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1822 1823 1824 1825 1826 1827 1828 1829 1830 1831 1832 1833 1834 1835 1836 1837 1838 1839 1840 1841 1842 1843 1844 1845 | // Copyright (c) 1997, 2012 INRIA Sophia-Antipolis (France).
// All rights reserved.
//
// This file is part of CGAL (www.cgal.org).
// You can redistribute it and/or modify it under the terms of the GNU
// General Public License as published by the Free Software Foundation,
// either version 3 of the License, or (at your option) any later version.
//
// Licensees holding a valid commercial license may use this file in
// accordance with the commercial license agreement provided with the software.
//
// This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
// WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
//
// $URL$
// $Id$
//
//
// Author(s) : Tran Kai Frank DA
// Andreas Fabri <Andreas.Fabri@geometryfactory.com>
#ifndef CGAL_ALPHA_SHAPE_2_H
#define CGAL_ALPHA_SHAPE_2_H
#include <CGAL/license/Alpha_shapes_2.h>
#include <CGAL/basic.h>
#include <list>
#include <set>
#include <map>
#include <vector>
#include <algorithm>
#include <utility>
#include <iostream>
#include <CGAL/utility.h>
#include <CGAL/Unique_hash_map.h>
#include <CGAL/Triangulation_vertex_base_2.h>
#include <CGAL/Triangulation_face_base_2.h>
#include <CGAL/Alpha_shape_vertex_base_2.h>
#include <CGAL/Alpha_shape_face_base_2.h>
#include <CGAL/internal/Lazy_alpha_nt_2.h>
namespace CGAL {
template < class Dt,class ExactAlphaComparisonTag = Tag_false>
class Alpha_shape_2 : public Dt
{
// DEFINITION The class Alpha_shape_2<Dt> represents the family
// of alpha-shapes of points in a plane for all positive alpha. It
// maintains the underlying Delaunay triangulation which represents
// connectivity and order among its faces. Each k-dimensional face of the
// Delaunay triangulation is associated with an interval that specifies
// for which values of alpha the face belongs to the alpha-shape (sorted
// linear arrays resp. multimaps or interval trees). There are links
// between the intervals and the k-dimensional faces of the Delaunay
// triangulation (multimaps resp. std::hashtables).
//
//------------------------- TYPES ------------------------------------
public:
typedef Dt Triangulation;
typedef typename Dt::Geom_traits Gt;
typedef typename Dt::Triangulation_data_structure Tds;
typedef typename internal::Alpha_nt_selector_2<
Gt, ExactAlphaComparisonTag, typename Dt::Weighted_tag>::Type_of_alpha Type_of_alpha;
typedef typename internal::Alpha_nt_selector_2<
Gt, ExactAlphaComparisonTag, typename Dt::Weighted_tag>::Compute_squared_radius_2 Compute_squared_radius_2;
typedef typename internal::Alpha_nt_selector_2<
Gt, ExactAlphaComparisonTag, typename Dt::Weighted_tag>::Side_of_bounded_circle_2 Side_of_bounded_circle_2;
typedef Type_of_alpha NT;
typedef Type_of_alpha FT;
//check simplices are correctly instantiated
CGAL_static_assertion( (boost::is_same<NT, typename Dt::Face::NT>::value) );
CGAL_static_assertion( (boost::is_same<NT, typename Dt::Vertex::NT>::value) );
typedef typename Dt::Point Point;
typedef typename Gt::Point_2 Point_2;
typedef typename Gt::Segment_2 Segment;
typedef typename Gt::Line_2 Line;
typedef typename Dt::Face_handle Face_handle;
typedef typename Dt::Vertex_handle Vertex_handle;
typedef typename Dt::Edge Edge;
typedef typename Dt::Face_circulator Face_circulator;
typedef typename Dt::Edge_circulator Edge_circulator;
typedef typename Dt::Vertex_circulator Vertex_circulator;
typedef typename Dt::Finite_faces_iterator Finite_faces_iterator;
typedef typename Dt::Edge_iterator Edge_iterator;
typedef typename Dt::Finite_vertices_iterator Finite_vertices_iterator;
typedef typename Dt::Locate_type Locate_type;
typedef typename Dt::size_type size_type;
using Dt::finite_vertices_begin;
using Dt::finite_vertices_end;
using Dt::faces_begin;
using Dt::faces_end;
using Dt::edges_begin;
using Dt::edges_end;
using Dt::number_of_vertices;
using Dt::cw;
using Dt::ccw;
using Dt::VERTEX;
using Dt::EDGE;
using Dt::FACE;
using Dt::OUTSIDE_CONVEX_HULL;
using Dt::OUTSIDE_AFFINE_HULL;
using Dt::dimension;
using Dt::is_infinite;
// for backward compatibility
typedef Finite_vertices_iterator Vertex_iterator;
typedef Finite_faces_iterator Face_iterator;
private:
typedef std::multimap< Type_of_alpha, Face_handle > Interval_face_map;
typedef typename Interval_face_map::value_type Interval_face;
typedef typename Tds::Face::Interval_3 Interval3;
typedef std::multimap< Interval3, Edge > Interval_edge_map;
typedef typename Interval_edge_map::value_type Interval_edge;
typedef std::pair< Type_of_alpha, Type_of_alpha > Interval2;
typedef std::multimap< Interval2, Vertex_handle > Interval_vertex_map;
typedef typename Interval_vertex_map::value_type Interval_vertex;
typedef Face_handle const const_void;
typedef std::pair<const_void, int> const_Edge;
typedef std::vector< Type_of_alpha > Alpha_spectrum;
typedef std::vector< Segment > Vect_seg;
typedef Unique_hash_map< Face_handle, bool > Marked_face_set;
public:
typedef typename std::list< Vertex_handle >::iterator
Alpha_shape_vertices_iterator;
typedef typename std::list< Edge >::iterator Alpha_shape_edges_iterator;
typedef typename Alpha_spectrum::const_iterator Alpha_iterator;
// An iterator that allow to traverse the sorted sequence of
// different alpha-values. The iterator is bidirectional and
// non-mutable. Its value-type is Type_of_alpha
enum Classification_type {EXTERIOR, SINGULAR, REGULAR, INTERIOR};
// Distinguishes the different cases for classifying a
// k-dimensional face of the underlying Delaunay triangulation of
// the alpha-shape.
//
// `EXTERIOR' if the face does not belong to the alpha-complex.
//
// `SINGULAR' if the face belongs to the boundary of the
// alpha-shape, but is not incident to any higher-dimensional
// face of the alpha-complex
//
// `REGULAR' if face belongs to the boundary of the alpha-shape
// and is incident to a higher-dimensional face of the
// alpha-complex
//
// `INTERIOR' if the face belongs to the alpha-complex, but does
// not belong to the boundary of the alpha-shape
enum Mode {GENERAL, REGULARIZED};
// In general, an alpha shape is a non-connected, mixed-dimension
// polygon. Its regularized version is formed by the set of
// regular edges and their vertices
//------------------------ private VARIABLES -------------------------
private:
// only finite edges and faces are inserted into the maps
Interval_face_map _interval_face_map;
Interval_edge_map _interval_edge_map;
Interval_vertex_map _interval_vertex_map;
Alpha_spectrum _alpha_spectrum;
Type_of_alpha _alpha;
Mode _mode;
// should be constants
Type_of_alpha Infinity;
Type_of_alpha UNDEFINED;
mutable std::list< Vertex_handle > Alpha_shape_vertices_list;
mutable std::list< Edge > Alpha_shape_edges_list;
mutable bool use_vertex_cache;
mutable bool use_edge_cache;
public:
//------------------------- CONSTRUCTORS ------------------------------
// Introduces an empty alpha-shape `A' for a positive
// alpha-value `alpha'. Precondition: `alpha' >= 0.
Alpha_shape_2(Type_of_alpha alpha = Type_of_alpha(0),
Mode m = GENERAL)
: _alpha(alpha), _mode(m), Infinity(-1), UNDEFINED(-2),
use_vertex_cache(false), use_edge_cache(false)
{}
// Introduces an alpha-shape `A' for a positive alpha-value
// `alpha' that is initialized with the points in the range
// from first to last
template <class InputIterator>
Alpha_shape_2(const InputIterator& first,
const InputIterator& last,
const Type_of_alpha& alpha = Type_of_alpha(0),
Mode m = GENERAL)
: _alpha(alpha), _mode(m), Infinity(-1), UNDEFINED(-2) ,
use_vertex_cache(false), use_edge_cache(false)
{
Dt::insert(first, last);
if (dimension() == 2)
{
// Compute the associated _interval_face_map
initialize_interval_face_map();
// Compute the associated _interval_edge_map
initialize_interval_edge_map();
// Compute the associated _interval_vertex_map
initialize_interval_vertex_map();
// merge the two maps
initialize_alpha_spectrum();
}
}
// Introduces an alpha-shape `A' for a positive alpha-value
// `alpha' that is initialized with the triangulation
Alpha_shape_2(Dt& dt,
const Type_of_alpha& alpha = Type_of_alpha(0),
Mode m = GENERAL)
: _alpha(alpha), _mode(m), Infinity(-1), UNDEFINED(-2) ,
use_vertex_cache(false), use_edge_cache(false)
{
Dt::swap(dt);
if (dimension() == 2)
{
// Compute the associated _interval_face_map
initialize_interval_face_map();
// Compute the associated _interval_edge_map
initialize_interval_edge_map();
// Compute the associated _interval_vertex_map
initialize_interval_vertex_map();
// merge the two maps
initialize_alpha_spectrum();
}
}
public:
//----------- OUTPUT POINTS CONNECTED BY PAIRS ----------------------
std::list<Point_2> Output();
std::ostream& op_ostream(std::ostream& os) const;
//----------------------- OPERATIONS ---------------------------------
// Introduces an alpha-shape `A' for a positive alpha-value
// `alpha' that is initialized with the points in the range
// from first to last
template < class InputIterator >
std::ptrdiff_t make_alpha_shape(const InputIterator& first,
const InputIterator& last)
{
clear();
size_type n = Dt::insert(first, last);
if (dimension() == 2)
{
// Compute the associated _interval_face_map
initialize_interval_face_map();
// Compute the associated _interval_edge_map
initialize_interval_edge_map();
// Compute the associated _interval_vertex_map
initialize_interval_vertex_map();
// merge the two maps
initialize_alpha_spectrum();
}
return n;
}
private :
//--------------------- INITIALIZATION OF PRIVATE MEMBERS -----------
void initialize_interval_face_map();
void initialize_interval_edge_map();
void initialize_interval_vertex_map();
void initialize_alpha_spectrum();
//---------------------------------------------------------------------
public:
void clear()
{
// clears the structure
Dt::clear();
_interval_face_map.clear();
_interval_edge_map.clear();
_interval_vertex_map.clear();
_alpha_spectrum.clear();
Alpha_shape_vertices_list.clear();
Alpha_shape_edges_list.clear();
set_alpha(Type_of_alpha(0));
set_mode(GENERAL);
}
//----------------------- PRIVATE MEMBERS --------------------------
private:
struct Less
{
bool operator()(const Interval_edge& ie,
const Type_of_alpha& alpha)
{
return ie.first.first < alpha;
}
bool operator()( const Type_of_alpha& alpha,
const Interval_edge& ie)
{
return alpha < ie.first.first;
}
// Needed for STL implementations of upper_bound which in debug mode
// check sortedness of range
bool operator()(const Interval_edge& ie,
const Interval_edge& ie2) const
{
return ie < ie2;
}
};
//----------------------- ACCESS TO PRIVATE MEMBERS -----------------
private:
Type_of_alpha find_interval(const Face_handle& f) const
{
return f->get_alpha();
// return the value Alpha f the face f
}
Interval3 find_interval(const_Edge e) const
{ // corriger le parametrage
return (e.first)->get_ranges(e.second);
// return the Interval3 for the edge n
}
//---------------------------------------------------------------------
public:
Type_of_alpha set_alpha(const Type_of_alpha& alpha)
{
// Sets the alpha-value to `alpha'. Precondition: `alpha' >= 0.
// Returns the previous alpha
Type_of_alpha previous_alpha = _alpha;
_alpha = alpha;
use_vertex_cache = false;
use_edge_cache = false;
return previous_alpha;
}
const Type_of_alpha& get_alpha() const
{
// Returns the current alpha-value.
return _alpha;
}
const Type_of_alpha& get_nth_alpha(size_type n) const
{
// Returns the n-th alpha-value.
// n < size()
if (! _alpha_spectrum.empty())
return _alpha_spectrum[n];
else
return UNDEFINED;
}
size_type number_of_alphas() const
{
// Returns the number of not necessary different alpha-values
return _alpha_spectrum.size();
}
//---------------------------------------------------------------------
private:
// the dynamic version is not yet implemented
// desactivate the triangulation member functions
Vertex_handle insert(const Point& p);
// Inserts point `p' in the alpha shape and returns the
// corresponding vertex of the underlying Delaunay triangulation.
// If point `p' coincides with an already existing vertex, this
// vertex is returned and the alpha shape remains unchanged.
// Otherwise, the vertex is inserted in the underlying Delaunay
// triangulation and the associated intervals are updated.
void remove(Vertex_handle v);
// Removes the vertex from the underlying Delaunay triangulation.
// The created hole is retriangulated and the associated intervals
// are updated.
//---------------------------------------------------------------------
public:
Mode set_mode(Mode mode = GENERAL )
{
// Sets `A' to its general or regularized version. Returns the
// previous mode.
Mode previous_mode = _mode;
_mode = mode;
return previous_mode;
}
Mode get_mode() const
{
// Returns whether `A' is general or regularized.
return _mode;
}
//---------------------------------------------------------------------
private:
void
update_alpha_shape_vertex_list()const;
//---------------------------------------------------------------------
void
update_alpha_shape_edges_list() const;
//---------------------------------------------------------------------
public:
Alpha_shape_vertices_iterator alpha_shape_vertices_begin() const
{
if(!use_vertex_cache){
update_alpha_shape_vertex_list();
}
return Alpha_shape_vertices_list.begin();
}
// for backward compatibility
Alpha_shape_vertices_iterator Alpha_shape_vertices_begin()
{
return alpha_shape_vertices_begin();
}
//---------------------------------------------------------------------
Alpha_shape_vertices_iterator alpha_shape_vertices_end() const
{
return Alpha_shape_vertices_list.end();
}
Alpha_shape_vertices_iterator Alpha_shape_vertices_end() const
{
return Alpha_shape_vertices_list.end();
}
//---------------------------------------------------------------------
Alpha_shape_edges_iterator alpha_shape_edges_begin() const
{
if(!use_edge_cache){
update_alpha_shape_edges_list();
}
return Alpha_shape_edges_list.begin();
}
Alpha_shape_edges_iterator Alpha_shape_edges_begin() const
{
return alpha_shape_edges_begin();
}
//---------------------------------------------------------------------
Alpha_shape_edges_iterator alpha_shape_edges_end() const
{
return Alpha_shape_edges_list.end();
}
Alpha_shape_edges_iterator Alpha_shape_edges_end() const
{
return Alpha_shape_edges_list.end();
}
public:
// Traversal of the alpha-Values
//
// The alpha shape class defines an iterator that allows to
// visit the sorted sequence of alpha-values. This iterator is
// non-mutable and bidirectional. Its value type is Type_of_alpha.
Alpha_iterator alpha_begin() const
{
// Returns an iterator that allows to traverse the sorted sequence
// of alpha-values of `A'.
return _alpha_spectrum.begin();
}
Alpha_iterator alpha_end() const
{
// Returns the corresponding past-the-end iterator.
return _alpha_spectrum.end();
}
Alpha_iterator alpha_find(const Type_of_alpha& alpha) const
{
// Returns an iterator pointing to an element with alpha-value
// `alpha', or the corresponding past-the-end iterator if such an
// element is not found.
return std::find(_alpha_spectrum.begin(),
_alpha_spectrum.end(),
alpha);
}
Alpha_iterator alpha_lower_bound(const Type_of_alpha& alpha) const
{
// Returns an iterator pointing to the first element with
// alpha-value not less than `alpha'.
return std::lower_bound(_alpha_spectrum.begin(),
_alpha_spectrum.end(),
alpha);
}
Alpha_iterator alpha_upper_bound(const Type_of_alpha& alpha) const
{
// Returns an iterator pointing to the first element with
// alpha-value greater than `alpha'.
return std::upper_bound(_alpha_spectrum.begin(),
_alpha_spectrum.end(),
alpha);
}
//--------------------- PREDICATES -----------------------------------
// the classification predicates take
// amortized const time if STL_STD::HASH_TABLES
// O(log #alpha_shape ) otherwise
Classification_type classify(const Point& p ) const
{
return classify( p, get_alpha());
}
Classification_type classify(const Point& p,
const Type_of_alpha& alpha) const
{
// Classifies a point `p' with respect to `A'.
Locate_type type;
int i;
Face_handle pFace = this->locate(p, type, i);
switch (type)
{
case VERTEX : return classify(pFace->vertex(i), alpha);
case EDGE : return classify(pFace, i, alpha);
case FACE : return classify(pFace, alpha);
case OUTSIDE_CONVEX_HULL :
case OUTSIDE_AFFINE_HULL : return EXTERIOR;
default : return EXTERIOR;
}
}
//---------------------------------------------------------------------
Classification_type classify(const Face_handle& f) const
{
// Classifies the face `f' of the underlying Delaunay
// triangulation with respect to `A'.
return classify(f, get_alpha());
}
Classification_type classify(const Face_handle& f,
const Type_of_alpha& alpha) const
{
// Classifies the face `f' of the underlying Delaunay
// triangulation with respect to `A'.
// we consider close circles :
// f->radius < alpha <=> f exterior
// problem the operator [] is non-const
if (is_infinite(f)) return EXTERIOR;
// the version that computes the squared radius seems to be
// much faster
return (find_interval(f) <= alpha) ?
INTERIOR :
EXTERIOR;
}
//---------------------------------------------------------------------
Classification_type classify(const Edge& edge) const
{
return classify(edge.first, edge.second, get_alpha());
}
Classification_type classify(const Face_handle& f,
int i) const
{
return classify(f, i, get_alpha());
}
Classification_type classify(const Edge& edge,
const Type_of_alpha& alpha) const
{
return classify(edge.first, edge.second, alpha);
}
Classification_type classify(const Face_handle& f,
int i,
const Type_of_alpha& alpha) const;
//---------------------------------------------------------------------
Classification_type classify(const Vertex_handle& v) const
{
return classify(v, get_alpha());
}
Classification_type classify(const Vertex_handle& v,
const Type_of_alpha& alpha) const;
//--------------------- NB COMPONENTS ---------------------------------
int
number_solid_components() const
{
return number_of_solid_components(get_alpha());
}
int
number_of_solid_components() const
{
return number_of_solid_components(get_alpha());
}
size_type
number_solid_components(const Type_of_alpha& /* alpha */) const
{
return number_of_solid_components(get_alpha());
}
size_type
number_of_solid_components(const Type_of_alpha& alpha) const;
private:
void traverse(const Face_handle& pFace,
Marked_face_set& marked_face_set,
const Type_of_alpha alpha) const;
// class Line_face_circulator;
//----------------------------------------------------------------------
public:
Alpha_iterator find_optimal_alpha(size_type nb_components);
private:
Type_of_alpha find_alpha_solid() const;
//---------------------- PREDICATES ------------------------------------
private:
bool is_attached(const Face_handle& f, int i) const
{
Bounded_side b = Side_of_bounded_circle_2()(*this)(f->vertex(cw(i))->point(),
f->vertex(ccw(i))->point(),
f->vertex(i)->point());
return (b == ON_BOUNDED_SIDE) ? true : false;
}
//-------------------- GEOMETRIC PRIMITIVES ----------------------------
Type_of_alpha squared_radius(const Face_handle& f) const
{
return Compute_squared_radius_2()(*this)(f->vertex(0)->point(),
f->vertex(1)->point(),
f->vertex(2)->point());
}
Type_of_alpha squared_radius(const Face_handle& f, int i) const
{
return Compute_squared_radius_2()(*this)(f->vertex(ccw(i))->point(),
f->vertex(cw(i))->point());
}
//---------------------------------------------------------------------
private:
// prevent default copy constructor and default assigment
Alpha_shape_2(const Alpha_shape_2& A);
Alpha_shape_2& operator=(const Alpha_shape_2& A);
public:
// to debug
void print_edge_map();
};
//---------------------------------------------------------------------
//----------------------- MEMBER FUNCTIONS -----------------------------
//---------------------------------------------------------------------
template < class Dt, class EACT >
void
Alpha_shape_2<Dt,EACT>::initialize_interval_face_map()
{
Type_of_alpha alpha_f;
// only finite faces
for(Finite_faces_iterator face_it = faces_begin(); face_it != faces_end(); ++face_it)
{
alpha_f = squared_radius(face_it);
_interval_face_map.insert(Interval_face(alpha_f, face_it));
// cross references
face_it->set_alpha(alpha_f);
}
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
void
Alpha_shape_2<Dt,EACT>::initialize_interval_edge_map()
{
Edge_iterator edge_it;
Edge edge;
// only finite faces
for( edge_it = edges_begin();
edge_it != edges_end();
++edge_it)
{
Interval3 interval;
edge = (*edge_it);
Face_handle pFace = edge.first;
int i = edge.second;
Face_handle pNeighbor = pFace->neighbor(i);
int Neigh_i = pNeighbor->index(pFace);
// not on the convex hull
if(!is_infinite(pFace) && !is_infinite(pNeighbor))
{
Type_of_alpha squared_radius_Face =
find_interval(pFace);
Type_of_alpha squared_radius_Neighbor =
find_interval(pNeighbor);
if (squared_radius_Neighbor < squared_radius_Face)
{
edge = Edge(pNeighbor, Neigh_i);
Type_of_alpha coord_tmp = squared_radius_Face;
squared_radius_Face = squared_radius_Neighbor;
squared_radius_Neighbor = coord_tmp;
}
interval = (is_attached(pFace, i) ||
is_attached(pNeighbor, Neigh_i)) ?
make_triple(UNDEFINED,
squared_radius_Face,
squared_radius_Neighbor):
make_triple(squared_radius(pFace, i),
squared_radius_Face,
squared_radius_Neighbor);
}
else
{ // on the convex hull
if(is_infinite(pFace))
{
if (!is_infinite(pNeighbor))
{
interval = (is_attached(pNeighbor,
Neigh_i)) ?
make_triple(UNDEFINED,
find_interval(pNeighbor),
Infinity):
make_triple(squared_radius(pNeighbor,
Neigh_i),
find_interval(pNeighbor),
Infinity);
edge = Edge(pNeighbor, Neigh_i);
}
else
{
// both faces are infinite by definition unattached
// the edge is finite by construction
CGAL_triangulation_precondition((is_infinite(pNeighbor)
&& is_infinite(pFace)));
interval = make_triple(squared_radius(pFace, i),
Infinity,
Infinity);
}
}
else
{ // is_infinite(pNeighbor)
CGAL_triangulation_precondition((is_infinite(pNeighbor)
&& !is_infinite(pFace)));
if (is_attached(pFace, i))
interval = make_triple(UNDEFINED,
find_interval(pFace),
Infinity);
else
interval = make_triple(squared_radius(pFace, i),
find_interval(pFace),
Infinity);
}
}
_interval_edge_map.insert(Interval_edge(interval, edge));
// cross-links
(edge.first)->set_ranges(edge.second,interval);
// MY : to fix a bug I store the interval of the edge in both faces
Face_handle neighbor = (edge.first)->neighbor(edge.second);
int ni = neighbor->index(edge.first);
neighbor->set_ranges( ni, interval);
}
// Remark:
// The interval_edge_map will be sorted as follows
// first the attached edges on the convex hull
// second not on the convex hull
// third the un-attached edges on the convex hull
// finally not on the convex hull
//
// if we are in regularized mode we should sort differently
// by the second third first Key
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
void
Alpha_shape_2<Dt,EACT>::initialize_interval_vertex_map()
{
Type_of_alpha alpha_mid_v;
Type_of_alpha alpha_max_v;
Type_of_alpha alpha_f;
Finite_vertices_iterator vertex_it;
for( vertex_it = finite_vertices_begin();
vertex_it != finite_vertices_end();
++vertex_it)
{
Vertex_handle v = vertex_it;
Face_handle f;
alpha_max_v = Type_of_alpha(0);
alpha_mid_v = (!_interval_face_map.empty() ?
(--_interval_face_map.end())->first :
Type_of_alpha(0));
//----------------- examine incident edges --------------------------
// // if we used Edelsbrunner and Muecke's definition
// // singular means not incident to any higher-dimensional face
// // regular means incident to a higher-dimensional face
// Edge_circulator edge_circ = this->incident_edges(v),
// edge_done(edge_circ);
// do
// {
// f = (*edge_circ).first;
// int i = (*edge_circ).second;
// if (is_infinite(f, i))
// {
// alpha_max_v = Infinity;
// }
// else
// {
// Interval3 interval3 = find_interval(const_Edge(f, i));
// alpha_mid_v = (interval3.first != UNDEFINED) ?
// (CGAL::min)(alpha_mid_v, interval3.first):
// (CGAL::min)(alpha_mid_v, interval3.second);
// if (alpha_max_v != Infinity)
// {
// alpha_max_v = (interval3.third != Infinity) ?
// (CGAL::max)(alpha_max_v, interval3.third):
// Infinity;
// }
// }
// }
// while(++edge_circ != edge_done);
//-------------- examine incident faces --------------------------
// we use a different definition than Edelsbrunner and Muecke
// singular means not incident to any 2-dimensional face
// regular means incident to a 2-dimensional face
Face_circulator face_circ = this->incident_faces(v),
done = face_circ;
if (!face_circ.is_empty())
{
do
{
f = face_circ;
if (is_infinite(f))
{
alpha_max_v = Infinity;
// continue;
}
else
{
alpha_f = find_interval(f);
// if we define singular as not incident to a 2-dimensional
// face
alpha_mid_v = (CGAL::min)(alpha_mid_v, alpha_f);
if (alpha_max_v != Infinity)
alpha_max_v = (CGAL::max)(alpha_max_v, alpha_f);
}
}
while(++face_circ != done);
}
Interval2 interval = std::make_pair(alpha_mid_v, alpha_max_v);
_interval_vertex_map.insert(Interval_vertex(interval, vertex_it));
// cross references
vertex_it->set_range(interval);
}
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
void
Alpha_shape_2<Dt,EACT>::initialize_alpha_spectrum()
{
// skip the attached edges
// <=> _interval_edge_map.first.first == UNDEFINED
typename Interval_edge_map::iterator
edge_it = std::upper_bound(_interval_edge_map.begin(),
_interval_edge_map.end(),
UNDEFINED,
Less());
// merge the maps which is sorted and contains the alpha-values
// of the unattached edges and the triangles.
// eliminate duplicate values due to for example attached edges
// merge and copy from STL since assignment should be function object
typename Interval_face_map::iterator
face_it = _interval_face_map.begin();
_alpha_spectrum.reserve(_interval_face_map.size() +
_interval_edge_map.size()/ 2 );
// should be only the number of unattached edges
// size_type nb_unattached_edges;
// distance(edge_it, _interval_edge_map.end(), nb_unattached_edges);
// however the distance function is expensive
while (edge_it != _interval_edge_map.end() ||
face_it != _interval_face_map.end())
{
if (face_it != _interval_face_map.end() &&
(edge_it == _interval_edge_map.end() ||
((*face_it).first < (*edge_it).first.first)))
{
if (((_alpha_spectrum.empty() ||
_alpha_spectrum.back() < (*face_it).first)) &&
((*face_it).first > Type_of_alpha(0)))
_alpha_spectrum.push_back((*face_it).first);
face_it++;
}
else
{
if (((_alpha_spectrum.empty() ||
_alpha_spectrum.back() < (*edge_it).first.first)) &&
(((*edge_it).first.first) > Type_of_alpha(0)))
_alpha_spectrum.push_back((*edge_it).first.first);
edge_it++;
}
}
while (edge_it != _interval_edge_map.end())
{
if (((_alpha_spectrum.empty() ||
_alpha_spectrum.back() < (*edge_it).first.first))&&
(((*edge_it).first.first) > Type_of_alpha(0)))
_alpha_spectrum.push_back((*edge_it).first.first);
edge_it++;
}
while (face_it != _interval_face_map.end())
{
if (((_alpha_spectrum.empty() ||
_alpha_spectrum.back() < (*face_it).first))&&
((*face_it).first > Type_of_alpha(0)))
_alpha_spectrum.push_back((*face_it).first);
face_it++;
}
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
void
Alpha_shape_2<Dt,EACT>::update_alpha_shape_vertex_list()const {
//typedef typename Alpha_shape_2<Dt,EACT>::Interval_vertex_map
// Interval_vertex_map;
typename Interval_vertex_map::const_iterator vertex_alpha_it;
//const typename Alpha_shape_2<Dt,EACT>::Interval2* pInterval2;
const Interval2* pInterval2;
Vertex_handle v;
Alpha_shape_vertices_list.clear();
// write the regular vertices
for (vertex_alpha_it = _interval_vertex_map.begin();
vertex_alpha_it != _interval_vertex_map.end() &&
(*vertex_alpha_it).first.first <= get_alpha();
++vertex_alpha_it)
{
pInterval2 = &(*vertex_alpha_it).first;
if((pInterval2->second > get_alpha()
|| pInterval2->second == Infinity))
{
// alpha must be larger than the min boundary
// and alpha is smaller than the upper boundary
// which might be infinity
// write the vertex
v = (*vertex_alpha_it).second;
CGAL_triangulation_assertion((classify(v) == REGULAR));
Alpha_shape_vertices_list.push_back(v);
}
}
if (get_mode() == Alpha_shape_2<Dt,EACT>::GENERAL)
{
// write the singular vertices
for (;
vertex_alpha_it != _interval_vertex_map.end();
++vertex_alpha_it)
{
v = (*vertex_alpha_it).second;
CGAL_triangulation_assertion((classify(v) == SINGULAR));
Alpha_shape_vertices_list.push_back(v);
}
}
use_vertex_cache = true;
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
void
Alpha_shape_2<Dt,EACT>::update_alpha_shape_edges_list() const
{
// Writes the edges of the alpha shape `A' for the current $\alpha$-value
// to the container where 'out' refers to. Returns an output iterator
// which is the end of the constructed range.
//typedef typename Alpha_shape_2<Dt,EACT>::Interval_edge_map Interval_edge_map;
typename Interval_edge_map::const_iterator edge_alpha_it;
//const typename Alpha_shape_2<Dt,EACT>::Interval3* pInterval;
const Interval3* pInterval;
Alpha_shape_edges_list.clear();
if (get_mode() == REGULARIZED)
{
// it is much faster looking at the sorted intervals
// than looking at all sorted faces
// alpha must be larger than the mid boundary
// and alpha is smaller than the upper boundary
for (edge_alpha_it = _interval_edge_map.begin();
edge_alpha_it != _interval_edge_map.end() &&
(*edge_alpha_it).first.first <= get_alpha();
++edge_alpha_it)
{
pInterval = &(*edge_alpha_it).first;
CGAL_triangulation_assertion(pInterval->second != Infinity);
// since this happens only for convex hull of dimension 2
// thus singular
if(pInterval->second <= get_alpha() &&
(pInterval->third > get_alpha()
|| pInterval->third == Infinity))
{
// alpha must be larger than the mid boundary
// and alpha is smaller than the upper boundary
// which might be infinity
// visualize the boundary
CGAL_triangulation_assertion((classify((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second)
== REGULAR));
Alpha_shape_edges_list.push_back(Edge((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second));
}
}
}
else
{ // get_mode() == GENERAL -------------------------------------------
// draw the edges
for (edge_alpha_it = _interval_edge_map.begin();
edge_alpha_it != _interval_edge_map.end() &&
(*edge_alpha_it).first.first <= get_alpha();
++edge_alpha_it)
{
pInterval = &(*edge_alpha_it).first;
if (pInterval->first == UNDEFINED)
{
CGAL_triangulation_assertion(pInterval->second != Infinity);
// since this happens only for convex hull of dimension 2
// thus singular
if(pInterval->second <= get_alpha() &&
(pInterval->third > get_alpha()
|| pInterval->third == Infinity))
{
// alpha must be larger than the mid boundary
// and alpha is smaller than the upper boundary
// which might be infinity
// visualize the boundary
CGAL_triangulation_assertion((classify((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second)
== REGULAR));
Alpha_shape_edges_list.push_back(Edge((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second));
}
}
else
{
if(pInterval->third > get_alpha()
|| pInterval->third == Infinity)
{
// if alpha is smaller than the upper boundary
// which might be infinity
// visualize the boundary
CGAL_triangulation_assertion(((classify((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second)
== REGULAR)
|| (classify((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second)
== SINGULAR)));
Alpha_shape_edges_list.push_back(Edge((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second));
}
}
}
}
use_edge_cache = true;
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
typename Alpha_shape_2<Dt,EACT>::Classification_type
Alpha_shape_2<Dt,EACT>::classify(const Face_handle& f, int i,
const Type_of_alpha& alpha) const
{
// Classifies the edge `e' of the underlying Delaunay
// triangulation with respect to `A'.
// the version that uses a simplified version without crosslinks
// is much slower
if (is_infinite(f, i))
return EXTERIOR;
// we store only finite edges in _edge_interval_map
Interval3 interval = find_interval(const_Edge(f, i));
// (*(_edge_interval_map.find(const_Edge(f, i)))).second;
if (alpha < interval.second)
{
if (get_mode() == REGULARIZED ||
interval.first == UNDEFINED ||
alpha < interval.first)
return EXTERIOR;
else // alpha >= interval.first
return SINGULAR;
}
else
{ // alpha >= interval.second
if (interval.third == Infinity ||
alpha < interval.third)
return REGULAR;
else // alpha >= interval.third
return INTERIOR;
}
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
typename Alpha_shape_2<Dt,EACT>::Classification_type
Alpha_shape_2<Dt,EACT>::classify(const Vertex_handle& v,
const Type_of_alpha& alpha) const
{
// Classifies the vertex `v' of the underlying Delaunay
// triangulation with respect to `A'.
Interval2 interval = v->get_range();
if (alpha < interval.first)
{
if (get_mode() == REGULARIZED)
return EXTERIOR;
else // general => vertices are never exterior
return SINGULAR;
}
else
{ // alpha >= interval.first
if (interval.second == Infinity ||
alpha < interval.second)
return REGULAR;
else // alpha >= interval.second
return INTERIOR;
}
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
typename Alpha_shape_2<Dt,EACT>::size_type
Alpha_shape_2<Dt,EACT>::number_of_solid_components(const Type_of_alpha& alpha) const
{
// Determine the number of connected solid components
typedef typename Marked_face_set::Data Data;
Marked_face_set marked_face_set(false);
Finite_faces_iterator face_it;
size_type nb_solid_components = 0;
if (number_of_vertices()==0)
return 0;
// only finite faces
for( face_it = faces_begin();
face_it != faces_end();
++face_it)
{
Face_handle pFace = face_it;
CGAL_triangulation_postcondition( pFace != NULL);
if (classify(pFace, alpha) == INTERIOR){
Data& data = marked_face_set[pFace];
if(data == false)
{
// we traverse only interior faces
traverse(pFace, marked_face_set, alpha);
nb_solid_components++;
}
}
}
return nb_solid_components;
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
void
Alpha_shape_2<Dt,EACT>::traverse(const Face_handle& pFace,
Marked_face_set& marked_face_set,
const Type_of_alpha alpha) const
{
typedef typename Marked_face_set::Data Data;
std::list<Face_handle> faces;
faces.push_back(pFace);
Face_handle pNeighbor, fh;
while(! faces.empty()){
fh = faces.front();
faces.pop_front();
for (int i=0; i<3; i++)
{
pNeighbor = fh->neighbor(i);
CGAL_triangulation_assertion(pNeighbor != NULL);
if (classify(pNeighbor, alpha) == INTERIOR){
Data& data = marked_face_set[pNeighbor];
if(data == false){
data = true;
faces.push_back(pNeighbor);
}
}
}
}
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
typename Alpha_shape_2<Dt,EACT>::Alpha_iterator
Alpha_shape_2<Dt,EACT>::find_optimal_alpha(size_type nb_components)
{
// find the minimum alpha that satisfies the properties
// (1) nb_components solid components
// (2) all data points on the boundary or in its interior
Type_of_alpha alpha = find_alpha_solid();
// from this alpha on the alpha_solid satisfies property (2)
Alpha_iterator first = alpha_lower_bound(alpha);
if (number_of_solid_components(alpha) == nb_components)
{
if ((first+1) < alpha_end())
return (first+1);
else
return first;
}
// do binary search on the alpha values
// number_of_solid_components() is a monotone function
// if we start with find_alpha_solid
Alpha_iterator last = alpha_end();
Alpha_iterator middle;
std::ptrdiff_t len = last - first - 1;
std::ptrdiff_t half;
while (len > 0)
{
half = len / 2;
middle = first + half;
#ifdef CGAL_DEBUG_ALPHA_SHAPE_2
std::cout << "first : " << *first << " last : " << *(first+len)
<< " mid : " << *middle
<< " nb comps : " << number_of_solid_components(*middle)
<< std::endl;
#endif // CGAL_DEBUG_ALPHA_SHAPE_2
if (number_of_solid_components(*middle) > nb_components)
{
first = middle + 1;
len = len - half - 1;
}
else
{ // number_of_solid_components(*middle) <= nb_components
len = half;
}
}
if ((first+1) < alpha_end())
return (first+1);
else
return first;
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
typename Alpha_shape_2<Dt,EACT>::Type_of_alpha
Alpha_shape_2<Dt,EACT>::find_alpha_solid() const
{
// compute the minumum alpha such that all data points
// are either on the boundary or in the interior
// not necessarily connected
// starting point for searching
// takes O(#alpha_shape) time
Type_of_alpha alpha_solid = 0;
if (number_of_vertices()<3) return alpha_solid;
Finite_vertices_iterator vertex_it;
// only finite vertices
for( vertex_it = finite_vertices_begin();
vertex_it != finite_vertices_end();
++vertex_it)
{
Type_of_alpha alpha_min_v = (--_interval_face_map.end())->first;
Face_circulator face_circ = this->incident_faces(vertex_it);
Face_circulator done = face_circ;
do
{
Face_handle f = face_circ;
if (! is_infinite(f))
alpha_min_v = (CGAL::min)(find_interval(f),
alpha_min_v);
}
while (++face_circ != done);
alpha_solid = (CGAL::max)(alpha_min_v, alpha_solid);
}
return alpha_solid;
}
//-------------------------------------------------------------------------
template < class Dt, class EACT >
std::ostream&
Alpha_shape_2<Dt,EACT>::op_ostream(std::ostream& os) const
{
typedef typename Alpha_shape_2<Dt,EACT>::Interval_vertex_map Interval_vertex_map ;
typedef typename Alpha_shape_2<Dt,EACT>::Interval_edge_map Interval_edge_map;
typename Interval_vertex_map::const_iterator vertex_alpha_it;
const typename Alpha_shape_2<Dt,EACT>::Interval2* pInterval2;
typename Interval_edge_map::const_iterator edge_alpha_it;
const typename Alpha_shape_2<Dt,EACT>::Interval3* pInterval;
Unique_hash_map< Vertex_handle, size_type > V;
size_type number_of_vertices = 0;
if (get_mode() == Alpha_shape_2<Dt,EACT>::REGULARIZED)
{
typename Alpha_shape_2<Dt,EACT>::Vertex_handle v;
for (vertex_alpha_it = _interval_vertex_map.begin();
vertex_alpha_it != _interval_vertex_map.end() &&
(*vertex_alpha_it).first.first <= get_alpha();
++vertex_alpha_it)
{
pInterval2 = &(*vertex_alpha_it).first;
#ifdef CGAL_DEBUG_ALPHA_SHAPE_2
typename Alpha_shape_2<Dt,EACT>::Type_of_alpha alpha =
get_alpha();
typename Alpha_shape_2<Dt,EACT>::Type_of_alpha alpha_mid =
pInterval2->first;
typename Alpha_shape_2<Dt,EACT>::Type_of_alpha alpha_max =
pInterval2->second;
#endif // CGAL_DEBUG_ALPHA_SHAPE_2
if((pInterval2->second > get_alpha()
|| pInterval2->second == Infinity))
{
// alpha must be larger than the min boundary
// and alpha is smaller than the upper boundary
// which might be infinity
// write the vertex
v = (*vertex_alpha_it).second;
CGAL_triangulation_assertion((classify(v) ==
Alpha_shape_2<Dt,EACT>::REGULAR));
// if we used Edelsbrunner and Muecke's definition
// regular means incident to a higher-dimensional face
// we would write too many vertices
V[v] = number_of_vertices++;
os << v->point() << std::endl;
}
}
// the vertices are oriented counterclockwise
typename Alpha_shape_2<Dt,EACT>::Face_handle f;
int i;
for (edge_alpha_it = _interval_edge_map.begin();
edge_alpha_it != _interval_edge_map.end() &&
(*edge_alpha_it).first.first <= get_alpha();
++edge_alpha_it)
{
pInterval = &(*edge_alpha_it).first;
CGAL_triangulation_assertion(pInterval->second != Infinity);
// since this happens only for convex hull of dimension 1
// thus singular
if(pInterval->second <= get_alpha() &&
(pInterval->third > get_alpha()
|| pInterval->third == Infinity))
{
// alpha must be larger than the mid boundary
// and alpha is smaller than the upper boundary
// which might be infinity
// visualize the boundary
f = (*edge_alpha_it).second.first;
i = (*edge_alpha_it).second.second;
// assure that all vertices are in ccw order
if (classify(f) == Alpha_shape_2<Dt,EACT>::EXTERIOR)
{
// take the reverse face
typename Alpha_shape_2<Dt,EACT>::Face_handle
pNeighbor = f->neighbor(i);
i = pNeighbor->index(f);
f = pNeighbor;
}
CGAL_triangulation_assertion((classify(f) ==
Alpha_shape_2<Dt,EACT>::INTERIOR));
CGAL_triangulation_assertion((classify(f, i) ==
Alpha_shape_2<Dt,EACT>::REGULAR));
os << V[f->vertex(f->ccw(i))] << ' '
<< V[f->vertex(f->cw(i))] << std::endl;
}
}
}
else
{ // get_mode() == GENERAL -----------------------------------------
typename Alpha_shape_2<Dt,EACT>::Vertex_handle v;
// write the regular vertices
for (vertex_alpha_it = _interval_vertex_map.begin();
vertex_alpha_it != _interval_vertex_map.end() &&
(*vertex_alpha_it).first.first <= get_alpha();
++vertex_alpha_it)
{
pInterval2 = &(*vertex_alpha_it).first;
if((pInterval2->second > get_alpha()
|| pInterval2->second == Infinity))
{
// alpha must be larger than the min boundary
// and alpha is smaller than the upper boundary
// which might be infinity
// write the vertex
v = (*vertex_alpha_it).second;
CGAL_triangulation_assertion((classify(v) ==
Alpha_shape_2<Dt,EACT>::REGULAR));
V[v] = number_of_vertices++;
os << v->point() << std::endl;
}
}
// write the singular vertices
for (;
vertex_alpha_it != _interval_vertex_map.end();
++vertex_alpha_it)
{
v = (*vertex_alpha_it).second;
CGAL_triangulation_assertion((classify(v) ==
Alpha_shape_2<Dt,EACT>::SINGULAR));
V[v] = number_of_vertices++;
os << v->point() << std::endl;
}
// the vertices are oriented counterclockwise
typename Alpha_shape_2<Dt,EACT>::Face_handle f;
int i;
for (edge_alpha_it = _interval_edge_map.begin();
edge_alpha_it != _interval_edge_map.end() &&
(*edge_alpha_it).first.first <= get_alpha();
++edge_alpha_it)
{
pInterval = &(*edge_alpha_it).first;
#ifdef CGAL_DEBUG_ALPHA_SHAPE_2
typename Alpha_shape_2<Dt,EACT>::Type_of_alpha alpha =
get_alpha();
typename Alpha_shape_2<Dt,EACT>::Type_of_alpha alpha_min =
pInterval->first;
typename Alpha_shape_2<Dt,EACT>::Type_of_alpha alpha_mid =
pInterval->second;
typename Alpha_shape_2<Dt,EACT>::Type_of_alpha alpha_max =
pInterval->third;
#endif // CGAL_DEBUG_ALPHA_SHAPE_2
if(pInterval->third > get_alpha()
|| pInterval->third == Infinity)
{
// if alpha is smaller than the upper boundary
// which might be infinity
// visualize the boundary
f = (*edge_alpha_it).second.first;
i = (*edge_alpha_it).second.second;
// write the regular edges
if (pInterval->second != Infinity &&
pInterval->second <= get_alpha())
{
CGAL_triangulation_assertion((classify(f, i) ==
Alpha_shape_2<Dt,EACT>::REGULAR));
// assure that all vertices are in ccw order
if (classify(f) == Alpha_shape_2<Dt,EACT>::EXTERIOR)
{
// take the reverse face
typename Alpha_shape_2<Dt,EACT>::Face_handle
pNeighbor = f->neighbor(i);
i = pNeighbor->index(f);
f = pNeighbor;
}
CGAL_triangulation_assertion((classify(f) ==
Alpha_shape_2<Dt,EACT>::INTERIOR));
os << V[f->vertex(f->ccw(i))] << ' '
<< V[f->vertex(f->cw(i))] << std::endl;
}
else
{ // pInterval->second == Infinity ||
// pInterval->second >= get_alpha())
// pInterval->second == Infinity happens only for convex hull
// of dimension 1 thus singular
// write the singular edges
if (pInterval->first != UNDEFINED)
{
CGAL_triangulation_assertion((classify(f, i) ==
Alpha_shape_2<Dt,EACT>::SINGULAR));
os << V[f->vertex(f->ccw(i))] << ' '
<< V[f->vertex(f->cw(i))] << std::endl;
}
}
}
}
}
return os;
}
//-------------------------------------------------------------------
template < class Dt, class EACT >
std::ostream&
operator<<(std::ostream& os, const Alpha_shape_2<Dt>& A)
{
return A.op_ostream(os);
}
//-------------------------------------------------------------------
template < class Dt, class EACT >
std::list<typename Alpha_shape_2<Dt,EACT>::Point_2>
Alpha_shape_2<Dt,EACT>::Output ()
{
typename Interval_edge_map::const_iterator edge_alpha_it;
const Interval3* pInterval;
std::list<Point_2> L;
if (get_mode() == REGULARIZED)
{
// it is much faster looking at the sorted intervals
// than looking at all sorted faces
// alpha must be larger than the mid boundary
// and alpha is smaller than the upper boundary
for (edge_alpha_it = _interval_edge_map.begin();
edge_alpha_it != _interval_edge_map.end() &&
(*edge_alpha_it).first.first <= get_alpha();
++edge_alpha_it)
{
pInterval = &(*edge_alpha_it).first;
if (pInterval->second != Infinity)
{
// since this happens only for convex hull of dimension 1
// thus singular
if(pInterval->second <= get_alpha() &&
(pInterval->third > get_alpha()
|| pInterval->third == Infinity))
{
// alpha must be larger than the mid boundary
// and alpha is smaller than the upper boundary
// which might be infinity
// visualize the boundary
CGAL_triangulation_assertion((classify((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second) ==
REGULAR));
// if we used Edelsbrunner and Muecke's definition
// regular means incident to a higher-dimensional face
// thus we would write to many vertices
L.push_back((this->segment((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second))
.source());
L.push_back((this->segment((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second))
.target());
}
}
}
}
else
{ // get_mode() == GENERAL
// draw the edges
for (edge_alpha_it = _interval_edge_map.begin();
edge_alpha_it != _interval_edge_map.end() &&
(*edge_alpha_it).first.first <= get_alpha();
++edge_alpha_it)
{
pInterval = &(*edge_alpha_it).first;
if (pInterval->first == UNDEFINED)
{
CGAL_triangulation_assertion(pInterval->second != Infinity);
// since this happens only for convex hull of dimension 1
// thus singular
if(pInterval->second <= get_alpha() &&
(pInterval->third > get_alpha()
|| pInterval->third == Infinity))
{
// alpha must be larger than the mid boundary
// and alpha is smaller than the upper boundary
// which might be infinity
// visualize the boundary
CGAL_triangulation_assertion((classify((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second) ==
REGULAR));
L.push_back((this->segment((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second))
.source());
L.push_back((this->segment((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second))
.target());
}
}
else
{
if(pInterval->third > get_alpha()
|| pInterval->third == Infinity)
{
// if alpha is smaller than the upper boundary
// which might be infinity
// visualize the boundary
CGAL_triangulation_assertion(((classify((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second) ==
REGULAR) ||
(classify((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second) ==
SINGULAR)));
L.push_back((this->segment((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second))
.source());
L.push_back((this->segment((*edge_alpha_it).second.first,
(*edge_alpha_it).second.second))
.target());
}
}
}
}
return L;
}
template < class Dt, class EACT >
void Alpha_shape_2<Dt,EACT>::print_edge_map()
{
for (typename Interval_edge_map::iterator iemapit= _interval_edge_map.begin();
iemapit != _interval_edge_map.end(); ++iemapit) {
Interval3 interval = (*iemapit).first;
Edge edge = (*iemapit).second;
Point p1 = edge.first->vertex(cw(edge.second))->point();
Point p2 = edge.first->vertex(ccw(edge.second))->point();
std::cout << "[ (" << p1 << ") - (" << p2 << ") ] : "
<< interval.first << " "
<< interval.second << " " << interval.third << std::endl;
}
}
} //namespace CGAL
#endif //CGAL_ALPHA_SHAPE_2_H
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