CAD4FE/src/CAD4FE_LocalEdgeCriteria.cpp

//---------------------------------------------------------------------------
#include <fstream>
#include <sstream>
              
//---------------------------------------------------------------------------
// include MAGIC Headers
#include "gestionversion.h"
#include <mg_geometrie.h>
#include <mg_maillage.h>
#include <mg_maillage_outils.h>
#include <ot_mathematique.h>

#include "CAD4FE_MCEdge.h"     
#include "CAD4FE_MCAA.h"   
#include "CAD4FE_MCBody.h"
#include "CAD4FE_mg_utils.h"
#include "CAD4FE_Intersection_Plane_MG_MAILLAGE.h"
#include "ot_algorithme_geometrique.h"
#include "CAD4FE_Criteria.h"
#include "CAD4FE_ColorMap.h"

#pragma hdrstop

#include "CAD4FE_LocalEdgeCriteria.h"

//---------------------------------------------------------------------------

#pragma package(smart_init)

using namespace CAD4FE;

//------------------------------------------------------------------------------
// Edge Local Properties

LocalEdgeCriteria::LocalEdgeCriteria(MG_SEGMENT * __seg, MCAA * __mcaa, MG_MAILLAGE * __mesh, MG_SEGMENT * __startSeg)
: _seg(__seg), _mcaa(__mcaa), _mesh(__mesh), _startSeg(__startSeg), _normalOffset(NULL)
{
        double x[2][3];
        MG_UTILS::MG_NOEUD_GET_XYZ(_seg->get_noeud1(), x[0]);
        MG_UTILS::MG_NOEUD_GET_XYZ(_seg->get_noeud2(), x[1]);
        //        _deletionScoreOppositeEdge = 0;

        /* GF Debug int nb_triangles_adj_start_segment = __startSeg->get_lien_triangle()->get_nb();
        printf("start seg %ld : %d triangles adjacents\n", __startSeg->get_id(), nb_triangles_adj_start_segment);*/

        for (unsigned i=0; i<3; i++)
        {
                _P[i] = .5*(x[0][i]+x[1][i]);
                _N[i] = x[1][i]-_P[i];
        }   
                     
        _meshSize = 0;
        _normalOffset = 0;

        _mcEdge = NULL;

        Update();       
        if (_mcEdge) time = _mcEdge->time;
}
//------------------------------------------------------------------------------

LocalEdgeCriteria::~LocalEdgeCriteria()
{
        delete  _normalOffset;
}
//------------------------------------------------------------------------------

void
LocalEdgeCriteria::Update(bool __reconstructNormalOffset)
{
    _meshSize = _mcaa->GetSize(_P);
    
    double targetLength = .86*_meshSize;
    if ( __reconstructNormalOffset
        ||!_normalOffset                                                   )
// inutile?        || fabs ( 1 - 2*targetLength/_normalOffset->GetTargetLength()) > .1)
    {
        if (_normalOffset) delete _normalOffset;
        _normalOffset = new Intersection_Plane_MG_MAILLAGE(_P, _N, _mesh, targetLength, _startSeg, NULL);
    }

    InitSetOfTouchingEdges();

        std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl  = _normalOffset->GetPolyline();
        int nb_pts = pl.size();
        int o = _normalOffset->GetOriginIndex();

        // Get the mc edge attached to the start segment
        {
                MG_SEGMENT * seg = pl[o].E;
                MG_ELEMENT_TOPOLOGIQUE * topo = seg->get_lien_topologie();
                if ( topo && topo->get_dimension() == 1)
                {
                        MCEdge * edge = (MCEdge*) topo;
                        _mcEdge = edge;
                        time = _mcEdge->time;
                }
                else
                {
                    _mcEdge = (MCEdge*)_seg->get_lien_topologie();
                }
        }

        for (unsigned i=0; i<2; i++)
        {
                _lengthToOppositeEdges[i] = 0;
                _oppositeEdgesPolylineIndices[i] = -1;
                _oppositeEdges[i] = NULL;
        }

        for (int j = 0; j < 2; j++)
        {
                for (int i = 0; i+1 < nb_pts; i++)
                {
                        int k[2];
                        if (j == 0)
                        {
                                k[0] = o - i;
                                k[1] = o - i - 1;
                                if (k[1] < 0 || k[1] >= nb_pts)
                                        break;
                        }
                        else if (j == 1)
                        {
                                k[0] = o + i;
                                k[1] = o + i + 1;
                                if (k[1] < 0 || k[1] >= nb_pts)
                                        break;
                        }

                        MG_SEGMENT * Seg [2];
                        MG_NOEUD * No [2];
                        OT_VECTEUR_3D xyz[2];
                        double dl;

                        for (unsigned l = 0; l < 2; l++)
                        {
                                xyz[l] = pl[k[l]].X;
                                Seg[l] = pl[k[l]].E;
                                No[l] = pl[k[l]].V;
                        }

                        MG_ELEMENT_TOPOLOGIQUE * topo;
                        topo = Seg[1]->get_lien_topologie();

                        if (topo  && topo->get_dimension() == 1 )
                        {
                                _oppositeEdges[j] = (MCEdge *) topo;
                                _oppositeEdgesPolylineIndices[j] = k[1];
                        }
                        else
                        {
                                _oppositeEdges[j] = NULL;
                                _oppositeEdgesPolylineIndices[j] = -1;
                        }

                        dl = (xyz[0] - xyz[1]).get_longueur();
                        _lengthToOppositeEdges[j] += dl;

                        if ( _oppositeEdges[j] )
                                break;
                }
        }
                                 
        _point = pl[o].X;
        double * segStart = pl[0].X, * segEnd = pl[nb_pts-1].X;
        for (unsigned i=0;i<3;i++)
        {
                _segment [0][i] = segStart[i];
                _segment [1][i] = segEnd[i];
        }

        /** Compute the local edge properties */
        // Face width
        _faceWidth = std::min( _lengthToOppositeEdges[0], _lengthToOppositeEdges[1] );
        // Epsilon (distance between the mesh and the geometry
        _epsilon = OT_ALGORITHME_GEOMETRIQUE::Dist3D_Point_Segment( _segment [0], _segment [1], _point);
        // Angle between the 2 edge segments
        if ( _segment [0] == _point || _segment [1] == _point )
            _deviationAngle = 0;
        else
            _deviationAngle = OT_ALGORITHME_GEOMETRIQUE::Angle3D_Segment_Segment( _segment [0], _point, _segment [1] );
}
//------------------------------------------------------------------------------

double LocalEdgeCriteria::DeletionScore_FaceWidth() const
{
    double criterionFaceWidth;
    double limitFaceWidth = _meshSize / _mcaa->GetMaxOverdensity();

    if ( _oppositeEdges[0] || _oppositeEdges[1] )
    {
        if (_faceWidth <  limitFaceWidth)
            criterionFaceWidth = 1 - _faceWidth / limitFaceWidth;
        else
            criterionFaceWidth = .05 * (1 - _faceWidth / limitFaceWidth);
    }
    else
        criterionFaceWidth = -.05;

    return criterionFaceWidth;
}          
//------------------------------------------------------------------------------

double LocalEdgeCriteria::DeletionScore_DeviationAngle() const
{             
    double criterionAngle;                 
    double limitAngle = _mcaa->GetLimitAngle();

        if (_deviationAngle < limitAngle)
                criterionAngle = 1 - _deviationAngle / limitAngle;
        else
                criterionAngle = .2*(1 - _deviationAngle / limitAngle);

    return criterionAngle;
}
//------------------------------------------------------------------------------

double LocalEdgeCriteria::DeletionScore() const
{
        int i, NB_CRITERIA = 0;
        double score = 0;
        double val[10];

        if (_mcaa->GetMCBody()->G21()->GetArc(_mcEdge->get_id())->Rank() != 2)
            return 0;

        if (_mcEdge && _mcEdge->get_nb_ccf())
            return 0;

        val[NB_CRITERIA++] = DeletionScore_FaceWidth();
        val[NB_CRITERIA++] = DeletionScore_DeviationAngle();
        //        val[NB_CRITERIA++] = DeletionScore_OppositeEdge();

        for (i=0;i<NB_CRITERIA;i++)
        {
            if (score < val[i])
            {
                score = val[i];
            }
        }

        return score;
}
//------------------------------------------------------------------------------

void LocalEdgeCriteria::GetPolylineVertex(int i, float * __vec3f) const
{
    const double * vec3d = _normalOffset->GetPolyline()[i].X;
    for (int i=0; i<3; i++)
        __vec3f[i] = vec3d[i];
}
//------------------------------------------------------------------------------

unsigned LocalEdgeCriteria::GetPolylineVerticesCount() const
{
    return _normalOffset->GetPolyline().size();
}
//------------------------------------------------------------------------------

std::string
LocalEdgeCriteria::InventorText()
{
        std::ostringstream out;

        unsigned char rgb[3];
        ColorMap::jetColorMap(rgb, 1-DeletionScore(), 0, 1);
        _normalOffset->SetColor(rgb);
        out << _normalOffset->InventorText();

        for (unsigned j=0; j<2; j++)
        if (_oppositeEdgesPolylineIndices[j] != -1) {
                int i = _oppositeEdgesPolylineIndices[j];
                std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl  = _normalOffset->GetPolyline();
                out << "\nSeparator { #sep1 \n";
                out <<  "\n Coordinate3 {\n point [ \n";
                out <<  pl[i].X[0] << " " <<pl[i].X[1] << " " << pl[i].X[2] << " \n";
                out <<  "\n]\n}\n";
                out << "PolygonOffset { \n";
                out << "styles POINTS \n";
                out << "factor 4.0   \n";
                out << "units 1.0    \n";
                out << "}          \n";
                out <<  "DrawStyle {\npointSize 4\n}\n";
                out <<  "BaseColor { \n rgb  1.0 0.0 0.0\n }\n";
                out <<  "PointSet {\nstartIndex "<<0<<"\nnumPoints "<<1<<"\n}\n";
                out << "} # end Sep1 \n";
        }

        return out.str();
}
//------------------------------------------------------------------------------

MCEdge * LocalEdgeCriteria::GetEdge()
{
        return _mcEdge;
}
//------------------------------------------------------------------------------

MG_SEGMENT * LocalEdgeCriteria::GetSegment() 
{       
    return _seg;
}
//------------------------------------------------------------------------------

double  LocalEdgeCriteria::GetFaceWidth()
{
        return _faceWidth;
}
//------------------------------------------------------------------------------

double LocalEdgeCriteria::GetEpsilon()
{
        return _epsilon;
}
//------------------------------------------------------------------------------

double  LocalEdgeCriteria::GetDeviationAngle()
{                    
        return _deviationAngle;
}
//------------------------------------------------------------------------------
bool LocalEdgeCriteria::IsTouchingEdge(MCEdge * __mcEdge)
{
        return _setTouchingEdge.find(__mcEdge) != _setTouchingEdge.end();
}                                                                              
//------------------------------------------------------------------------------
bool LocalEdgeCriteria::IsTouchingSegment(MG_SEGMENT * __segment)
{
        if (__segment == NULL)
            return false;

        std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl  = _normalOffset->GetPolyline();
        unsigned nb_pts = pl.size();

        // Get the mc edge attached to the start segment
        for (unsigned i = 0; i < nb_pts; i++)
        {
                MG_SEGMENT * seg = pl[i].E;

                if (seg == __segment)
                    return true;
        }

        return false;
}                                                                             
//------------------------------------------------------------------------------
bool LocalEdgeCriteria::IsStartSegment(MG_SEGMENT * __segment)
{                             
        if (__segment == NULL)
            return false;
            
        std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl  = _normalOffset->GetPolyline();
        unsigned int o = _normalOffset->GetOriginIndex();

        return (pl[o].E == __segment);
}
//------------------------------------------------------------------------------

MCEdge * LocalEdgeCriteria::GetTouchingEdge(int __index)
{
        if (__index >= 0 && __index < 2)
            return _oppositeEdges[__index];
        else
        {
            printf("Error GetTouchingEdge: __index = %d\n", __index);
            return NULL;
        }
}
//------------------------------------------------------------------------------

double LocalEdgeCriteria::GetLengthToTouchingEdge(int __index)
{
        if (__index >= 0 && __index < 2)
            return _lengthToOppositeEdges[__index];
        else
        {
            printf("Error GetLengthToTouchingEdge: __index = %d\n", __index);
            return -1;
        }
}
//------------------------------------------------------------------------------
MCEdge * LocalEdgeCriteria::GetClosestTouchingEdge()
{
        return (_lengthToOppositeEdges[0] < _lengthToOppositeEdges[1])
              ?  _oppositeEdges[0]
              : _oppositeEdges[1];
}
//------------------------------------------------------------------------------
double * LocalEdgeCriteria::GetClosestTouchingEdgePoint()
{
        int i = (_lengthToOppositeEdges[0] < _lengthToOppositeEdges[1])
              ?  0
              : 1;
        return _normalOffset->GetPolyline()[ _oppositeEdgesPolylineIndices [i] ].X;
}

double * LocalEdgeCriteria::GetTouchingEdgePoint(int __index)
{
        if (__index >= 0 && __index < 2)
            return _normalOffset->GetPolyline()[ _oppositeEdgesPolylineIndices [__index] ].X;
        else
        {             
            printf("Error GetLengthToTouchingEdge: __index = %d\n", __index);
            return 0;
        }
}
//------------------------------------------------------------------------------
void LocalEdgeCriteria::CheckMCTess()
{
        std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl  = _normalOffset->GetPolyline();
        int nb_pts = pl.size();
        int o = _normalOffset->GetOriginIndex();

        for (int j = 0; j < 2; j++)
        {
                for (int i = 0; i+1 < nb_pts; i++)
                {
                        int k[2];
                        if (j == 0)
                        {
                                k[0] = o - i;
                                k[1] = o - i - 1;
                                if (k[1] < 0 || k[1] >= nb_pts)
                                        break;
                        }
                        else if (j == 1)
                        {
                                k[0] = o + i;
                                k[1] = o + i + 1;
                                if (k[1] < 0 || k[1] >= nb_pts)
                                        break;
                        }

                        MG_SEGMENT * Seg [2];
                        MG_NOEUD * No [2];
                        OT_VECTEUR_3D xyz[2];
                        double dl;

                        for (unsigned l = 0; l < 2; l++)
                        {
                                xyz[l] = pl[k[l]].X;
                                Seg[l] = pl[k[l]].E;
                                No[l] = pl[k[l]].V;
                        }

                        MG_ELEMENT_TOPOLOGIQUE * topo;
                        topo = Seg[1]->get_lien_topologie();

                        if ( ! _mcaa->GetMCTess()->contient(Seg[1]))
                            printf("The MC Tessellation does not contains a segment crossed by LEC's polyline !\n");
                        _mcaa->CheckIfTopoExists(topo);
                        if (topo->get_dimension() < 2)
                            break;
                }
        }
}

// void LocalEdgeCriteria::Set_DeletionScore_OppositeEdge(double __value)
// {
//     _deletionScoreOppositeEdge = __value;
// }

// double LocalEdgeCriteria::DeletionScore_OppositeEdge() const
// {
//     if (_deletionScoreOppositeEdge>0)
//         printf("ha!\n");
//     return _deletionScoreOppositeEdge;
// }

double LocalEdgeCriteria::GetMeshSize()
{
    return _meshSize;
}

void LocalEdgeCriteria::InitSetOfTouchingEdges()
{
    std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl  = _normalOffset->GetPolyline();
    unsigned nb_pts = pl.size();
                                     
    _setTouchingEdge.clear();
    for (unsigned i = 0; i < nb_pts; i++)
    {
            MG_SEGMENT * seg = pl[i].E;
            MG_ELEMENT_TOPOLOGIQUE * topo = seg->get_lien_topologie();
            if (topo && topo->get_dimension() == 1)
                _setTouchingEdge.insert((MCEdge*)topo);
    }
}
Revision:	569
Committed:	Thu Oct 16 14:36:31 2014 UTC (10 years, 6 months ago) by foucault
File size:	16712 byte(s)
Error occurred while calculating annotation data.
Log Message:	Mise à jour pour CAD4FE (Gilles) : operation 1 (tentative)
#	Content
1	//---------------------------------------------------------------------------
2	#include <fstream>
3	#include <sstream>
4
5	//---------------------------------------------------------------------------
6	// include MAGIC Headers
7	#include "gestionversion.h"
8	#include <mg_geometrie.h>
9	#include <mg_maillage.h>
10	#include <mg_maillage_outils.h>
11	#include <ot_mathematique.h>
12
13	#include "CAD4FE_MCEdge.h"
14	#include "CAD4FE_MCAA.h"
15	#include "CAD4FE_MCBody.h"
16	#include "CAD4FE_mg_utils.h"
17	#include "CAD4FE_Intersection_Plane_MG_MAILLAGE.h"
18	#include "ot_algorithme_geometrique.h"
19	#include "CAD4FE_Criteria.h"
20	#include "CAD4FE_ColorMap.h"
21
22	#pragma hdrstop
23
24	#include "CAD4FE_LocalEdgeCriteria.h"
25
26	//---------------------------------------------------------------------------
27
28	#pragma package(smart_init)
29
30	using namespace CAD4FE;
31
32	//------------------------------------------------------------------------------
33	// Edge Local Properties
34
35	LocalEdgeCriteria::LocalEdgeCriteria(MG_SEGMENT * __seg, MCAA * __mcaa, MG_MAILLAGE * __mesh, MG_SEGMENT * __startSeg)
36	: _seg(__seg), _mcaa(__mcaa), _mesh(__mesh), _startSeg(__startSeg), _normalOffset(NULL)
37	{
38	double x[2][3];
39	MG_UTILS::MG_NOEUD_GET_XYZ(_seg->get_noeud1(), x[0]);
40	MG_UTILS::MG_NOEUD_GET_XYZ(_seg->get_noeud2(), x[1]);
41	// _deletionScoreOppositeEdge = 0;
42
43	/* GF Debug int nb_triangles_adj_start_segment = __startSeg->get_lien_triangle()->get_nb();
44	printf("start seg %ld : %d triangles adjacents\n", __startSeg->get_id(), nb_triangles_adj_start_segment);*/
45
46	for (unsigned i=0; i<3; i++)
47	{
48	_P[i] = .5*(x[0][i]+x[1][i]);
49	_N[i] = x[1][i]-_P[i];
50	}
51
52	_meshSize = 0;
53	_normalOffset = 0;
54
55	_mcEdge = NULL;
56
57	Update();
58	if (_mcEdge) time = _mcEdge->time;
59	}
60	//------------------------------------------------------------------------------
61
62	LocalEdgeCriteria::~LocalEdgeCriteria()
63	{
64	delete _normalOffset;
65	}
66	//------------------------------------------------------------------------------
67
68	void
69	LocalEdgeCriteria::Update(bool __reconstructNormalOffset)
70	{
71	_meshSize = _mcaa->GetSize(_P);
72
73	double targetLength = .86*_meshSize;
74	if ( __reconstructNormalOffset
75	\|\|!_normalOffset )
76	// inutile? \|\| fabs ( 1 - 2*targetLength/_normalOffset->GetTargetLength()) > .1)
77	{
78	if (_normalOffset) delete _normalOffset;
79	_normalOffset = new Intersection_Plane_MG_MAILLAGE(_P, _N, _mesh, targetLength, _startSeg, NULL);
80	}
81
82	InitSetOfTouchingEdges();
83
84	std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl = _normalOffset->GetPolyline();
85	int nb_pts = pl.size();
86	int o = _normalOffset->GetOriginIndex();
87
88	// Get the mc edge attached to the start segment
89	{
90	MG_SEGMENT * seg = pl[o].E;
91	MG_ELEMENT_TOPOLOGIQUE * topo = seg->get_lien_topologie();
92	if ( topo && topo->get_dimension() == 1)
93	{
94	MCEdge * edge = (MCEdge*) topo;
95	_mcEdge = edge;
96	time = _mcEdge->time;
97	}
98	else
99	{
100	_mcEdge = (MCEdge*)_seg->get_lien_topologie();
101	}
102	}
103
104	for (unsigned i=0; i<2; i++)
105	{
106	_lengthToOppositeEdges[i] = 0;
107	_oppositeEdgesPolylineIndices[i] = -1;
108	_oppositeEdges[i] = NULL;
109	}
110
111	for (int j = 0; j < 2; j++)
112	{
113	for (int i = 0; i+1 < nb_pts; i++)
114	{
115	int k[2];
116	if (j == 0)
117	{
118	k[0] = o - i;
119	k[1] = o - i - 1;
120	if (k[1] < 0 \|\| k[1] >= nb_pts)
121	break;
122	}
123	else if (j == 1)
124	{
125	k[0] = o + i;
126	k[1] = o + i + 1;
127	if (k[1] < 0 \|\| k[1] >= nb_pts)
128	break;
129	}
130
131	MG_SEGMENT * Seg [2];
132	MG_NOEUD * No [2];
133	OT_VECTEUR_3D xyz[2];
134	double dl;
135
136	for (unsigned l = 0; l < 2; l++)
137	{
138	xyz[l] = pl[k[l]].X;
139	Seg[l] = pl[k[l]].E;
140	No[l] = pl[k[l]].V;
141	}
142
143	MG_ELEMENT_TOPOLOGIQUE * topo;
144	topo = Seg[1]->get_lien_topologie();
145
146	if (topo && topo->get_dimension() == 1 )
147	{
148	_oppositeEdges[j] = (MCEdge *) topo;
149	_oppositeEdgesPolylineIndices[j] = k[1];
150	}
151	else
152	{
153	_oppositeEdges[j] = NULL;
154	_oppositeEdgesPolylineIndices[j] = -1;
155	}
156
157	dl = (xyz[0] - xyz[1]).get_longueur();
158	_lengthToOppositeEdges[j] += dl;
159
160	if ( _oppositeEdges[j] )
161	break;
162	}
163	}
164
165	_point = pl[o].X;
166	double * segStart = pl[0].X, * segEnd = pl[nb_pts-1].X;
167	for (unsigned i=0;i<3;i++)
168	{
169	_segment [0][i] = segStart[i];
170	_segment [1][i] = segEnd[i];
171	}
172
173	/** Compute the local edge properties */
174	// Face width
175	_faceWidth = std::min( _lengthToOppositeEdges[0], _lengthToOppositeEdges[1] );
176	// Epsilon (distance between the mesh and the geometry
177	_epsilon = OT_ALGORITHME_GEOMETRIQUE::Dist3D_Point_Segment( _segment [0], _segment [1], _point); // Angle between the 2 edge segments
178	if ( _segment [0] == _point \|\| _segment [1] == _point )
179	_deviationAngle = 0;
180	else
181	_deviationAngle = OT_ALGORITHME_GEOMETRIQUE::Angle3D_Segment_Segment( _segment [0], _point, _segment [1] );
182	}
183	//------------------------------------------------------------------------------
184
185	double LocalEdgeCriteria::DeletionScore_FaceWidth() const
186	{
187	double criterionFaceWidth;
188	double limitFaceWidth = _meshSize / _mcaa->GetMaxOverdensity();
189
190	if ( _oppositeEdges[0] \|\| _oppositeEdges[1] )
191	{
192	if (_faceWidth < limitFaceWidth)
193	criterionFaceWidth = 1 - _faceWidth / limitFaceWidth;
194	else
195	criterionFaceWidth = .05 * (1 - _faceWidth / limitFaceWidth);
196	}
197	else
198	criterionFaceWidth = -.05;
199
200	return criterionFaceWidth;
201	}
202	//------------------------------------------------------------------------------
203
204	double LocalEdgeCriteria::DeletionScore_DeviationAngle() const
205	{
206	double criterionAngle;
207	double limitAngle = _mcaa->GetLimitAngle();
208
209	if (_deviationAngle < limitAngle)
210	criterionAngle = 1 - _deviationAngle / limitAngle;
211	else
212	criterionAngle = .2*(1 - _deviationAngle / limitAngle);
213
214	return criterionAngle;
215	}
216	//------------------------------------------------------------------------------
217
218	double LocalEdgeCriteria::DeletionScore() const
219	{
220	int i, NB_CRITERIA = 0;
221	double score = 0;
222	double val[10];
223
224	if (_mcaa->GetMCBody()->G21()->GetArc(_mcEdge->get_id())->Rank() != 2)
225	return 0;
226
227	if (_mcEdge && _mcEdge->get_nb_ccf())
228	return 0;
229
230	val[NB_CRITERIA++] = DeletionScore_FaceWidth();
231	val[NB_CRITERIA++] = DeletionScore_DeviationAngle();
232	// val[NB_CRITERIA++] = DeletionScore_OppositeEdge();
233
234	for (i=0;i<NB_CRITERIA;i++)
235	{
236	if (score < val[i])
237	{
238	score = val[i];
239	}
240	}
241
242	return score;
243	}
244	//------------------------------------------------------------------------------
245
246	void LocalEdgeCriteria::GetPolylineVertex(int i, float * __vec3f) const
247	{
248	const double * vec3d = _normalOffset->GetPolyline()[i].X;
249	for (int i=0; i<3; i++)
250	__vec3f[i] = vec3d[i];
251	}
252	//------------------------------------------------------------------------------
253
254	unsigned LocalEdgeCriteria::GetPolylineVerticesCount() const
255	{
256	return _normalOffset->GetPolyline().size();
257	}
258	//------------------------------------------------------------------------------
259
260	std::string
261	LocalEdgeCriteria::InventorText()
262	{
263	std::ostringstream out;
264
265	unsigned char rgb[3];
266	ColorMap::jetColorMap(rgb, 1-DeletionScore(), 0, 1);
267	_normalOffset->SetColor(rgb);
268	out << _normalOffset->InventorText();
269
270	for (unsigned j=0; j<2; j++)
271	if (_oppositeEdgesPolylineIndices[j] != -1) {
272	int i = _oppositeEdgesPolylineIndices[j];
273	std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl = _normalOffset->GetPolyline();
274	out << "\nSeparator { #sep1 \n";
275	out << "\n Coordinate3 {\n point [ \n";
276	out << pl[i].X[0] << " " <<pl[i].X[1] << " " << pl[i].X[2] << " \n";
277	out << "\n]\n}\n";
278	out << "PolygonOffset { \n";
279	out << "styles POINTS \n";
280	out << "factor 4.0 \n";
281	out << "units 1.0 \n";
282	out << "} \n";
283	out << "DrawStyle {\npointSize 4\n}\n";
284	out << "BaseColor { \n rgb 1.0 0.0 0.0\n }\n";
285	out << "PointSet {\nstartIndex "<<0<<"\nnumPoints "<<1<<"\n}\n";
286	out << "} # end Sep1 \n";
287	}
288
289	return out.str();
290	}
291	//------------------------------------------------------------------------------
292
293	MCEdge * LocalEdgeCriteria::GetEdge()
294	{
295	return _mcEdge;
296	}
297	//------------------------------------------------------------------------------
298
299	MG_SEGMENT * LocalEdgeCriteria::GetSegment()
300	{
301	return _seg;
302	}
303	//------------------------------------------------------------------------------
304
305	double LocalEdgeCriteria::GetFaceWidth()
306	{
307	return _faceWidth;
308	}
309	//------------------------------------------------------------------------------
310
311	double LocalEdgeCriteria::GetEpsilon()
312	{
313	return _epsilon;
314	}
315	//------------------------------------------------------------------------------
316
317	double LocalEdgeCriteria::GetDeviationAngle()
318	{
319	return _deviationAngle;
320	}
321	//------------------------------------------------------------------------------
322	bool LocalEdgeCriteria::IsTouchingEdge(MCEdge * __mcEdge)
323	{
324	return _setTouchingEdge.find(__mcEdge) != _setTouchingEdge.end();
325	}
326	//------------------------------------------------------------------------------
327	bool LocalEdgeCriteria::IsTouchingSegment(MG_SEGMENT * __segment)
328	{
329	if (__segment == NULL)
330	return false;
331
332	std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl = _normalOffset->GetPolyline();
333	unsigned nb_pts = pl.size();
334
335	// Get the mc edge attached to the start segment
336	for (unsigned i = 0; i < nb_pts; i++)
337	{
338	MG_SEGMENT * seg = pl[i].E;
339
340	if (seg == __segment)
341	return true;
342	}
343
344	return false;
345	}
346	//------------------------------------------------------------------------------
347	bool LocalEdgeCriteria::IsStartSegment(MG_SEGMENT * __segment)
348	{
349	if (__segment == NULL)
350	return false;
351
352	std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl = _normalOffset->GetPolyline();
353	unsigned int o = _normalOffset->GetOriginIndex();
354
355	return (pl[o].E == __segment);
356	}
357	//------------------------------------------------------------------------------
358
359	MCEdge * LocalEdgeCriteria::GetTouchingEdge(int __index)
360	{
361	if (__index >= 0 && __index < 2)
362	return _oppositeEdges[__index];
363	else
364	{
365	printf("Error GetTouchingEdge: __index = %d\n", __index);
366	return NULL;
367	}
368	}
369	//------------------------------------------------------------------------------
370
371	double LocalEdgeCriteria::GetLengthToTouchingEdge(int __index)
372	{
373	if (__index >= 0 && __index < 2)
374	return _lengthToOppositeEdges[__index];
375	else
376	{
377	printf("Error GetLengthToTouchingEdge: __index = %d\n", __index);
378	return -1;
379	}
380	}
381	//------------------------------------------------------------------------------
382	MCEdge * LocalEdgeCriteria::GetClosestTouchingEdge()
383	{
384	return (_lengthToOppositeEdges[0] < _lengthToOppositeEdges[1])
385	? _oppositeEdges[0]
386	: _oppositeEdges[1];
387	}
388	//------------------------------------------------------------------------------
389	double * LocalEdgeCriteria::GetClosestTouchingEdgePoint()
390	{
391	int i = (_lengthToOppositeEdges[0] < _lengthToOppositeEdges[1])
392	? 0
393	: 1;
394	return _normalOffset->GetPolyline()[ _oppositeEdgesPolylineIndices [i] ].X;
395	}
396
397	double * LocalEdgeCriteria::GetTouchingEdgePoint(int __index)
398	{
399	if (__index >= 0 && __index < 2)
400	return _normalOffset->GetPolyline()[ _oppositeEdgesPolylineIndices [__index] ].X;
401	else
402	{
403	printf("Error GetLengthToTouchingEdge: __index = %d\n", __index);
404	return 0;
405	}
406	}
407	//------------------------------------------------------------------------------
408	void LocalEdgeCriteria::CheckMCTess()
409	{
410	std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl = _normalOffset->GetPolyline();
411	int nb_pts = pl.size();
412	int o = _normalOffset->GetOriginIndex();
413
414	for (int j = 0; j < 2; j++)
415	{
416	for (int i = 0; i+1 < nb_pts; i++)
417	{
418	int k[2];
419	if (j == 0)
420	{
421	k[0] = o - i;
422	k[1] = o - i - 1;
423	if (k[1] < 0 \|\| k[1] >= nb_pts)
424	break;
425	}
426	else if (j == 1)
427	{
428	k[0] = o + i;
429	k[1] = o + i + 1;
430	if (k[1] < 0 \|\| k[1] >= nb_pts)
431	break;
432	}
433
434	MG_SEGMENT * Seg [2];
435	MG_NOEUD * No [2];
436	OT_VECTEUR_3D xyz[2];
437	double dl;
438
439	for (unsigned l = 0; l < 2; l++)
440	{
441	xyz[l] = pl[k[l]].X;
442	Seg[l] = pl[k[l]].E;
443	No[l] = pl[k[l]].V;
444	}
445
446	MG_ELEMENT_TOPOLOGIQUE * topo;
447	topo = Seg[1]->get_lien_topologie();
448
449	if ( ! _mcaa->GetMCTess()->contient(Seg[1]))
450	printf("The MC Tessellation does not contains a segment crossed by LEC's polyline !\n");
451	_mcaa->CheckIfTopoExists(topo);
452	if (topo->get_dimension() < 2)
453	break;
454	}
455	}
456	}
457
458	// void LocalEdgeCriteria::Set_DeletionScore_OppositeEdge(double __value)
459	// {
460	// _deletionScoreOppositeEdge = __value;
461	// }
462
463	// double LocalEdgeCriteria::DeletionScore_OppositeEdge() const
464	// {
465	// if (_deletionScoreOppositeEdge>0)
466	// printf("ha!\n");
467	// return _deletionScoreOppositeEdge;
468	// }
469
470	double LocalEdgeCriteria::GetMeshSize()
471	{
472	return _meshSize;
473	}
474
475	void LocalEdgeCriteria::InitSetOfTouchingEdges()
476	{
477	std::vector <Intersection_Plane_MG_MAILLAGE::Vertex> & pl = _normalOffset->GetPolyline();
478	unsigned nb_pts = pl.size();
479
480	_setTouchingEdge.clear();
481	for (unsigned i = 0; i < nb_pts; i++)
482	{
483	MG_SEGMENT * seg = pl[i].E;
484	MG_ELEMENT_TOPOLOGIQUE * topo = seg->get_lien_topologie();
485	if (topo && topo->get_dimension() == 1)
486	_setTouchingEdge.insert((MCEdge*)topo);
487	}
488	}