diff options
Diffstat (limited to 'src/Skeleton_blocker/include/gudhi/Skeleton_blocker_complex.h')
-rw-r--r-- | src/Skeleton_blocker/include/gudhi/Skeleton_blocker_complex.h | 2650 |
1 files changed, 1279 insertions, 1371 deletions
diff --git a/src/Skeleton_blocker/include/gudhi/Skeleton_blocker_complex.h b/src/Skeleton_blocker/include/gudhi/Skeleton_blocker_complex.h index 15425384..7c0bc652 100644 --- a/src/Skeleton_blocker/include/gudhi/Skeleton_blocker_complex.h +++ b/src/Skeleton_blocker/include/gudhi/Skeleton_blocker_complex.h @@ -20,23 +20,25 @@ * along with this program. If not, see <http://www.gnu.org/licenses/>. */ -#ifndef GUDHI_SKELETON_BLOCKER_COMPLEX_H -#define GUDHI_SKELETON_BLOCKER_COMPLEX_H +#ifndef SRC_SKELETON_BLOCKER_INCLUDE_GUDHI_SKELETON_BLOCKER_COMPLEX_H_ +#define SRC_SKELETON_BLOCKER_INCLUDE_GUDHI_SKELETON_BLOCKER_COMPLEX_H_ +#include <boost/graph/adjacency_list.hpp> +#include <boost/graph/connected_components.hpp> +#include <boost/iterator/transform_iterator.hpp> +#include <boost/range/adaptor/map.hpp> +#include <iostream> +#include <fstream> +#include <sstream> +#include <memory> #include <map> #include <list> #include <set> #include <vector> -#include <iostream> #include <string> -#include <fstream> -#include <sstream> -#include <memory> -#include <boost/graph/adjacency_list.hpp> -#include <boost/graph/connected_components.hpp> -#include <boost/iterator/transform_iterator.hpp> -#include <boost/range/adaptor/map.hpp> +#include <algorithm> +#include <utility> #include "gudhi/Skeleton_blocker/iterators/Skeleton_blockers_iterators.h" #include "gudhi/Skeleton_blocker_link_complex.h" @@ -48,1385 +50,1291 @@ #include "gudhi/Skeleton_blocker/internal/Top_faces.h" #include "gudhi/Utils.h" - namespace Gudhi { namespace skbl { - /** *@class Skeleton_blocker_complex *@brief Abstract Simplicial Complex represented with a skeleton/blockers pair. *@ingroup skbl */ template<class SkeletonBlockerDS> -class Skeleton_blocker_complex -{ - template<class ComplexType> friend class Complex_vertex_iterator; - template<class ComplexType> friend class Complex_neighbors_vertices_iterator; - template<class ComplexType> friend class Complex_edge_iterator; - template<class ComplexType> friend class Complex_edge_around_vertex_iterator; - - - template<class ComplexType> friend class Skeleton_blocker_link_complex; - template<class ComplexType> friend class Skeleton_blocker_link_superior; - template<class ComplexType> friend class Skeleton_blocker_sub_complex; - -public: - - /** - * @brief The type of stored vertex node, specified by the template SkeletonBlockerDS - */ - typedef typename SkeletonBlockerDS::Graph_vertex Graph_vertex; - - /** - * @brief The type of stored edge node, specified by the template SkeletonBlockerDS - */ - typedef typename SkeletonBlockerDS::Graph_edge Graph_edge; - - typedef typename SkeletonBlockerDS::Root_vertex_handle Root_vertex_handle; - - /** - * @brief The type of an handle to a vertex of the complex. - */ - typedef typename SkeletonBlockerDS::Vertex_handle Vertex_handle; - typedef typename Root_vertex_handle::boost_vertex_handle boost_vertex_handle; - - - /** - * @brief A ordered set of integers that represents a simplex. - */ - typedef Skeleton_blocker_simplex<Vertex_handle> Simplex_handle; - typedef Skeleton_blocker_simplex<Root_vertex_handle> Root_simplex_handle; - - - /** - * @brief Handle to a blocker of the complex. - */ - typedef Simplex_handle* Blocker_handle; - - - - typedef typename Root_simplex_handle::Simplex_vertex_const_iterator Root_simplex_iterator; - typedef typename Simplex_handle::Simplex_vertex_const_iterator Simplex_handle_iterator; - - -protected: - - typedef typename boost::adjacency_list - < boost::setS, //edges - boost::vecS, // vertices - boost::undirectedS, - Graph_vertex, - Graph_edge - > Graph; - //todo/remark : edges are not sorted, it heavily penalizes computation for SuperiorLink - // (eg Link with greater vertices) - // that burdens simplex iteration / complex initialization via list of simplices. - // to avoid that, one should modify the graph by storing two lists of adjacency for every - // vertex, the one with superior and the one with lower vertices, that way there is - // no more extra cost for computation of SuperiorLink - typedef typename boost::graph_traits<Graph>::vertex_iterator boost_vertex_iterator; - typedef typename boost::graph_traits<Graph>::edge_iterator boost_edge_iterator; - -protected: - typedef typename boost::graph_traits<Graph>::adjacency_iterator boost_adjacency_iterator; - -public: - /** - * @brief Handle to an edge of the complex. - */ - typedef typename boost::graph_traits<Graph>::edge_descriptor Edge_handle; - - -protected: - typedef std::multimap<Vertex_handle,Simplex_handle *> BlockerMap; - typedef typename std::multimap<Vertex_handle,Simplex_handle *>::value_type BlockerPair; - typedef typename std::multimap<Vertex_handle,Simplex_handle *>::iterator BlockerMapIterator; - typedef typename std::multimap<Vertex_handle,Simplex_handle *>::const_iterator BlockerMapConstIterator; - -protected: - int num_vertices_; - int num_blockers_; - - typedef Skeleton_blocker_complex_visitor<Vertex_handle> Visitor; - // typedef Visitor* Visitor_ptr; - Visitor* visitor; - - /** - * @details If 'x' is a Vertex_handle of a vertex in the complex then degree[x] = d is its degree. - * - * This quantity is updated when adding/removing edge. - * - * This is useful because the operation - * list.size() is done in linear time. - */ - std::vector<boost_vertex_handle> degree_; - Graph skeleton; /** 1-skeleton of the simplicial complex. */ - - - //todo remove!!! - - /** Each vertex can access to the blockers passing through it. */ - BlockerMap blocker_map_; - - - - -public: - - - - - ///////////////////////////////////////////////////////////////////////////// - /** @name Constructors, Destructors - */ - //@{ - /** - *@brief constructs a simplicial complex with a given number of vertices and a visitor. - */ - Skeleton_blocker_complex(int num_vertices_ = 0,Visitor* visitor_=NULL):visitor(visitor_){ - clear(); - for (int i=0; i<num_vertices_; ++i){ - add_vertex(); - } - } - -private: - - /** - * this nested class is used for the next constructor that takes as an input a list of simplices. - * It stores a vector where the ith cell contains a set of i-simplices - * - */ - class Simplices_sets_from_list{ - private: - typedef std::set< Simplex_handle> Container_simplices; - typedef typename Container_simplices::iterator Simplices_iterator; - int dimension_; - std::vector<Container_simplices > simplices_; - - public: - Simplices_sets_from_list(std::list<Simplex_handle>& simplices): - dimension_(-1){ - assert(!simplices.empty()); - - for(auto simplex = simplices.begin() ; simplex != simplices.end(); ++simplex ){ - dimension_ = std::max(dimension_,(int)simplex->dimension()); - } - simplices_ = std::vector<Container_simplices >(dimension_+1); - - // compute k-simplices - for(auto simplex = simplices.begin() ; simplex != simplices.end(); ++simplex ){ - simplices_[simplex->dimension()].insert(*simplex); - } - } - - Simplices_iterator begin(int k){ - assert(0<= k && k<= dimension_); - return simplices_[k].begin(); - } - - Simplices_iterator end(int k){ - assert(0<= k && k<= dimension_); - return simplices_[k].end(); - } - - - Container_simplices& simplices(int k){ - return simplices_[k]; - } - - int dimension(){ - return dimension_; - } - - bool contains(const Simplex_handle& simplex) const{ - if(simplex.dimension()>dimension_) - return false; - else - return simplices_[simplex.dimension()].find(simplex)!= simplices_[simplex.dimension()].end(); - } - - void print(){ - for(int i = 0; i < dimension_; ++i){ - std::cout << i<<"-simplices"<<std::endl; - auto l = simplices_[i]; - for(auto s : l){ - std::cout << s<<std::endl; - } - } - } - }; - - - void compute_next_expand( - Simplices_sets_from_list& simplices, - int dim, - std::list<Simplex_handle>& next_expand) - { - next_expand.clear(); - - // high_resolution_clock::time_point tbeginfor = high_resolution_clock::now(); - // auto durationlooplink = std::chrono::duration_cast<std::chrono::microseconds>( tbeginfor - tbeginfor ).count(); - - for(auto sigma = simplices.begin(dim); sigma != simplices.end(dim); ++sigma){ - // high_resolution_clock::time_point tbeg = high_resolution_clock::now(); - Simplex_handle t(*sigma); - Skeleton_blocker_link_superior<Skeleton_blocker_complex> link(*this,t); - // xxx all time here, most likely because accessing superior edges needs passing through lower one - // currently - - // durationlooplink += std::chrono::duration_cast<std::chrono::microseconds>( high_resolution_clock::now() - tbeg ).count(); - - for(auto v : link.vertex_range()){ - Vertex_handle v_in_complex(*this->get_address( link.get_id(v)) ); - t.add_vertex(v_in_complex); - next_expand.push_back(t); - t.remove_vertex(v_in_complex); - } - } - // high_resolution_clock::time_point t2 = high_resolution_clock::now(); - // auto durationlooptotal = std::chrono::duration_cast<std::chrono::microseconds>( t2 - tbeginfor ).count(); - // DBGVALUE(durationlooptotal); - // DBGVALUE(durationlooplink); - } - - - -public: - /** - * @brief Constructor with a list of simplices. - * @details The list of simplices must be the list - * of simplices of a simplicial complex. - */ - Skeleton_blocker_complex(std::list<Simplex_handle>& simplices,Visitor* visitor_=NULL): - num_vertices_(0),num_blockers_(0), - visitor(visitor_){ - Simplices_sets_from_list set_simplices(simplices); - - int dim = set_simplices.dimension(); - - - // add 1-skeleton to the complex - for(auto v_it = set_simplices.begin(0); v_it != set_simplices.end(0); ++v_it) - add_vertex(); - - for(auto e_it = set_simplices.begin(1); e_it != set_simplices.end(1); ++e_it){ - Vertex_handle a = e_it->first_vertex(); - Vertex_handle b = e_it->last_vertex(); - assert(contains_vertex(a) && contains_vertex(b)); - add_edge(a,b); - } - - // then add blockers - for(int current_dim = 1 ; current_dim <=dim ; ++current_dim){ - std::list<Simplex_handle> expansion_simplices; - compute_next_expand(set_simplices,current_dim,expansion_simplices); - - for(const auto &simplex : expansion_simplices) { - if(!set_simplices.contains(simplex)){ - add_blocker(simplex); - } - } - } - } - - - // We cannot use the default copy constructor since we need - // to make a copy of each of the blockers - Skeleton_blocker_complex(const Skeleton_blocker_complex& copy){ - visitor = NULL; - degree_ = copy.degree_; - skeleton = Graph(copy.skeleton); - num_vertices_ = copy.num_vertices_; - - num_blockers_ = 0; - // we copy the blockers - for (auto blocker : copy.const_blocker_range()){ - add_blocker(*blocker); - } - } - -/** -*/ - Skeleton_blocker_complex& operator=(const Skeleton_blocker_complex& copy){ - clear(); - visitor = NULL; - degree_ = copy.degree_; - skeleton = Graph(copy.skeleton); - num_vertices_ = copy.num_vertices_; - - num_blockers_ = 0; - // we copy the blockers - for (auto blocker : copy.const_blocker_range()) - add_blocker(*blocker); - return *this; - } - - - /** - * The destructor delete all blockers allocated. - */ - virtual ~Skeleton_blocker_complex(){ - clear(); - } - - /** - * @details Clears the simplicial complex. After a call to this function, - * blockers are destroyed. The 1-skeleton and the set of blockers - * are both empty. - */ - virtual void clear(){ - // xxx for now the responsabilty of freeing the visitor is for - // the user - visitor = NULL; - - degree_.clear(); - num_vertices_ =0; - - remove_blockers(); - - skeleton.clear(); - } - -/** -*@brief allows to change the visitor. -*/ - void set_visitor(Visitor* other_visitor){ - visitor = other_visitor; - } - - //@} - - - - - ///////////////////////////////////////////////////////////////////////////// - /** @name Vertices operations - */ - //@{ - -public: - - /** - * @brief Return a local Vertex_handle of a vertex given a global one. - * @remark Assume that the vertex is present in the complex. - */ - Vertex_handle operator[](Root_vertex_handle global) const{ - auto local(get_address(global)); - assert(local); - return *local; - } - - /** - * @brief Return the vertex node associated to local Vertex_handle. - * @remark Assume that the vertex is present in the complex. - */ - Graph_vertex& operator[](Vertex_handle address){ - assert(0<=address.vertex && address.vertex< boost::num_vertices(skeleton)); - return skeleton[address.vertex]; - } - - /** - * @brief Return the vertex node associated to local Vertex_handle. - * @remark Assume that the vertex is present in the complex. - */ - const Graph_vertex& operator[](Vertex_handle address) const{ - assert(0<=address.vertex && address.vertex< boost::num_vertices(skeleton)); - return skeleton[address.vertex]; - } - - /** - * @brief Adds a vertex to the simplicial complex and returns its Vertex_handle. - */ - Vertex_handle add_vertex(){ - Vertex_handle address(boost::add_vertex(skeleton)); - num_vertices_++; - (*this)[address].activate(); - // safe since we now that we are in the root complex and the field 'address' and 'id' - // are identical for every vertices - (*this)[address].set_id(Root_vertex_handle(address.vertex)); - degree_.push_back(0); - if (visitor) visitor->on_add_vertex(address); - return address; - } - - - /** - * @brief Remove a vertex from the simplicial complex - * @remark It just deactivates the vertex with a boolean flag but does not - * remove it from vertices from complexity issues. - */ - void remove_vertex(Vertex_handle address){ - assert(contains_vertex(address)); - // We remove b - boost::clear_vertex(address.vertex,skeleton); - (*this)[address].deactivate(); - num_vertices_--; - degree_[address.vertex]=-1; - if (visitor) visitor->on_remove_vertex(address); - } - -/** -*/ - bool contains_vertex(Vertex_handle u) const{ - if (u.vertex<0 || u.vertex>=boost::num_vertices(skeleton)) return false; - return (*this)[u].is_active(); - } - -/** -*/ - bool contains_vertex(Root_vertex_handle u) const{ - boost::optional<Vertex_handle> address = get_address(u); - return address && (*this)[*address].is_active(); - } - - - /** - * @return true iff the simplicial complex contains all vertices - * of simplex sigma - */ - bool contains_vertices(const Simplex_handle & sigma) const{ - for (auto vertex : sigma) - if(!contains_vertex(vertex)) return false; - return true; - } - - /** - * @brief Given an Id return the address of the vertex having this Id in the complex. - * @remark For a simplicial complex, the address is the id but it may not be the case for a SubComplex. - */ - virtual boost::optional<Vertex_handle> get_address(Root_vertex_handle id) const{ - boost::optional<Vertex_handle> res; - if ( id.vertex< boost::num_vertices(skeleton) ) res = Vertex_handle(id.vertex);//xxx - return res; - } - - - - /** - * return the id of a vertex of adress local present in the graph - */ - Root_vertex_handle get_id(Vertex_handle local) const{ - assert(0<=local.vertex && local.vertex< boost::num_vertices(skeleton)); - return (*this)[local].get_id(); - } - - - /** - * @brief Convert an address of a vertex of a complex to the address in - * the current complex. - * @details - * If the current complex is a sub (or sup) complex of 'other', it converts - * the address of a vertex v expressed in 'other' to the address of the vertex - * v in the current one. - * @remark this methods uses Root_vertex_handle to identify the vertex and - * assumes the vertex is present in the current complex. - */ - Vertex_handle convert_handle_from_another_complex( - const Skeleton_blocker_complex& other,Vertex_handle vh_in_other) const{ - auto vh_in_current_complex = get_address(other.get_id(vh_in_other)); - assert(vh_in_current_complex); - return *vh_in_current_complex; - } - - /** - * @brief return the graph degree of a vertex. - */ - int degree(Vertex_handle local) const{ - assert(0<=local.vertex && local.vertex< boost::num_vertices(skeleton)); - return degree_[local.vertex]; - } - - //@} - - ///////////////////////////////////////////////////////////////////////////// - /** @name Edges operations - */ - //@{ - -public: - - /** - * @brief return an edge handle if the two vertices forms - * an edge in the complex - */ - boost::optional<Edge_handle> operator[](const std::pair<Vertex_handle,Vertex_handle>& ab) const{ - boost::optional<Edge_handle> res; - std::pair<Edge_handle,bool> edge_pair(boost::edge(ab.first.vertex,ab.second.vertex,skeleton)); - if (edge_pair.second) - res = edge_pair.first; - return res; - } - - /** - * @brief returns the stored node associated to an edge - */ - Graph_edge& operator[](Edge_handle edge_handle){ - return skeleton[edge_handle]; - } - - /** - * @brief returns the stored node associated to an edge - */ - const Graph_edge& operator[](Edge_handle edge_handle) const{ - return skeleton[edge_handle]; - } - - /** - * @brief returns the first vertex of an edge - * @details it assumes that the edge is present in the complex - */ - Vertex_handle first_vertex(Edge_handle edge_handle) const{ - return source(edge_handle,skeleton); - } - - /** - * @brief returns the first vertex of an edge - * @details it assumes that the edge is present in the complex - */ - Vertex_handle second_vertex(Edge_handle edge_handle) const{ - return target(edge_handle,skeleton); - } - - /** - * @brief returns the simplex made with the two vertices of the edge - * @details it assumes that the edge is present in the complex - - */ - Simplex_handle get_vertices(Edge_handle edge_handle) const{ - auto edge((*this)[edge_handle]); - return Simplex_handle((*this)[edge.first()],(*this)[edge.second()]); - } - - /** - * @brief Adds an edge between vertices a and b and all its cofaces. - */ - Edge_handle add_edge(Vertex_handle a, Vertex_handle b){ - assert(contains_vertex(a) && contains_vertex(b)); - assert(a!=b); - - auto edge_handle((*this)[std::make_pair(a,b)]); - // std::pair<Edge_handle,bool> pair_descr_bool = (*this)[std::make_pair(a,b)]; - // Edge_handle edge_descr; - // bool edge_present = pair_descr_bool.second; - if (!edge_handle) - { - edge_handle = boost::add_edge(a.vertex,b.vertex,skeleton).first; - (*this)[*edge_handle].setId(get_id(a),get_id(b)); - degree_[a.vertex]++; - degree_[b.vertex]++; - if (visitor) visitor->on_add_edge(a,b); - } - return *edge_handle; - } - - /** - * @brief Adds all edges and their cofaces of a simplex to the simplicial complex. - */ - void add_edges(const Simplex_handle & sigma){ - Simplex_handle_iterator i, j; - for (i = sigma.begin() ; i != sigma.end() ; ++i) - for (j = i, j++ ; j != sigma.end() ; ++j) - add_edge(*i,*j); - } - - /** - * @brief Removes an edge from the simplicial complex and all its cofaces. - * @details returns the former Edge_handle representing the edge - */ - virtual Edge_handle remove_edge(Vertex_handle a, Vertex_handle b){ - bool found; - Edge_handle edge; - tie(edge,found) = boost::edge(a.vertex,b.vertex,skeleton); - if (found) - { - if (visitor) visitor->on_remove_edge(a,b); - // if (heapCollapse.Contains(edge)) heapCollapse.Delete(edge); - boost::remove_edge(a.vertex,b.vertex,skeleton); - degree_[a.vertex]--; - degree_[b.vertex]--; - } - return edge; - } - - - /** - * @brief Removes edge and its cofaces from the simplicial complex. - */ - void remove_edge(Edge_handle edge){ - assert(contains_vertex(first_vertex(edge))); - assert(contains_vertex(second_vertex(edge))); - remove_edge(first_vertex(edge),second_vertex(edge)); - } - - - /** - * @brief The complex is reduced to its set of vertices. - * All the edges and blockers are removed. - */ - void keep_only_vertices(){ - remove_blockers(); - - for(auto u : vertex_range()){ - while (this->degree(u)> 0) - { - Vertex_handle v(*(adjacent_vertices(u.vertex, this->skeleton).first)); - this->remove_edge(u,v); - } - } - } - - - /** - * @return true iff the simplicial complex contains an edge between - * vertices a and b - */ - bool contains_edge(Vertex_handle a, Vertex_handle b) const{ - //if (a.vertex<0 || b.vertex <0) return false; - return boost::edge(a.vertex,b.vertex,skeleton).second; - } - - - /** - * @return true iff the simplicial complex contains all vertices - * and all edges of simplex sigma - */ - bool contains_edges(const Simplex_handle & sigma) const{ - for (auto i = sigma.begin() ; i != sigma.end() ; ++i){ - if(!contains_vertex(*i)) return false; - for (auto j=i; ++j != sigma.end() ; ){ - if (!contains_edge(*i,*j)) - return false; - } - } - return true; - } - //@} - - - - ///////////////////////////////////////////////////////////////////////////// - /** @name Blockers operations - */ - //@{ - - /** - * @brief Adds the simplex to the set of blockers and - * returns a Blocker_handle toward it if was not present before and 0 otherwise. - */ - Blocker_handle add_blocker(const Simplex_handle& blocker){ - assert(blocker.dimension()>1); - if (contains_blocker(blocker)) - { - //std::cerr << "ATTEMPT TO ADD A BLOCKER ALREADY THERE ---> BLOCKER IGNORED" << endl; - return 0; - } - else{ - if (visitor) visitor->on_add_blocker(blocker); - Blocker_handle blocker_pt = new Simplex_handle(blocker); - num_blockers_++; - auto vertex = blocker_pt->begin(); - while(vertex != blocker_pt->end()) - { - blocker_map_.insert(BlockerPair(*vertex,blocker_pt)); - ++vertex; - } - return blocker_pt; - } - } - -protected: - /** - * @brief Adds the simplex to the set of blockers - */ - void add_blocker(Blocker_handle blocker){ - if (contains_blocker(*blocker)) - { - //std::cerr << "ATTEMPT TO ADD A BLOCKER ALREADY THERE ---> BLOCKER IGNORED" << endl; - return; - } - else{ - if (visitor) visitor->on_add_blocker(*blocker); - num_blockers_++; - auto vertex = blocker->begin(); - while(vertex != blocker->end()) - { - blocker_map_.insert(BlockerPair(*vertex,blocker)); - ++vertex; - } - } - } - - -protected: - /** - * Removes sigma from the blocker map of vertex v - */ - void remove_blocker(const Blocker_handle sigma, Vertex_handle v){ - Complex_blocker_around_vertex_iterator blocker; - for (blocker = blocker_range(v).begin(); - blocker != blocker_range(v).end(); - ++blocker - ){ - if (*blocker == sigma) break; - } - if (*blocker != sigma){ - std::cerr << "bug ((*blocker).second == sigma) ie try to remove a blocker not present\n"; - assert(false); - } - else{ - blocker_map_.erase(blocker.current_position()); - } - } - -public: - /** - * @brief Removes the simplex from the set of blockers. - * @remark sigma has to belongs to the set of blockers - */ - void remove_blocker(const Blocker_handle sigma){ - for (auto vertex : *sigma){ - remove_blocker(sigma,vertex); - } - num_blockers_--; - } - - - - - /** - * @brief Remove all blockers, in other words, it expand the simplicial - * complex to the smallest flag complex that contains it. - */ - void remove_blockers(){ - // Desallocate the blockers - while (!blocker_map_.empty()){ - delete_blocker(blocker_map_.begin()->second); - } - num_blockers_ = 0; - blocker_map_.clear(); - } - -protected: - /** - * Removes the simplex sigma from the set of blockers. - * sigma has to belongs to the set of blockers - * - * @remark contrarily to delete_blockers does not call the destructor - */ - void remove_blocker(const Simplex_handle& sigma){ - assert(contains_blocker(sigma)); - for (auto vertex : sigma) - remove_blocker(sigma,vertex); - num_blockers_--; - } - - - - -public: - /** - * Removes the simplex s from the set of blockers - * and desallocate s. - */ - void delete_blocker(Blocker_handle sigma){ - if (visitor) visitor->on_delete_blocker(sigma); - remove_blocker(sigma); - delete sigma; - } - - - /** - * @return true iff s is a blocker of the simplicial complex - */ - bool contains_blocker(const Blocker_handle s) const{ - if (s->dimension()<2) - return false; - - Vertex_handle a = s->first_vertex(); - - for (auto blocker : const_blocker_range(a)){ - if ( s == *blocker ) - return true; - } - return false; - } - - /** - * @return true iff s is a blocker of the simplicial complex - */ - bool contains_blocker(const Simplex_handle & s) const{ - if (s.dimension()<2) - return false; - - Vertex_handle a = s.first_vertex(); - - for (auto blocker : const_blocker_range(a)){ - if ( s == *blocker ) - return true; - } - return false; - } - - -private: - /** - * @return true iff a blocker of the simplicial complex - * is a face of sigma. - */ - bool blocks(const Simplex_handle & sigma) const{ - - for(auto blocker : const_blocker_range()){ - if ( sigma.contains(*blocker) ) - return true; - } - return false; - } - - //@} - - - -protected: - /** - * @details Adds to simplex the neighbours of v e.g. \f$ n \leftarrow n \cup N(v) \f$. - * If keep_only_superior is true then only vertices that are greater than v are added. - */ - virtual void add_neighbours(Vertex_handle v, Simplex_handle & n,bool keep_only_superior=false) const{ - boost_adjacency_iterator ai, ai_end; - for (tie(ai, ai_end) = adjacent_vertices(v.vertex, skeleton); ai != ai_end; ++ai){ - if (keep_only_superior){ - if (*ai>v.vertex) - n.add_vertex(Vertex_handle(*ai)); - } - else - n.add_vertex(Vertex_handle(*ai)); - } - } - - /** - * @details Add to simplex res all vertices which are - * neighbours of alpha: ie \f$ res \leftarrow res \cup N(alpha) \f$. - * - * If 'keep_only_superior' is true then only vertices that are greater than alpha are added. - * todo revoir - * - */ - virtual void add_neighbours(const Simplex_handle &alpha, Simplex_handle & res,bool keep_only_superior=false) const{ - res.clear(); - auto alpha_vertex = alpha.begin(); - add_neighbours(*alpha_vertex,res,keep_only_superior); - for (alpha_vertex = (alpha.begin())++ ; alpha_vertex != alpha.end() ; ++alpha_vertex) - keep_neighbours(*alpha_vertex,res,keep_only_superior); - } - - /** - * @details Remove from simplex n all vertices which are - * not neighbours of v e.g. \f$ res \leftarrow res \cap N(v) \f$. - * If 'keep_only_superior' is true then only vertices that are greater than v are keeped. - */ - virtual void keep_neighbours(Vertex_handle v, Simplex_handle& res,bool keep_only_superior=false) const{ - Simplex_handle nv; - add_neighbours(v,nv,keep_only_superior); - res.intersection(nv); - } - - /** - * @details Remove from simplex all vertices which are - * neighbours of v eg \f$ res \leftarrow res \setminus N(v) \f$. - * If 'keep_only_superior' is true then only vertices that are greater than v are added. - */ - virtual void remove_neighbours(Vertex_handle v, Simplex_handle & res,bool keep_only_superior=false) const{ - Simplex_handle nv; - add_neighbours(v,nv,keep_only_superior); - res.difference(nv); - } - - -public: - - /** - * @brief Compute the local vertices of 's' in the current complex - * If one of them is not present in the complex then the return value is uninitialized. - * - * - */ - //xxx rename get_address et place un using dans sub_complex - boost::optional<Simplex_handle> get_simplex_address(const Root_simplex_handle& s) const - { - boost::optional<Simplex_handle> res; - - Simplex_handle s_address; - //Root_simplex_const_iterator i; - for (auto i = s.begin() ; i != s.end() ; ++i) - { - boost::optional<Vertex_handle> address = get_address(*i); - if (!address) - return res; - else - s_address.add_vertex(*address); - } - res = s_address; - return res; - } - - /** - * @brief returns a simplex with vertices which are the id of vertices of the - * argument. - */ - Root_simplex_handle get_id(const Simplex_handle& local_simplex) const{ - Root_simplex_handle global_simplex; - for (auto x = local_simplex.begin(); x!= local_simplex.end();++x){ - global_simplex.add_vertex(get_id(*x)); - - } - return global_simplex; - - } - - - /** - * @brief returns true iff the simplex s belongs to the simplicial - * complex. - */ - virtual bool contains(const Simplex_handle & s) const{ - if (s.dimension() == -1 ) return false; - else - if (s.dimension() ==0 ){ - return contains_vertex(s.first_vertex()); - } - else - return ( contains_edges(s) && !blocks(s) ); - } - - /* - * @brief returnrs true iff the complex is empty. - */ - bool empty() const{ - return num_vertices()==0; - } - - /* - * @brief returns the number of vertices in the complex. - */ - int num_vertices() const{ - //remark boost::num_vertices(skeleton) counts deactivated vertices - return num_vertices_; - } - - /* - * @brief returns the number of edges in the complex. - * @details currently in O(n) - */ - // todo cache the value - int num_edges() const{ - return boost::num_edges(skeleton); - } - - /* - * @brief returns the number of blockers in the complex. - */ - int num_blockers() const{ - return num_blockers_; - } - - /* - * @brief returns true iff the graph of the 1-skeleton of the complex is complete. - */ - bool complete() const{ - return (num_vertices()*(num_vertices()-1))/2 == num_edges(); - } - - /** - * @brief returns the number of connected components in the graph of the 1-skeleton. - */ - int num_connected_components() const{ - int num_vert_collapsed = skeleton.vertex_set().size() - num_vertices(); - std::vector<int> component(skeleton.vertex_set().size()); - return boost::connected_components(this->skeleton,&component[0]) - num_vert_collapsed; - } - - /** - * @brief %Test if the complex is a cone. - * @details Runs in O(n) where n is the number of vertices. - */ - bool is_cone() const{ - if (num_vertices()==0) return false; - if (num_vertices()==1) return true; - for(auto vi : vertex_range()){ - //xxx todo faire une methode bool is_in_blocker(Vertex_handle) - if (blocker_map_.find(vi)==blocker_map_.end()){ - // no blocker passes through the vertex, we just need to - // check if the current vertex is linked to all others vertices of the complex - if (degree_[vi.vertex] == num_vertices()-1) - return true; - } - } - return false; - } - - //@} - - - ///////////////////////////////////////////////////////////////////////////// - /** @name Vertex iterators - */ - //@{ - - typedef Complex_vertex_iterator<Skeleton_blocker_complex> CVI; //todo rename - - // /** - // * @brief Range over the vertices of the simplicial complex. - // * Methods .begin() and .end() return a Complex_vertex_iterator. - // */ - typedef boost::iterator_range < Complex_vertex_iterator<Skeleton_blocker_complex> > Complex_vertex_range; - - /** - * @brief Returns a Complex_vertex_range over all vertices of the complex - */ - Complex_vertex_range vertex_range() const - { - auto begin = Complex_vertex_iterator<Skeleton_blocker_complex>(this); - auto end = Complex_vertex_iterator<Skeleton_blocker_complex>(this,0); - return Complex_vertex_range(begin,end); - } - - typedef boost::iterator_range < Complex_neighbors_vertices_iterator<Skeleton_blocker_complex> > Complex_neighbors_vertices_range; - - /** - * @brief Returns a Complex_edge_range over all edges of the simplicial complex that passes trough v - */ - Complex_neighbors_vertices_range vertex_range(Vertex_handle v) const - { - auto begin = Complex_neighbors_vertices_iterator<Skeleton_blocker_complex>(this,v); - auto end = Complex_neighbors_vertices_iterator<Skeleton_blocker_complex>(this,v,0); - return Complex_neighbors_vertices_range(begin,end); - } - - //@} - - - /** @name Edge iterators - */ - //@{ - - - typedef boost::iterator_range <Complex_edge_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>> - Complex_edge_range; - - /** - * @brief Returns a Complex_edge_range over all edges of the simplicial complex - */ - Complex_edge_range edge_range() const - { - auto begin = Complex_edge_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>(this); - auto end = Complex_edge_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>(this,0); - return Complex_edge_range(begin,end); - } - - - - typedef boost::iterator_range <Complex_edge_around_vertex_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>> - Complex_edge_around_vertex_range; - /** - * @brief Returns a Complex_edge_range over all edges of the simplicial complex that passes - * through 'v' - */ - Complex_edge_around_vertex_range edge_range(Vertex_handle v) const - { - auto begin = Complex_edge_around_vertex_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>(this,v); - auto end = Complex_edge_around_vertex_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>(this,v,0); - return Complex_edge_around_vertex_range(begin,end); - } - - - - //@} - - - /** @name Triangles iterators - */ - //@{ -private: - typedef Skeleton_blocker_link_complex<Skeleton_blocker_complex<SkeletonBlockerDS> > Link; - typedef Skeleton_blocker_link_superior<Skeleton_blocker_complex<SkeletonBlockerDS> > Superior_link; -public: - typedef Triangle_around_vertex_iterator<Skeleton_blocker_complex,Superior_link> Superior_triangle_around_vertex_iterator; - - - typedef boost::iterator_range < Triangle_around_vertex_iterator<Skeleton_blocker_complex,Link> > Complex_triangle_around_vertex_range; - - /** - * @brief Range over triangles around a vertex of the simplicial complex. - * Methods .begin() and .end() return a Triangle_around_vertex_iterator. - * - */ - Complex_triangle_around_vertex_range triangle_range(Vertex_handle v) const - { - auto begin = Triangle_around_vertex_iterator<Skeleton_blocker_complex,Link>(this,v); - auto end = Triangle_around_vertex_iterator<Skeleton_blocker_complex,Link>(this,v,0); - return Complex_triangle_around_vertex_range(begin,end); - } - - - typedef boost::iterator_range<Triangle_iterator<Skeleton_blocker_complex> > Complex_triangle_range; - - /** - * @brief Range over triangles of the simplicial complex. - * Methods .begin() and .end() return a Triangle_around_vertex_iterator. - * - */ - Complex_triangle_range triangle_range() const - { - auto end = Triangle_iterator<Skeleton_blocker_complex>(this,0); - if(empty()){ - return Complex_triangle_range(end,end); - } - else{ - auto begin = Triangle_iterator<Skeleton_blocker_complex>(this); - return Complex_triangle_range(begin,end); - } - - } - - - //@} - - - - /** @name Simplices iterators - */ - //@{ - typedef Simplex_around_vertex_iterator<Skeleton_blocker_complex,Link> Complex_simplex_around_vertex_iterator; - - /** - * @brief Range over the simplices of the simplicial complex around a vertex. - * Methods .begin() and .end() return a Complex_simplex_around_vertex_iterator. - */ - typedef boost::iterator_range < Complex_simplex_around_vertex_iterator > Complex_simplex_around_vertex_range; - - /** - * @brief Returns a Complex_simplex_around_vertex_range over all the simplices around a vertex of the complex - */ - Complex_simplex_around_vertex_range simplex_range(Vertex_handle v) const - { - assert(contains_vertex(v)); - return Complex_simplex_around_vertex_range( - Complex_simplex_around_vertex_iterator(this,v), - Complex_simplex_around_vertex_iterator(this,v,true) - ); - } - - // typedef Simplex_iterator<Skeleton_blocker_complex,Superior_link> Complex_simplex_iterator; - typedef Simplex_iterator<Skeleton_blocker_complex> Complex_simplex_iterator; - - typedef boost::iterator_range < Complex_simplex_iterator > Complex_simplex_range; - - /** - * @brief Returns a Complex_simplex_range over all the simplices of the complex - */ - Complex_simplex_range simplex_range() const - { - Complex_simplex_iterator end(this,true); - if(empty()){ - return Complex_simplex_range(end,end); - } - else{ - Complex_simplex_iterator begin(this); - return Complex_simplex_range(begin,end); - } - } - - - //@} - - - /** @name Blockers iterators - */ - //@{ -private: - /** - * @brief Iterator over the blockers adjacent to a vertex - */ - typedef Blocker_iterator_around_vertex_internal< - typename std::multimap<Vertex_handle,Simplex_handle *>::iterator, - Blocker_handle> - Complex_blocker_around_vertex_iterator; - - /** - * @brief Iterator over (constant) blockers adjacent to a vertex - */ - typedef Blocker_iterator_around_vertex_internal< - typename std::multimap<Vertex_handle,Simplex_handle *>::const_iterator, - const Blocker_handle> - Const_complex_blocker_around_vertex_iterator; - - typedef boost::iterator_range <Complex_blocker_around_vertex_iterator> Complex_blocker_around_vertex_range; - typedef boost::iterator_range <Const_complex_blocker_around_vertex_iterator> Const_complex_blocker_around_vertex_range; - -public: - - - /** - * @brief Returns a range of the blockers of the complex passing through a vertex - */ - Complex_blocker_around_vertex_range blocker_range(Vertex_handle v) - { - auto begin = Complex_blocker_around_vertex_iterator(blocker_map_.lower_bound(v)); - auto end = Complex_blocker_around_vertex_iterator(blocker_map_.upper_bound(v)); - return Complex_blocker_around_vertex_range(begin,end); - } - - /** - * @brief Returns a range of the blockers of the complex passing through a vertex - */ - Const_complex_blocker_around_vertex_range const_blocker_range(Vertex_handle v) const - { - auto begin = Const_complex_blocker_around_vertex_iterator(blocker_map_.lower_bound(v)); - auto end = Const_complex_blocker_around_vertex_iterator(blocker_map_.upper_bound(v)); - return Const_complex_blocker_around_vertex_range(begin,end); - } - - - - -private: - - /** - * @brief Iterator over the blockers. - */ - typedef Blocker_iterator_internal< - typename std::multimap<Vertex_handle,Simplex_handle *>::iterator, - Blocker_handle> - Complex_blocker_iterator; - - /** - * @brief Iterator over the (constant) blockers. - */ - typedef Blocker_iterator_internal< - typename std::multimap<Vertex_handle,Simplex_handle *>::const_iterator, - const Blocker_handle> - Const_complex_blocker_iterator; - - typedef boost::iterator_range <Complex_blocker_iterator> Complex_blocker_range; - typedef boost::iterator_range <Const_complex_blocker_iterator> Const_complex_blocker_range; - - -public: - - /** - * @brief Returns a range of the blockers of the complex - */ - Complex_blocker_range blocker_range() - { - auto begin = Complex_blocker_iterator(blocker_map_.begin(), blocker_map_.end() ); - auto end = Complex_blocker_iterator(blocker_map_.end() , blocker_map_.end() ); - return Complex_blocker_range(begin,end); - } - - /** - * @brief Returns a range of the blockers of the complex - */ - Const_complex_blocker_range const_blocker_range() const - { - auto begin = Const_complex_blocker_iterator(blocker_map_.begin(), blocker_map_.end() ); - auto end = Const_complex_blocker_iterator(blocker_map_.end() , blocker_map_.end() ); - return Const_complex_blocker_range(begin,end); - } - - - - - //@} - - - - - - ///////////////////////////////////////////////////////////////////////////// - /** @name Print and IO methods - */ - //@{ -public: - - std::string to_string() const{ - std::ostringstream stream; - stream<<num_vertices()<<" vertices:\n"<<vertices_to_string()<<std::endl; - stream<<num_edges()<<" edges:\n"<<edges_to_string()<<std::endl; - stream<<num_blockers()<<" blockers:\n"<<blockers_to_string()<<std::endl; - return stream.str(); - } - - std::string vertices_to_string() const{ - std::ostringstream stream; - for(auto vertex : vertex_range()) - stream << "("<<(*this)[vertex].get_id()<<"),"; - stream<< std::endl; - return stream.str(); - } - - std::string edges_to_string() const{ - std::ostringstream stream; - for(auto edge : edge_range()) - stream << "("<< (*this)[edge].first()<<","<< (*this)[edge].second() << ")"<<" id = "<< (*this)[edge].index()<< std::endl; - stream<< std::endl; - return stream.str(); - } - - - std::string blockers_to_string() const{ - std::ostringstream stream; - for (auto bl:blocker_map_){ - stream << bl.first << " => " << bl.second << ":"<<*bl.second <<"\n"; - } - return stream.str(); - } - - //@} - +class Skeleton_blocker_complex { + template<class ComplexType> friend class Complex_vertex_iterator; + template<class ComplexType> friend class Complex_neighbors_vertices_iterator; + template<class ComplexType> friend class Complex_edge_iterator; + template<class ComplexType> friend class Complex_edge_around_vertex_iterator; + + template<class ComplexType> friend class Skeleton_blocker_link_complex; + template<class ComplexType> friend class Skeleton_blocker_link_superior; + template<class ComplexType> friend class Skeleton_blocker_sub_complex; + + public: + /** + * @brief The type of stored vertex node, specified by the template SkeletonBlockerDS + */ + typedef typename SkeletonBlockerDS::Graph_vertex Graph_vertex; + + /** + * @brief The type of stored edge node, specified by the template SkeletonBlockerDS + */ + typedef typename SkeletonBlockerDS::Graph_edge Graph_edge; + + typedef typename SkeletonBlockerDS::Root_vertex_handle Root_vertex_handle; + + /** + * @brief The type of an handle to a vertex of the complex. + */ + typedef typename SkeletonBlockerDS::Vertex_handle Vertex_handle; + typedef typename Root_vertex_handle::boost_vertex_handle boost_vertex_handle; + + /** + * @brief A ordered set of integers that represents a simplex. + */ + typedef Skeleton_blocker_simplex<Vertex_handle> Simplex_handle; + typedef Skeleton_blocker_simplex<Root_vertex_handle> Root_simplex_handle; + + /** + * @brief Handle to a blocker of the complex. + */ + typedef Simplex_handle* Blocker_handle; + + typedef typename Root_simplex_handle::Simplex_vertex_const_iterator Root_simplex_iterator; + typedef typename Simplex_handle::Simplex_vertex_const_iterator Simplex_handle_iterator; + + protected: + typedef typename boost::adjacency_list<boost::setS, // edges + boost::vecS, // vertices + boost::undirectedS, Graph_vertex, Graph_edge> Graph; + // todo/remark : edges are not sorted, it heavily penalizes computation for SuperiorLink + // (eg Link with greater vertices) + // that burdens simplex iteration / complex initialization via list of simplices. + // to avoid that, one should modify the graph by storing two lists of adjacency for every + // vertex, the one with superior and the one with lower vertices, that way there is + // no more extra cost for computation of SuperiorLink + typedef typename boost::graph_traits<Graph>::vertex_iterator boost_vertex_iterator; + typedef typename boost::graph_traits<Graph>::edge_iterator boost_edge_iterator; + + protected: + typedef typename boost::graph_traits<Graph>::adjacency_iterator boost_adjacency_iterator; + + public: + /** + * @brief Handle to an edge of the complex. + */ + typedef typename boost::graph_traits<Graph>::edge_descriptor Edge_handle; + + protected: + typedef std::multimap<Vertex_handle, Simplex_handle *> BlockerMap; + typedef typename std::multimap<Vertex_handle, Simplex_handle *>::value_type BlockerPair; + typedef typename std::multimap<Vertex_handle, Simplex_handle *>::iterator BlockerMapIterator; + typedef typename std::multimap<Vertex_handle, Simplex_handle *>::const_iterator BlockerMapConstIterator; + + protected: + int num_vertices_; + int num_blockers_; + + typedef Skeleton_blocker_complex_visitor<Vertex_handle> Visitor; + // typedef Visitor* Visitor_ptr; + Visitor* visitor; + + /** + * @details If 'x' is a Vertex_handle of a vertex in the complex then degree[x] = d is its degree. + * + * This quantity is updated when adding/removing edge. + * + * This is useful because the operation + * list.size() is done in linear time. + */ + std::vector<boost_vertex_handle> degree_; + Graph skeleton; /** 1-skeleton of the simplicial complex. */ + + // todo remove!!! + + /** Each vertex can access to the blockers passing through it. */ + BlockerMap blocker_map_; + + public: + ///////////////////////////////////////////////////////////////////////////// + /** @name Constructors, Destructors + */ + //@{ + /** + *@brief constructs a simplicial complex with a given number of vertices and a visitor. + */ + explicit Skeleton_blocker_complex(int num_vertices_ = 0, Visitor* visitor_ = NULL) + : visitor(visitor_) { + clear(); + for (int i = 0; i < num_vertices_; ++i) { + add_vertex(); + } + } + + private: + /** + * this nested class is used for the next constructor that takes as an input a list of simplices. + * It stores a vector where the ith cell contains a set of i-simplices + * + */ + class Simplices_sets_from_list { + private: + typedef std::set<Simplex_handle> Container_simplices; + typedef typename Container_simplices::iterator Simplices_iterator; + int dimension_; + std::vector<Container_simplices> simplices_; + + public: + explicit Simplices_sets_from_list(std::list<Simplex_handle>& simplices) + : dimension_(-1) { + assert(!simplices.empty()); + + for (auto simplex = simplices.begin(); simplex != simplices.end(); + ++simplex) { + dimension_ = std::max(dimension_, static_cast<int>(simplex->dimension())); + } + simplices_ = std::vector < Container_simplices > (dimension_ + 1); + + // compute k-simplices + for (auto simplex = simplices.begin(); simplex != simplices.end(); + ++simplex) { + simplices_[simplex->dimension()].insert(*simplex); + } + } + + Simplices_iterator begin(int k) { + assert(0 <= k && k <= dimension_); + return simplices_[k].begin(); + } + + Simplices_iterator end(int k) { + assert(0 <= k && k <= dimension_); + return simplices_[k].end(); + } + + Container_simplices& simplices(int k) { + return simplices_[k]; + } + + int dimension() { + return dimension_; + } + + bool contains(const Simplex_handle& simplex) const { + if (simplex.dimension() > dimension_) + return false; + else + return simplices_[simplex.dimension()].find(simplex) + != simplices_[simplex.dimension()].end(); + } + + void print() { + for (int i = 0; i < dimension_; ++i) { + std::cout << i << "-simplices" << std::endl; + auto l = simplices_[i]; + for (auto s : l) { + std::cout << s << std::endl; + } + } + } + }; + + void compute_next_expand(Simplices_sets_from_list& simplices, int dim, + std::list<Simplex_handle>& next_expand) { + next_expand.clear(); + + // high_resolution_clock::time_point tbeginfor = high_resolution_clock::now(); + // auto durationlooplink = std::chrono::duration_cast<std::chrono::microseconds>( tbeginfor - tbeginfor ).count(); + + for (auto sigma = simplices.begin(dim); sigma != simplices.end(dim); + ++sigma) { + // high_resolution_clock::time_point tbeg = high_resolution_clock::now(); + Simplex_handle t(*sigma); + Skeleton_blocker_link_superior<Skeleton_blocker_complex> link(*this, t); + // xxx all time here, most likely because accessing superior edges needs passing through lower one + // currently + + // durationlooplink += std::chrono::duration_cast<std::chrono::microseconds>( high_resolution_clock::now() - tbeg ).count(); + + for (auto v : link.vertex_range()) { + Vertex_handle v_in_complex(*this->get_address(link.get_id(v))); + t.add_vertex(v_in_complex); + next_expand.push_back(t); + t.remove_vertex(v_in_complex); + } + } + // high_resolution_clock::time_point t2 = high_resolution_clock::now(); + // auto durationlooptotal = std::chrono::duration_cast<std::chrono::microseconds>( t2 - tbeginfor ).count(); + // DBGVALUE(durationlooptotal); + // DBGVALUE(durationlooplink); + } + + public: + /** + * @brief Constructor with a list of simplices. + * @details The list of simplices must be the list + * of simplices of a simplicial complex. + */ + Skeleton_blocker_complex(std::list<Simplex_handle>& simplices, + Visitor* visitor_ = NULL) + : num_vertices_(0), + num_blockers_(0), + visitor(visitor_) { + Simplices_sets_from_list set_simplices(simplices); + + int dim = set_simplices.dimension(); + + // add 1-skeleton to the complex + for (auto v_it = set_simplices.begin(0); v_it != set_simplices.end(0); + ++v_it) + add_vertex(); + + for (auto e_it = set_simplices.begin(1); e_it != set_simplices.end(1); + ++e_it) { + Vertex_handle a = e_it->first_vertex(); + Vertex_handle b = e_it->last_vertex(); + assert(contains_vertex(a) && contains_vertex(b)); + add_edge(a, b); + } + + // then add blockers + for (int current_dim = 1; current_dim <= dim; ++current_dim) { + std::list<Simplex_handle> expansion_simplices; + compute_next_expand(set_simplices, current_dim, expansion_simplices); + + for (const auto &simplex : expansion_simplices) { + if (!set_simplices.contains(simplex)) { + add_blocker(simplex); + } + } + } + } + + // We cannot use the default copy constructor since we need + // to make a copy of each of the blockers + Skeleton_blocker_complex(const Skeleton_blocker_complex& copy) { + visitor = NULL; + degree_ = copy.degree_; + skeleton = Graph(copy.skeleton); + num_vertices_ = copy.num_vertices_; + + num_blockers_ = 0; + // we copy the blockers + for (auto blocker : copy.const_blocker_range()) { + add_blocker(*blocker); + } + } + + /** + */ + Skeleton_blocker_complex& operator=(const Skeleton_blocker_complex& copy) { + clear(); + visitor = NULL; + degree_ = copy.degree_; + skeleton = Graph(copy.skeleton); + num_vertices_ = copy.num_vertices_; + + num_blockers_ = 0; + // we copy the blockers + for (auto blocker : copy.const_blocker_range()) + add_blocker(*blocker); + return *this; + } + + /** + * The destructor delete all blockers allocated. + */ + virtual ~Skeleton_blocker_complex() { + clear(); + } + + /** + * @details Clears the simplicial complex. After a call to this function, + * blockers are destroyed. The 1-skeleton and the set of blockers + * are both empty. + */ + virtual void clear() { + // xxx for now the responsabilty of freeing the visitor is for + // the user + visitor = NULL; + + degree_.clear(); + num_vertices_ = 0; + + remove_blockers(); + + skeleton.clear(); + } + + /** + *@brief allows to change the visitor. + */ + void set_visitor(Visitor* other_visitor) { + visitor = other_visitor; + } + + //@} + + ///////////////////////////////////////////////////////////////////////////// + /** @name Vertices operations + */ + //@{ + public: + /** + * @brief Return a local Vertex_handle of a vertex given a global one. + * @remark Assume that the vertex is present in the complex. + */ + Vertex_handle operator[](Root_vertex_handle global) const { + auto local(get_address(global)); + assert(local); + return *local; + } + + /** + * @brief Return the vertex node associated to local Vertex_handle. + * @remark Assume that the vertex is present in the complex. + */ + Graph_vertex& operator[](Vertex_handle address) { + assert( + 0 <= address.vertex && address.vertex < boost::num_vertices(skeleton)); + return skeleton[address.vertex]; + } + + /** + * @brief Return the vertex node associated to local Vertex_handle. + * @remark Assume that the vertex is present in the complex. + */ + const Graph_vertex& operator[](Vertex_handle address) const { + assert( + 0 <= address.vertex && address.vertex < boost::num_vertices(skeleton)); + return skeleton[address.vertex]; + } + + /** + * @brief Adds a vertex to the simplicial complex and returns its Vertex_handle. + */ + Vertex_handle add_vertex() { + Vertex_handle address(boost::add_vertex(skeleton)); + num_vertices_++; + (*this)[address].activate(); + // safe since we now that we are in the root complex and the field 'address' and 'id' + // are identical for every vertices + (*this)[address].set_id(Root_vertex_handle(address.vertex)); + degree_.push_back(0); + if (visitor) + visitor->on_add_vertex(address); + return address; + } + + /** + * @brief Remove a vertex from the simplicial complex + * @remark It just deactivates the vertex with a boolean flag but does not + * remove it from vertices from complexity issues. + */ + void remove_vertex(Vertex_handle address) { + assert(contains_vertex(address)); + // We remove b + boost::clear_vertex(address.vertex, skeleton); + (*this)[address].deactivate(); + num_vertices_--; + degree_[address.vertex] = -1; + if (visitor) + visitor->on_remove_vertex(address); + } + + /** + */ + bool contains_vertex(Vertex_handle u) const { + if (u.vertex < 0 || u.vertex >= boost::num_vertices(skeleton)) + return false; + return (*this)[u].is_active(); + } + + /** + */ + bool contains_vertex(Root_vertex_handle u) const { + boost::optional<Vertex_handle> address = get_address(u); + return address && (*this)[*address].is_active(); + } + + /** + * @return true iff the simplicial complex contains all vertices + * of simplex sigma + */ + bool contains_vertices(const Simplex_handle & sigma) const { + for (auto vertex : sigma) + if (!contains_vertex(vertex)) + return false; + return true; + } + + /** + * @brief Given an Id return the address of the vertex having this Id in the complex. + * @remark For a simplicial complex, the address is the id but it may not be the case for a SubComplex. + */ + virtual boost::optional<Vertex_handle> get_address( + Root_vertex_handle id) const { + boost::optional<Vertex_handle> res; + if (id.vertex < boost::num_vertices(skeleton)) + res = Vertex_handle(id.vertex); // xxx + return res; + } + + /** + * return the id of a vertex of adress local present in the graph + */ + Root_vertex_handle get_id(Vertex_handle local) const { + assert(0 <= local.vertex && local.vertex < boost::num_vertices(skeleton)); + return (*this)[local].get_id(); + } + + /** + * @brief Convert an address of a vertex of a complex to the address in + * the current complex. + * @details + * If the current complex is a sub (or sup) complex of 'other', it converts + * the address of a vertex v expressed in 'other' to the address of the vertex + * v in the current one. + * @remark this methods uses Root_vertex_handle to identify the vertex and + * assumes the vertex is present in the current complex. + */ + Vertex_handle convert_handle_from_another_complex( + const Skeleton_blocker_complex& other, Vertex_handle vh_in_other) const { + auto vh_in_current_complex = get_address(other.get_id(vh_in_other)); + assert(vh_in_current_complex); + return *vh_in_current_complex; + } + + /** + * @brief return the graph degree of a vertex. + */ + int degree(Vertex_handle local) const { + assert(0 <= local.vertex && local.vertex < boost::num_vertices(skeleton)); + return degree_[local.vertex]; + } + + //@} + + ///////////////////////////////////////////////////////////////////////////// + /** @name Edges operations + */ + //@{ + public: + /** + * @brief return an edge handle if the two vertices forms + * an edge in the complex + */ + boost::optional<Edge_handle> operator[]( + const std::pair<Vertex_handle, Vertex_handle>& ab) const { + boost::optional<Edge_handle> res; + std::pair<Edge_handle, bool> edge_pair( + boost::edge(ab.first.vertex, ab.second.vertex, skeleton)); + if (edge_pair.second) + res = edge_pair.first; + return res; + } + + /** + * @brief returns the stored node associated to an edge + */ + Graph_edge& operator[](Edge_handle edge_handle) { + return skeleton[edge_handle]; + } + + /** + * @brief returns the stored node associated to an edge + */ + const Graph_edge& operator[](Edge_handle edge_handle) const { + return skeleton[edge_handle]; + } + + /** + * @brief returns the first vertex of an edge + * @details it assumes that the edge is present in the complex + */ + Vertex_handle first_vertex(Edge_handle edge_handle) const { + return static_cast<Vertex_handle>(source(edge_handle, skeleton)); + } + + /** + * @brief returns the first vertex of an edge + * @details it assumes that the edge is present in the complex + */ + Vertex_handle second_vertex(Edge_handle edge_handle) const { + return static_cast<Vertex_handle>(target(edge_handle, skeleton)); + } + + /** + * @brief returns the simplex made with the two vertices of the edge + * @details it assumes that the edge is present in the complex + + */ + Simplex_handle get_vertices(Edge_handle edge_handle) const { + auto edge((*this)[edge_handle]); + return Simplex_handle((*this)[edge.first()], (*this)[edge.second()]); + } + + /** + * @brief Adds an edge between vertices a and b and all its cofaces. + */ + Edge_handle add_edge(Vertex_handle a, Vertex_handle b) { + assert(contains_vertex(a) && contains_vertex(b)); + assert(a != b); + + auto edge_handle((*this)[std::make_pair(a, b)]); + // std::pair<Edge_handle,bool> pair_descr_bool = (*this)[std::make_pair(a,b)]; + // Edge_handle edge_descr; + // bool edge_present = pair_descr_bool.second; + if (!edge_handle) { + edge_handle = boost::add_edge(a.vertex, b.vertex, skeleton).first; + (*this)[*edge_handle].setId(get_id(a), get_id(b)); + degree_[a.vertex]++; + degree_[b.vertex]++; + if (visitor) + visitor->on_add_edge(a, b); + } + return *edge_handle; + } + + /** + * @brief Adds all edges and their cofaces of a simplex to the simplicial complex. + */ + void add_edges(const Simplex_handle & sigma) { + Simplex_handle_iterator i, j; + for (i = sigma.begin(); i != sigma.end(); ++i) + for (j = i, j++; j != sigma.end(); ++j) + add_edge(*i, *j); + } + + /** + * @brief Removes an edge from the simplicial complex and all its cofaces. + * @details returns the former Edge_handle representing the edge + */ + virtual Edge_handle remove_edge(Vertex_handle a, Vertex_handle b) { + bool found; + Edge_handle edge; + tie(edge, found) = boost::edge(a.vertex, b.vertex, skeleton); + if (found) { + if (visitor) + visitor->on_remove_edge(a, b); + // if (heapCollapse.Contains(edge)) heapCollapse.Delete(edge); + boost::remove_edge(a.vertex, b.vertex, skeleton); + degree_[a.vertex]--; + degree_[b.vertex]--; + } + return edge; + } + + /** + * @brief Removes edge and its cofaces from the simplicial complex. + */ + void remove_edge(Edge_handle edge) { + assert(contains_vertex(first_vertex(edge))); + assert(contains_vertex(second_vertex(edge))); + remove_edge(first_vertex(edge), second_vertex(edge)); + } + + /** + * @brief The complex is reduced to its set of vertices. + * All the edges and blockers are removed. + */ + void keep_only_vertices() { + remove_blockers(); + + for (auto u : vertex_range()) { + while (this->degree(u) > 0) { + Vertex_handle v(*(adjacent_vertices(u.vertex, this->skeleton).first)); + this->remove_edge(u, v); + } + } + } + + /** + * @return true iff the simplicial complex contains an edge between + * vertices a and b + */ + bool contains_edge(Vertex_handle a, Vertex_handle b) const { + // if (a.vertex<0 || b.vertex <0) return false; + return boost::edge(a.vertex, b.vertex, skeleton).second; + } + + /** + * @return true iff the simplicial complex contains all vertices + * and all edges of simplex sigma + */ + bool contains_edges(const Simplex_handle & sigma) const { + for (auto i = sigma.begin(); i != sigma.end(); ++i) { + if (!contains_vertex(*i)) + return false; + for (auto j = i; ++j != sigma.end();) { + if (!contains_edge(*i, *j)) + return false; + } + } + return true; + } + //@} + + ///////////////////////////////////////////////////////////////////////////// + /** @name Blockers operations + */ + //@{ + /** + * @brief Adds the simplex to the set of blockers and + * returns a Blocker_handle toward it if was not present before and 0 otherwise. + */ + Blocker_handle add_blocker(const Simplex_handle& blocker) { + assert(blocker.dimension() > 1); + if (contains_blocker(blocker)) { + // std::cerr << "ATTEMPT TO ADD A BLOCKER ALREADY THERE ---> BLOCKER IGNORED" << endl; + return 0; + } else { + if (visitor) + visitor->on_add_blocker(blocker); + Blocker_handle blocker_pt = new Simplex_handle(blocker); + num_blockers_++; + auto vertex = blocker_pt->begin(); + while (vertex != blocker_pt->end()) { + blocker_map_.insert(BlockerPair(*vertex, blocker_pt)); + ++vertex; + } + return blocker_pt; + } + } + + protected: + /** + * @brief Adds the simplex to the set of blockers + */ + void add_blocker(Blocker_handle blocker) { + if (contains_blocker(*blocker)) { + // std::cerr << "ATTEMPT TO ADD A BLOCKER ALREADY THERE ---> BLOCKER IGNORED" << endl; + return; + } else { + if (visitor) + visitor->on_add_blocker(*blocker); + num_blockers_++; + auto vertex = blocker->begin(); + while (vertex != blocker->end()) { + blocker_map_.insert(BlockerPair(*vertex, blocker)); + ++vertex; + } + } + } + + protected: + /** + * Removes sigma from the blocker map of vertex v + */ + void remove_blocker(const Blocker_handle sigma, Vertex_handle v) { + Complex_blocker_around_vertex_iterator blocker; + for (blocker = blocker_range(v).begin(); blocker != blocker_range(v).end(); + ++blocker) { + if (*blocker == sigma) + break; + } + if (*blocker != sigma) { + std::cerr + << "bug ((*blocker).second == sigma) ie try to remove a blocker not present\n"; + assert(false); + } else { + blocker_map_.erase(blocker.current_position()); + } + } + + public: + /** + * @brief Removes the simplex from the set of blockers. + * @remark sigma has to belongs to the set of blockers + */ + void remove_blocker(const Blocker_handle sigma) { + for (auto vertex : *sigma) { + remove_blocker(sigma, vertex); + } + num_blockers_--; + } + + /** + * @brief Remove all blockers, in other words, it expand the simplicial + * complex to the smallest flag complex that contains it. + */ + void remove_blockers() { + // Desallocate the blockers + while (!blocker_map_.empty()) { + delete_blocker(blocker_map_.begin()->second); + } + num_blockers_ = 0; + blocker_map_.clear(); + } + + protected: + /** + * Removes the simplex sigma from the set of blockers. + * sigma has to belongs to the set of blockers + * + * @remark contrarily to delete_blockers does not call the destructor + */ + void remove_blocker(const Simplex_handle& sigma) { + assert(contains_blocker(sigma)); + for (auto vertex : sigma) + remove_blocker(sigma, vertex); + num_blockers_--; + } + + public: + /** + * Removes the simplex s from the set of blockers + * and desallocate s. + */ + void delete_blocker(Blocker_handle sigma) { + if (visitor) + visitor->on_delete_blocker(sigma); + remove_blocker(sigma); + delete sigma; + } + + /** + * @return true iff s is a blocker of the simplicial complex + */ + bool contains_blocker(const Blocker_handle s) const { + if (s->dimension() < 2) + return false; + + Vertex_handle a = s->first_vertex(); + + for (auto blocker : const_blocker_range(a)) { + if (s == *blocker) + return true; + } + return false; + } + + /** + * @return true iff s is a blocker of the simplicial complex + */ + bool contains_blocker(const Simplex_handle & s) const { + if (s.dimension() < 2) + return false; + + Vertex_handle a = s.first_vertex(); + + for (auto blocker : const_blocker_range(a)) { + if (s == *blocker) + return true; + } + return false; + } + + private: + /** + * @return true iff a blocker of the simplicial complex + * is a face of sigma. + */ + bool blocks(const Simplex_handle & sigma) const { + for (auto blocker : const_blocker_range()) { + if (sigma.contains(*blocker)) + return true; + } + return false; + } + + //@} + + protected: + /** + * @details Adds to simplex the neighbours of v e.g. \f$ n \leftarrow n \cup N(v) \f$. + * If keep_only_superior is true then only vertices that are greater than v are added. + */ + virtual void add_neighbours(Vertex_handle v, Simplex_handle & n, + bool keep_only_superior = false) const { + boost_adjacency_iterator ai, ai_end; + for (tie(ai, ai_end) = adjacent_vertices(v.vertex, skeleton); ai != ai_end; + ++ai) { + if (keep_only_superior) { + if (*ai > v.vertex) { + n.add_vertex(Vertex_handle(*ai)); + } + } else { + n.add_vertex(Vertex_handle(*ai)); + } + } + } + + /** + * @details Add to simplex res all vertices which are + * neighbours of alpha: ie \f$ res \leftarrow res \cup N(alpha) \f$. + * + * If 'keep_only_superior' is true then only vertices that are greater than alpha are added. + * todo revoir + * + */ + virtual void add_neighbours(const Simplex_handle &alpha, Simplex_handle & res, + bool keep_only_superior = false) const { + res.clear(); + auto alpha_vertex = alpha.begin(); + add_neighbours(*alpha_vertex, res, keep_only_superior); + for (alpha_vertex = (alpha.begin())++; alpha_vertex != alpha.end(); + ++alpha_vertex) + keep_neighbours(*alpha_vertex, res, keep_only_superior); + } + + /** + * @details Remove from simplex n all vertices which are + * not neighbours of v e.g. \f$ res \leftarrow res \cap N(v) \f$. + * If 'keep_only_superior' is true then only vertices that are greater than v are keeped. + */ + virtual void keep_neighbours(Vertex_handle v, Simplex_handle& res, + bool keep_only_superior = false) const { + Simplex_handle nv; + add_neighbours(v, nv, keep_only_superior); + res.intersection(nv); + } + + /** + * @details Remove from simplex all vertices which are + * neighbours of v eg \f$ res \leftarrow res \setminus N(v) \f$. + * If 'keep_only_superior' is true then only vertices that are greater than v are added. + */ + virtual void remove_neighbours(Vertex_handle v, Simplex_handle & res, + bool keep_only_superior = false) const { + Simplex_handle nv; + add_neighbours(v, nv, keep_only_superior); + res.difference(nv); + } + + public: + /** + * @brief Compute the local vertices of 's' in the current complex + * If one of them is not present in the complex then the return value is uninitialized. + * + * + */ + // xxx rename get_address et place un using dans sub_complex + boost::optional<Simplex_handle> get_simplex_address( + const Root_simplex_handle& s) const { + boost::optional<Simplex_handle> res; + + Simplex_handle s_address; + // Root_simplex_const_iterator i; + for (auto i = s.begin(); i != s.end(); ++i) { + boost::optional<Vertex_handle> address = get_address(*i); + if (!address) + return res; + else + s_address.add_vertex(*address); + } + res = s_address; + return res; + } + + /** + * @brief returns a simplex with vertices which are the id of vertices of the + * argument. + */ + Root_simplex_handle get_id(const Simplex_handle& local_simplex) const { + Root_simplex_handle global_simplex; + for (auto x = local_simplex.begin(); x != local_simplex.end(); ++x) { + global_simplex.add_vertex(get_id(*x)); + } + return global_simplex; + } + + /** + * @brief returns true iff the simplex s belongs to the simplicial + * complex. + */ + virtual bool contains(const Simplex_handle & s) const { + if (s.dimension() == -1) { + return false; + } else if (s.dimension() == 0) { + return contains_vertex(s.first_vertex()); + } else { + return (contains_edges(s) && !blocks(s)); + } + } + + /* + * @brief returnrs true iff the complex is empty. + */ + bool empty() const { + return num_vertices() == 0; + } + + /* + * @brief returns the number of vertices in the complex. + */ + int num_vertices() const { + // remark boost::num_vertices(skeleton) counts deactivated vertices + return num_vertices_; + } + + /* + * @brief returns the number of edges in the complex. + * @details currently in O(n) + */ + // todo cache the value + int num_edges() const { + return boost::num_edges(skeleton); + } + + /* + * @brief returns the number of blockers in the complex. + */ + int num_blockers() const { + return num_blockers_; + } + + /* + * @brief returns true iff the graph of the 1-skeleton of the complex is complete. + */ + bool complete() const { + return (num_vertices() * (num_vertices() - 1)) / 2 == num_edges(); + } + + /** + * @brief returns the number of connected components in the graph of the 1-skeleton. + */ + int num_connected_components() const { + int num_vert_collapsed = skeleton.vertex_set().size() - num_vertices(); + std::vector<int> component(skeleton.vertex_set().size()); + return boost::connected_components(this->skeleton, &component[0]) + - num_vert_collapsed; + } + + /** + * @brief %Test if the complex is a cone. + * @details Runs in O(n) where n is the number of vertices. + */ + bool is_cone() const { + if (num_vertices() == 0) + return false; + if (num_vertices() == 1) + return true; + for (auto vi : vertex_range()) { + // xxx todo faire une methode bool is_in_blocker(Vertex_handle) + if (blocker_map_.find(vi) == blocker_map_.end()) { + // no blocker passes through the vertex, we just need to + // check if the current vertex is linked to all others vertices of the complex + if (degree_[vi.vertex] == num_vertices() - 1) + return true; + } + } + return false; + } + + //@} + + ///////////////////////////////////////////////////////////////////////////// + /** @name Vertex iterators + */ + //@{ + typedef Complex_vertex_iterator<Skeleton_blocker_complex> CVI; // todo rename + + // + // @brief Range over the vertices of the simplicial complex. + // Methods .begin() and .end() return a Complex_vertex_iterator. + // + typedef boost::iterator_range< + Complex_vertex_iterator<Skeleton_blocker_complex> > Complex_vertex_range; + + /** + * @brief Returns a Complex_vertex_range over all vertices of the complex + */ + Complex_vertex_range vertex_range() const { + auto begin = Complex_vertex_iterator<Skeleton_blocker_complex>(this); + auto end = Complex_vertex_iterator<Skeleton_blocker_complex>(this, 0); + return Complex_vertex_range(begin, end); + } + + typedef boost::iterator_range< + Complex_neighbors_vertices_iterator<Skeleton_blocker_complex> > Complex_neighbors_vertices_range; + + /** + * @brief Returns a Complex_edge_range over all edges of the simplicial complex that passes trough v + */ + Complex_neighbors_vertices_range vertex_range(Vertex_handle v) const { + auto begin = Complex_neighbors_vertices_iterator<Skeleton_blocker_complex>( + this, v); + auto end = Complex_neighbors_vertices_iterator<Skeleton_blocker_complex>( + this, v, 0); + return Complex_neighbors_vertices_range(begin, end); + } + + //@} + + /** @name Edge iterators + */ + //@{ + + typedef boost::iterator_range< + Complex_edge_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>> Complex_edge_range; + + /** + * @brief Returns a Complex_edge_range over all edges of the simplicial complex + */ + Complex_edge_range edge_range() const { + auto begin = Complex_edge_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>(this); + auto end = Complex_edge_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>(this, 0); + return Complex_edge_range(begin, end); + } + + typedef boost::iterator_range <Complex_edge_around_vertex_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>> + Complex_edge_around_vertex_range; + /** + * @brief Returns a Complex_edge_range over all edges of the simplicial complex that passes + * through 'v' + */ + Complex_edge_around_vertex_range edge_range(Vertex_handle v) const { + auto begin = Complex_edge_around_vertex_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>(this, v); + auto end = Complex_edge_around_vertex_iterator<Skeleton_blocker_complex<SkeletonBlockerDS>>(this, v, 0); + return Complex_edge_around_vertex_range(begin, end); + } + + //@} + + /** @name Triangles iterators + */ + //@{ + private: + typedef Skeleton_blocker_link_complex<Skeleton_blocker_complex<SkeletonBlockerDS> > Link; + typedef Skeleton_blocker_link_superior<Skeleton_blocker_complex<SkeletonBlockerDS> > Superior_link; + + public: + typedef Triangle_around_vertex_iterator<Skeleton_blocker_complex, Superior_link> Superior_triangle_around_vertex_iterator; + + typedef boost::iterator_range < Triangle_around_vertex_iterator<Skeleton_blocker_complex, Link> > Complex_triangle_around_vertex_range; + + /** + * @brief Range over triangles around a vertex of the simplicial complex. + * Methods .begin() and .end() return a Triangle_around_vertex_iterator. + * + */ + Complex_triangle_around_vertex_range triangle_range(Vertex_handle v) const { + auto begin = Triangle_around_vertex_iterator<Skeleton_blocker_complex, Link>(this, v); + auto end = Triangle_around_vertex_iterator<Skeleton_blocker_complex, Link>(this, v, 0); + return Complex_triangle_around_vertex_range(begin, end); + } + + typedef boost::iterator_range<Triangle_iterator<Skeleton_blocker_complex> > Complex_triangle_range; + + /** + * @brief Range over triangles of the simplicial complex. + * Methods .begin() and .end() return a Triangle_around_vertex_iterator. + * + */ + Complex_triangle_range triangle_range() const { + auto end = Triangle_iterator<Skeleton_blocker_complex>(this, 0); + if (empty()) { + return Complex_triangle_range(end, end); + } else { + auto begin = Triangle_iterator<Skeleton_blocker_complex>(this); + return Complex_triangle_range(begin, end); + } + } + + //@} + + /** @name Simplices iterators + */ + //@{ + typedef Simplex_around_vertex_iterator<Skeleton_blocker_complex, Link> Complex_simplex_around_vertex_iterator; + + /** + * @brief Range over the simplices of the simplicial complex around a vertex. + * Methods .begin() and .end() return a Complex_simplex_around_vertex_iterator. + */ + typedef boost::iterator_range < Complex_simplex_around_vertex_iterator > Complex_simplex_around_vertex_range; + + /** + * @brief Returns a Complex_simplex_around_vertex_range over all the simplices around a vertex of the complex + */ + Complex_simplex_around_vertex_range simplex_range(Vertex_handle v) const { + assert(contains_vertex(v)); + return Complex_simplex_around_vertex_range( + Complex_simplex_around_vertex_iterator(this, v), + Complex_simplex_around_vertex_iterator(this, v, true)); + } + + // typedef Simplex_iterator<Skeleton_blocker_complex,Superior_link> Complex_simplex_iterator; + typedef Simplex_iterator<Skeleton_blocker_complex> Complex_simplex_iterator; + + typedef boost::iterator_range < Complex_simplex_iterator > Complex_simplex_range; + + /** + * @brief Returns a Complex_simplex_range over all the simplices of the complex + */ + Complex_simplex_range simplex_range() const { + Complex_simplex_iterator end(this, true); + if (empty()) { + return Complex_simplex_range(end, end); + } else { + Complex_simplex_iterator begin(this); + return Complex_simplex_range(begin, end); + } + } + + //@} + + /** @name Blockers iterators + */ + //@{ + private: + /** + * @brief Iterator over the blockers adjacent to a vertex + */ + typedef Blocker_iterator_around_vertex_internal< + typename std::multimap<Vertex_handle, Simplex_handle *>::iterator, + Blocker_handle> + Complex_blocker_around_vertex_iterator; + + /** + * @brief Iterator over (constant) blockers adjacent to a vertex + */ + typedef Blocker_iterator_around_vertex_internal< + typename std::multimap<Vertex_handle, Simplex_handle *>::const_iterator, + const Blocker_handle> + Const_complex_blocker_around_vertex_iterator; + + typedef boost::iterator_range <Complex_blocker_around_vertex_iterator> Complex_blocker_around_vertex_range; + typedef boost::iterator_range <Const_complex_blocker_around_vertex_iterator> Const_complex_blocker_around_vertex_range; + + public: + /** + * @brief Returns a range of the blockers of the complex passing through a vertex + */ + Complex_blocker_around_vertex_range blocker_range(Vertex_handle v) { + auto begin = Complex_blocker_around_vertex_iterator(blocker_map_.lower_bound(v)); + auto end = Complex_blocker_around_vertex_iterator(blocker_map_.upper_bound(v)); + return Complex_blocker_around_vertex_range(begin, end); + } + + /** + * @brief Returns a range of the blockers of the complex passing through a vertex + */ + Const_complex_blocker_around_vertex_range const_blocker_range(Vertex_handle v) const { + auto begin = Const_complex_blocker_around_vertex_iterator(blocker_map_.lower_bound(v)); + auto end = Const_complex_blocker_around_vertex_iterator(blocker_map_.upper_bound(v)); + return Const_complex_blocker_around_vertex_range(begin, end); + } + + private: + /** + * @brief Iterator over the blockers. + */ + typedef Blocker_iterator_internal< + typename std::multimap<Vertex_handle,Simplex_handle *>::iterator, + Blocker_handle> + Complex_blocker_iterator; + + /** + * @brief Iterator over the (constant) blockers. + */ + typedef Blocker_iterator_internal< + typename std::multimap<Vertex_handle,Simplex_handle *>::const_iterator, + const Blocker_handle> + Const_complex_blocker_iterator; + + typedef boost::iterator_range <Complex_blocker_iterator> Complex_blocker_range; + typedef boost::iterator_range <Const_complex_blocker_iterator> Const_complex_blocker_range; + + public: + /** + * @brief Returns a range of the blockers of the complex + */ + Complex_blocker_range blocker_range() { + auto begin = Complex_blocker_iterator(blocker_map_.begin(), blocker_map_.end() ); + auto end = Complex_blocker_iterator(blocker_map_.end() , blocker_map_.end() ); + return Complex_blocker_range(begin, end); + } + + /** + * @brief Returns a range of the blockers of the complex + */ + Const_complex_blocker_range const_blocker_range() const { + auto begin = Const_complex_blocker_iterator(blocker_map_.begin(), blocker_map_.end() ); + auto end = Const_complex_blocker_iterator(blocker_map_.end(), blocker_map_.end() ); + return Const_complex_blocker_range(begin, end); + } + + //@} + + ///////////////////////////////////////////////////////////////////////////// + /** @name Print and IO methods + */ + //@{ + public: + std::string to_string() const { + std::ostringstream stream; + stream << num_vertices() << " vertices:\n" << vertices_to_string() << std::endl; + stream << num_edges() << " edges:\n" << edges_to_string() << std::endl; + stream << num_blockers() << " blockers:\n" << blockers_to_string() << std::endl; + return stream.str(); + } + + std::string vertices_to_string() const { + std::ostringstream stream; + for (auto vertex : vertex_range()) { + stream << "(" << (*this)[vertex].get_id() << "),"; + } + stream << std::endl; + return stream.str(); + } + + std::string edges_to_string() const { + std::ostringstream stream; + for (auto edge : edge_range()) { + stream << "(" << (*this)[edge].first() << "," << (*this)[edge].second() << ")" << " id = " << (*this)[edge].index() << std::endl; + } + stream << std::endl; + return stream.str(); + } + + std::string blockers_to_string() const { + std::ostringstream stream; + for (auto bl : blocker_map_) { + stream << bl.first << " => " << bl.second << ":" << *bl.second << std::endl; + } + return stream.str(); + } + + //@} }; - - /** * build a simplicial complex from a collection * of top faces. */ -template<typename Complex,typename SimplexHandleIterator> -unsigned make_complex_from_top_faces(Complex& complex,SimplexHandleIterator begin,SimplexHandleIterator end){ - typedef typename Complex::Simplex_handle Simplex_handle; - - int dimension = 0; - for(auto top_face = begin; top_face != end; ++top_face) - dimension = std::max(dimension,top_face->dimension()); - - std::vector< std::set<Simplex_handle> > simplices_per_dimension(dimension+1); - - - for(auto top_face = begin; top_face != end; ++top_face){ - register_faces(simplices_per_dimension,*top_face); - } - - // compute list of simplices - std::list<Simplex_handle> simplices; - for(int dim = 0 ; dim <= dimension ; ++dim){ - std::copy( - simplices_per_dimension[dim].begin(), - simplices_per_dimension[dim].end(), - std::back_inserter(simplices) - ); - } - complex = Complex(simplices); - return simplices.size(); +template<typename Complex, typename SimplexHandleIterator> +unsigned make_complex_from_top_faces(Complex& complex, + SimplexHandleIterator begin, + SimplexHandleIterator end) { + typedef typename Complex::Simplex_handle Simplex_handle; + + int dimension = 0; + for (auto top_face = begin; top_face != end; ++top_face) + dimension = std::max(dimension, top_face->dimension()); + + std::vector < std::set<Simplex_handle> + > simplices_per_dimension(dimension + 1); + + for (auto top_face = begin; top_face != end; ++top_face) { + register_faces(simplices_per_dimension, *top_face); + } + + // compute list of simplices + std::list<Simplex_handle> simplices; + for (int dim = 0; dim <= dimension; ++dim) { + std::copy(simplices_per_dimension[dim].begin(), + simplices_per_dimension[dim].end(), + std::back_inserter(simplices)); + } + complex = Complex(simplices); + return simplices.size(); } -} // namespace skbl - -} // namespace GUDHI - +} // namespace skbl +} // namespace Gudhi -#endif +#endif // SRC_SKELETON_BLOCKER_INCLUDE_GUDHI_SKELETON_BLOCKER_COMPLEX_H_ |