path: root/src/Alpha_complex/include/gudhi/Alpha_complex.h

/*    This file is part of the Gudhi Library. The Gudhi library
 *    (Geometric Understanding in Higher Dimensions) is a generic C++
 *    library for computational topology.
 *
 *    Author(s):       Vincent Rouvreau
 *
 *    Copyright (C) 2015  INRIA Saclay (France)
 *
 *    This program is free software: you can redistribute it and/or modify
 *    it under the terms of the GNU General Public License as published by
 *    the Free Software Foundation, either version 3 of the License, or
 *    (at your option) any later version.
 *
 *    This program is distributed in the hope that it will be useful,
 *    but WITHOUT ANY WARRANTY; without even the implied warranty of
 *    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *    GNU General Public License for more details.
 *
 *    You should have received a copy of the GNU General Public License
 *    along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */

#ifndef ALPHA_COMPLEX_H_
#define ALPHA_COMPLEX_H_

// to construct a simplex_tree from Delaunay_triangulation
#include <gudhi/graph_simplicial_complex.h>
#include <gudhi/Simplex_tree.h>
#include <gudhi/Debug_utils.h>
// to construct a Delaunay_triangulation from a OFF file
#include <gudhi/Delaunay_triangulation_off_io.h>

#include <stdlib.h>
#include <math.h>  // isnan, fmax

#include <CGAL/Delaunay_triangulation.h>
#include <CGAL/Epick_d.h>

#include <iostream>
#include <vector>
#include <string>
#include <limits>  // NaN
#include <map>
#include <utility>  // std::pair
#include <stdexcept>

namespace Gudhi {

namespace alphacomplex {

/**
 * \brief Alpha complex data structure.
 *
 * \details
 * The data structure can be constructed from a CGAL Delaunay triangulation (for more informations on CGAL Delaunay 
 * triangulation, please refer to the corresponding chapter in page http://doc.cgal.org/latest/Triangulation/) or from
 * an OFF file (cf. Delaunay_triangulation_off_reader).
 * 
 * Please refer to \ref alpha_complex for examples.
 *
 */
template<class Kernel>
class Alpha_complex : public Simplex_tree<> {
 private:
  // From Simplex_tree
  // Type required to insert into a simplex_tree (with or without subfaces).
  typedef std::vector<Vertex_handle> Vector_vertex;

  // Simplex_result is the type returned from simplex_tree insert function.
  typedef typename std::pair<Simplex_handle, bool> Simplex_result;

  // Delaunay_triangulation type required to create an alpha-complex.
  typedef typename CGAL::Delaunay_triangulation<Kernel> Delaunay_triangulation;

  typedef typename Kernel::Compute_squared_radius_d Squared_Radius;
  typedef typename Kernel::Side_of_bounded_sphere_d Is_Gabriel;
  typedef typename Kernel::Point_dimension_d        Point_Dimension;

  typedef typename Kernel::Point_d Point_d;

  // Type required to compute squared radius, or side of bounded sphere on a vector of points.
  typedef typename std::vector<Point_d> Vector_of_CGAL_points;

  // Vertex_iterator type from CGAL.
  typedef typename Delaunay_triangulation::Vertex_iterator CGAL_vertex_iterator;

  // size_type type from CGAL.
  typedef typename Delaunay_triangulation::size_type size_type;

  // Double map type to switch from CGAL vertex iterator to simplex tree vertex handle and vice versa.
  typedef typename std::map< CGAL_vertex_iterator, Vertex_handle > Map_vertex_iterator_to_handle;
  //typedef typename std::map< Vertex_handle, CGAL_vertex_iterator > Map_vertex_handle_to_iterator;
  typedef typename std::vector< CGAL_vertex_iterator > Vector_vertex_iterator;

 private:
  /** \brief Map to switch from CGAL vertex iterator to simplex tree vertex handle.*/
  Map_vertex_iterator_to_handle vertex_iterator_to_handle_;
  /** \brief Vertex iterator vector to switch from simplex tree vertex handle to CGAL vertex iterator.
   * Vertex handles are inserted sequentially, starting at 0.*/
  Vector_vertex_iterator vertex_handle_to_iterator_;
  /** \brief Pointer on the CGAL Delaunay triangulation.*/
  Delaunay_triangulation* triangulation_;
  /** \brief Kernel for triangulation_ functions access.*/
  Kernel kernel_;

 public:
  /** \brief Alpha_complex constructor from an OFF file name.
   * Uses the Delaunay_triangulation_off_reader to construct the Delaunay triangulation required to initialize 
   * the Alpha_complex.
   *
   * @param[in] off_file_name OFF file [path and] name.
   * @param[in] max_alpha_square maximum for alpha square value. Default value is +\f$\infty\f$.
   */
  Alpha_complex(const std::string& off_file_name,
                Filtration_value max_alpha_square = std::numeric_limits<Filtration_value>::infinity())
      : triangulation_(nullptr) {
    Gudhi::Delaunay_triangulation_off_reader<Delaunay_triangulation> off_reader(off_file_name);
    if (!off_reader.is_valid()) {
      std::cerr << "Alpha_complex - Unable to read file " << off_file_name << "\n";
      exit(-1);  // ----- >>
    }
    triangulation_ = off_reader.get_complex();
    init(max_alpha_square);
  }

  /** \brief Alpha_complex constructor from a Delaunay triangulation.
   *
   * @param[in] triangulation_ptr Pointer on a <a target="_blank"
   * href="http://doc.cgal.org/latest/Triangulation/index.html#Chapter_Triangulations">
   * CGAL::Delaunay_triangulation<Kernel></a> \cite cgal:hdj-t-15b.
   * @param[in] max_alpha_square maximum for alpha square value. Default value is +\f$\infty\f$.
   */
  Alpha_complex(Delaunay_triangulation* triangulation_ptr,
                Filtration_value max_alpha_square = std::numeric_limits<Filtration_value>::infinity())
      : triangulation_(triangulation_ptr) {
   init(max_alpha_square);
  }

  /** \brief Alpha_complex constructor from a list of points.
   *
   * @param[in] points Range of points to triangulate. Points must be in Kernel::Point_d
   * @param[in] max_alpha_square maximum for alpha square value. Default value is +\f$\infty\f$.
   * 
   * The type InputPointRange must be a range for which std::begin and
   * std::end return input iterators on a Kernel::Point_d.
   * \warning In debug mode, the exception std::invalid_argument is thrown if an empty input point range is passed as
   * argument.
   */
  template<typename InputPointRange >
  Alpha_complex(const InputPointRange& points,
                Filtration_value max_alpha_square = std::numeric_limits<Filtration_value>::infinity())
      : triangulation_(nullptr) {
    auto first = std::begin(points);
    auto last = std::end(points);
    
    GUDHI_CHECK((first == last),
                std::invalid_argument ("Alpha_complex::Alpha_complex(InputPointRange) - Empty input point range"));
    
    if (first != last) {
      // point_dimension function initialization
      Point_Dimension point_dimension = kernel_.point_dimension_d_object();

      // Delaunay triangulation is point dimension minus one.
      triangulation_ = new Delaunay_triangulation(point_dimension(*first) - 1);
    
      size_type inserted = triangulation_->insert(first, last);
      if (inserted != (last -first)) {
        std::cerr << "Alpha_complex - insertion failed " << inserted << " != " << (last -first) << "\n";
        exit(-1);  // ----- >>
      }
      init(max_alpha_square);
    }
  }

  /** \brief Alpha_complex destructor.
   *
   * @warning Deletes the Delaunay triangulation.
   */
  ~Alpha_complex() {
    delete triangulation_;
  }

  /** \brief get_point returns the point corresponding to the vertex given as parameter.
   *
   * @param[in] vertex Vertex handle of the point to retrieve.
   * @return The point found.
   * @warning Exception std::out_of_range is thrown in case vertex is not found.
   */
  Point_d get_point(Vertex_handle vertex) const {
    return vertex_handle_to_iterator_.at(vertex)->point();
  }

 private:
  /** \brief Initialize the Alpha_complex from the Delaunay triangulation.
   *
   * @param[in] max_alpha_square maximum for alpha square value.
   * 
   * @warning Delaunay triangulation must be already constructed with at least one vertex and dimension must be more 
   * than 0.
   * 
   * Initialization can be launched once.
   */
  void init(Filtration_value max_alpha_square) {
    if (triangulation_ == nullptr) {
      std::cerr << "Alpha_complex init - Cannot init from a NULL triangulation\n";
      return;  // ----- >>
    }
    if (triangulation_->number_of_vertices() < 1) {
      std::cerr << "Alpha_complex init - Cannot init from a triangulation without vertices\n";
      return;  // ----- >>
    }
    if (triangulation_->maximal_dimension() < 1) {
      std::cerr << "Alpha_complex init - Cannot init from a zero-dimension triangulation\n";
      return;  // ----- >>
    }
    if (num_vertices() > 0) {
      std::cerr << "Alpha_complex init - Cannot init twice\n";
      return;  // ----- >>
    }

    set_dimension(triangulation_->maximal_dimension());
    // set_filtration to +inf for prune_above_filtration to be done (if necessary) 
    set_filtration(std::numeric_limits<Filtration_value>::infinity());

    // --------------------------------------------------------------------------------------------
    // double map to retrieve simplex tree vertex handles from CGAL vertex iterator and vice versa
    // Start to insert at handle = 0 - default integer value
    Vertex_handle vertex_handle = Vertex_handle();
    // Loop on triangulation vertices list
    for (CGAL_vertex_iterator vit = triangulation_->vertices_begin(); vit != triangulation_->vertices_end(); ++vit) {
      if (!triangulation_->is_infinite(*vit)) {
#ifdef DEBUG_TRACES
        std::cout << "Vertex insertion - " << vertex_handle << " -> " << vit->point() << std::endl;
#endif  // DEBUG_TRACES

        vertex_iterator_to_handle_.emplace(vit, vertex_handle);
        vertex_handle_to_iterator_.push_back(vit);
        vertex_handle++;
      }
    }
    // --------------------------------------------------------------------------------------------
    
    // --------------------------------------------------------------------------------------------
    // Simplex_tree construction from loop on triangulation finite full cells list
    for (auto cit = triangulation_->finite_full_cells_begin(); cit != triangulation_->finite_full_cells_end(); ++cit) {
      Vector_vertex vertexVector;
#ifdef DEBUG_TRACES
      std::cout << "Simplex_tree insertion ";
#endif  // DEBUG_TRACES
      for (auto vit = cit->vertices_begin(); vit != cit->vertices_end(); ++vit) {
        if (*vit != nullptr) {
#ifdef DEBUG_TRACES
          std::cout << " " << vertex_iterator_to_handle_[*vit];
#endif  // DEBUG_TRACES
          // Vector of vertex construction for simplex_tree structure
          vertexVector.push_back(vertex_iterator_to_handle_[*vit]);
        }
      }
#ifdef DEBUG_TRACES
      std::cout << std::endl;
#endif  // DEBUG_TRACES
      // Insert each simplex and its subfaces in the simplex tree - filtration is NaN
      Simplex_result insert_result = insert_simplex_and_subfaces(vertexVector,
                                                                 std::numeric_limits<double>::quiet_NaN());
    }
    // --------------------------------------------------------------------------------------------

    // --------------------------------------------------------------------------------------------
    // ### For i : d -> 0
    for (int decr_dim = dimension(); decr_dim >= 0; decr_dim--) {
      // ### Foreach Sigma of dim i
      for (auto f_simplex : skeleton_simplex_range(decr_dim)) {
        int f_simplex_dim = dimension(f_simplex);
        if (decr_dim == f_simplex_dim) {
          Vector_of_CGAL_points pointVector;
#ifdef DEBUG_TRACES
          std::cout << "Sigma of dim " << decr_dim << " is";
#endif  // DEBUG_TRACES
          for (auto vertex : simplex_vertex_range(f_simplex)) {
            pointVector.push_back(get_point(vertex));
#ifdef DEBUG_TRACES
            std::cout << " " << vertex;
#endif  // DEBUG_TRACES
          }
#ifdef DEBUG_TRACES
          std::cout << std::endl;
#endif  // DEBUG_TRACES
          // ### If filt(Sigma) is NaN : filt(Sigma) = alpha(Sigma)
          if (isnan(filtration(f_simplex))) {
            Filtration_value alpha_complex_filtration = 0.0;
            // No need to compute squared_radius on a single point - alpha is 0.0
            if (f_simplex_dim > 0) {
              // squared_radius function initialization
              Squared_Radius squared_radius = kernel_.compute_squared_radius_d_object();

              alpha_complex_filtration = squared_radius(pointVector.begin(), pointVector.end());
            }
            assign_filtration(f_simplex, alpha_complex_filtration);
#ifdef DEBUG_TRACES
            std::cout << "filt(Sigma) is NaN : filt(Sigma) =" << filtration(f_simplex) << std::endl;
#endif  // DEBUG_TRACES
          }
          propagate_alpha_filtration(f_simplex, decr_dim);
        }
      }
    }
    // --------------------------------------------------------------------------------------------

    // --------------------------------------------------------------------------------------------
    // As Alpha value is an approximation, we have to make filtration non decreasing while increasing the dimension
    make_filtration_non_decreasing();
    // Remove all simplices that have a filtration value greater than max_alpha_square
    prune_above_filtration(max_alpha_square);
    // --------------------------------------------------------------------------------------------
  }

  template<typename Simplex_handle>
  void propagate_alpha_filtration(Simplex_handle f_simplex, int decr_dim) {
    // ### Foreach Tau face of Sigma
    for (auto f_boundary : boundary_simplex_range(f_simplex)) {
#ifdef DEBUG_TRACES
      std::cout << " | --------------------------------------------------\n";
      std::cout << " | Tau ";
      for (auto vertex : simplex_vertex_range(f_boundary)) {
        std::cout << vertex << " ";
      }
      std::cout << "is a face of Sigma\n";
      std::cout << " | isnan(filtration(Tau)=" << isnan(filtration(f_boundary)) << std::endl;
#endif  // DEBUG_TRACES
      // ### If filt(Tau) is not NaN
      if (!isnan(filtration(f_boundary))) {
        // ### filt(Tau) = fmin(filt(Tau), filt(Sigma))
        Filtration_value alpha_complex_filtration = fmin(filtration(f_boundary), filtration(f_simplex));
        assign_filtration(f_boundary, alpha_complex_filtration);
#ifdef DEBUG_TRACES
        std::cout << " | filt(Tau) = fmin(filt(Tau), filt(Sigma)) = " << filtration(f_boundary) << std::endl;
#endif  // DEBUG_TRACES
        // ### Else
      } else {
        // No need to compute is_gabriel for dimension <= 2
        // i.e. : Sigma = (3,1) => Tau = 1
        if (decr_dim > 1) {
          // insert the Tau points in a vector for is_gabriel function
          Vector_of_CGAL_points pointVector;
          Vertex_handle vertexForGabriel = Vertex_handle();
          for (auto vertex : simplex_vertex_range(f_boundary)) {
            pointVector.push_back(get_point(vertex));
          }
          // Retrieve the Sigma point that is not part of Tau - parameter for is_gabriel function
          Point_d point_for_gabriel;
          for (auto vertex : simplex_vertex_range(f_simplex)) {
            point_for_gabriel = get_point(vertex);
            if (std::find(pointVector.begin(), pointVector.end(), point_for_gabriel) == pointVector.end()) {
              // vertex is not found in Tau
              vertexForGabriel = vertex;
              // No need to continue loop
              break;
            }
          }
          // is_gabriel function initialization
          Is_Gabriel is_gabriel = kernel_.side_of_bounded_sphere_d_object();
          bool is_gab = is_gabriel(pointVector.begin(), pointVector.end(), point_for_gabriel)
              != CGAL::ON_BOUNDED_SIDE;
#ifdef DEBUG_TRACES
          std::cout << " | Tau is_gabriel(Sigma)=" << is_gab << " - vertexForGabriel=" << vertexForGabriel << std::endl;
#endif  // DEBUG_TRACES
          // ### If Tau is not Gabriel of Sigma
          if (false == is_gab) {
            // ### filt(Tau) = filt(Sigma)
            Filtration_value alpha_complex_filtration = filtration(f_simplex);
            assign_filtration(f_boundary, alpha_complex_filtration);
#ifdef DEBUG_TRACES
            std::cout << " | filt(Tau) = filt(Sigma) = " << filtration(f_boundary) << std::endl;
#endif  // DEBUG_TRACES
          }
        }
      }
    }
  }
};

}  // namespace alphacomplex

}  // namespace Gudhi

#endif  // ALPHA_COMPLEX_H_