dust3d/thirdparty/cgal/CGAL-4.13/include/CGAL/Combinatorial_map_operations.h

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Executable File

// Copyright (c) 2010-2011 CNRS and LIRIS' Establishments (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 Lesser General Public License as
// published by the Free Software Foundation; either version 3 of the License,
// or (at your option) any later version.
//
// Licensees holding a valid commercial license may use this file in
// accordance with the commercial license agreement provided with the software.
//
// This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
// WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
//
// $URL$
// $Id$
// SPDX-License-Identifier: LGPL-3.0+
//
// Author(s) : Guillaume Damiand <guillaume.damiand@liris.cnrs.fr>
//
#ifndef CGAL_COMBINATORIAL_MAP_OPERATIONS_H
#define CGAL_COMBINATORIAL_MAP_OPERATIONS_H 1
#include <CGAL/Dart_const_iterators.h>
#include <CGAL/internal/Combinatorial_map_group_functors.h>
#include <deque>
#define CGAL_BETAINV(i) (i>1?i:(i==1?0:1))
namespace CGAL
{
/** @file Combinatorial_map_operations.h
* Some operations to modify a combinatorial map.
*/
/** Test if an i-cell can be removed.
* An i-cell can be removed if i==CMap::dimension or i==CMap::dimension-1,
* or if there are at most two (i+1)-cell incident to it.
* @param adart a dart of the i-cell.
* @return true iff the i-cell can be removed.
*/
template <class CMap, unsigned int i, unsigned int nmi=CMap::dimension-i>
struct Is_removable_functor
{
static bool run(const CMap& amap, typename CMap::Dart_const_handle adart)
{
// TODO? Optimisation for dim-2, and to not test all the darts of the cell?
bool res = true;
for ( CGAL::CMap_dart_const_iterator_of_cell<CMap,i> it(amap, adart);
res && it.cont(); ++it )
{
if ( amap.template beta<i+2,i+1>(it)!=
amap.template beta<CGAL_BETAINV(i+1),i+2>(it) )
res = false;
}
return res;
}
};
// Specialization for i=CMap::dimension
template <class CMap, unsigned int i>
struct Is_removable_functor<CMap, i, 0>
{
static bool run(const CMap&, typename CMap::Dart_const_handle)
{ return true; }
};
// Specialization for i=CMap::dimension-1
template <class CMap, unsigned int i>
struct Is_removable_functor<CMap, i, 1>
{
static bool run(const CMap&, typename CMap::Dart_const_handle)
{ return true; }
};
/** Test if an i-cell can be removed.
* An i-cell can be removed if i==CMap::dimension or i==CMap::dimension-1,
* or if there are at most two (i+1)-cell incident to it.
* @param adart a dart of the i-cell.
* @return true iff the i-cell can be removed.
*/
#ifndef CGAL_NO_DEPRECATED_CODE
template < class CMap, unsigned int i >
CGAL_DEPRECATED bool is_removable(const CMap& amap,
typename CMap::Dart_const_handle adart)
{ return CGAL::Is_removable_functor<CMap, i>::run(amap,adart); }
#endif // CGAL_NO_DEPRECATED_CODE
/** Remove an i-cell, 0<i<dimension, and merge eventually both incident
* (i+1)-cells.
* @param amap the used combinatorial map.
* @param adart a dart of the i-cell to remove.
* @param update_attributes a boolean to update the enabled attributes
* (deprecated, now we use are_attributes_automatically_managed())
* @return the number of deleted darts.
*/
template<class CMap, unsigned int i, unsigned int nmi>
struct Remove_cell_functor
{
static size_t run(CMap& amap, typename CMap::Dart_handle adart,
bool update_attributes)
{
CGAL_static_assertion ( 1<=i && i<CMap::dimension );
CGAL_assertion( (amap.template is_removable<i>(adart)) );
size_t res = 0;
typename CMap::Dart_handle d1, d2;
typename CMap::Dart_handle dg1=amap.null_handle, dg2=amap.null_handle;
typename CMap::size_type mark = amap.get_new_mark();
typename CMap::size_type mark_modified_darts = amap.get_new_mark();
std::deque<typename CMap::Dart_handle> to_erase;
const int iinv = CGAL_BETAINV(i);
// First we store and mark all the darts of the i-cell to remove.
for ( CGAL::CMap_dart_iterator_basic_of_cell<CMap,i> it(amap,adart,mark);
it.cont(); ++it )
{
to_erase.push_back(it);
if ( !amap.template is_free<i+1>(it) && dg1==amap.null_handle )
{ dg1=it; dg2=amap.template beta<i+1>(it); }
amap.mark(it, mark);
++res;
}
if (amap.are_attributes_automatically_managed() && update_attributes)
{
// We group the two (i+1)-cells incident if they exist.
if ( dg1!=amap.null_handle )
CGAL::internal::Group_attribute_functor_run<CMap, i+1>::
run(amap, dg1, dg2);
}
// During the operation, we store in modified_darts the darts modified
// to test after the loop the non void attributes that are split.
std::deque<typename CMap::Dart_handle> modified_darts;
// If i==1, we modify beta1, thus in modified_darts we store all
// the darts having beta0 modified, and in modified_darts2 all the
// darts having beta1 modified. For i>1 all the modified darts are
// stored in modified_darts.
std::deque<typename CMap::Dart_handle> modified_darts2;
std::deque<typename CMap::Dart_handle> &first_modified_darts=
(i==1?modified_darts2:modified_darts);
// For each dart of the i-cell, we modify i-links of neighbors.
typename std::deque<typename CMap::Dart_handle>::iterator it =
to_erase.begin();
for ( ; it!=to_erase.end(); ++it )
{
if (i!=1 || amap.template beta<1>(*it)!=*it) // for 1-removal of a dart loop, nothing to do
{
d1=amap.template beta<iinv>(*it);
while (d1!=amap.null_dart_handle && amap.is_marked(d1, mark))
{
d1=amap.template beta<i+1, iinv>(d1);
if (d1==amap. template beta<iinv>(*it))
{ d1=amap.null_dart_handle; }
}
d2=amap.template beta<i+1,i>(*it);
while ( d2!=amap.null_dart_handle && amap.is_marked(d2, mark) )
{
d2=amap.template beta<i+1,i>(d2);
if ( d2==amap.template beta<i+1,i>(*it) )
{ d2=amap.null_dart_handle; }
}
if ( d1!=amap.null_dart_handle )
{
if ( d2!=amap.null_dart_handle && d1!=d2 )
{
amap.template basic_link_beta<i>(d1, d2);
amap.mark(d1, mark_modified_darts);
amap.mark(d2, mark_modified_darts);
first_modified_darts.push_back(d1);
modified_darts.push_back(d2);
}
else
{
if (d1==d2)
{
amap.template basic_link_beta<i>(d1, d1);
amap.mark(d1, mark_modified_darts);
first_modified_darts.push_back(d1);
}
else if ( !amap.template is_free<i>(d1) )
{
amap.template unlink_beta<i>(d1);
amap.mark(d1, mark_modified_darts);
first_modified_darts.push_back(d1);
}
}
}
else if ( d2!=amap.null_dart_handle )
{
if ( !amap.template is_free<iinv>(d2) )
{
amap.template unlink_beta<iinv>(d2);
amap.mark(d2, mark_modified_darts);
modified_darts.push_back(d2);
}
}
}
if ( amap.template is_free<i+1>(*it) &&
!amap.template is_free<i>(*it) )
{
d1 = amap.template beta<i>(*it);
if ( !amap.template is_free<iinv>(d1) )
{
amap.template unlink_beta<iinv>(d1);
amap.mark(d1, mark_modified_darts);
modified_darts.push_back(d1);
}
}
}
if (amap.are_attributes_automatically_managed() && update_attributes)
{
// We test the split of all the incident cells for all the non
// void attributes.
if ( i==1 )
CMap::Helper::template Foreach_enabled_attributes_except
<CGAL::internal::Test_split_attribute_functor<CMap,i>, i>::
run(amap, modified_darts, modified_darts2,
mark_modified_darts);
else
CMap::Helper::template Foreach_enabled_attributes_except
<CGAL::internal::Test_split_attribute_functor<CMap,i>, i>::
run(amap, modified_darts, mark_modified_darts);
}
// We remove all the darts of the i-cell.
for ( it=to_erase.begin(); it!=to_erase.end(); ++it )
{ amap.erase_dart(*it); }
CGAL_assertion( amap.is_whole_map_unmarked(mark) );
amap.free_mark(mark);
// If no attribute is enabled (or if only i-attributes are enabled),
// the darts are not unmark by Foreach_enabled_attributes_except.
// Thus we unmark them now.
if ( !amap.is_whole_map_unmarked(mark_modified_darts) )
{
for ( typename std::deque<typename CMap::Dart_handle>::
iterator it=modified_darts.begin();
it!=modified_darts.end(); ++it )
amap.unmark(*it, mark_modified_darts);
if ( i==1 )
{
for ( typename std::deque<typename CMap::Dart_handle>::
iterator it=modified_darts2.begin();
it!=modified_darts2.end(); ++it )
amap.unmark(*it, mark_modified_darts);
}
}
CGAL_assertion ( amap.is_whole_map_unmarked(mark_modified_darts) );
amap.free_mark(mark_modified_darts);
#ifdef CGAL_CMAP_TEST_VALID_REMOVALS
CGAL_assertion( amap.is_valid() );
#endif
return res;
}
};
/** Remove a d-cell, in a d-map (special case).
* @param amap the used combinatorial map.
* @param adart a dart of the d-cell to remove.
* @param update_attributes a boolean to update the enabled attributes
* (deprecated, now we use are_attributes_automatically_managed())
* @return the number of deleted darts.
*/
template<class CMap,unsigned int i>
struct Remove_cell_functor<CMap,i,0>
{
static size_t run(CMap& amap, typename CMap::Dart_handle adart,
bool update_attributes)
{
typename CMap::size_type mark = amap.get_new_mark();
std::deque<typename CMap::Dart_handle> to_erase;
size_t res = 0;
std::deque<typename CMap::Dart_handle> modified_darts;
// We mark all the darts of the d-cell.
for ( CGAL::CMap_dart_iterator_basic_of_cell<CMap,CMap::dimension>
it(amap,adart,mark); it.cont(); ++it )
{
to_erase.push_back(it);
amap.mark(it,mark);
++res;
}
// We unlink all the darts of the d-cell for beta-d.
typename std::deque<typename CMap::Dart_handle>::iterator
it = to_erase.begin();
for ( it = to_erase.begin(); it != to_erase.end(); ++it )
{
if ( !amap.template is_free<CMap::dimension>(*it) &&
!amap.is_marked(amap.template beta<CMap::dimension>(*it), mark) )
{
if (amap.are_attributes_automatically_managed() && update_attributes)
{
modified_darts.push_back(amap.template beta<CMap::dimension>(*it));
}
amap.template unlink_beta_for_involution<CMap::dimension>(*it);
}
}
if (amap.are_attributes_automatically_managed() && update_attributes)
{
// We test the split of all the incident cells for all the non
// void attributes.
CMap::Helper::template Foreach_enabled_attributes_except
<CGAL::internal::Test_split_attribute_functor<CMap,i>,
CMap::dimension>::run(amap, modified_darts);
}
// We remove all the darts of the d-cell.
for ( it = to_erase.begin(); it != to_erase.end(); ++it )
{ amap.erase_dart(*it); }
CGAL_assertion( amap.is_whole_map_unmarked(mark) );
amap.free_mark(mark);
#ifdef CGAL_CMAP_TEST_VALID_REMOVALS
CGAL_assertion( amap.is_valid() );
#endif
return res;
}
};
/** Remove a vertex, and merge eventually both incident edges.
* @param amap the used combinatorial map.
* @param adart a dart of the vertex to remove.
* @param update_attributes a boolean to update the enabled attributes
* (deprecated, now we use are_attributes_automatically_managed())
* @return the number of deleted darts.
*/
template<class CMap,unsigned int nmi>
struct Remove_cell_functor<CMap,0,nmi>
{
static size_t run(CMap& amap, typename CMap::Dart_handle adart,
bool update_attributes)
{
CGAL_assertion( (amap.template is_removable<0>(adart)) );
size_t res = 0;
typename CMap::Dart_handle d1, d2;
typename CMap::Dart_handle dg1=amap.null_handle, dg2=amap.null_handle;
typename CMap::size_type mark = amap.get_new_mark();
// First we store and mark all the darts of the 0-cell to remove.
std::deque<typename CMap::Dart_handle> to_erase;
for ( CGAL::CMap_dart_iterator_basic_of_cell<CMap,0> it(amap,adart,mark);
it.cont(); ++it )
{
to_erase.push_back(it);
if ( !amap.template is_free<0>(it) && dg1==amap.null_handle )
{ dg1=it; dg2=amap.template beta<0>(it); }
amap.mark(it, mark);
++res;
}
if (amap.are_attributes_automatically_managed() && update_attributes )
{
// We group the two edges incident if they exist.
if ( dg1!=amap.null_handle )
CGAL::internal::Group_attribute_functor_run<CMap, 1>::
run(amap, dg1, dg2);
}
// During the operation, we store in modified_darts the darts modified
// by beta0 to test after the loop non void attributes that are split.
std::deque<typename CMap::Dart_handle> modified_darts;
// And we store in modified_darts2 all the darts having beta1 modified.
std::deque<typename CMap::Dart_handle> modified_darts2;
// For each dart of the vertex, we modify 0 and 1-links of neighbors.
typename std::deque<typename CMap::Dart_handle>::iterator it =
to_erase.begin();
for ( ; it != to_erase.end(); ++it)
{
if ( !amap.template is_free<0>(*it) )
{
if ( !amap.template is_free<1>(*it) &&
amap.template beta<0>(*it)!=(*it) )
{
amap.basic_link_beta_1(amap.template beta<0>(*it),
amap.template beta<1>(*it));
if (amap.are_attributes_automatically_managed() && update_attributes)
{
modified_darts.push_back(amap.template beta<0>(*it));
modified_darts2.push_back(amap.template beta<1>(*it));
// TODO push only one out of two dart ?
}
}
else
{
amap.template dart_unlink_beta<1>(amap.template beta<0>(*it));
if (amap.are_attributes_automatically_managed() && update_attributes)
{
modified_darts.push_back(amap.template beta<0>(*it));
}
}
for ( unsigned int j=2; j<=CMap::dimension; ++j )
{
if ( !amap.is_free(*it,j) )
{
amap.basic_link_beta(amap.template beta<0>(*it),
amap.beta(*it,j), j);
//((*it)->beta(0))->basic_link_beta((*it)->beta(j),j);
}
}
}
else
{
if ( !amap.template is_free<1>(*it) )
{
amap.template dart_unlink_beta<0>(amap.template beta<1>(*it));
if (amap.are_attributes_automatically_managed() && update_attributes)
{
modified_darts2.push_back(amap.template beta<1>(*it));
}
}
for ( unsigned int j=2; j<=CMap::dimension; ++j )
{
if ( !amap.is_free(*it,j) )
{ amap.unlink_beta(*it, j); }
}
}
}
if (amap.are_attributes_automatically_managed() && update_attributes)
{
// We test the split of all the incident cells for all the non
// void attributes.
CMap::Helper::template Foreach_enabled_attributes_except
<CGAL::internal::Test_split_attribute_functor<CMap,0>, 1>::
run(amap, modified_darts, modified_darts2);
}
// We remove all the darts of the 0-cell.
for ( it=to_erase.begin(); it!=to_erase.end(); ++it )
{ amap.erase_dart(*it); }
CGAL_assertion( amap.is_whole_map_unmarked(mark) );
amap.free_mark(mark);
#ifdef CGAL_CMAP_TEST_VALID_REMOVALS
CGAL_assertion( amap.is_valid() );
#endif
return res;
}
};
/** Remove an i-cell, 0<=i<=dimension.
* @param amap the used combinatorial map.
* @param adart a dart of the i-cell to remove.
* @param update_attributes a boolean to update the enabled attributes
* @return the number of deleted darts.
*/
#ifndef CGAL_NO_DEPRECATED_CODE
template < class CMap, unsigned int i >
CGAL_DEPRECATED size_t remove_cell(CMap& amap, typename CMap::Dart_handle adart,
bool update_attributes = true)
{
return CGAL::Remove_cell_functor<CMap,i,CMap::dimension-i>::
run(amap,adart,update_attributes);
}
#endif // CGAL_NO_DEPRECATED_CODE
/** Test if an i-cell can be contracted.
* An i-cell can be contracted if i==1
* or if there are at most two (i-1)-cell incident to it.
* @param adart a dart of the i-cell.
* @return true iff the i-cell can be contracted.
*/
template <class CMap, unsigned int i>
struct Is_contractible_functor
{
static bool run(const CMap& amap, typename CMap::Dart_const_handle adart)
{
// TODO ? Optimisation possible to not test all the darts of the cell ?
bool res = true;
for ( CGAL::CMap_dart_const_iterator_of_cell<CMap,i> it(amap, adart);
res && it.cont(); ++it )
{
if ( amap.template beta<i-2,i-1>(it)!=
amap.template beta<i-1,CGAL_BETAINV(i-2)>(it) )
res = false;
}
return res;
}
};
// Specialization for i=0
template <class CMap>
struct Is_contractible_functor<CMap, 0>
{
static bool run(const CMap&, typename CMap::Dart_const_handle)
{ return false; }
};
// Specialization for i=1
template <class CMap>
struct Is_contractible_functor<CMap, 1>
{
static bool run(const CMap&, typename CMap::Dart_const_handle)
{ return true; }
};
/** Test if an i-cell can be contracted.
* An i-cell can be contracted if i==1
* or if there are at most two (i-1)-cell incident to it.
* @param adart a dart of the i-cell.
* @return true iff the i-cell can be contracted.
*/
#ifndef CGAL_NO_DEPRECATED_CODE
template < class CMap, unsigned int i >
CGAL_DEPRECATED bool is_contractible(const CMap& amap, typename CMap::Dart_const_handle adart)
{ return CGAL::Is_contractible_functor<CMap, i>::run(amap,adart); }
#endif // CGAL_NO_DEPRECATED_CODE
/** Contract an i-cell, 1<i<=dimension, and merge eventually both incident
* (i-1)-cells.
* @param amap the used combinatorial map.
* @param adart a dart of the i-cell to contract.
* @return the number of deleted darts.
*/
template<class CMap, unsigned int i>
struct Contract_cell_functor
{
static size_t run(CMap& amap, typename CMap::Dart_handle adart,
bool update_attributes)
{
CGAL_static_assertion ( 2<=i && i<=CMap::dimension );
CGAL_assertion( (amap.template is_contractible<i>(adart)) );
size_t res = 0;
typename CMap::Dart_handle d1, d2;
typename CMap::Dart_handle dg1=amap.null_handle, dg2=amap.null_handle;
typename CMap::size_type mark = amap.get_new_mark();
typename CMap::size_type mark_modified_darts = amap.get_new_mark();
const int imuinv = CGAL_BETAINV(i-1);
// First we store and mark all the darts of the i-cell to contract.
std::deque<typename CMap::Dart_handle> to_erase;
for ( CGAL::CMap_dart_iterator_basic_of_cell<CMap,i> it(amap,adart,mark);
it.cont(); ++it )
{
to_erase.push_back(it);
if ( !amap.template is_free<i-1>(it) && dg1==amap.null_handle )
{ dg1=it; dg2=amap.template beta<i-1>(it); }
amap.mark(it, mark);
++res;
}
if ( amap.are_attributes_automatically_managed() && update_attributes )
{
// We group the two (i-1)-cells incident if they exist.
if ( dg1!=amap.null_handle )
CGAL::internal::Group_attribute_functor_run<CMap,i-1>::
run(amap, dg1, dg2);
}
// During the operation, we store in modified_darts the darts modified
// to test after the loop the non void attributes that are split.
std::deque<typename CMap::Dart_handle> modified_darts;
// For each dart of the i-cell, we modify i-links of neighbors.
typename std::deque<typename CMap::Dart_handle>::iterator it =
to_erase.begin();
for ( ; it!=to_erase.end(); ++it )
{
d1 = amap.template beta<i>(*it);
while ( d1!=amap.null_dart_handle && amap.is_marked(d1, mark) )
{
d1 = amap.template beta<imuinv,i>(d1);
if (d1 == amap.template beta<i>(*it)) d1 = amap.null_dart_handle;
}
if ( !amap.is_marked(d1, mark_modified_darts) )
{
d2 = amap.template beta<i-1,i>(*it);
while ( d2!=amap.null_dart_handle && amap.is_marked(d2, mark) )
{
d2 = amap.template beta<i-1,i>(d2);
if ( d2==amap.template beta<i-1,i>(*it) )
d2=amap.null_dart_handle;
}
if ( !amap.is_marked(d2, mark_modified_darts) )
{
if (d1 != amap.null_dart_handle)
{
if (d2 != amap.null_dart_handle && d1!=d2 )
{
amap.template basic_link_beta_for_involution<i>(d1, d2);
amap.mark(d1, mark_modified_darts);
amap.mark(d2, mark_modified_darts);
modified_darts.push_back(d1);
modified_darts.push_back(d2);
// TODO push only one out of two dart ?
}
else
{
if ( !amap.template is_free<i>(d1) )
{
amap.template unlink_beta<i>(d1);
CGAL_assertion( !amap.is_marked(d1, mark_modified_darts) );
amap.mark(d1, mark_modified_darts);
modified_darts.push_back(d1);
}
}
}
else if (d2 != amap.null_dart_handle)
{
if ( !amap.is_free(d2,i) )
{
amap.template unlink_beta<i>(d2);
CGAL_assertion( !amap.is_marked(d2, mark_modified_darts) );
amap.mark(d2, mark_modified_darts);
modified_darts.push_back(d2);
}
}
}
}
if (amap.is_free(*it,i-1) && !amap.is_free(*it,i))
{
d1 = amap.beta(*it,i);
if ( !amap.is_free(d1,i) )
{
amap.template unlink_beta<i>(d1);
CGAL_assertion( !amap.is_marked(d1, mark_modified_darts) );
amap.mark(d1, mark_modified_darts);
modified_darts.push_back(d1);
}
}
}
if ( amap.are_attributes_automatically_managed() && update_attributes )
{
// We test the split of all the incident cells for all the non
// void attributes.
CMap::Helper::template Foreach_enabled_attributes_except
<CGAL::internal::Test_split_attribute_functor<CMap,i>, i>::
run(amap, modified_darts, mark_modified_darts);
}
// We remove all the darts of the i-cell.
for ( it=to_erase.begin(); it!=to_erase.end(); ++it )
{ amap.erase_dart(*it); }
CGAL_assertion( amap.is_whole_map_unmarked(mark) );
amap.free_mark(mark);
// If no attribute is enabled (or if only i-attributes are enabled),
// the darts are not unmark by Foreach_enabled_attributes_except.
// Thus we unmark them now.
if ( !amap.is_whole_map_unmarked(mark_modified_darts) )
{
for ( typename std::deque<typename CMap::Dart_handle>::
iterator it=modified_darts.begin();
it!=modified_darts.end(); ++it )
amap.unmark(*it, mark_modified_darts);
}
CGAL_assertion ( amap.is_whole_map_unmarked(mark_modified_darts) );
amap.free_mark(mark_modified_darts);
#ifdef CGAL_CMAP_TEST_VALID_CONTRACTIONS
CGAL_assertion( amap.is_valid() );
#endif
return res;
}
};
/** Contract an edge, and merge eventually both incident vertices.
* @param amap the used combinatorial map.
* @param adart a dart of the edge to contract.
* @return the number of deleted darts.
*/
template<class CMap>
struct Contract_cell_functor<CMap,1>
{
static size_t run(CMap& amap, typename CMap::Dart_handle adart,
bool update_attributes)
{
CGAL_assertion( (amap.template is_contractible<1>(adart)) );
size_t res = 0;
typename CMap::Dart_handle d1, d2;
typename CMap::Dart_handle dg1=amap.null_handle, dg2=amap.null_handle;
typename CMap::size_type amark = amap.get_new_mark();
// First we store and mark all the darts of the 1-cell to contract.
std::deque<typename CMap::Dart_handle> to_erase;
for ( CGAL::CMap_dart_iterator_basic_of_cell<CMap,1> it(amap,adart,amark);
it.cont(); ++it )
{
to_erase.push_back(it);
if ( dg1==amap.null_handle && !amap.template is_free<0>(it) &&
!amap.template is_free<1>(it) )
{ dg1=amap.template beta<0>(it); dg2=amap.template beta<1>(it); }
amap.mark(it, amark);
++res;
}
if ( amap.are_attributes_automatically_managed() && update_attributes )
{
// We group the two vertices incident if they exist.
if ( dg1!=amap.null_handle )
CGAL::internal::Group_attribute_functor_run<CMap, 0, 1>::
run(amap, dg1, dg2);
}
// During the operation, we store in modified_darts the darts modified
// by beta0 to test after the loop non void attributes that are split.
std::deque<typename CMap::Dart_handle> modified_darts;
// And we store in modified_darts2 all the darts having beta1 modified.
std::deque<typename CMap::Dart_handle> modified_darts2;
// For each dart of the cell, we modify link of neighbors.
typename std::deque<typename CMap::Dart_handle>::iterator it =
to_erase.begin();
for ( ; it!=to_erase.end(); ++it )
{
if ( !amap.template is_free<0>(*it) )
{
if ( !amap.template is_free<1>(*it) )
{
if ( amap.template beta<1>(*it)!=*it )
{
/*modified_darts2.push_back((*it)->template beta<0>());
if ( (*it)->beta(0)!=(*it)->beta(1) )*/
if ( amap.are_attributes_automatically_managed() && update_attributes )
{
if (!amap.is_marked(amap.template beta<1>(*it), amark))
{ modified_darts.push_back(amap.template beta<1>(*it)); }
}
amap.basic_link_beta_1(amap.template beta<0>(*it),
amap.template beta<1>(*it));
}
}
else
{
if ( amap.are_attributes_automatically_managed() && update_attributes )
{
if (!amap.is_marked(amap.template beta<0>(*it), amark))
{ modified_darts2.push_back(amap.template beta<0>(*it)); }
}
amap.template dart_unlink_beta<1>(amap.template beta<0>(*it));
}
}
else
{
if ( !amap.template is_free<1>(*it) )
{
if ( amap.are_attributes_automatically_managed() && update_attributes )
{
if (!amap.is_marked(amap.template beta<1>(*it), amark))
{ modified_darts.push_back(amap.template beta<1>(*it)); }
}
amap.template dart_unlink_beta<0>(amap.template beta<1>(*it));
}
}
}
// We remove all the darts of the cell.
for ( it=to_erase.begin(); it!=to_erase.end(); ++it )
{ amap.erase_dart(*it); }
CGAL_assertion( amap.is_whole_map_unmarked(amark) );
amap.free_mark(amark);
if ( amap.are_attributes_automatically_managed() && update_attributes )
{
// We test the split of all the incident cells for all the non
// void attributes.
CMap::Helper::template Foreach_enabled_attributes_except
<CGAL::internal::Test_split_attribute_functor<CMap,1>, 1>::
run(amap, modified_darts, modified_darts2);
}
#ifdef CGAL_CMAP_TEST_VALID_CONTRACTIONS
CGAL_assertion( amap.is_valid() );
#endif
return res;
}
};
/** Contract an i-cell, 1<=i<=dimension.
* @param amap the used combinatorial map.
* @param adart a dart of the i-cell to remove.
* @return the number of deleted darts.
*/
#ifndef CGAL_NO_DEPRECATED_CODE
template < class CMap, unsigned int i >
CGAL_DEPRECATED size_t contract_cell(CMap& amap, typename CMap::Dart_handle adart,
bool update_attributes)
{ return CGAL::Contract_cell_functor<CMap,i>::run(amap,adart, update_attributes); }
#endif // CGAL_NO_DEPRECATED_CODE
} // namespace CGAL
#endif // CGAL_COMBINATORIAL_MAP_OPERATIONS_H //
// EOF //