subdivision3.hpp 36.8 KB
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/*******************************************************************************
* CGoGN: Combinatorial and Geometric modeling with Generic N-dimensional Maps  *
* version 0.1                                                                  *
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* Copyright (C) 2009-2011, IGG Team, LSIIT, University of Strasbourg           *
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*                                                                              *
* This library is free software; 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 2.1 of the License, or (at your     *
* option) any later version.                                                   *
*                                                                              *
* This library 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 Lesser General Public License  *
* for more details.                                                            *
*                                                                              *
* You should have received a copy of the GNU Lesser General Public License     *
* along with this library; if not, write to the Free Software Foundation,      *
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301 USA.           *
*                                                                              *
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* Web site: http://cgogn.u-strasbg.fr/                                         *
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* Contact information: cgogn@unistra.fr                                        *
*                                                                              *
*******************************************************************************/

#include "Algo/Geometry/centroid.h"
#include "Algo/Modelisation/subdivision.h"
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#include "Algo/Modelisation/extrusion.h"
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namespace CGoGN
{

namespace Algo
{

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namespace IHM
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{

template <typename PFP>
void subdivideEdge(typename PFP::MAP& map, Dart d, typename PFP::TVEC3& position)
{
	assert(map.getDartLevel(d) <= map.getCurrentLevel() || !"Access to a dart introduced after current level") ;
	assert(!map.edgeIsSubdivided(d) || !"Trying to subdivide an already subdivided edge") ;

	unsigned int eLevel = map.edgeLevel(d) ;

	unsigned int cur = map.getCurrentLevel() ;
	map.setCurrentLevel(eLevel) ;

	Dart dd = map.phi2(d) ;
	typename PFP::VEC3 p1 = position[d] ;
	typename PFP::VEC3 p2 = position[map.phi1(d)] ;

	map.setCurrentLevel(eLevel + 1) ;

	map.cutEdge(d) ;
	unsigned int eId = map.getEdgeId(d) ;
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	map.setEdgeId(map.phi1(d), eId, EDGE) ; //mise a jour de l'id d'arrete sur chaque moitie d'arete
	map.setEdgeId(map.phi1(dd), eId, EDGE) ;
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	map.setFaceId(EDGE, d) ; //mise a jour de l'id de face sur chaque brin de chaque moitie d'arete
	map.setFaceId(EDGE, dd) ;
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	position[map.phi1(d)] = (p1 + p2) * typename PFP::REAL(0.5) ;

	map.setCurrentLevel(cur) ;
}

template <typename PFP>
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void subdivideFace(typename PFP::MAP& map, Dart d, typename PFP::TVEC3& position, SubdivideType sType)
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{
	assert(map.getDartLevel(d) <= map.getCurrentLevel() || !"Access to a dart introduced after current level") ;
	assert(!map.faceIsSubdivided(d) || !"Trying to subdivide an already subdivided face") ;

	unsigned int fLevel = map.faceLevel(d) ;
	Dart old = map.faceOldestDart(d) ;

	unsigned int cur = map.getCurrentLevel() ;
	map.setCurrentLevel(fLevel) ;		// go to the level of the face to subdivide its edges

	unsigned int degree = 0 ;
	typename PFP::VEC3 p ;
	Dart it = old ;
	do
	{
		++degree;
		p += position[it] ;
		if(!map.edgeIsSubdivided(it))							// first cut the edges (if they are not already)
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			Algo::IHM::subdivideEdge<PFP>(map, it, position) ;	// and compute the degree of the face
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		it = map.phi1(it) ;
	} while(it != old) ;
	p /= typename PFP::REAL(degree) ;

	map.setCurrentLevel(fLevel + 1) ;			// go to the next level to perform face subdivision

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	Dart res;
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	if(degree == 3 && sType == Algo::IHM::S_TRI)	//subdiviser une face triangulaire
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	{
		Dart dd = map.phi1(old) ;
		Dart e = map.phi1(map.phi1(dd)) ;
		map.splitFace(dd, e) ;					// insert a new edge
		unsigned int id = map.getNewEdgeId() ;
		map.setEdgeId(map.phi_1(dd), id, EDGE) ;		// set the edge id of the inserted edge to the next available id

		unsigned int idface = map.getFaceId(old);
		map.setFaceId(dd, idface, FACE) ;
		map.setFaceId(e, idface, FACE) ;

		dd = e ;
		e = map.phi1(map.phi1(dd)) ;
		map.splitFace(dd, e) ;
		id = map.getNewEdgeId() ;
		map.setEdgeId(map.phi_1(dd), id, EDGE) ;

		map.setFaceId(dd, idface, FACE) ;
		map.setFaceId(e, idface, FACE) ;

		dd = e ;
		e = map.phi1(map.phi1(dd)) ;
		map.splitFace(dd, e) ;
		id = map.getNewEdgeId() ;
		map.setEdgeId(map.phi_1(dd), id, EDGE) ;

		map.setFaceId(dd, idface, FACE) ;
		map.setFaceId(e, idface, FACE) ;
	}
	else
	{
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		Dart dd = map.phi1(old) ;
		map.splitFace(dd, map.phi1(map.phi1(dd))) ;

		Dart ne = map.phi2(map.phi_1(dd));
		Dart ne2 = map.phi2(ne);
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		map.cutEdge(ne) ;
		unsigned int id = map.getNewEdgeId() ;
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		map.setEdgeId(ne, id, EDGE) ;
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		id = map.getNewEdgeId() ;
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		map.setEdgeId(ne2, id, EDGE) ;
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		position[map.phi2(ne)] = p ;
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		dd = map.phi1(map.phi1(map.phi1(map.phi1(ne)))) ;
		while(dd != ne)
		{
			Dart next = map.phi1(map.phi1(dd)) ;
			map.splitFace(map.phi1(ne), dd) ;
			Dart nne = map.phi2(map.phi_1(dd)) ;
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			id = map.getNewEdgeId() ;
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			map.setEdgeId(nne, id, EDGE) ;
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			dd = next ;
		}

		unsigned int idface = map.getFaceId(old);
		Dart e = dd;
		do
		{
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			map.setFaceId(dd, idface, DART) ;
			map.setFaceId(map.phi2(dd), idface, DART) ;
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			dd = map.phi2(map.phi1(dd));
		}
		while(dd != ne);
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	}
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	map.setCurrentLevel(cur) ;
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}

template <typename PFP>
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Dart subdivideVolumeGen(typename PFP::MAP& map, Dart d, typename PFP::TVEC3& position)
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{
	assert(map.getDartLevel(d) <= map.getCurrentLevel() || !"Access to a dart introduced after current level") ;
	assert(!map.volumeIsSubdivided(d) || !"Trying to subdivide an already subdivided volume") ;

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	unsigned int vLevel = map.volumeLevel(d);
	Dart old = map.volumeOldestDart(d);
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	unsigned int cur = map.getCurrentLevel();
	map.setCurrentLevel(vLevel);
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	/*
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	 * au niveau du volume courant i
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	 * stockage d'un brin de chaque face de celui-ci
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	 * avec calcul du centroid
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	 */

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	DartMarkerStore mf(map);		// Lock a face marker to save one dart per face
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	CellMarker mv(map, VERTEX);
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	typename PFP::VEC3 volCenter;
	unsigned count = 0 ;
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	//Store faces that are traversed and start with the face of d
	std::vector<Dart> visitedFaces;
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	visitedFaces.reserve(512);
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	visitedFaces.push_back(old);

	//Store the edges before the cutEdge
	std::vector<Dart> oldEdges;
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	oldEdges.reserve(512);
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	mf.markOrbit(FACE, old) ;
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	for(std::vector<Dart>::iterator face = visitedFaces.begin(); face != visitedFaces.end(); ++face)
	{
		Dart e = *face ;
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		do
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		{
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			//add one old edge per vertex to the old edge list
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			//compute volume centroid
			if(!mv.isMarked(e))
			{
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				mv.mark(e);
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				volCenter += position[e];
				++count;
				oldEdges.push_back(e);
			}
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			// add all face neighbours to the table
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			Dart ee = map.phi2(e) ;
			if(!mf.isMarked(ee)) // not already marked
			{
				visitedFaces.push_back(ee) ;
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				mf.markOrbit(FACE, ee) ;
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			}
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			e = map.phi1(e) ;
		} while(e != *face) ;
	}

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	volCenter /= typename PFP::REAL(count) ;

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	/*
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	 * Subdivision
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	 */
	//Store the darts from quadrangulated faces
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	std::vector<std::pair<Dart,Dart> > subdividedfacesQ;
	subdividedfacesQ.reserve(25);

	std::vector<std::pair<Dart,Dart> > subdividedfacesT;
	subdividedfacesT.reserve(25);

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	//First step : subdivide edges and faces
	//creates a i+1 edge level and i+1 face level
	for (std::vector<Dart>::iterator face = visitedFaces.begin(); face != visitedFaces.end(); ++face)
	{
		Dart d = *face;

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		//if needed subdivide face
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		if(!map.faceIsSubdivided(d))
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			Algo::IHM::subdivideFace<PFP>(map, d, position);
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		//save a dart from the subdivided face
		unsigned int cur = map.getCurrentLevel() ;
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		unsigned int fLevel = map.faceLevel(d) + 1; //puisque dans tous les cas, la face est subdivisee
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		map.setCurrentLevel(fLevel) ;
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		//test si la face est triangulaire ou non
		if(map.phi1(map.phi1(map.phi1(d))) == d)
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		{
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			//std::cout << "trian" << std::endl;
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			Dart cf = map.phi2(map.phi1(d));
			Dart e = cf;
			do
			{
				subdividedfacesT.push_back(std::pair<Dart,Dart>(e,map.phi2(e)));
				e = map.phi1(e);
			}while (e != cf);
		}
		else
		{
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			//std::cout << "quad" << std::endl;
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			Dart cf = map.phi1(d);
			Dart e = cf;
			do
			{
				subdividedfacesQ.push_back(std::pair<Dart,Dart>(e,map.phi2(e)));
				e = map.phi2(map.phi1(e));
			}while (e != cf);


		}
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		map.setCurrentLevel(cur);
	}
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	map.setCurrentLevel(vLevel + 1) ; // go to the next level to perform volume subdivision
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	std::vector<Dart> newEdges;	//save darts from inner edges
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	newEdges.reserve(50);
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	//Second step : deconnect each corner, close each hole, subdivide each new face into 3
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	for (std::vector<Dart>::iterator edge = oldEdges.begin(); edge != oldEdges.end(); ++edge)
	{
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		//std::vector<Dart>::iterator edge = oldEdges.begin();
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		Dart e = *edge;
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		Dart f1 = map.phi1(*edge);
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		Dart f2 = map.phi2(f1);
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		do
		{
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			if(map.phi1(map.phi1(map.phi1(e))) != e)
			{
				map.unsewFaces(map.phi1(map.phi1(e))); //remplacer par une boucle qui découd toute la face et non juste une face carre (jusqu'a phi_1(e))
			}

			map.unsewFaces(map.phi1(e));
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			e = map.phi2(map.phi_1(e));
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		}
		while(e != *edge);
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		map.closeHole(f1);
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		//degree du sommet exterieur
		unsigned int cornerDegree = map.Map2::vertexDegree(*edge);
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		//tourner autour du sommet pour connaitre le brin d'un sommet de valence < cornerDegree
		bool found = false;
		Dart stop = e;
		do
		{
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			if(map.Map2::vertexDegree(map.phi2(map.phi1(e))) < cornerDegree)
			{
				stop = map.phi2(map.phi1(e));
				found = true;
			}
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			e = map.phi2(map.phi_1(e));
		}
		while(!found && e != *edge);
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		//si il existe un sommet de degre inferieur au degree du coin
		if(found)
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		{
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			//chercher le brin de faible degree suivant
			bool found2 = false;
			Dart dd = map.phi1(stop);
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			do
			{
				if(map.Map2::vertexDegree(dd) < cornerDegree)
					found2 = true;
				else
					dd = map.phi1(dd);
			}
			while(!found2);

			//cas de la pyramide
			if(dd == stop)
			{
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				//std::cout << "pyramide" << std::endl;
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				map.splitFace(dd, map.phi1(map.phi1(dd)));
			}
			else
			{
				map.splitFace(dd, stop);
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				//calcul de la taille des faces de chaque cote de stop
				if(!( (map.Map2::faceDegree(map.phi_1(stop)) == 3 && map.Map2::faceDegree(map.phi2(map.phi_1(stop))) == 4) ||
						(map.Map2::faceDegree(map.phi_1(stop)) == 4 && map.Map2::faceDegree(map.phi2(map.phi_1(stop))) == 3) ))
				{
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					//std::cout << "octaedre ou hexaedre" << std::endl;
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					Dart ne = map.phi_1(stop) ;
					map.cutEdge(ne);
					position[map.phi1(ne)] = volCenter;
					stop = map.phi2(map.phi1(ne));

					bool finished = false;
					Dart it = map.phi2(ne);

					do
					{
						//chercher le brin de faible degree suivant
						bool found2 = false;
						Dart dd = map.phi1(it);

						do
						{
							if(dd == stop)
								finished = true;
							else if(map.Map2::vertexDegree(dd) < cornerDegree)
								found2 = true;
							else
								dd = map.phi1(dd);
						}
						while(!found2 & !finished);

						if(found2)
						{
							map.splitFace(it,dd);
						}

						it = map.phi_1(dd);

						if(it == stop)
							finished = true;

					}
					while(!finished);

				}
				else
				{
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					//std::cout << "prisme" << std::endl;
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					//tester si besoin de fermer f2 (par exemple pas besoin pour hexa... mais pour tet, octa, prisme oui)
					//map.closeHole(f2);
				}

			}
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		}
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		//sinon cas du tetraedre
		else
		{
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			//std::cout << "tetraedre" << std::endl;
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			//tester si besoin de fermer f2 (par exemple pas besoin pour hexa... mais pour tet, octa, prisme oui)
			//map.closeHole(f2);
		}

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	}
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	//std::cout << "1ere etape finished" << std::endl;
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	CellMarker mtf(map, FACE);

	//Etape 2
	for (std::vector<std::pair<Dart,Dart> >::iterator edges = subdividedfacesT.begin(); edges != subdividedfacesT.end(); ++edges)
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	{
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		Dart f1 = (*edges).first;
		Dart f2 = (*edges).second;
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//Fonction isTetrahedron ??
//		//if(Algo::Modelisation::Tetrahedron::isTetrahedron<PFP>(map,f2))
		if(  (map.Map2::faceDegree(f2) == 3 && map.Map2::faceDegree(map.phi2(f2)) == 3 &&
				map.Map2::faceDegree(map.phi2(map.phi_1(f2))) == 3) && map.Map2::vertexDegree(f2) == 3)
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		{ //cas du tetrahedre
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			//std::cout << "ajout d'une face" << std::endl;
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			if(map.phi3(map.phi2(f2)) == map.phi2(f2))
			{
				Dart nf = map.newFace(3);
				map.sewVolumes(map.phi2(f2),nf);
			}

			if(map.phi2(map.phi3(map.phi2(f2))) == map.phi3(map.phi2(f2)))
			{
				map.sewFaces(map.phi3(map.phi2(f2)), f1);
			}
		}
		else
		{
			if(!mtf.isMarked(f1))
			{
				mtf.mark(f1);

				map.closeHole(f1);

				if(map.Map2::faceDegree(map.phi2(f2)) == 3)
				{
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					//std::cout << "ajout d'un tetraedre" << std::endl;
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					Dart x = Algo::Modelisation::trianguleFace<PFP>(map, map.phi2(f1));
					position[x] = volCenter;
				}
				else
				{
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					//std::cout << "ajout d'un prisme" << std::endl;
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					//Dart x = Algo::Modelisation::extrudeFace<PFP>(map,position,map.phi2(f1),5.0);
					Dart c = Algo::Modelisation::trianguleFace<PFP>(map, map.phi2(f1));

					Dart cc = c;
					// cut edges
					do
					{

						typename PFP::VEC3 p1 = position[cc] ;
						typename PFP::VEC3 p2 = position[map.phi1(cc)] ;

						map.cutEdge(cc);

						position[map.phi1(cc)] = (p1 + p2) * typename PFP::REAL(0.5) ;

						cc = map.phi2(map.phi_1(cc));
					}while (cc != c);

					// cut faces
					do
					{
						Dart d1 = map.phi1(cc);
						Dart d2 = map.phi_1(cc);
						map.splitFace(d1,d2);
						cc = map.phi2(map.phi_1(cc));//map.Map2::alpha1(cc);
					}while (cc != c);

					//merge central faces by removing edges
					bool notFinished=true;
					do
					{
						Dart d1 = map.Map2::alpha1(cc);
						if (d1 == cc)			// last edge is pending edge inside of face
							notFinished = false;
						map.deleteFace(cc);
						cc = d1;
					} while (notFinished);


					map.closeHole(map.phi1(map.phi1(map.phi2(f1))));

				}
			}
		}

	}

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	//std::cout << "2e etape finished" << std::endl;
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	{
		//Third step : 3-sew internal faces
		for (std::vector<std::pair<Dart,Dart> >::iterator it = subdividedfacesT.begin(); it != subdividedfacesT.end(); ++it)
		{
			Dart f1 = (*it).first;
			Dart f2 = (*it).second;



			if(map.phi3(map.phi2(f1)) == map.phi2(f1) && map.phi3(map.phi2(f2)) == map.phi2(f2))
			{
				if(map.getEmbedding(VERTEX, map.phi_1(map.phi2(f2))) == map.getEmbedding(VERTEX, map.phi_1(map.phi2(f1))))
				{
					map.Map3::sewVolumes(map.phi2(f2), map.phi2(f1));
				}
				else
				{

				//id pour toutes les faces interieures
				map.sewVolumes(map.phi2(f2), map.phi2(f1));


				}

				//Fais a la couture !!!!!
				unsigned int idface = map.getNewFaceId();
				map.setFaceId(map.phi2(f1),idface, FACE);
			}


			//FAIS a la couture !!!!!!!
			//id pour toutes les aretes exterieurs des faces quadrangulees
			unsigned int idedge = map.getEdgeId(f1);
			map.setEdgeId(map.phi2(f1), idedge, DART);
			map.setEdgeId( map.phi2(f2), idedge, DART);

		}

		//LA copie de L'id est a gerer avec le sewVolumes normalement !!!!!!
		//id pour les aretes interieurs : (i.e. 16 pour un octa)
		DartMarker mne(map);
		for(std::vector<Dart>::iterator it = newEdges.begin() ; it != newEdges.end() ; ++it)
		{
			if(!mne.isMarked(*it))
			{
				unsigned int idedge = map.getNewEdgeId();
				map.setEdgeId(*it, idedge, EDGE);
				mne.markOrbit(EDGE,*it);
			}
		}
	}

	{
		//Third step : 3-sew internal faces
		for (std::vector<std::pair<Dart,Dart> >::iterator it = subdividedfacesQ.begin(); it != subdividedfacesQ.end(); ++it)
		{
			Dart f1 = (*it).first;
			Dart f2 = (*it).second;

			if(map.phi3(map.phi2(f1)) == map.phi2(f1) && map.phi3(map.phi2(f2)) == map.phi2(f2))
			{
				//id pour toutes les faces interieures
				map.sewVolumes(map.phi2(f2), map.phi2(f1));

				//Fais a la couture !!!!!
				unsigned int idface = map.getNewFaceId();
				map.setFaceId(map.phi2(f1),idface, FACE);
			}

			//FAIS a la couture !!!!!!!
			//id pour toutes les aretes exterieurs des faces quadrangulees
			unsigned int idedge = map.getEdgeId(f1);
			map.setEdgeId(map.phi2(f1), idedge, DART);
			map.setEdgeId( map.phi2(f2), idedge, DART);
		}
		//LA copie de L'id est a gerer avec le sewVolumes normalement !!!!!!
		//id pour les aretes interieurs : (i.e. 16 pour un octa)
		DartMarker mne(map);
		for(std::vector<Dart>::iterator it = newEdges.begin() ; it != newEdges.end() ; ++it)
		{
			if(!mne.isMarked(*it))
			{
				unsigned int idedge = map.getNewEdgeId();
				map.setEdgeId(*it, idedge, EDGE);
				mne.markOrbit(EDGE,*it);
			}
		}
	}


	//cas tordu pour le prisme
	for (std::vector<std::pair<Dart,Dart> >::iterator it = subdividedfacesT.begin(); it != subdividedfacesT.end(); ++it)
	{
		Dart f1 = (*it).first;
		Dart f2 = (*it).second;

		if(  !(map.Map2::faceDegree(f2) == 3 && map.Map2::faceDegree(map.phi2(f2)) == 3 &&
				map.Map2::faceDegree(map.phi2(map.phi1(f2))) == 3 && map.Map2::faceDegree(map.phi2(map.phi_1(f2))) == 3))
		{


			if(map.phi2(map.phi1(map.phi1(map.phi2(f1)))) == map.phi3(map.phi2(map.phi1(map.phi1(map.phi2(f1))))) &&
					map.phi2(map.phi3(map.phi2(map.phi3(map.phi2(map.phi3(map.phi2(map.phi2(map.phi1(map.phi1(map.phi2(f1))))))))))) ==
							map.phi3(map.phi2(map.phi3(map.phi2(map.phi3(map.phi2(map.phi3(map.phi2(map.phi2(map.phi1(map.phi1(map.phi2(f1))))))))))))
			)
			{
				map.sewVolumes(map.phi2(map.phi1(map.phi1(map.phi2(f1)))),
						map.phi2(map.phi3(map.phi2(map.phi3(map.phi2(map.phi3(map.phi1(map.phi1(map.phi2(f1))))))))));
			}

		}

	}
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	map.setCurrentLevel(cur) ;
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	return subdividedfacesQ.begin()->first;
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}
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template <typename PFP>
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Dart subdivideVolume(typename PFP::MAP& map, Dart d, typename PFP::TVEC3& position)
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{
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	assert(map.getDartLevel(d) <= map.getCurrentLevel() || !"Access to a dart introduced after current level") ;
	assert(!map.volumeIsSubdivided(d) || !"Trying to subdivide an already subdivided volume") ;
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	assert(!map.neighborhoodLevelDiffersByOne(d) || !"Trying to subdivide a volume with neighborhood Level difference greater than 1");
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	unsigned int vLevel = map.volumeLevel(d);
	Dart old = map.volumeOldestDart(d);
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	unsigned int cur = map.getCurrentLevel();
	map.setCurrentLevel(vLevel);
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	/*
	 * au niveau du volume courant i
	 * stockage d'un brin de chaque face de celui-ci
	 * avec calcul du centroid
	 */
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	DartMarkerStore mf(map);		// Lock a face marker to save one dart per face
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	CellMarker mv(map, VERTEX);
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	typename PFP::VEC3 volCenter;
	unsigned count = 0 ;
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	//Store faces that are traversed and start with the face of d
	std::vector<Dart> visitedFaces;
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	visitedFaces.reserve(512);
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	visitedFaces.push_back(old);
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	//Store the edges before the cutEdge
	std::vector<Dart> oldEdges;
	oldEdges.reserve(20);
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	mf.markOrbit(FACE, old) ;
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	for(std::vector<Dart>::iterator face = visitedFaces.begin(); face != visitedFaces.end(); ++face)
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	{
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		Dart e = *face ;
		do
		{
			//add one old edge per vertex to the old edge list
			//compute volume centroid
			if(!mv.isMarked(e))
			{
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				mv.mark(e);
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				volCenter += position[e];
				++count;
				oldEdges.push_back(e);
			}

			// add all face neighbours to the table
			Dart ee = map.phi2(e) ;
			if(!mf.isMarked(ee)) // not already marked
			{
				visitedFaces.push_back(ee) ;
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				mf.markOrbit(FACE, ee) ;
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			}

			e = map.phi1(e) ;
		} while(e != *face) ;
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	}

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	volCenter /= typename PFP::REAL(count) ;
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	/*
	 * Subdivision
	 */
	//Store the darts from quadrangulated faces
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	std::vector<std::pair<Dart,Dart> > subdividedfacesQ;
	subdividedfacesQ.reserve(25);
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	std::vector<std::pair<Dart,Dart> > subdividedfacesT;
	subdividedfacesT.reserve(25);
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	//First step : subdivide edges and faces
	//creates a i+1 edge level and i+1 face level
	for (std::vector<Dart>::iterator face = visitedFaces.begin(); face != visitedFaces.end(); ++face)
	{
		Dart d = *face;
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		//if needed subdivide face
		if(!map.faceIsSubdivided(d))
			Algo::IHM::subdivideFace<PFP>(map, d, position);
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		//save a dart from the subdivided face
		unsigned int cur = map.getCurrentLevel() ;

		unsigned int fLevel = map.faceLevel(d) + 1; //puisque dans tous les cas, la face est subdivisee
		map.setCurrentLevel(fLevel) ;



		//test si la face est triangulaire ou non
		if(map.phi1(map.phi1(map.phi1(d))) == d)
		{
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			//std::cout << "trian" << std::endl;
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			Dart cf = map.phi2(map.phi1(d));
			Dart e = cf;
			do
			{
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				subdividedfacesT.push_back(std::pair<Dart,Dart>(e,map.phi2(e)));
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				e = map.phi1(e);
			}while (e != cf);
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		}
		else
		{
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			//std::cout << "quad" << std::endl;
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			Dart cf = map.phi1(d);
			Dart e = cf;
			do
			{
				subdividedfacesQ.push_back(std::pair<Dart,Dart>(e,map.phi2(e)));
				e = map.phi2(map.phi1(e));
			}while (e != cf);

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		}

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		map.setCurrentLevel(cur);
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	}
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	map.setCurrentLevel(vLevel + 1) ; // go to the next level to perform volume subdivision
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	std::vector<Dart> newEdges;	//save darts from inner edges
	newEdges.reserve(50);

	bool istet = true;

	//Second step : deconnect each corner, close each hole, subdivide each new face into 3
	for (std::vector<Dart>::iterator edge = oldEdges.begin(); edge != oldEdges.end(); ++edge)
	{
		Dart e = *edge;

		Dart f1 = map.phi1(*edge);
		Dart f2 = map.phi2(f1);

		do
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		{
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			if(map.phi1(map.phi1(map.phi1(e))) != e)
				map.unsewFaces(map.phi1(map.phi1(e)));

			map.unsewFaces(map.phi1(e));


			e = map.phi2(map.phi_1(e));
		}
		while(e != *edge);

		map.closeHole(f1);

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		//fonction qui calcule le degree max des faces atour d'un sommet
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		unsigned int fdeg = map.faceDegree(map.phi2(f1));


		if(fdeg > 4)
		{
			Dart old = map.phi2(map.phi1(e));
			Dart dd = map.phi1(map.phi1(old)) ;
			map.splitFace(old,dd) ;
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			Dart ne = map.phi1(map.phi1(old)) ;

			map.cutEdge(ne);
			position[map.phi1(ne)] = volCenter; //plonger a la fin de la boucle ????
			newEdges.push_back(ne);
			newEdges.push_back(map.phi1(ne));


			Dart stop = map.phi2(map.phi1(ne));
			ne = map.phi2(ne);
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			do
			{
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				dd = map.phi1(map.phi1(map.phi1(ne)));
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				//A Verifier !!
				map.splitFace(ne, dd) ;
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				newEdges.push_back(map.phi1(dd));
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				ne = map.phi2(map.phi_1(ne));
				dd = map.phi1(map.phi1(dd));
			}
			while(dd != stop);
		}
		else if(fdeg > 3)
		{
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			map.closeHole(f2);
			map.sewVolumes(map.phi2(f1),map.phi2(f2));

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			istet = false;
			Dart old = map.phi2(map.phi1(*edge));
			Dart dd = map.phi1(old) ;
			map.splitFace(old,dd) ;
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			Dart ne = map.phi1(old);
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			map.cutEdge(ne);
			position[map.phi1(ne)] = volCenter; //plonger a la fin de la boucle ????
			newEdges.push_back(ne);
			newEdges.push_back(map.phi1(ne));
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			Dart stop = map.phi2(map.phi1(ne));
			ne = map.phi2(ne);
			do
			{
				dd = map.phi1(map.phi1(ne));
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				map.splitFace(ne, dd) ;
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				newEdges.push_back(map.phi1(dd));
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				ne = map.phi2(map.phi_1(ne));
				dd = map.phi1(dd);
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			}
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			while(dd != stop);
		}
		else
		{
			map.closeHole(f2);
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			map.sewVolumes(map.phi2(f1),map.phi2(f2));
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			unsigned int idface = map.getNewFaceId();
			map.setFaceId(map.phi2(f1),idface, FACE);
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		}

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	}

	if(!istet)
	{
		for (std::vector<Dart>::iterator edge = oldEdges.begin(); edge != oldEdges.end(); ++edge)
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		{
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			Dart e = *edge;
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			Dart x = map.phi_1(map.phi2(map.phi1(*edge)));
			Dart f = x;
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			do
			{
				Dart f3 = map.phi3(f);
				Dart tmp =  map.phi_1(map.phi2(map.phi_1(map.phi2(map.phi_1(f3)))));
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				map.unsewFaces(f3);
				map.unsewFaces(tmp);
				map.sewFaces(f3, tmp);
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				unsigned int idface = map.getNewFaceId();
				map.setFaceId(map.phi2(f3),idface, FACE);
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				f = map.phi2(map.phi_1(f));
			}while(f != x);
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		}

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	}

	{
	//Third step : 3-sew internal faces
	for (std::vector<std::pair<Dart,Dart> >::iterator it = subdividedfacesT.begin(); it != subdividedfacesT.end(); ++it)
	{
		Dart f1 = (*it).first;
		Dart f2 = (*it).second;

		//FAIS a la couture !!!!!!!
		//id pour toutes les aretes exterieurs des faces quadrangulees
		unsigned int idedge = map.getEdgeId(f1);
		map.setEdgeId(map.phi2(f1), idedge, DART);
		map.setEdgeId( map.phi2(f2), idedge, DART);

	}

	//LA copie de L'id est a gerer avec le sewVolumes normalement !!!!!!
	//id pour les aretes interieurs : (i.e. 16 pour un octa)
	DartMarker mne(map);
	for(std::vector<Dart>::iterator it = newEdges.begin() ; it != newEdges.end() ; ++it)
	{
		if(!mne.isMarked(*it))
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		{
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			unsigned int idedge = map.getNewEdgeId();
			map.setEdgeId(*it, idedge, EDGE);
			mne.markOrbit(EDGE,*it);
		}
	}
	}
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	{
	//Third step : 3-sew internal faces
	for (std::vector<std::pair<Dart,Dart> >::iterator it = subdividedfacesQ.begin(); it != subdividedfacesQ.end(); ++it)
	{
		Dart f1 = (*it).first;
		Dart f2 = (*it).second;
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		if(map.phi3(map.phi2(f1)) == map.phi2(f1) && map.phi3(map.phi2(f2)) == map.phi2(f2))
		{
			//id pour toutes les faces interieures
			map.sewVolumes(map.phi2(f1), map.phi2(f2));

			//Fais a la couture !!!!!
			unsigned int idface = map.getNewFaceId();
			map.setFaceId(map.phi2(f1),idface, FACE);
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		}

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		//FAIS a la couture !!!!!!!
		//id pour toutes les aretes exterieurs des faces quadrangulees
		unsigned int idedge = map.getEdgeId(f1);
		map.setEdgeId(map.phi2(f1), idedge, DART);
		map.setEdgeId( map.phi2(f2), idedge, DART);
	}

	//LA copie de L'id est a gerer avec le sewVolumes normalement !!!!!!
	//id pour les aretes interieurs : (i.e. 6 pour un hexa)
	DartMarker mne(map);
	for(std::vector<Dart>::iterator it = newEdges.begin() ; it != newEdges.end() ; ++it)
	{
		if(!mne.isMarked(*it))
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		{
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			unsigned int idedge = map.getNewEdgeId();
			map.setEdgeId(*it, idedge, EDGE);
			mne.markOrbit(EDGE,*it);
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		}
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	}
	}
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	map.setCurrentLevel(cur) ;
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	return subdividedfacesQ.begin()->first;
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}

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template <typename PFP>
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Dart subdivideVolumeClassic(typename PFP::MAP& map, Dart d, typename PFP::TVEC3& position)
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{
	assert(map.getDartLevel(d) <= map.getCurrentLevel() || !"Access to a dart introduced after current level") ;
	assert(!map.volumeIsSubdivided(d) || !"Trying to subdivide an already subdivided volume") ;

	unsigned int vLevel = map.volumeLevel(d);
	Dart old = map.volumeOldestDart(d);

	unsigned int cur = map.getCurrentLevel();
	map.setCurrentLevel(vLevel);


	/*
	 * au niveau du volume courant i
	 * stockage d'un brin de chaque face de celui-ci
	 * avec calcul du centroid
	 */

	DartMarkerStore mf(map);		// Lock a face marker to save one dart per face
	CellMarker mv(map, VERTEX);

	typename PFP::VEC3 volCenter;
	unsigned count = 0 ;

	//Store faces that are traversed and start with the face of d
	std::vector<Dart> visitedFaces;
	visitedFaces.reserve(20);
	visitedFaces.push_back(old);

	//Store the edges before the cutEdge
	std::vector<Dart> oldEdges;
	oldEdges.reserve(20);

	mf.markOrbit(FACE, old) ;

	for(std::vector<Dart>::iterator face = visitedFaces.begin(); face != visitedFaces.end(); ++face)
	{
		Dart e = *face ;
		do
		{
			//add one old edge per vertex to the old edge list
			//compute volume centroid
			if(!mv.isMarked(e))
			{
				mv.mark(e);
				volCenter += position[e];
				++count;
				oldEdges.push_back(e);
			}

			// add all face neighbours to the table
			Dart ee = map.phi2(e) ;
			if(!mf.isMarked(ee)) // not already marked
			{
				visitedFaces.push_back(ee) ;
				mf.markOrbit(FACE, ee) ;
			}

			e = map.phi1(e) ;
		} while(e != *face) ;
	}

	volCenter /= typename PFP::REAL(count) ;

	/*
	 * Subdivision
	 */

	//Store the darts from quadrangulated faces
	std::vector<std::pair<Dart,Dart> > subdividedfaces;
	subdividedfaces.reserve(25);

	//First step : subdivide edges and faces
	//creates a i+1 edge level and i+1 face level
	for (std::vector<Dart>::iterator face = visitedFaces.begin(); face != visitedFaces.end(); ++face)
	{
		Dart d = *face;

		//if needed subdivide face
		if(!map.faceIsSubdivided(d))
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			Algo::IHM::subdivideFace<PFP>(map, d, position, Algo::IHM::S_QUAD);
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		//save a dart from the subdivided face
		unsigned int cur = map.getCurrentLevel() ;

		unsigned int fLevel = map.faceLevel(d) + 1; //puisque dans tous les cas, la face est subdivisee
		map.setCurrentLevel(fLevel) ;


		//le brin est forcement du niveau cur
		Dart cf = map.phi1(d);
		Dart e = cf;
		do
		{
			subdividedfaces.push_back(std::pair<Dart,Dart>(e,map.phi2(e)));
			e = map.phi2(map.phi1(e));
		}while (e != cf);

		map.setCurrentLevel(cur);
	}

	map.setCurrentLevel(vLevel + 1) ; // go to the next level to perform volume subdivision

	std::vector<Dart> newEdges;	//save darts from inner edges
	newEdges.reserve(50);

	//Second step : deconnect each corner, close each hole, subdivide each new face into 3
	for (std::vector<Dart>::iterator edge = oldEdges.begin(); edge != oldEdges.end(); ++edge)
	{
		Dart e = *edge;

		Dart f1 = map.phi1(*edge);

		do
		{
			map.unsewFaces(map.phi1(map.phi1(e)));

			map.unsewFaces(map.phi1(e));

			e = map.phi2(map.phi_1(e));
		}
		while(e != *edge);

		map.closeHole(f1);

		Dart old = map.phi2(map.phi1(e));
		Dart dd = map.phi1(map.phi1(old)) ;
		map.splitFace(old,dd) ;

		Dart ne = map.phi1(map.phi1(old)) ;

		map.cutEdge(ne);
		position[map.phi1(ne)] = volCenter; //plonger a la fin de la boucle ????
		newEdges.push_back(ne);
		newEdges.push_back(map.phi1(ne));


		Dart stop = map.phi2(map.phi1(ne));
		ne = map.phi2(ne);
		do
		{
			dd = map.phi1(map.phi1(map.phi1(ne)));

			//A Verifier !!
			map.splitFace(ne, dd) ;

			newEdges.push_back(map.phi1(dd));

			ne = map.phi2(map.phi_1(ne));
			dd = map.phi1(map.phi1(dd));
		}
		while(dd != stop);
	}

	//Third step : 3-sew internal faces
	for (std::vector<std::pair<Dart,Dart> >::iterator it = subdividedfaces.begin(); it != subdividedfaces.end(); ++it)
	{
		Dart f1 = (*it).first;
		Dart f2 = (*it).second;

		if(map.phi3(map.phi2(f1)) == map.phi2(f1) && map.phi3(map.phi2(f2)) == map.phi2(f2))
		{
				//id pour toutes les faces interieures
				map.sewVolumes(map.phi2(f1), map.phi2(f2));

				//Fais a la couture !!!!!
				unsigned int idface = map.getNewFaceId();
				map.setFaceId(map.phi2(f1),idface, FACE);
		}

		//FAIS a la couture !!!!!!!
		//id pour toutes les aretes exterieurs des faces quadrangulees
		unsigned int idedge = map.getEdgeId(f1);
		map.setEdgeId(map.phi2(f1), idedge, DART);
		map.setEdgeId( map.phi2(f2), idedge, DART);
	}

	//LA copie de L'id est a gerer avec le sewVolumes normalement !!!!!!
	//id pour les aretes interieurs : (i.e. 6 pour un hexa)
	DartMarker mne(map);
	for(std::vector<Dart>::iterator it = newEdges.begin() ; it != newEdges.end() ; ++it)
	{
		if(!mne.isMarked(*it))
		{
			unsigned int idedge = map.getNewEdgeId();
			map.setEdgeId(*it, idedge, EDGE);
			mne.markOrbit(EDGE,*it);
		}
	}

	map.setCurrentLevel(cur) ;

	return subdividedfaces.begin()->first;
}
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/************************************************************************************************
 * 									Simplification												*
 ************************************************************************************************/
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template <typename PFP>
void coarsenEdge(typename PFP::MAP& map, Dart d, typename PFP::TVEC3& position)
{
	assert(map.getDartLevel(d) <= map.getCurrentLevel() || !"Access to a dart introduced after current level") ;
	assert(map.edgeCanBeCoarsened(d) || !"Trying to coarsen an edge that can not be coarsened") ;

	unsigned int cur = map.getCurrentLevel() ;
	map.setCurrentLevel(cur + 1) ;
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	map.uncutEdge(d) ;
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	map.setCurrentLevel(cur) ;
}

template <typename PFP>
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void coarsenFace(typename PFP::MAP& map, Dart d, typename PFP::TVEC3& position, SubdivideType sType)
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{
	assert(map.getDartLevel(d) <= map.getCurrentLevel() || !"Access to a dart introduced after current level") ;
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	assert(map.faceIsSubdividedOnce(d) || !"Trying to coarsen a non-subdivided face or a more than once subdivided face") ;
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	unsigned int cur = map.getCurrentLevel() ;

	unsigned int degree = 0 ;
	Dart fit = d ;
	do
	{
		++degree ;
		fit = map.phi1(fit) ;
	} while(fit != d) ;

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	Dart d3 = map.phi3(d);

	if(degree == 3 && sType == Algo::IHM::S_TRI)
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	{
//		fit = d ;
//		do
//		{
//			map.setCurrentLevel(cur + 1) ;
//			Dart innerEdge = map.phi1(fit) ;
//			map.setCurrentLevel(map.getMaxLevel()) ;
//			map.mergeFaces(innerEdge) ;
//			map.setCurrentLevel(cur) ;
//			fit = map.phi1(fit) ;
//		} while(fit != d) ;
	}
	else
	{
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		//map.setCurrentLevel(cur + 1) ;
		//Dart centralV = map.phi1(map.phi1(d)) ;
		//map.setCurrentLevel(map.getMaxLevel()) ;
		//map.deleteVertex(centralV) ;
		//map.setCurrentLevel(cur) ;

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		map.setCurrentLevel(cur + 1) ;
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		Dart d3 = map.phi3(d);
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		map.setCurrentLevel(cur) ;

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		fit = d ;
		do
		{
			map.setCurrentLevel(cur + 1) ;

			Dart innerEdge = map.phi1(fit);
			Dart innerEdge3 = map.phi3(innerEdge);
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			if(innerEdge != innerEdge3)
			{
				map.unsewVolumes(innerEdge);
				map.Map2::mergeFaces(innerEdge3);
			}

			map.Map2::mergeFaces(innerEdge) ;

			map.setCurrentLevel(cur) ;
			fit = map.phi1(fit);

		}while(fit != d);

		map.setCurrentLevel(cur + 1) ;
		if(d != d3)
			map.sewVolumes(d, d3);
		map.setCurrentLevel(cur) ;

	}

// A faire de coarsenVolume
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//	fit = d ;
//	do
//	{
//		if(map.edgeCanBeCoarsened(fit))
//			coarsenEdge<PFP>(map, fit, position) ;
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//
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//		fit = map.phi1(fit) ;
//	} while(fit != d) ;
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}

template <typename PFP>
void coarsenVolume(typename PFP::MAP& map, Dart d, typename PFP::TVEC3& position)
{
	assert(map.getDartLevel(d) <= map.getCurrentLevel() || !"Access to a dart introduced after current level") ;
	//assert(map.volumeIsSubdivdedOnce(d) || !"Trying to coarsen a non-subdivided volume or a more than once subdivided volume") ;

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	unsigned int cur = map.getCurrentLevel() ;

	/*
	 * au niveau du volume courant i
	 * stockage d'un brin de chaque face de celui-ci
	 * avec calcul du centroid
	 */

	DartMarkerStore mf(map);		// Lock a face marker to save one dart per face

	//Store faces that are traversed and start with the face of d
	std::vector<Dart> visitedFaces;
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	visitedFaces.reserve(512);
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	visitedFaces.push_back(d);

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	mf.markOrbit(FACE, d) ;
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	for(std::vector<Dart>::iterator face = visitedFaces.begin(); face != visitedFaces.end(); ++face)
	{
		Dart e = *face ;
		do
		{
			// add all face neighbours to the table
			Dart ee = map.phi2(e) ;
			if(!mf.isMarked(ee)) // not already marked
			{
				visitedFaces.push_back(ee) ;
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				mf.markOrbit(FACE, ee) ;
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			}

			e = map.phi1(e) ;
		} while(e != *face) ;
	}

	/*
	 * fusionner tous les volumes internes
	 */
	map.setCurrentLevel(cur + 1) ;
	Dart centralV = map.phi_1(map.phi2(map.phi1(d)));
	map.deleteVertex(centralV) ;
	map.setCurrentLevel(cur) ;

	/*
	 * simplifier les faces
	 */
	for(std::vector<Dart>::iterator face = visitedFaces.begin(); face != visitedFaces.end(); ++face)
	{
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		Dart fit = *face;
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		if(map.faceCanBeCoarsened(fit))
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		{
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			Algo::IHM::coarsenFace<PFP>(map, fit, position, Algo::IHM::S_QUAD);