mark=get_new_mark(); CGAL::CMap_dart_iterator_basic_of_involution I1(*this, adart1, mark); CGAL::CMap_dart_iterator_basic_of_involution_inv I2(*this, adart2, mark); // This first loop do not modify the map, but only the attributes // (by calling when required the onmerge functors). for ( ; I1.cont(); ++I1, ++I2 ) { Helper::template Foreach_enabled_attributes_except , i>:: run(*this, I1, I2); } // Now we update the beta links. negate_mark( mark ); for ( I1.rewind(), I2.rewind(); I1.cont(); ++I1, ++I2 ) { basic_link_beta_for_involution(I1, I2); } negate_mark( mark ); CGAL_assertion( is_whole_map_unmarked(mark) ); free_mark(mark); } /** Sew by betai the two given darts plus all the required darts * to satisfy the combinatorial map validity, and updates enabled * attributes when necessary so that the final map is valid. * @param adart1 the first dart. * @param adart2 the second dart. * @pre is_sewable(adart1, adart2). * @post is_valid() */ template void sew(Dart_handle adart1, Dart_handle adart2) { if ( are_attributes_automatically_managed() ) { if ( i==0 ) sew_0(adart1, adart2); else if ( i==1 ) sew_1(adart1, adart2); else sew_for_involution(adart1, adart2); } else topo_sew(adart1, adart2); } /** Sew by betai the two given darts plus all the required darts * to satisfy the combinatorial map validity. Enabled attributes * are updated only if update_attributes==true. * @param adart1 the first dart. * @param adart2 the second dart. * @param update_attributes a boolean to update the enabled attributes * (deprecated, now we use are_attributes_automatically_managed()) * @pre is_sewable(adart1, adart2). */ template void sew(Dart_handle adart1, Dart_handle adart2, bool update_attributes) { if ( update_attributes ) sew(adart1, adart2); else topo_sew(adart1, adart2); } /** Topological unsew by beta1 the given dart plus all the required darts * to satisfy the combinatorial map validity: but do not update attributes * thus the map can be non valid * @param adart first dart. * @pre !adart->is_free(1). */ void topo_unsew_1(Dart_handle adart) { CGAL_assertion( !this->template is_free<1>(adart) ); size_type m = get_new_mark(); std::deque dartv; for ( CGAL::CMap_dart_iterator_basic_of_cell it(*this, adart, m); it.cont(); ++it ) { mark(it,m); dartv.push_back(it); } for ( CGAL::CMap_dart_iterator_of_involution it(*this, adart); it.cont(); ++it ) { if ( is_marked(it,m) ) unlink_beta_1(it); else unlink_beta_0(it); } for ( typename std::deque::iterator it=dartv.begin(); it!=dartv.end(); ++it ) { unmark(*it,m); } CGAL_assertion( is_whole_map_unmarked(m) ); free_mark(m); } /** Topological unsew by beta0 the given dart plus all the required darts * to satisfy the combinatorial map validity: but do not update attributes * thus the map can be non valid * @param adart first dart. * @pre !adart->is_free(0). */ void topo_unsew_0(Dart_handle adart) { CGAL_assertion( !this->template is_free<0>(adart) ); topo_unsew_1(this->template beta<0>(adart) ); } /** Topological unsew by betai the given dart plus all the required darts * to satisfy the combinatorial map validity: but do not update attributes * thus the map can be non valid * @param adart first dart. * @pre !adart->is_free(i). * @pre 2<=i<=dimension. */ template void topo_unsew_for_involution(Dart_handle adart) { CGAL_assertion( !this->template is_free(adart) ); CGAL_assertion( 2<=i && i<=Self::dimension ); for ( CGAL::CMap_dart_iterator_of_involution it(*this, adart); it.cont(); ++it ) { unlink_beta(it); } } /** Topological unsew by betai the given dart plus all the required darts * to satisfy the combinatorial map validity: but do not update attributes * thus the map can be non valid * @param adart first dart. * @pre !adart->is_free(i). */ template void topo_unsew(Dart_handle adart) { if ( i==0 ) topo_unsew_0(adart); else if ( i==1 ) topo_unsew_1(adart); else topo_unsew_for_involution(adart); } /** Unsew by beta0 the given dart plus all the required darts * to satisfy the combinatorial map validity, and update enabled * attributes when necessary so that the final map is valid. * @param adart first dart. * @pre !adart->is_free(0). * @post is_valid() */ void unsew_0(Dart_handle adart) { CGAL_assertion( !this->template is_free<0>(adart) ); size_type m=get_new_mark(); std::deque dartv; std::deque modified_darts; std::deque modified_darts2; for ( CGAL::CMap_dart_iterator_basic_of_cell it(*this, adart, m); it.cont(); ++it ) { mark(it, m); dartv.push_back(it); } for ( CGAL::CMap_dart_iterator_of_involution it(*this, adart); it.cont(); ++it ) { if ( is_marked(it, m) ) { modified_darts.push_back(it); modified_darts2.push_back(beta<0>(it)); unlink_beta_0(it); } else { modified_darts2.push_back(it); modified_darts.push_back(beta<1>(it)); unlink_beta_1(it); } } for ( typename std::deque::iterator it=dartv.begin(); it!=dartv.end(); ++it ) { unmark(*it,m); } CGAL_assertion( is_whole_map_unmarked(m) ); free_mark(m); // We test the split of all the incident cells for all the non // void attributes. Helper::template Foreach_enabled_attributes_except , 1>:: run(*this, modified_darts, modified_darts2); } /** Unsew by beta1 the given dart plus all the required darts * to satisfy the combinatorial map validity, and update enabled * attributes when necessary so that the final map is valid. * @param adart first dart. * @pre !adart->is_free(1). * @post is_valid() */ void unsew_1(Dart_handle adart) { CGAL_assertion( !this->template is_free<1>(adart) ); size_type m = get_new_mark(); std::deque dartv; std::deque modified_darts; std::deque modified_darts2; for ( CGAL::CMap_dart_iterator_basic_of_cell it(*this, adart, m); it.cont(); ++it) { mark(it, m); dartv.push_back(it); } for ( CGAL::CMap_dart_iterator_of_involution it(*this, adart); it.cont(); ++it ) { if ( is_marked(it, m) ) { modified_darts2.push_back(it); modified_darts.push_back(beta<1>(it)); unlink_beta_1(it); } else { modified_darts.push_back(it); modified_darts2.push_back(beta<0>(it)); unlink_beta_0(it); } } for ( typename std::deque::iterator it=dartv.begin(); it!=dartv.end(); ++it) { unmark(*it, m); } CGAL_assertion( is_whole_map_unmarked(m) ); free_mark(m); // We test the split of all the incident cells for all the non // void attributes. Helper::template Foreach_enabled_attributes_except , 1>:: run(*this, modified_darts, modified_darts2); } /** Unsew by betai the given dart plus all the required darts * to satisfy the combinatorial map validity, and update enabled * attributes when necessary so that the final map is valid. * @param adart first dart. * @pre !adart->is_free(i). * @post is_valid() * @pre 2<=i<=dimension */ template void unsew_for_involution(Dart_handle adart) { CGAL_assertion(2<=i && i<=Self::dimension); CGAL_assertion( !this->template is_free(adart) ); std::deque modified_darts; for ( CGAL::CMap_dart_iterator_of_involution it(*this, adart); it.cont(); ++it ) { modified_darts.push_back(it); modified_darts.push_back(beta(it)); unlink_beta_for_involution(it); } // We test the split of all the incident cells for all the non // void attributes. Helper::template Foreach_enabled_attributes_except , i>:: run(*this, modified_darts); } /** Unsew by betai the given dart plus all the required darts * to satisfy the combinatorial map validity, and update enabled * attributes when necessary so that the final map is valid. * @param adart first dart. * @pre !adart->is_free(i). * @post is_valid() */ template void unsew(Dart_handle adart) { if ( are_attributes_automatically_managed() ) { if ( i==0 ) unsew_0(adart); else if ( i==1 ) unsew_1(adart); else unsew_for_involution(adart); } else topo_unsew(adart); } /** Unsew by betai the given dart plus all the required darts * to satisfy the combinatorial map validity. Enabled attributes * are updated only if update_attributes==true. * @param adart first dart. * @param update_attributes a boolean to update the enabled attributes * (deprecated, now we use are_attributes_automatically_managed()) * @pre !adart->is_free(i). */ template void unsew(Dart_handle adart, bool update_attributes) { if ( update_attributes ) unsew(adart); else topo_unsew(adart); } /** Reverse the orientation (swap beta 0 & 1 links) of the entire map. * A valid map after this operation remains valid. * @param none * @return none */ void reverse_orientation() { internal::Reverse_orientation_of_map_functor::run(*this); } /** Reverse the orientation (swap beta 0 & 1 links) of the connected * component containing the given dart. * A valid map after this operation remains valid. * @param adart handle to a dart * @return none */ void reverse_orientation_connected_component (Dart_handle adart, size_type amark=INVALID_MARK) { internal::Reverse_orientation_of_connected_component_functor:: run(*this, adart, amark); } /// Keep the biggest connected component. /// @return the size (in number of darts) of the biggest cc. std::size_t keep_biggest_connected_component() { std::map ccs; size_type treated=get_new_mark(); for (auto it=darts().begin(), itend=darts().end(); it!=itend; ++it) { if (!is_marked(it, treated)) { ccs[mark_cell(it, treated)]=it; } } if (ccs.size()>1) { // Here all darts are marked this->template unmark_cell(ccs.rbegin()->second, treated); // Unmark the biggest cc erase_marked_darts(treated); } free_mark(treated); return ccs.rbegin()->first; } /** Count the marked cells (at least one marked dart). * @param amark the mark to consider. * @param avector containing the dimensions of the cells to count. * @return a vector containing the number of cells. */ std::vector count_marked_cells(size_type amark, const std::vector& acells) const { std::vector res(dimension+2); std::vector marks(dimension+2); // Initialization of the result for ( unsigned int i=0; i,dimension+1>:: run(*this, it, marks, res); } } // Unmarking darts std::vector tounmark; for ( unsigned int i=0; i 0 ) { for ( typename Dart_range::const_iterator it(darts().begin()), itend(darts().end()); it!=itend; ++it) { for ( unsigned int i=0; i count_cells(const std::vector& acells) const { std::vector res; size_type m = get_new_mark(); negate_mark(m); // We mark all the cells. res = count_marked_cells(m, acells); negate_mark(m); // We unmark the cells free_mark(m); return res; } /** Count the number of cells in each dimension. * @return a vector containing the number of cells. */ std::vector count_all_cells() const { std::vector dim(dimension+2); for ( unsigned int i=0; i & amarks) const { set_dart_marks(adart, amarks ^ mmask_marks); } /** Get simultaneously all the marks of a given dart. * @param adart the dart. * @return allt the marks of adart. */ std::bitset get_marks(Dart_const_handle adart) const { return get_dart_marks(adart) ^ mmask_marks; } /** Get the mask associated to a given mark. * @param amark the mark. * @return the mask associated to mark amark. */ bool get_mask_mark(size_type amark) const { CGAL_assertion(amark>=0 && amarktemplate is_free<1>(d1))); /* CGAL_assertion((belong_to_same_cell<0>(this->template beta<1>(d1), d2))); */ if (d2==beta<2>(d1)) { return 0; } Dart_const_handle dd1=d1; std::size_t res=1; while (beta<1>(dd1)!=d2) { if (this->template is_free<2>(beta<1>(dd1))) { return (std::numeric_limits::max)(); } ++res; dd1=beta<1, 2>(dd1); CGAL_assertion(!this->template is_free<1>(dd1)); CGAL_assertion(beta<1>(dd1)==d2 || dd1!=d1); } return res; } /// @return the negative turn between the two given darts. // @pre beta1(d1) and d2 must belong to the same vertex. std::size_t negative_turn(Dart_const_handle d1, Dart_const_handle d2) const { CGAL_assertion((!this->template is_free<1>(d1))); /* CGAL_assertion((belong_to_same_cell<0>(this->template beta<1>(d1), d2))); */ if (d2==beta<2>(d1)) { return 0; } if (this->template is_free<2>(d1) || this->template is_free<2>(d2)) { return (std::numeric_limits::max)(); } d1=beta<2>(d1); d2=beta<2>(d2); Dart_const_handle dd1=d1; std::size_t res=1; while (beta<0>(dd1)!=d2) { if (this->template is_free<2>(beta<0>(dd1))) { return (std::numeric_limits::max)(); } ++res; dd1=beta<0, 2>(dd1); CGAL_assertion(!this->template is_free<0>(dd1)); CGAL_assertion(beta<0>(dd1)==d2 || dd1!=d1); } return res; } /** Erase marked darts from the map. * Marked darts are unlinked before to be removed, thus surviving darts * are correctly linked, but the map is not necessarily valid depending * on the configuration of removed darts. User must check carefully marked * darts before calling this method. * @param amark the mark of darts to erase. * @return the number of removed darts. */ unsigned int erase_marked_darts(size_type amark) { unsigned int res = 0, i = 0; Dart_handle d; for ( typename Dart_range::iterator it(darts().begin()), itend(darts().end()); it!=itend; ) { d = it++; if (is_marked(d, amark)) { for ( i = 0; i <= dimension; ++i) { if (!is_free(d, i)) unlink_beta(d, i); } erase_dart(d); ++res; } } return res; } //************************************************************************** // Dart_of_orbit_basic_range template struct Dart_of_orbit_basic_range : public CGAL::CMap_range , CGAL::CMap_dart_const_iterator_basic_of_orbit > { typedef CGAL::CMap_range , CGAL::CMap_dart_const_iterator_basic_of_orbit > Base; Dart_of_orbit_basic_range(Self &amap, Dart_handle adart, size_type amark=INVALID_MARK): Base(amap, adart, amark) {} }; //************************************************************************** // Dart_of_orbit_basic_const_range template struct Dart_of_orbit_basic_const_range : public CGAL::CMap_const_range > { typedef CGAL::CMap_const_range > Base; Dart_of_orbit_basic_const_range(const Self &amap, Dart_const_handle adart, size_type amark=INVALID_MARK): Base(amap, adart, amark) {} }; //************************************************************************** // Dart_of_orbit_range template struct Dart_of_orbit_range : public CGAL::CMap_range , CGAL::CMap_dart_const_iterator_of_orbit > { typedef CGAL::CMap_range , CGAL::CMap_dart_const_iterator_of_orbit > Base; Dart_of_orbit_range(Self &amap, Dart_handle adart) : Base(amap,adart) {} }; //************************************************************************** // Dart_of_orbit_const_range template struct Dart_of_orbit_const_range : public CGAL::CMap_const_range > { typedef CGAL::CMap_const_range > Base; Dart_of_orbit_const_range(const Self &amap, Dart_const_handle adart): Base(amap,adart) {} }; //************************************************************************** /// @return a range on all the darts of the given orbit template Dart_of_orbit_range darts_of_orbit(Dart_handle adart) { return Dart_of_orbit_range(*this,adart); } //-------------------------------------------------------------------------- template Dart_of_orbit_const_range darts_of_orbit(Dart_const_handle adart) const { return Dart_of_orbit_const_range(*this,adart); } //-------------------------------------------------------------------------- template Dart_of_orbit_basic_range darts_of_orbit_basic(Dart_handle adart, size_type amark=INVALID_MARK) { return Dart_of_orbit_basic_range(*this,adart,amark); } //-------------------------------------------------------------------------- template Dart_of_orbit_basic_const_range darts_of_orbit_basic(Dart_const_handle adart, size_type amark=INVALID_MARK) const { return Dart_of_orbit_basic_const_range(*this,adart,amark); } //************************************************************************** // Dart_of_cell_basic_range template struct Dart_of_cell_basic_range: public CGAL::CMap_range , CGAL::CMap_dart_const_iterator_basic_of_cell > { typedef CGAL::CMap_range , CGAL::CMap_dart_const_iterator_basic_of_cell > Base; Dart_of_cell_basic_range(Self &amap, Dart_handle adart, size_type amark=INVALID_MARK) : Base(amap, adart, amark) {} }; //************************************************************************** // Dart_of_cell_basic_const_range template struct Dart_of_cell_basic_const_range: public CMap_const_range > { typedef CMap_const_range > Base; Dart_of_cell_basic_const_range(const Self &amap, Dart_const_handle adart, size_type amark=INVALID_MARK) : Base(amap, adart, amark) {} }; //************************************************************************** // Dart_of_cell_range template struct Dart_of_cell_range: public CGAL::CMap_range , CGAL::CMap_dart_const_iterator_of_cell > { typedef CGAL::CMap_range , CGAL::CMap_dart_const_iterator_of_cell > Base; Dart_of_cell_range(Self &amap, Dart_handle adart) : Base(amap, adart) {} }; //************************************************************************** // Dart_of_cell_const_range template struct Dart_of_cell_const_range: public CMap_const_range > { typedef CMap_const_range > Base; Dart_of_cell_const_range(const Self &amap, Dart_const_handle adart) : Base(amap, adart) {} }; //-------------------------------------------------------------------------- /// @return a range on all the darts of the given i-cell template Dart_of_cell_basic_range darts_of_cell_basic(Dart_handle adart, size_type amark=INVALID_MARK) { return Dart_of_cell_basic_range(*this,adart,amark); } //-------------------------------------------------------------------------- template Dart_of_cell_basic_const_range darts_of_cell_basic (Dart_const_handle adart, size_type amark=INVALID_MARK) const { return Dart_of_cell_basic_const_range(*this,adart,amark); } //-------------------------------------------------------------------------- template Dart_of_cell_basic_range darts_of_cell_basic(Dart_handle adart, size_type amark=INVALID_MARK) { return darts_of_cell_basic(adart,amark); } //-------------------------------------------------------------------------- template Dart_of_cell_basic_const_range darts_of_cell_basic(Dart_const_handle adart, size_type amark=INVALID_MARK) const { return darts_of_cell_basic(adart,amark); } //-------------------------------------------------------------------------- template Dart_of_cell_range darts_of_cell(Dart_handle adart) { return Dart_of_cell_range(*this,adart); } //-------------------------------------------------------------------------- template Dart_of_cell_const_range darts_of_cell(Dart_const_handle adart) const { return Dart_of_cell_const_range(*this,adart); } //-------------------------------------------------------------------------- template Dart_of_cell_range darts_of_cell(Dart_handle adart) { return darts_of_cell(adart); } //-------------------------------------------------------------------------- template Dart_of_cell_const_range darts_of_cell(Dart_const_handle adart) const { return darts_of_cell(adart); } //************************************************************************** // Dart_of_involution_basic_range template struct Dart_of_involution_basic_range: public CGAL::CMap_range , CGAL::CMap_dart_const_iterator_basic_of_involution > { typedef CGAL::CMap_range , CGAL::CMap_dart_const_iterator_basic_of_involution > Base; Dart_of_involution_basic_range(Self &amap, Dart_handle adart, size_type amark=INVALID_MARK): Base(amap, adart, amark) {} }; //************************************************************************** // Dart_of_involution_basic_const_range template struct Dart_of_involution_basic_const_range: public CMap_const_range > { typedef CMap_const_range > Base; Dart_of_involution_basic_const_range(const Self &amap, Dart_const_handle adart, size_type amark=INVALID_MARK) : Base(amap, adart, amark) {} }; //************************************************************************** template Dart_of_involution_basic_range darts_of_involution_basic(Dart_handle adart, size_type amark=INVALID_MARK) { return Dart_of_involution_basic_range(*this,adart,amark); } //-------------------------------------------------------------------------- template Dart_of_involution_basic_const_range darts_of_involution_basic(Dart_const_handle adart, size_type amark=INVALID_MARK) const { return Dart_of_involution_basic_const_range(*this,adart,amark); } //-------------------------------------------------------------------------- template Dart_of_involution_basic_range darts_of_involution_basic(Dart_handle adart, size_type amark=INVALID_MARK) { return Dart_of_involution_basic_range (*this,adart,amark); } //-------------------------------------------------------------------------- template Dart_of_involution_basic_const_range darts_of_involution_basic(Dart_const_handle adart, size_type amark=INVALID_MARK) const { return Dart_of_involution_basic_const_range (*this,adart,amark); } //************************************************************************** // Dart_of_involution_inv_basic_range template struct Dart_of_involution_inv_basic_range: public CGAL::CMap_range , CGAL::CMap_dart_const_iterator_basic_of_involution_inv > { typedef CGAL::CMap_range , CGAL::CMap_dart_const_iterator_basic_of_involution_inv > Base; Dart_of_involution_inv_basic_range(Self &amap, Dart_handle adart, size_type amark=INVALID_MARK): Base(amap, adart, amark) {} }; //************************************************************************** // Dart_of_involution_inv_basic_const_range template struct Dart_of_involution_inv_basic_const_range: public CMap_const_range > { typedef CMap_const_range > Base; Dart_of_involution_inv_basic_const_range(const Self &amap, Dart_const_handle adart, size_type amark=INVALID_MARK) : Base(amap, adart, amark) {} }; //************************************************************************** template Dart_of_involution_inv_basic_range darts_of_involution_inv_basic(Dart_handle adart, size_type amark=INVALID_MARK) { return Dart_of_involution_inv_basic_range(*this,adart,amark); } //-------------------------------------------------------------------------- template Dart_of_involution_inv_basic_const_range darts_of_involution_inv_basic(Dart_const_handle adart, size_type amark=INVALID_MARK) const { return Dart_of_involution_inv_basic_const_range (*this,adart,amark); } //-------------------------------------------------------------------------- template Dart_of_involution_inv_basic_range darts_of_involution_inv_basic(Dart_handle adart, size_type amark=INVALID_MARK) { return Dart_of_involution_inv_basic_range (*this,adart,amark); } //-------------------------------------------------------------------------- template Dart_of_involution_inv_basic_const_range darts_of_involution_inv_basic(Dart_const_handle adart, size_type amark=INVALID_MARK) const { return Dart_of_involution_inv_basic_const_range (*this,adart,amark); } //************************************************************************** // Dart_of_involution_range template struct Dart_of_involution_range: public CGAL::CMap_range , CGAL::CMap_dart_const_iterator_of_involution > { typedef CGAL::CMap_range , CGAL::CMap_dart_const_iterator_of_involution > Base; Dart_of_involution_range(Self &amap, Dart_handle adart) : Base(amap, adart) {} }; //************************************************************************** // Dart_of_involution_const_range template struct Dart_of_involution_const_range: public CMap_const_range > { typedef CMap_const_range > Base; Dart_of_involution_const_range(const Self &amap, Dart_const_handle adart): Base(amap, adart) {} }; //************************************************************************** template Dart_of_involution_range darts_of_involution(Dart_handle adart) { return Dart_of_involution_range(*this,adart); } //-------------------------------------------------------------------------- template Dart_of_involution_const_range darts_of_involution(Dart_const_handle adart) const { return Dart_of_involution_const_range(*this,adart); } //-------------------------------------------------------------------------- template Dart_of_involution_range darts_of_involution(Dart_handle adart) { return Dart_of_involution_range(*this,adart); } //-------------------------------------------------------------------------- template Dart_of_involution_const_range darts_of_involution(Dart_const_handle adart) const { return Dart_of_involution_const_range(*this,adart); } //************************************************************************** // Dart_of_involution_inv_range template struct Dart_of_involution_inv_range: public CGAL::CMap_range , CGAL::CMap_dart_const_iterator_of_involution_inv > { typedef CGAL::CMap_range , CGAL::CMap_dart_const_iterator_of_involution_inv > Base; Dart_of_involution_inv_range(Self &amap, Dart_handle adart) : Base(amap, adart) {} }; //************************************************************************** // Dart_of_involution_inv_const_range template struct Dart_of_involution_inv_const_range: public CMap_const_range > { typedef CMap_const_range > Base; Dart_of_involution_inv_const_range(const Self &amap, Dart_const_handle adart): Base(amap, adart) {} }; //************************************************************************** template Dart_of_involution_inv_range darts_of_involution_inv(Dart_handle adart) { return Dart_of_involution_inv_range(*this,adart); } //-------------------------------------------------------------------------- template Dart_of_involution_inv_const_range darts_of_involution_inv(Dart_const_handle adart) const { return Dart_of_involution_inv_const_range(*this,adart); } //-------------------------------------------------------------------------- template Dart_of_involution_inv_range darts_of_involution_inv(Dart_handle adart) { return Dart_of_involution_inv_range(*this,adart); } //-------------------------------------------------------------------------- template Dart_of_involution_inv_const_range darts_of_involution_inv(Dart_const_handle adart) const { return Dart_of_involution_inv_const_range (*this,adart); } //************************************************************************** // Dart_basic_range struct Dart_basic_range { typedef CGAL::CMap_dart_iterator_basic_of_all iterator; typedef CGAL::CMap_dart_const_iterator_basic_of_all const_iterator; Dart_basic_range(Self &amap) : mmap(amap) {} iterator begin() { return iterator(mmap); } iterator end() { return iterator(mmap,mmap.null_handle); } const_iterator begin() const { return const_iterator(mmap); } const_iterator end() const { return const_iterator(mmap,mmap.null_handle); } size_type size() const { return mmap.number_of_darts(); } bool empty() const { return mmap.is_empty(); } private: Self & mmap; }; //************************************************************************** // Dart_basic_const_range struct Dart_basic_const_range { typedef CGAL::CMap_dart_const_iterator_basic_of_all const_iterator; Dart_basic_const_range(Self &amap) : mmap(amap) {} const_iterator begin() const { return const_iterator(mmap); } const_iterator end() const { return const_iterator(mmap,mmap.null_handle); } size_type size() const { return mmap.number_of_darts(); } bool empty() const { return mmap.is_empty(); } private: const Self & mmap; }; //************************************************************************** Dart_basic_range darts_basic() { return Dart_basic_range(*this); } //-------------------------------------------------------------------------- Dart_basic_const_range darts_basic() const { return Dart_basic_const_range(*this); } //************************************************************************** // One_dart_per_incident_cell_range template struct One_dart_per_incident_cell_range: public CGAL::CMap_range , CGAL::CMap_one_dart_per_incident_cell_const_iterator > { typedef CGAL::CMap_range , CGAL::CMap_one_dart_per_incident_cell_const_iterator > Base; One_dart_per_incident_cell_range(Self &amap, Dart_handle adart): Base(amap, adart) {} }; //************************************************************************** // One_dart_per_incident_cell_const_range template struct One_dart_per_incident_cell_const_range: public CMap_const_range > { typedef CMap_const_range > Base; One_dart_per_incident_cell_const_range(const Self &amap, Dart_const_handle adart) : Base(amap, adart) {} }; //************************************************************************** // One_dart_per_cell_range template struct One_dart_per_cell_range { typedef CGAL::CMap_one_dart_per_cell_iterator iterator; typedef CGAL::CMap_one_dart_per_cell_const_iterator const_iterator; One_dart_per_cell_range(Self &amap) : mmap(amap), msize(0) {} iterator begin() { return iterator(mmap); } iterator end() { return iterator(mmap,mmap.null_handle); } const_iterator begin() const { return const_iterator(mmap); } const_iterator end() const { return const_iterator(mmap,mmap.null_handle); } size_type size() const { if (msize==0) for ( const_iterator it=begin(), itend=end(); it!=itend; ++it) ++msize; return msize; } bool empty() const { return mmap.is_empty(); } private: Self & mmap; mutable size_type msize; }; //************************************************************************** // One_dart_per_cell_const_range template struct One_dart_per_cell_const_range { typedef CGAL::CMap_one_dart_per_cell_const_iterator const_iterator; One_dart_per_cell_const_range(const Self &amap) : mmap(amap), msize(0) {} const_iterator begin() const { return const_iterator(mmap); } const_iterator end() const { return const_iterator(mmap,mmap.null_handle); } size_type size() const { if (msize==0) for ( const_iterator it=begin(), itend=end(); it!=itend; ++it) ++msize; return msize; } bool empty() const { return mmap.is_empty(); } private: const Self & mmap; mutable size_type msize; }; //************************************************************************** /// @return a range on the i-cells incindent to the given j-cell. template One_dart_per_incident_cell_range one_dart_per_incident_cell(Dart_handle adart) { return One_dart_per_incident_cell_range(*this,adart); } //-------------------------------------------------------------------------- template One_dart_per_incident_cell_const_range one_dart_per_incident_cell(Dart_const_handle adart) const { return One_dart_per_incident_cell_const_range(*this,adart); } //-------------------------------------------------------------------------- template One_dart_per_incident_cell_range one_dart_per_incident_cell(Dart_handle adart) { return one_dart_per_incident_cell(adart); } //-------------------------------------------------------------------------- template One_dart_per_incident_cell_const_range one_dart_per_incident_cell(Dart_const_handle adart) const { return one_dart_per_incident_cell(adart); } //-------------------------------------------------------------------------- /// @return a range on all the i-cells template One_dart_per_cell_range one_dart_per_cell() { return One_dart_per_cell_range(*this); } //-------------------------------------------------------------------------- template One_dart_per_cell_const_range one_dart_per_cell() const { return One_dart_per_cell_const_range(*this); } //-------------------------------------------------------------------------- template One_dart_per_cell_range one_dart_per_cell() { return one_dart_per_cell(); } //-------------------------------------------------------------------------- template One_dart_per_cell_const_range one_dart_per_cell() const { return one_dart_per_cell(); } //-------------------------------------------------------------------------- public: /** Compute the dual of a Combinatorial_map. * @param amap the cmap in which we build the dual of this map. * @param adart a dart of the initial map, nullptr by default. * @return adart of the dual map, the dual of adart if adart!=nullptr, * any dart otherwise. * As soon as we don't modify this map and amap map, we can iterate * simultaneously through all the darts of the two maps and we have * each time of the iteration two "dual" darts. */ Dart_handle dual(Self& amap, Dart_handle adart=null_handle) { CGAL_assertion( is_without_boundary(dimension) ); CGAL::Unique_hash_map< Dart_handle, Dart_handle, typename Self::Hash_function > dual; Dart_handle d, d2, res = amap.null_handle; // We clear amap. TODO return a new amap ? amap.clear(); // We create a copy of all the dart of the map. for ( typename Dart_range::iterator it=darts().begin(); it!=darts().end(); ++it) { dual[it] = amap.create_dart(); internal::Copy_dart_info_functor:: run(static_cast(amap), static_cast(*this), it, dual[it]); if ( it==adart && res==amap.null_handle ) res = dual[it]; } // Then we link the darts by using the dual formula : // G(B,b1,b2,...,bn-1,bn) => // dual(G)=(B, b(n-1)obn, b(n-2)obn,...,b1obn, bn) // We suppose darts are run in the same order for both maps. typename Dart_range::iterator it2=amap.darts().begin(); for ( typename Dart_range::iterator it=darts().begin(); it!=darts().end(); ++it, ++it2) { d = it2; // The supposition on the order allows to avoid d=dual[it]; CGAL_assertion( it2==dual[it] ); // First case outside the loop since we need to use link_beta1 if ( amap.template is_free<1>(d) && beta(it)!=null_dart_handle ) amap.basic_link_beta_1(d, dual[beta(it)]); // and during the loop we use link_beta(d1,d2,i) for ( unsigned int i=dimension-2; i>=1; --i) { if ( amap.is_free(d,dimension-i) && beta(it, dimension, i)!=null_dart_handle ) amap.basic_link_beta(d, dual[beta(it, dimension, i)], dimension-i); } if ( amap.template is_free(d) ) { CGAL_assertion ( !this->template is_free(it) ); amap.basic_link_beta(d, dual[beta(it)], dimension); } } // CGAL_postcondition(amap2.is_valid()); if ( res==amap.null_handle ) res = amap.darts().begin(); return res; } /** Test if the connected component of cmap containing dart dh1 is * isomorphic to the connected component of map2 containing dart dh2, * starting from dh1 and dh2. * @param dh1 initial dart for this map * @param map2 the second combinatorial map * @param dh2 initial dart for map2 * @param testDartInfo Boolean to test the equality of dart info (true) * or not (false) * @param testAttributes Boolean to test the equality of attributes (true) * or not (false) * @param testPoint Boolean to test the equality of points (true) * or not (false) (used for LCC) * @return true iff the cc of map is isomorphic to the cc of map2 starting * from dh1 and dh2; by testing the equality of dartinfo and/or * attributes and/or points. */ template bool are_cc_isomorphic(Dart_const_handle dh1, const Combinatorial_map_base & map2, typename Combinatorial_map_base ::Dart_const_handle dh2, bool testDartInfo=true, bool testAttributes=true, bool testPoint=true) const { #if defined(CGAL_CMAP_DART_DEPRECATED) && !defined(CGAL_NO_DEPRECATED_CODE) CGAL_USE(testDartInfo); #endif typedef Combinatorial_map_base Map2; bool match = true; // Two stacks used to run through the two maps. std::deque< Dart_const_handle > toTreat1; std::deque< typename Map2::Dart_const_handle > toTreat2; // A dart of this map is marked with m1 if its bijection was set // (and similarly for mark m2 and darts of map2) size_type m1 = get_new_mark(); size_type m2 = map2.get_new_mark(); // A dart of this map is marked with markpush if it was already pushed // in the queue toTreat1. size_type markpush = get_new_mark(); toTreat1.push_back(dh1); toTreat2.push_back(dh2); Dart_const_handle current; typename Map2::Dart_const_handle other; unsigned int i = 0; CGAL::Unique_hash_map bijection; while (match && !toTreat1.empty()) { // Next dart current = toTreat1.front(); toTreat1.pop_front(); other = toTreat2.front(); toTreat2.pop_front(); if (!is_marked(current, m1)) { if (map2.is_marked(other, m2)) { match=false; } else { bijection[current] = other; mark(current, m1); map2.mark(other, m2); // We first test info of darts #if !defined(CGAL_CMAP_DART_DEPRECATED) || defined(CGAL_NO_DEPRECATED_CODE) if (match && testDartInfo) match=internal::Test_is_same_dart_info_functor:: run(*this, map2, current, other); #endif // We need to test in both direction because // Foreach_enabled_attributes only test non void attributes // of Self. Functor Test_is_same_attribute_functor will modify // the value of match to false if attributes do not match if (testAttributes) { if (match) Helper::template Foreach_enabled_attributes < internal::Test_is_same_attribute_functor >:: run(*this, map2, current, other, match); if (match) Map2::Helper::template Foreach_enabled_attributes < internal::Test_is_same_attribute_functor >:: run(map2, *this, other, current, match); } if (match && testPoint) { // Only point of 0-attributes are tested. TODO test point of all // attributes ? match=internal::Test_is_same_attribute_point_functor ::run(*this, map2, current, other); } // We test if the injection is valid with its neighboors. // We go out as soon as it is not satisfied. for (i = 0; match && i <= dimension; ++i) { if ( i>map2.dimension ) { if (!is_free(current,i)) { match=false; } } else { if (is_free(current,i)) { if (!map2.is_free(other,i)) { match=false; } } else { if (map2.is_free(other,i)) { match=false; } else { if (is_marked(beta(current,i), m1) != map2.is_marked(map2.beta(other,i), m2)) { match=false; } else { if (!is_marked(beta(current,i), m1)) { if (!is_marked(beta(current,i), markpush)) { toTreat1.push_back(beta(current,i)); toTreat2.push_back(map2.beta(other,i)); mark(beta(current,i), markpush); } } else { if (bijection[beta(current,i)]!=map2.beta(other,i)) { match=false; } } } } } } } // Now we test if the second map has more beta links than the first for ( i=dimension+1; match && i<=map2.dimension; ++i ) { if (!map2.is_free(other,i)) { match=false; } } } } else { if (!map2.is_marked(other, m2)) { match=false; } } } // Here we test if both queue are empty if ( !toTreat1.empty() || !toTreat2.empty() ) { match=false; } // Here we unmark all the marked darts. toTreat1.clear(); toTreat2.clear(); toTreat1.push_back(dh1); toTreat2.push_back(dh2); unmark(dh1, m1); unmark(dh1, markpush); map2.unmark(dh2, m2); while (!toTreat1.empty()) { current = toTreat1.front(); toTreat1.pop_front(); other = toTreat2.front(); toTreat2.pop_front(); for (i = 0; i <= dimension; ++i) { if (!is_free(current,i) && is_marked(beta(current,i), markpush)) { toTreat1.push_back(beta(current,i)); toTreat2.push_back(map2.beta(other,i)); unmark(beta(current,i), m1); unmark(beta(current,i), markpush); map2.unmark(map2.beta(other,i), m2); } } } assert(is_whole_map_unmarked(m1)); assert(is_whole_map_unmarked(markpush)); assert(map2.is_whole_map_unmarked(m2)); free_mark(m1); free_mark(markpush); map2.free_mark(m2); return match; } /** Test if this cmap is isomorphic to map2. * @pre cmap is connected. * @param map2 the second combinatorial map * @param testDartInfo Boolean to test the equality of dart info (true) * or not (false) * @param testAttributes Boolean to test the equality of attributes (true) * or not (false) * @param testPoint Boolean to test the equality of points (true) * or not (false) (used for LCC) * @return true iff this map is isomorphic to map2, testing the equality * of attributes if testAttributes is true */ template bool is_isomorphic_to(const Combinatorial_map_base & map2, bool testDartInfo=true, bool testAttributes=true, bool testPoint=true) const { if (is_empty() && map2.is_empty()) return true; if (is_empty() || map2.is_empty()) return false; Dart_const_handle d1=darts().begin(); for (typename Combinatorial_map_base:: Dart_range::const_iterator it(map2.darts().begin()), itend(map2.darts().end()); it!=itend; ++it) { if (are_cc_isomorphic(d1, map2, it, testDartInfo, testAttributes, testPoint)) { return true; } } return false; } /** Test if the attributes of this map are automatically updated. * @return true iff the boolean automatic_attributes_management is set to true. */ bool are_attributes_automatically_managed() const { return automatic_attributes_management; } /** Sets the automatic_attributes_management boolean. */ void set_automatic_attributes_management(bool newval) { if (this->automatic_attributes_management == false && newval == true) { correct_invalid_attributes(); } this->automatic_attributes_management = newval; } /** Create an half-edge. * @return a dart of the new half-edge. */ Dart_handle make_half_edge() { return create_dart(); } /** Create an edge. * if closed==true, the edge has no 2-free dart. * (note that for CMap there is no differente between true and false, but * this is not the case for GMap) * @return a dart of the new edge. */ Dart_handle make_edge(bool /*closed*/=false) { Dart_handle d1 = create_dart(); Dart_handle d2 = create_dart(); this->template basic_link_beta_for_involution<2>(d1, d2); return d1; } /** Create an edge given 2 Attribute_handle<0>. * Note that this function can be used only if 0-attributes are non void * @param h0 the first vertex handle. * @param h1 the second vertex handle. * if closed==true, the edge has no 2-free dart. * (note that for CMap there is no differente between true and false, but * this is not the case for GMap) * @return the dart of the new edge incident to h0. */ Dart_handle make_segment(typename Attribute_handle<0>::type h0, typename Attribute_handle<0>::type h1, bool /*closed*/=false) { Dart_handle d1 = this->make_edge(); set_dart_attribute<0>(d1,h0); set_dart_attribute<0>(this->beta<2>(d1),h1); return d1; } /** Create a combinatorial polygon of length alg * (a cycle of alg darts beta1 links together). * @return a new dart. */ Dart_handle make_combinatorial_polygon(unsigned int alg) { CGAL_assertion(alg>0); Dart_handle start = create_dart(); Dart_handle prev = start; for ( unsigned int nb=1; nb0); unsigned int nb = 0; Dart_const_handle cur = adart; do { ++nb; if ( cur==null_dart_handle ) return false; // Open face cur = beta(cur,1); } while( cur!=adart ); return (nb==alg); } /** Create a triangle given 3 Attribute_handle<0>. * @param h0 the first handle. * @param h1 the second handle. * @param h2 the third handle. * Note that this function can be used only if 0-attributes are non void * @return the dart of the new triangle incident to h0 and to edge h0h1. */ Dart_handle make_triangle(typename Attribute_handle<0>::type h0, typename Attribute_handle<0>::type h1, typename Attribute_handle<0>::type h2) { Dart_handle d1 = this->make_combinatorial_polygon(3); set_dart_attribute<0>(d1,h0); set_dart_attribute<0>(this->beta<1>(d1),h1); set_dart_attribute<0>(this->beta<0>(d1),h2); return d1; } /** Create a quadrangle given 4 Vertex_attribute_handle. * @param h0 the first vertex handle. * @param h1 the second vertex handle. * @param h2 the third vertex handle. * @param h3 the fourth vertex handle. * Note that this function can be used only if 0-attributes are non void * @return the dart of the new quadrilateral incident to h0 and to edge h0h1. */ Dart_handle make_quadrangle(typename Attribute_handle<0>::type h0, typename Attribute_handle<0>::type h1, typename Attribute_handle<0>::type h2, typename Attribute_handle<0>::type h3) { Dart_handle d1 = this->make_combinatorial_polygon(4); set_dart_attribute<0>(d1,h0); set_dart_attribute<0>(this->beta<1>(d1),h1); set_dart_attribute<0>(this->beta<1,1>(d1), h2); set_dart_attribute<0>(this->beta<0>(d1),h3); return d1; } /** Create a combinatorial tetrahedron from 4 triangles. * @param d1 a dart onto a first triangle. * @param d2 a dart onto a second triangle. * @param d3 a dart onto a third triangle. * @param d4 a dart onto a fourth triangle. * @return d1. */ Dart_handle make_combinatorial_tetrahedron(Dart_handle d1, Dart_handle d2, Dart_handle d3, Dart_handle d4) { basic_link_beta_for_involution(d1, d2, 2); basic_link_beta_for_involution(d3, beta(d2, 0), 2); basic_link_beta_for_involution(beta(d1, 1), beta(d3, 0), 2); basic_link_beta_for_involution(d4, beta(d2, 1), 2); basic_link_beta_for_involution(beta(d4, 0), beta(d3, 1), 2); basic_link_beta_for_involution(beta(d4, 1), beta(d1, 0), 2); return d1; } /** Test if a volume is a combinatorial tetrahedron. * @param adart an intial dart * @return true iff the volume containing adart is a combinatorial tetrahedron. */ bool is_volume_combinatorial_tetrahedron(Dart_const_handle d1) const { Dart_const_handle d2 = beta(d1, 2); Dart_const_handle d3 = beta(d2, 0, 2); Dart_const_handle d4 = beta(d2, 1, 2); if ( d1==null_dart_handle || d2==null_dart_handle || d3==null_dart_handle || d4==null_dart_handle ) return false; if ( !is_face_combinatorial_polygon(d1, 3) || !is_face_combinatorial_polygon(d2, 3) || !is_face_combinatorial_polygon(d3, 3) || !is_face_combinatorial_polygon(d4, 3) ) return false; // TODO do better with marks (?). if ( belong_to_same_cell<2,1>(d1, d2) || belong_to_same_cell<2,1>(d1, d3) || belong_to_same_cell<2,1>(d1, d4) || belong_to_same_cell<2,1>(d2, d3) || belong_to_same_cell<2,1>(d2, d4) || belong_to_same_cell<2,1>(d3, d4) ) return false; if ( beta(d1,1,2)!=beta(d3,0) || beta(d4,0,2)!=beta(d3,1) || beta(d4,1,2)!=beta(d1,0) ) return false; return true; } /** Create a new combinatorial tetrahedron. * @return a new dart. */ Dart_handle make_combinatorial_tetrahedron() { Dart_handle d1 = make_combinatorial_polygon(3); Dart_handle d2 = make_combinatorial_polygon(3); Dart_handle d3 = make_combinatorial_polygon(3); Dart_handle d4 = make_combinatorial_polygon(3); return make_combinatorial_tetrahedron(d1, d2, d3, d4); } /** Create a combinatorial hexahedron from 6 quadrilaterals. * @param d1 a dart onto a first quadrilateral. * @param d2 a dart onto a second quadrilateral. * @param d3 a dart onto a third quadrilateral. * @param d4 a dart onto a fourth quadrilateral. * @param d5 a dart onto a fifth quadrilateral. * @param d6 a dart onto a sixth quadrilateral. * @return d1. */ Dart_handle make_combinatorial_hexahedron(Dart_handle d1, Dart_handle d2, Dart_handle d3, Dart_handle d4, Dart_handle d5, Dart_handle d6) { basic_link_beta_for_involution(d1, beta(d4, 1, 1), 2); basic_link_beta_for_involution(beta(d1, 1), beta(d6, 0) , 2); basic_link_beta_for_involution(beta(d1, 1, 1), d2 , 2); basic_link_beta_for_involution(beta(d1, 0), d5 , 2); basic_link_beta_for_involution(d3, beta(d2, 1, 1), 2); basic_link_beta_for_involution(beta(d3, 1), beta(d6, 1) , 2); basic_link_beta_for_involution(beta(d3, 1, 1), d4 , 2); basic_link_beta_for_involution(beta(d3, 0), beta(d5, 1, 1), 2); basic_link_beta_for_involution(d6, beta(d4, 1) , 2); basic_link_beta_for_involution(beta(d6, 1, 1), beta(d2, 1) , 2); basic_link_beta_for_involution(beta(d5, 0), beta(d4, 0) , 2); basic_link_beta_for_involution(beta(d5, 1), beta(d2, 0) , 2); return d1; } /** Test if a volume is a combinatorial hexahedron. * @param adart an intial dart * @return true iff the volume containing adart is a combinatorial hexahedron. */ bool is_volume_combinatorial_hexahedron(Dart_const_handle d1) const { Dart_const_handle d2 = beta(d1, 1, 1, 2); Dart_const_handle d3 = beta(d2, 1, 1, 2); Dart_const_handle d4 = beta(d3, 1, 1, 2); Dart_const_handle d5 = beta(d1, 0, 2); Dart_const_handle d6 = beta(d4, 1, 2); if ( d1==null_dart_handle || d2==null_dart_handle || d3==null_dart_handle || d4==null_dart_handle || d5==null_dart_handle || d6==null_dart_handle ) return false; if (!is_face_combinatorial_polygon(d1, 4) || !is_face_combinatorial_polygon(d2, 4) || !is_face_combinatorial_polygon(d3, 4) || !is_face_combinatorial_polygon(d4, 4) || !is_face_combinatorial_polygon(d5, 4) || !is_face_combinatorial_polygon(d6, 4) ) return false; // TODO do better with marks. if ( belong_to_same_cell<2,1>(d1, d2) || belong_to_same_cell<2,1>(d1, d3) || belong_to_same_cell<2,1>(d1, d4) || belong_to_same_cell<2,1>(d1, d5) || belong_to_same_cell<2,1>(d1, d6) || belong_to_same_cell<2,1>(d2, d3) || belong_to_same_cell<2,1>(d2, d4) || belong_to_same_cell<2,1>(d2, d5) || belong_to_same_cell<2,1>(d2, d6) || belong_to_same_cell<2,1>(d3, d4) || belong_to_same_cell<2,1>(d3, d5) || belong_to_same_cell<2,1>(d3, d6) || belong_to_same_cell<2,1>(d4, d5) || belong_to_same_cell<2,1>(d4, d6) || belong_to_same_cell<2,1>(d5, d6) ) return false; if ( beta(d1,2) !=beta(d4,1,1) || beta(d1,1,2) !=beta(d6,0) || beta(d3,1,2) !=beta(d6,1) || beta(d3,0,2) !=beta(d5,1,1) || beta(d6,1,1,2)!=beta(d2,1) || beta(d5,0,2) !=beta(d4,0) || beta(d5,1,2) !=beta(d2,0) ) return false; return true; } /** Create a new combinatorial hexahedron. * @return a new dart. */ Dart_handle make_combinatorial_hexahedron() { Dart_handle d1 = make_combinatorial_polygon(4); Dart_handle d2 = make_combinatorial_polygon(4); Dart_handle d3 = make_combinatorial_polygon(4); Dart_handle d4 = make_combinatorial_polygon(4); Dart_handle d5 = make_combinatorial_polygon(4); Dart_handle d6 = make_combinatorial_polygon(4); return make_combinatorial_hexahedron(d1, d2, d3, d4, d5, d6); } /** Test if an i-cell can be removed. * An i-cell can be removed if i==dimension or i==dimension-1, * or if there are at most two (i+1)-cell incident to it. * @param adart a dart of the i-cell. * @return true iff the i-cell can be removed. */ template < unsigned int i > bool is_removable(Dart_const_handle adart) const { return CGAL::Is_removable_functor::run(*this, adart); } /** Remove an i-cell, 0<=i<=dimension. * @param adart a dart of the i-cell to remove. * @param update_attributes a boolean to update the enabled attributes * @return the number of deleted darts. */ template < unsigned int i > size_t remove_cell(Dart_handle adart, bool update_attributes = true) { return CGAL::Remove_cell_functor:: run(*this,adart,update_attributes); } /** Test if an i-cell can be contracted. * An i-cell can be contracted if i==1 * or if there are at most two (i-1)-cell incident to it. * @param adart a dart of the i-cell. * @return true iff the i-cell can be contracted. */ template < unsigned int i > bool is_contractible(Dart_const_handle adart) const { return CGAL::Is_contractible_functor::run(*this,adart); } /** Contract an i-cell, 1<=i<=dimension. * @param adart a dart of the i-cell to remove. * @return the number of deleted darts. */ template < unsigned int i > size_t contract_cell(Dart_handle adart, bool update_attributes = true) { return CGAL::Contract_cell_functor:: run(*this,adart, update_attributes); } /** Insert a vertex in a given edge. * @param adart a dart of the edge (!=nullptr && !=null_dart_handle). * @param update_attributes a boolean to update the enabled attributes * @return a dart of the new vertex. */ Dart_handle insert_cell_0_in_cell_1( Dart_handle adart, typename Attribute_handle<0>::type ah=null_handle, bool update_attributes=true ) { Dart_handle d1, d2; size_type amark=get_new_mark(); // 1) We store all the darts of the edge. std::deque vect; size_type m=get_new_mark(); { for ( typename Dart_of_cell_basic_range<1>::iterator it=darts_of_cell_basic<1>(adart, m).begin(); it != darts_of_cell_basic<1>(adart, m).end(); ++it ) vect.push_back(it); } // 2) For each dart of the cell, we modify link of neighbors. typename std::deque::iterator it = vect.begin(); for (; it != vect.end(); ++it) { d1 = create_dart(); if (!this->template is_free<1>(*it)) { basic_link_beta_1(d1, this->template beta<1>(*it)); } for ( unsigned int dim=2; dim<=dimension; ++dim ) { if (!is_free(*it, dim) && is_marked(beta(*it, dim), amark)) { basic_link_beta_for_involution(beta(*it, dim), d1, dim); basic_link_beta_for_involution(*it, beta(*it, dim, 1), dim); } } basic_link_beta_1(*it, d1); if (are_attributes_automatically_managed() && update_attributes) { // We copy all the attributes except for dim=0 Helper::template Foreach_enabled_attributes_except , 0>:: run(*this,*it,d1); } if (ah != null_handle) { // We initialise the 0-atttrib to ah internal::Set_i_attribute_of_dart_functor:: run(*this, d1, ah); } mark(*it, amark); } for (it = vect.begin(); it != vect.end(); ++it) { unmark(*it, m); unmark(*it, amark); } CGAL_assertion(is_whole_map_unmarked(m)); CGAL_assertion(is_whole_map_unmarked(amark)); free_mark(m); free_mark(amark); if (are_attributes_automatically_managed() && update_attributes) { internal::Degroup_attribute_functor_run:: run(*this, adart, this->template beta<1>(adart)); } #ifdef CGAL_CMAP_TEST_VALID_INSERTIONS CGAL_assertion( is_valid() ); #endif return this->template beta<1>(adart); } /** Insert a vertex in the given 2-cell which is split in triangles, * once for each inital edge of the facet. * @param adart a dart of the facet to triangulate. * @param update_attributes a boolean to update the enabled attributes * (deprecated, now we use are_attributes_automatically_managed()) * @return A dart incident to the new vertex. */ Dart_handle insert_cell_0_in_cell_2( Dart_handle adart, typename Attribute_handle<0>::type ah=null_handle, bool update_attributes=true ) { CGAL_assertion(adart!=null_dart_handle); Dart_handle first=adart, prev=null_handle, cur=null_handle, next=null_handle, n1=null_handle, n2=null_handle, nn1=null_handle, nn2=null_handle; // If the facet is open, we search the dart 0-free while ( !this->template is_free<0>(first) && this->template beta<0>(first)!=adart ) first = this->template beta<0>(first); // Mark used to mark darts already treated. size_type treated = get_new_mark(); // Stack of marked darts std::deque tounmark; // Now we run through the facet cur = first; do { next = this->template beta<1>(cur); mark(cur, treated); tounmark.push_back(cur); if (!this->template is_free<0>(cur)) { n1=create_dart(); link_beta_0(cur, n1); } else n1 = null_handle; if (!this->template is_free<1>(cur)) { n2 = create_dart(); link_beta_1(cur, n2); } else n2 = null_handle; if ( n1!=null_handle ) { if ( n2!=null_handle ) basic_link_beta_0(n1, n2); if ( prev!=null_handle ) this->template basic_link_beta_for_involution<2>(prev, n1); if (are_attributes_automatically_managed() && update_attributes) { internal::Set_i_attribute_of_dart_functor:: run(*this, n1, ah); } } for (unsigned int dim=3; dim<=dimension; ++dim) { if ( !is_free(adart, dim) ) { if ( !is_marked(beta(cur, dim), treated) ) { if (n1!=null_handle) { nn1=create_dart(); link_beta_1(beta(cur, dim), nn1); basic_link_beta_for_involution(n1, nn1, dim); } else nn1=null_handle; if (n2!=null_handle) { nn2=create_dart(); link_beta_0(beta(cur, dim), nn2); basic_link_beta_for_involution(n2, nn2, dim); if (are_attributes_automatically_managed() && update_attributes) { internal::Set_i_attribute_of_dart_functor:: run(*this, nn2, ah); } } else nn2=null_handle; if (nn1 != null_handle && nn2 != null_handle) basic_link_beta_1(nn1, nn2); if (nn1 != null_handle && prev != null_handle) this->template basic_link_beta_for_involution<2>(nn1, beta(prev, dim)); mark(beta(cur, dim), treated); } else { if ( n1!=null_handle ) basic_link_beta_for_involution(n1, beta(cur, dim, 1), dim); if ( n2!=null_handle ) basic_link_beta_for_involution(n2, beta(cur, dim, 0), dim); } } } prev = n2; cur = next; } while(cur!=first && cur!=null_dart_handle); if (n2 != null_handle) { this->template basic_link_beta_for_involution<2> (this->template beta<0>(first), n2); for (unsigned int dim=3; dim<=dimension; ++dim) { if ( !is_free(adart, dim) ) { this->template basic_link_beta_for_involution<2>(beta(first, 0, dim), beta(n2, dim)); } } } // Now we unmark all marked darts, and we degroup the new faces with the // initial one (if 2-attributes are non void). for ( typename std::deque::iterator itd=tounmark.begin(); itd!=tounmark.end(); ++itd ) { unmark(*itd, treated); for (unsigned int dim=3; dim<=dimension; ++dim) { if ( !is_free(*itd, dim) ) unmark(beta(*itd, dim), treated); } if ( *itd!=adart ) if (are_attributes_automatically_managed() && update_attributes) { internal::Degroup_attribute_functor_run:: run(*this, adart, *itd); } } CGAL_assertion(is_whole_map_unmarked(treated)); free_mark(treated); #ifdef CGAL_CMAP_TEST_VALID_INSERTIONS CGAL_assertion( is_valid() ); #endif return n1; } /** Insert a dangling edge in a 2-cell between given by a dart. * @param adart1 a first dart of the facet (!=nullptr && !=null_dart_handle). * @param update_attributes a boolean to update the enabled attributes * @return a dart of the new edge, not incident to the vertex of adart1. */ Dart_handle insert_dangling_cell_1_in_cell_2( Dart_handle adart1, typename Attribute_handle<0>:: type ah=null_handle, bool update_attributes=true ) { size_type mark1 = get_new_mark(); std::deque to_unmark; { for ( CMap_dart_iterator_basic_of_cell it(*this,adart1,mark1); it.cont(); ++it ) { to_unmark.push_back(it); mark(it,mark1); } } Dart_handle d1 = null_handle; Dart_handle d2 = null_handle; unsigned int s1 = 0; size_type treated=get_new_mark(); CMap_dart_iterator_basic_of_involution it1(*this, adart1, treated); for ( ; it1.cont(); ++it1) { d1 = create_dart(); d2 = create_dart(); if ( is_marked(it1, mark1) ) s1 = 0; else s1 = 1; if ( !is_free(it1, s1) ) { if ( s1==0 ) link_beta_1(beta<0>(it1), d2); else link_beta_0(beta<1>(it1), d2); } if (s1==0) { link_beta_0(it1, d1); link_beta_0(d1, d2); } else { link_beta_1(it1, d1); link_beta_1(d1, d2); } basic_link_beta_for_involution<2>(d1, d2); for ( unsigned int dim=3; dim<=dimension; ++dim) { if ( !is_free(it1, dim) && is_marked(beta(it1, dim), treated) ) { basic_link_beta_for_involution (beta(it1, dim, CGAL_BETAINV(s1)), d1, dim); basic_link_beta_for_involution (beta(it1, dim, CGAL_BETAINV(s1), 2), d2, dim); } } if (are_attributes_automatically_managed() && update_attributes && ah!=nullptr) { internal::Set_i_attribute_of_dart_functor::run(*this, d1, ah); } mark(it1, treated); } negate_mark(treated); for ( it1.rewind(); it1.cont(); ++it1 ) { mark(it1, treated); } CGAL_assertion( is_whole_map_marked(treated) ); free_mark(treated); for ( typename std::deque::iterator it=to_unmark.begin(); it!=to_unmark.end(); ++it) { unmark(*it, mark1); } CGAL_assertion( is_whole_map_unmarked(mark1) ); free_mark(mark1); #ifdef CGAL_CMAP_TEST_VALID_INSERTIONS CGAL_assertion( is_valid() ); #endif return this->template beta<0>(adart1); } /** Test if an edge can be inserted onto a 2-cell between two given darts. * @param adart1 a first dart. * @param adart2 a second dart. * @return true iff an edge can be inserted between adart1 and adart2. */ bool is_insertable_cell_1_in_cell_2(Dart_const_handle adart1, Dart_const_handle adart2) const { if ( adart1==adart2 ) return false; for ( CMap_dart_const_iterator_of_orbit it(*this,adart1); it.cont(); ++it ) { if ( it==adart2 ) return true; } return false; } /** Insert an edge in a 2-cell between two given darts. * @param adart1 a first dart of the facet (!=nullptr && !=null_dart_handle). * @param adart2 a second dart of the facet. If nullptr insert a dangling edge. * @param update_attributes a boolean to update the enabled attributes * @return a dart of the new edge, and not incident to the * same vertex than adart1. */ Dart_handle insert_cell_1_in_cell_2(Dart_handle adart1, Dart_handle adart2, bool update_attributes=true) { if ( adart2==null_handle ) return insert_dangling_cell_1_in_cell_2(adart1, null_handle, update_attributes); CGAL_assertion(is_insertable_cell_1_in_cell_2(adart1, adart2)); size_type m1=get_new_mark(); CMap_dart_iterator_basic_of_involution it1(*this, adart1, m1); size_type m2=get_new_mark(); CMap_dart_iterator_basic_of_involution it2(*this, adart2, m2); size_type mark1=get_new_mark(); std::deque to_unmark; { for ( CMap_dart_iterator_basic_of_cell it(*this,adart1,mark1); it.cont(); ++it ) { to_unmark.push_back(it); mark(it, mark1); } } Dart_handle d1=null_handle; Dart_handle d2=null_handle; unsigned int s1=0; size_type treated=get_new_mark(); for ( ; it1.cont(); ++it1, ++it2) { CGAL_assertion ( it2.cont() ); d1 = create_dart(); d2 = create_dart(); if ( is_marked(it1, mark1) ) s1 = 0; else s1 = 1; if ( !is_free(it1, s1) ) { if ( s1==0 ) link_beta_1(this->template beta<0>(it1), d2); else link_beta_0(this->template beta<1>(it1), d2); } if ( !is_free(it2, s1) ) { if ( s1==0 ) link_beta_1(this->template beta<0>(it2), d1); else link_beta_0(this->template beta<1>(it2), d1); } if ( s1==0 ) { link_beta_0(it1, d1); link_beta_0(it2, d2); } else { link_beta_1(it1, d1); link_beta_1(it2, d2); } this->template basic_link_beta_for_involution<2>(d2, d1); for ( unsigned int dim=3; dim<=dimension; ++dim) { if ( !is_free(it1, dim) && is_marked(beta(it1, dim), treated) ) { basic_link_beta_for_involution (beta(it1, dim, CGAL_BETAINV(s1)), d1, dim); basic_link_beta_for_involution (beta(it1, dim, CGAL_BETAINV(s1), 2), d2, dim); } } mark(it1,treated); } if (are_attributes_automatically_managed() && update_attributes) { internal::Degroup_attribute_functor_run::run(*this, d1, d2); } negate_mark(m1); negate_mark(m2); it1.rewind(); it2.rewind(); for ( ; it1.cont(); ++it1, ++it2) { mark(it1,m1); unmark(it1,treated); mark(it2,m2); } negate_mark(m1); negate_mark(m2); CGAL_assertion( is_whole_map_unmarked(m1) ); CGAL_assertion( is_whole_map_unmarked(m2) ); CGAL_assertion( is_whole_map_unmarked(treated) ); free_mark(m1); free_mark(m2); free_mark(treated); typename std::deque::iterator it = to_unmark.begin(); for (; it != to_unmark.end(); ++it) { unmark(*it, mark1); } CGAL_assertion( is_whole_map_unmarked(mark1) ); free_mark(mark1); #ifdef CGAL_CMAP_TEST_VALID_INSERTIONS CGAL_assertion( is_valid() ); #endif return this->template beta<0>(adart1); } /** Test if a 2-cell can be inserted onto a given 3-cell along * a path of edges. * @param afirst iterator on the beginning of the path. * @param alast iterator on the end of the path. * @return true iff a 2-cell can be inserted along the path. */ template bool is_insertable_cell_2_in_cell_3(InputIterator afirst, InputIterator alast) const { CGAL_assertion( dimension>= 3 ); // The path must have at least one dart. if (afirst==alast) return false; Dart_const_handle prec = null_handle; Dart_const_handle od = null_handle; for (InputIterator it(afirst); it!=alast; ++it) { // The path must contain only non empty darts. if (*it == null_handle || *it==null_dart_handle) return false; // Two consecutive darts of the path must belong to two edges // incident to the same vertex of the same volume. if (prec != null_handle) { od = other_extremity(prec); if ( od==null_handle ) return false; // of and *it must belong to the same vertex of the same volume if ( !belong_to_same_cell<0, 2>(od, *it) ) return false; } prec = *it; } // The path must be closed. od = other_extremity(prec); if ( od==null_handle ) return false; if (!belong_to_same_cell<0, 2>(od, *afirst)) return false; return true; } /** Insert a 2-cell in a given 3-cell along a path of darts. * @param afirst iterator on the beginning of the path. * @param alast iterator on the end of the path. * @param update_attributes a boolean to update the enabled attributes * @return a dart of the new 2-cell. */ template Dart_handle insert_cell_2_in_cell_3(InputIterator afirst, InputIterator alast, bool update_attributes=true) { CGAL_assertion(is_insertable_cell_2_in_cell_3(afirst,alast)); Dart_handle prec = null_handle, d = null_handle, dd = null_handle, first = null_handle, it0=null_handle; bool withBeta3 = false; { for (InputIterator it(afirst); !withBeta3 && it!=alast; ++it) { if (!this->template is_free<2>(*it)) withBeta3 = true; } } { for (InputIterator it(afirst); it!=alast; ++it) { d = create_dart(); if (withBeta3) { dd = create_dart(); if ( !this->template is_free<2>((*it)) ) basic_link_beta_for_involution<2>(this->template beta<2>(*it), dd); this->template basic_link_beta_for_involution<3>(d, dd); } this->template basic_link_beta_for_involution<2>(*it, d); if (prec != null_handle) { basic_link_beta_0(prec, d); if (withBeta3) basic_link_beta_1(this->template beta<3>(prec), dd); } else first = d; Helper::template Foreach_enabled_attributes_except , 2>:: run(*this,d,*it); if (withBeta3) { Helper::template Foreach_enabled_attributes_except , 2>:: run(*this,dd,d); } prec = d; } } basic_link_beta_0(prec, first); if ( withBeta3 ) { basic_link_beta_1(this->template beta<3>(prec), this->template beta<3>(first)); } // Make copies of the new facet for dimension >=4 assert(!is_free(first, 2)); for ( unsigned int dim=4; dim<=dimension; ++dim ) { if ( !is_free(beta(first, 2), dim) ) { Dart_handle first2 = null_handle; prec = null_handle; for ( CMap_dart_iterator_basic_of_orbit it(*this, first); it.cont(); ++it ) { d = create_dart(); basic_link_beta_for_involution(it, d, dim); if (withBeta3) { dd = create_dart(); basic_link_beta_for_involution(this->template beta<3>(it), dd, dim); this->template basic_link_beta_for_involution<3>(d, dd); if (!this->template is_free<2>(this->template beta<3>(it))) basic_link_beta_for_involution<2>(beta(it, 3, 2, dim), dd); } assert(!is_free(it, 2)); this->template basic_link_beta_for_involution<2>(beta(it, 2, dim), d); if ( prec!=null_handle ) { basic_link_beta_0(prec, d); if (withBeta3) { basic_link_beta_1(this->template beta<3>(prec), dd); } } else first2 = d; it0=beta(it, 2, dim); // Required because // Group_attribute_functor_of_dart takes references in parameter Helper::template Foreach_enabled_attributes_except , 2>:: run(*this,d,it0); if (withBeta3) Helper::template Foreach_enabled_attributes_except , 2>:: run(*this,dd,d); prec = d; } basic_link_beta_0( prec, first2 ); if ( withBeta3 ) { basic_link_beta_1( this->template beta<3>(prec), this->template beta<3>(first2) ); } } } // Degroup the attributes if ( withBeta3 ) { // Here we cannot use Degroup_attribute_functor_run as new darts do not // have their 3-attribute if (are_attributes_automatically_managed() && update_attributes) { CGAL::internal::Degroup_attribute_functor_run:: run(*this, first, this->template beta<3>(first)); } } #ifdef CGAL_CMAP_TEST_VALID_INSERTIONS CGAL_assertion( is_valid() ); #endif return first; } protected: /// Number of times each mark is reserved. 0 if the mark is free. mutable size_type mnb_times_reserved_marks[NB_MARKS]; /// Mask marks to know the value of unmark dart, for each index i. mutable std::bitset mmask_marks; /// Number of used marks. mutable size_type mnb_used_marks; /// Index of each mark, in mfree_marks_stack or in mfree_marks_stack. mutable size_type mindex_marks[NB_MARKS]; /// "Stack" of free marks. mutable size_type mfree_marks_stack[NB_MARKS]; /// "Stack" of used marks. mutable size_type mused_marks_stack[NB_MARKS]; /// Number of marked darts for each used marks. mutable size_type mnb_marked_darts[NB_MARKS]; /// Automatic management of the attributes: /// true means attributes are always maintained updated during operations. bool automatic_attributes_management; /// Tuple of unary and binary functors (for all non void attributes). typename Helper::Split_functors m_onsplit_functors; typename Helper::Merge_functors m_onmerge_functors; }; template < unsigned int d_, class Items_, class Alloc_, class Storage_ > class Combinatorial_map : public Combinatorial_map_base, Items_, Alloc_, Storage_ > { public: typedef Combinatorial_map Self; typedef Combinatorial_map_base Base; typedef typename Base::Dart_handle Dart_handle; typedef typename Base::Dart_const_handle Dart_const_handle; typedef typename Base::Alloc Alloc; typedef typename Base::Exception_no_more_available_mark Exception_no_more_available_mark; Combinatorial_map() : Base() {} Combinatorial_map(const Self & amap) : Base(amap) {} template Combinatorial_map(const Combinatorial_map_base& amap) : Base(amap) {} template Combinatorial_map(const Combinatorial_map_base& amap, const Converters& converters) : Base(amap, converters) {} template Combinatorial_map(const Combinatorial_map_base& amap, const Converters& converters, const DartInfoConverter& dartinfoconverter) : Base(amap, converters, dartinfoconverter) {} template Combinatorial_map(const Combinatorial_map_base& amap, const Converters& converters, const DartInfoConverter& dartinfoconverter, const PointConverter& pointconverter) : Base(amap, converters, dartinfoconverter, pointconverter) {} }; } // namespace CGAL #if (BOOST_GCC >= 40900) _Pragma("GCC diagnostic pop") #endif #include #endif // CGAL_COMBINATORIAL_MAP_H // // EOF //