630 lines
20 KiB
C++
630 lines
20 KiB
C++
/****************************************************************************
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* VCGLib o o *
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* Visual and Computer Graphics Library o o *
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* _ O _ *
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* Copyright(C) 2004 \/)\/ *
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* Visual Computing Lab /\/| *
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* ISTI - Italian National Research Council | *
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* \ *
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* All rights reserved. *
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* *
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* This program is free software; you can redistribute it and/or modify *
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* it under the terms of the GNU General Public License as published by *
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* the Free Software Foundation; either version 2 of the License, or *
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* (at your option) any later version. *
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* *
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* This program is distributed in the hope that it will be useful, *
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* but WITHOUT ANY WARRANTY; without even the implied warranty of *
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
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* GNU General Public License (http://www.gnu.org/licenses/gpl.txt) *
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* for more details. *
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* *
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****************************************************************************/
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#ifndef __VCG_MESH_RESAMPLER
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#define __VCG_MESH_RESAMPLER
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#include <vcg/complex/trimesh/update/normal.h>
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#include <vcg/complex/trimesh/update/flag.h>
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#include <vcg/complex/trimesh/update/bounding.h>
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#include <vcg/complex/trimesh/update/edges.h>
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#include <vcg/complex/trimesh/create/marching_cubes.h>
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#include <vcg/space/index/grid_static_ptr.h>
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#include <vcg/complex/trimesh/closest.h>
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#include <vcg/space/box3.h>
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namespace vcg {
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namespace tri {
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/** \addtogroup trimesh */
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/*@{*/
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/*@{*/
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/** Class Resampler.
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This is class reasmpling a mesh using marching cubes methods
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@param OLD_MESH_TYPE (Template Parameter) Specifies the type of mesh to be resampled
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@param NEW_MESH_TYPE (Template Parameter) Specifies the type of output mesh.
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*/
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template <class OLD_MESH_TYPE,class NEW_MESH_TYPE, class FLT, class DISTFUNCTOR = vcg::face::PointDistanceBaseFunctor<typename OLD_MESH_TYPE::ScalarType > >
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class Resampler : public BasicGrid<FLT>
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{
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typedef OLD_MESH_TYPE Old_Mesh;
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typedef NEW_MESH_TYPE New_Mesh;
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//template <class OLD_MESH_TYPE,class NEW_MESH_TYPE>
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class Walker : BasicGrid<float>
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{
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private:
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typedef int VertexIndex;
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typedef OLD_MESH_TYPE Old_Mesh;
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typedef NEW_MESH_TYPE New_Mesh;
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typedef typename New_Mesh::CoordType NewCoordType;
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typedef typename New_Mesh::VertexType* VertexPointer;
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typedef typename Old_Mesh::FaceContainer FaceCont;
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typedef typename vcg::GridStaticPtr<typename Old_Mesh::FaceType> GridType;
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protected:
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int SliceSize;
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int CurrentSlice;
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typedef tri::FaceTmark<Old_Mesh> MarkerFace;
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MarkerFace markerFunctor;
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VertexIndex *_x_cs; // indici dell'intersezioni della superficie lungo gli Xedge della fetta corrente
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VertexIndex *_y_cs; // indici dell'intersezioni della superficie lungo gli Yedge della fetta corrente
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VertexIndex *_z_cs; // indici dell'intersezioni della superficie lungo gli Zedge della fetta corrente
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VertexIndex *_x_ns; // indici dell'intersezioni della superficie lungo gli Xedge della prossima fetta
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VertexIndex *_z_ns; // indici dell'intersezioni della superficie lungo gli Zedge della prossima fetta
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//float *_v_cs;///values of distance fields for each direction in current slice
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//float *_v_ns;///values of distance fields for each direction in next slice
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typedef typename std::pair<bool,float> field_value;
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field_value* _v_cs;
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field_value* _v_ns;
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New_Mesh *_newM;
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Old_Mesh *_oldM;
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GridType _g;
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public:
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float max_dim; // the limit value of the search (that takes into account of the offset)
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float offset; // an offset value that is always added to the returned value. Useful for extrarting isosurface at a different threshold
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bool DiscretizeFlag; // if the extracted surface should be discretized or not.
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bool MultiSampleFlag;
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bool AbsDistFlag; // if true the Distance Field computed is no more a signed one.
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Walker(const Box3f &_bbox, Point3i _siz )
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{
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this->bbox= _bbox;
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this->siz=_siz;
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ComputeDimAndVoxel();
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SliceSize = (this->siz.X()+1)*(this->siz.Z()+1);
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CurrentSlice = 0;
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offset=0;
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DiscretizeFlag=false;
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MultiSampleFlag=false;
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AbsDistFlag=false;
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_x_cs = new VertexIndex[ SliceSize ];
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_y_cs = new VertexIndex[ SliceSize ];
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_z_cs = new VertexIndex[ SliceSize ];
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_x_ns = new VertexIndex[ SliceSize ];
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_z_ns = new VertexIndex[ SliceSize ];
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_v_cs= new field_value[(this->siz.X()+1)*(this->siz.Z()+1)];
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_v_ns= new field_value[(this->siz.X()+1)*(this->siz.Z()+1)];
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};
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~Walker()
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{}
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float V(const Point3i &p)
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{
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return V(p.V(0),p.V(1),p.V(2));
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}
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std::pair<bool,float> VV(int x,int y,int z)
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{
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assert ((y==CurrentSlice)||(y==(CurrentSlice+1)));
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//test if it is outside the bb of the mesh
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//vcg::Point3f test=vcg::Point3f((float)x,(float)y,(float)z);
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/*if (!_oldM->bbox.IsIn(test))
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return (1.f);*/
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int index=GetSliceIndex(x,z);
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if (y==CurrentSlice) return _v_cs[index];
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else return _v_ns[index];
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}
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float V(int x,int y,int z)
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{
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if(DiscretizeFlag) return VV(x,y,z).second+offset<0?-1:1;
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return VV(x,y,z).second+offset;
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}
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///return true if the distance form the mesh is less than maxdim and return distance
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field_value DistanceFromMesh(Point3f &pp,Old_Mesh */*mesh*/)
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{
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float dist;
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typename Old_Mesh::FaceType *f=NULL;
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const float max_dist = max_dim;
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vcg::Point3f testPt;
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this->IPfToPf(pp,testPt);
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vcg::Point3f closestNormV,closestNormF;
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vcg::Point3f closestPt;
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vcg::Point3f pip(-1,-1,-1);
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// Note that PointDistanceBaseFunctor does not require the edge and plane precomptued.
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// while the PointDistanceFunctor requires them.
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DISTFUNCTOR PDistFunct;
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f = _g.GetClosest(PDistFunct,markerFunctor,testPt,max_dist,dist,closestPt);
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if (f==NULL) return field_value(false,0);
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if(AbsDistFlag) return field_value(true,dist);
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assert(!f->IsD());
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bool retIP;
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// To compute the interpolated normal we use the more robust function that require to know what is the most orhogonal direction of the face.
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if((*f).Flags() & Old_Mesh::FaceType::NORMX) retIP=InterpolationParameters(*f,0,closestPt, pip);
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else if((*f).Flags() & Old_Mesh::FaceType::NORMY) retIP=InterpolationParameters(*f,1,closestPt, pip);
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else if((*f).Flags() & Old_Mesh::FaceType::NORMZ) retIP=InterpolationParameters(*f,2,closestPt, pip);
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else assert(0);
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assert(retIP); // this should happen only if the starting mesh has degenerate faces.
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const float InterpolationEpsilon = 0.00001f;
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int zeroCnt=0;
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if(pip[0]<InterpolationEpsilon) ++zeroCnt;
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if(pip[1]<InterpolationEpsilon) ++zeroCnt;
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if(pip[2]<InterpolationEpsilon) ++zeroCnt;
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assert(zeroCnt<3);
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Point3f dir=(testPt-closestPt).Normalize();
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// Note that the two signs could be discordant.
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// Always choose the best one according to where the nearest point falls.
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float signBest;
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// Compute test if the point see the surface normal from inside or outside
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// Surface normal for improved robustness is computed both by face and interpolated from vertices.
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if(zeroCnt>0) // we Not are in the middle of the face so the face normal is NOT reliable.
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{
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closestNormV = (f->V(0)->cN())*pip[0] + (f->V(1)->cN())*pip[1] + (f->V(2)->cN())*pip[2] ;
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signBest = dir.dot(closestNormV) ;
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}
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else
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{
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closestNormF = f->cN() ;
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signBest = dir.dot(closestNormF) ;
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}
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if(signBest<0) dist=-dist;
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return field_value(true,dist);
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}
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field_value MultiDistanceFromMesh(Point3f &pp, Old_Mesh */*mesh*/)
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{
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float distSum=0;
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int positiveCnt=0; // positive results counter
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const int MultiSample=7;
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const Point3f delta[7]={Point3f(0,0,0),
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Point3f( 0.2, -0.01, -0.02),
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Point3f(-0.2, 0.01, 0.02),
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Point3f( 0.01, 0.2, 0.01),
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Point3f( 0.03, -0.2, -0.03),
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Point3f(-0.02, -0.03, 0.2 ),
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Point3f(-0.01, 0.01, -0.2 )};
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for(int qq=0;qq<MultiSample;++qq)
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{
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Point3f pp2=pp+delta[qq];
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field_value ff= DistanceFromMesh(pp2,_oldM);
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if(ff.first==false) return field_value(false,0);
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distSum += fabs(ff.second);
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if(ff.second>0) positiveCnt ++;
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}
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if(positiveCnt<=MultiSample/2) distSum = -distSum;
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return field_value(true, distSum/MultiSample);
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}
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/// compute the values if an entire slice (per y) distances>dig of a cell are signed with double of
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/// the distance of the bb
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void ComputeSliceValues(int slice,field_value *slice_values)
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{
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for (int i=0; i<=this->siz.X(); i++)
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{
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for (int k=0; k<=this->siz.Z(); k++)
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{
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int index=GetSliceIndex(i,k);
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Point3f pp(i,slice,k);
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if(this->MultiSampleFlag) slice_values[index] = MultiDistanceFromMesh(pp,_oldM);
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else slice_values[index] = DistanceFromMesh(pp,_oldM);
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}
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}
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//ComputeConsensus(slice,slice_values);
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}
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/*
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For some reasons it can happens that the sign of the computed distance could not correct.
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this function tries to correct these issues by flipping the isolated voxels with discordant sign
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*/
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void ComputeConsensus(int slice, field_value *slice_values)
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{
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float max_dist = min(min(this->voxel[0],this->voxel[1]),this->voxel[2]);
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int flippedCnt=0;
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int flippedTot=0;
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int flippedTimes=0;
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do
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{
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flippedCnt=0;
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for (int i=0; i<=this->siz.X(); i++)
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{
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for (int k=0; k<=this->siz.Z(); k++)
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{
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int goodCnt=0;
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int badCnt=0;
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int index=GetSliceIndex(i,k);
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int index_l,index_r,index_u,index_d;
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if(slice_values[index].first)
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{
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float curVal= slice_values[index].second;
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if(i > 0 ) index_l=GetSliceIndex(i-1,k); else index_l = index;
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if(i < this->siz.X() ) index_r=GetSliceIndex(i+1,k); else index_r = index;
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if(k > 0 ) index_d=GetSliceIndex(i,k-1); else index_d = index;
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if(k < this->siz.Z() ) index_u=GetSliceIndex(i,k+1); else index_u = index;
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if(slice_values[index_l].first) { goodCnt++; if(fabs(slice_values[index_l].second - curVal) > max_dist) badCnt++; }
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if(slice_values[index_r].first) { goodCnt++; if(fabs(slice_values[index_r].second - curVal) > max_dist) badCnt++; }
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if(slice_values[index_u].first) { goodCnt++; if(fabs(slice_values[index_u].second - curVal) > max_dist) badCnt++; }
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if(slice_values[index_d].first) { goodCnt++; if(fabs(slice_values[index_d].second - curVal) > max_dist) badCnt++; }
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if(badCnt >= goodCnt) {
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slice_values[index].second *=-1.0f;
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//slice_values[index].first = false;
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flippedCnt++;
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}
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}
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}
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}
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flippedTot+=flippedCnt;
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flippedTimes++;
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} while(flippedCnt>0);
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#ifndef NO_QT
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if(flippedTot>0)
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qDebug("Flipped %i values in %i times",flippedTot,flippedTimes);
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#endif
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}
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template<class EXTRACTOR_TYPE>
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void ProcessSlice(EXTRACTOR_TYPE &extractor)
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{
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for (int i=0; i<this->siz.X(); i++)
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{
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for (int k=0; k<this->siz.Z(); k++)
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{
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bool goodCell=true;
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Point3i p1(i,CurrentSlice,k);
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Point3i p2=p1+Point3i(1,1,1);
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for(int ii=0;ii<2;++ii)
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for(int jj=0;jj<2;++jj)
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for(int kk=0;kk<2;++kk)
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goodCell &= VV(p1[0]+ii,p1[1]+jj,p1[2]+kk).first;
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if(goodCell) extractor.ProcessCell(p1, p2);
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}
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}
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}
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template<class EXTRACTOR_TYPE>
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void BuildMesh(Old_Mesh &old_mesh,New_Mesh &new_mesh,EXTRACTOR_TYPE &extractor,vcg::CallBackPos *cb)
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{
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_newM=&new_mesh;
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_oldM=&old_mesh;
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// the following two steps are required to be sure that the point-face distance without precomputed data works well.
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tri::UpdateNormals<Old_Mesh>::PerFaceNormalized(old_mesh);
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tri::UpdateNormals<Old_Mesh>::PerVertexAngleWeighted(old_mesh);
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tri::UpdateFlags<Old_Mesh>::FaceProjection(old_mesh);
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int _size=(int)old_mesh.fn*100;
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_g.Set(_oldM->face.begin(),_oldM->face.end(),_size);
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markerFunctor.SetMesh(&old_mesh);
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_newM->Clear();
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Begin();
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extractor.Initialize();
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for (int j=0; j<=this->siz.Y(); j++)
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{
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cb((100*j)/this->siz.Y(),"Marching ");
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ProcessSlice<EXTRACTOR_TYPE>(extractor);//find cells where there is the isosurface and examine it
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NextSlice();
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}
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extractor.Finalize();
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typename New_Mesh::VertexIterator vi;
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for(vi=new_mesh.vert.begin();vi!=new_mesh.vert.end();++vi)
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if(!(*vi).IsD())
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{
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IPfToPf((*vi).cP(),(*vi).P());
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}
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}
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//return the index of a vertex in slide as it was stored
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int GetSliceIndex(int x,int z)
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{
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VertexIndex index = x+z*(this->siz.X()+1);
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return (index);
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}
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//swap slices , the initial value of distance fields ids set as double of bbox of space
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void NextSlice()
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{
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memset(_x_cs, -1, SliceSize*sizeof(VertexIndex));
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memset(_y_cs, -1, SliceSize*sizeof(VertexIndex));
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memset(_z_cs, -1, SliceSize*sizeof(VertexIndex));
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std::swap(_x_cs, _x_ns);
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std::swap(_z_cs, _z_ns);
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std::swap(_v_cs, _v_ns);
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CurrentSlice ++;
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ComputeSliceValues(CurrentSlice + 1,_v_ns);
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}
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//initialize data strucures , the initial value of distance fields ids set as double of bbox of space
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void Begin()
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{
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CurrentSlice = 0;
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memset(_x_cs, -1, SliceSize*sizeof(VertexIndex));
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memset(_y_cs, -1, SliceSize*sizeof(VertexIndex));
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memset(_z_cs, -1, SliceSize*sizeof(VertexIndex));
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memset(_x_ns, -1, SliceSize*sizeof(VertexIndex));
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memset(_z_ns, -1, SliceSize*sizeof(VertexIndex));
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ComputeSliceValues(CurrentSlice,_v_cs);
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ComputeSliceValues(CurrentSlice+1,_v_ns);
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}
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bool Exist(const vcg::Point3i &p1, const vcg::Point3i &p2, VertexPointer &v)
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{
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int i = p1.X();// - _bbox.min.X())/_cell_size.X();
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int z = p1.Z();// - _bbox.min.Z())/_cell_size.Z();
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VertexIndex index = i+z*this->siz.X();
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//VertexIndex index =GetSliceIndex(//
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int v_ind = 0;
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if (p1.X()!=p2.X()) //intersezione della superficie con un Xedge
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{
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if (p1.Y()==CurrentSlice)
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{
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if (_x_cs[index]!=-1)
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{
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v_ind = _x_cs[index];
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v = &_newM->vert[v_ind];
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assert(!v->IsD());
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return true;
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}
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}
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else
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{
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if (_x_ns[index]!=-1)
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{
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v_ind = _x_ns[index];
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v = &_newM->vert[v_ind];
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assert(!v->IsD());
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return true;
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}
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}
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v = NULL;
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return false;
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}
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else if (p1.Y()!=p2.Y()) //intersezione della superficie con un Yedge
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{
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if (_y_cs[index]!=-1)
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{
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v_ind =_y_cs[index];
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v = &_newM->vert[v_ind];
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assert(!v->IsD());
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return true;
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}
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else
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{
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v = NULL;
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return false;
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}
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}
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else if (p1.Z()!=p2.Z())
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//intersezione della superficie con un Zedge
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{
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if (p1.Y()==CurrentSlice)
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{
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if ( _z_cs[index]!=-1)
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{
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v_ind = _z_cs[index];
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v = &_newM->vert[v_ind];
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assert(!v->IsD());
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return true;
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}
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}
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else
|
|
{
|
|
if (_z_ns[index]!=-1)
|
|
{
|
|
v_ind = _z_ns[index];
|
|
v = &_newM->vert[v_ind];
|
|
assert(!v->IsD());
|
|
return true;
|
|
}
|
|
}
|
|
v = NULL;
|
|
return false;
|
|
}
|
|
assert (0);
|
|
return false;
|
|
}
|
|
|
|
///interpolate
|
|
NewCoordType Interpolate(const vcg::Point3i &p1, const vcg::Point3i &p2,int dir)
|
|
{
|
|
float f1 = (float)V(p1);
|
|
float f2 = (float)V(p2);
|
|
float u = (float) f1/(f1-f2);
|
|
NewCoordType ret=vcg::Point3f((float)p1.V(0),(float)p1.V(1),(float)p1.V(2));
|
|
ret.V(dir) = (float) p1.V(dir)*(1.f-u) + u*(float)p2.V(dir);
|
|
return (ret);
|
|
}
|
|
|
|
///if there is a vertex in z axis of a cell return the vertex or create it
|
|
void GetXIntercept(const vcg::Point3i &p1, const vcg::Point3i &p2, VertexPointer &v)
|
|
{
|
|
assert(p1.X()+1 == p2.X());
|
|
assert(p1.Y() == p2.Y());
|
|
assert(p1.Z() == p2.Z());
|
|
|
|
int i = p1.X();// (p1.X() - _bbox.min.X())/_cell_size.X();
|
|
int z = p1.Z();//(p1.Z() - _bbox.min.Z())/_cell_size.Z();
|
|
VertexIndex index = i+z*this->siz.X();
|
|
VertexIndex pos=-1;
|
|
if (p1.Y()==CurrentSlice)
|
|
{
|
|
if ((pos=_x_cs[index])==-1)
|
|
{
|
|
_x_cs[index] = (VertexIndex) _newM->vert.size();
|
|
pos = _x_cs[index];
|
|
Allocator<New_Mesh>::AddVertices( *_newM, 1 );
|
|
v = &_newM->vert[pos];
|
|
v->P()=Interpolate(p1,p2,0);
|
|
return;
|
|
}
|
|
}
|
|
if (p1.Y()==CurrentSlice+1)
|
|
{
|
|
if ((pos=_x_ns[index])==-1)
|
|
{
|
|
_x_ns[index] = (VertexIndex) _newM->vert.size();
|
|
pos = _x_ns[index];
|
|
Allocator<New_Mesh>::AddVertices( *_newM, 1 );
|
|
v = &_newM->vert[pos];
|
|
v->P()=Interpolate(p1,p2,0);
|
|
return;
|
|
}
|
|
}
|
|
assert(pos>=0);
|
|
v = &_newM->vert[pos];
|
|
}
|
|
|
|
///if there is a vertex in y axis of a cell return the vertex or create it
|
|
void GetYIntercept(const vcg::Point3i &p1, const vcg::Point3i &p2, VertexPointer &v)
|
|
{
|
|
assert(p1.X() == p2.X());
|
|
assert(p1.Y()+1 == p2.Y());
|
|
assert(p1.Z() == p2.Z());
|
|
|
|
int i = p1.X(); // (p1.X() - _bbox.min.X())/_cell_size.X();
|
|
int z = p1.Z(); // (p1.Z() - _bbox.min.Z())/_cell_size.Z();
|
|
VertexIndex index = i+z*this->siz.X();
|
|
VertexIndex pos=-1;
|
|
if ((pos=_y_cs[index])==-1)
|
|
{
|
|
_y_cs[index] = (VertexIndex) _newM->vert.size();
|
|
pos = _y_cs[index];
|
|
Allocator<New_Mesh>::AddVertices( *_newM, 1);
|
|
v = &_newM->vert[ pos ];
|
|
v->P()=Interpolate(p1,p2,1);
|
|
}
|
|
assert(pos>=0);
|
|
v = &_newM->vert[pos];
|
|
}
|
|
|
|
///if there is a vertex in z axis of a cell return the vertex or create it
|
|
void GetZIntercept(const vcg::Point3i &p1, const vcg::Point3i &p2, VertexPointer &v)
|
|
{
|
|
assert(p1.X() == p2.X());
|
|
assert(p1.Y() == p2.Y());
|
|
assert(p1.Z()+1 == p2.Z());
|
|
|
|
int i = p1.X(); //(p1.X() - _bbox.min.X())/_cell_size.X();
|
|
int z = p1.Z(); //(p1.Z() - _bbox.min.Z())/_cell_size.Z();
|
|
VertexIndex index = i+z*this->siz.X();
|
|
|
|
VertexIndex pos=-1;
|
|
if (p1.Y()==CurrentSlice)
|
|
{
|
|
if ((pos=_z_cs[index])==-1)
|
|
{
|
|
_z_cs[index] = (VertexIndex) _newM->vert.size();
|
|
pos = _z_cs[index];
|
|
Allocator<New_Mesh>::AddVertices( *_newM, 1 );
|
|
v = &_newM->vert[pos];
|
|
v->P()=Interpolate(p1,p2,2);
|
|
return;
|
|
}
|
|
}
|
|
if (p1.Y()==CurrentSlice+1)
|
|
{
|
|
if ((pos=_z_ns[index])==-1)
|
|
{
|
|
_z_ns[index] = (VertexIndex) _newM->vert.size();
|
|
pos = _z_ns[index];
|
|
Allocator<New_Mesh>::AddVertices( *_newM, 1 );
|
|
v = &_newM->vert[pos];
|
|
v->P()=Interpolate(p1,p2,2);
|
|
return;
|
|
}
|
|
}
|
|
assert(pos>=0);
|
|
v = &_newM->vert[pos];
|
|
}
|
|
|
|
};//end class walker
|
|
|
|
public:
|
|
|
|
typedef Walker /*< Old_Mesh,New_Mesh>*/ MyWalker;
|
|
|
|
typedef vcg::tri::MarchingCubes<New_Mesh, MyWalker> MyMarchingCubes;
|
|
|
|
///resample the mesh using marching cube algorithm ,the accuracy is the dimension of one cell the parameter
|
|
static void Resample(Old_Mesh &old_mesh,New_Mesh &new_mesh, Box3f volumeBox, vcg::Point3<int> accuracy,float max_dist, float thr=0, bool DiscretizeFlag=false, bool MultiSampleFlag=false, bool AbsDistFlag=false, vcg::CallBackPos *cb=0 )
|
|
{
|
|
///be sure that the bounding box is updated
|
|
vcg::tri::UpdateBounding<Old_Mesh>::Box(old_mesh);
|
|
|
|
MyWalker walker(volumeBox,accuracy);
|
|
|
|
walker.max_dim=max_dist+fabs(thr);
|
|
walker.offset = - thr;
|
|
walker.DiscretizeFlag = DiscretizeFlag;
|
|
walker.MultiSampleFlag = MultiSampleFlag;
|
|
walker.AbsDistFlag = AbsDistFlag;
|
|
MyMarchingCubes mc(new_mesh, walker);
|
|
walker.BuildMesh(old_mesh,new_mesh,mc,cb);
|
|
}
|
|
|
|
|
|
};//end class resampler
|
|
|
|
};//end namespace tri
|
|
};//end namespace vcg
|
|
#endif
|