521 lines
18 KiB
C++
521 lines
18 KiB
C++
#ifndef MIQ_QUADRANGULATOR_H
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#define MIQ_QUADRANGULATOR_H
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#include <vcg/complex/complex.h>
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#include <vcg/simplex/face/pos.h>
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#include <vcg/simplex/face/jumping_pos.h>
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#include <vcg/complex/algorithms/attribute_seam.h>
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#include <vcg/complex/algorithms/refine.h>
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#include <vcg/complex/algorithms/smooth.h>
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#include <vcg/complex/algorithms/clean.h>
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template <class MeshType>
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inline void ExtractVertex(const MeshType & srcMesh,
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const typename MeshType::FaceType & f,
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int whichWedge,
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const MeshType &dstMesh,
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typename MeshType::VertexType & v)
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{
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(void)srcMesh;
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(void)dstMesh;
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//v.P() = f.cP(whichWedge);
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v.ImportData(*f.cV(whichWedge));
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v.T() = f.cWT(whichWedge);
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}
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template <class MeshType>
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inline bool CompareVertex(const MeshType & m,
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const typename MeshType::VertexType & vA,
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const typename MeshType::VertexType & vB)
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{
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(void)m;
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return ((vA.cT() == vB.cT())&&(vA.cP()==vB.cP()));
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}
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template <class TriMesh,class PolyMesh>
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class Quadrangulator
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{
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public:
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typedef typename TriMesh::FaceType TriFaceType;
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typedef typename TriMesh::VertexType TriVertexType;
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typedef typename TriMesh::CoordType CoordType;
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typedef typename TriMesh::ScalarType ScalarType;
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typedef typename PolyMesh::FaceType PolyFaceType;
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typedef typename PolyMesh::VertexType PolyVertexType;
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typedef typename PolyMesh::CoordType PolyCoordType;
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typedef typename PolyMesh::ScalarType PolyScalarType;
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///the set of all edges that belongs to integer lines
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std::set<std::pair<TriFaceType*,int> > IntegerEdges;
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///the set of all integer vertices and the other vertices on integer lines which is connectes to
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std::map<TriVertexType*,std::vector<TriVertexType*> > IntegerLineAdj;
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///the set of integer vertices
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std::set<TriVertexType*> IntegerVertices;
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///temporary polygons
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std::vector<std::vector<TriVertexType *> > polygons;
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///drawing debug structures
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std::vector<std::pair<TriFaceType*,int> > IntegerLines;
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std::vector<TriVertexType*> IntegerVertex;
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private:
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static bool ToSplit(const vcg::Point2<ScalarType> &uv0,
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const vcg::Point2<ScalarType> &uv1,
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int Dir,
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int IntegerLine,
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ScalarType &alpha,
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ScalarType tolerance=0.0001)
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{
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ScalarType lineF=(ScalarType)IntegerLine;
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ScalarType val0=std::min(uv0.V(Dir),uv1.V(Dir));
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ScalarType val1=std::max(uv0.V(Dir),uv1.V(Dir));
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if (lineF<(val0+tolerance))return false;
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if (lineF>(val1-tolerance))return false;
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ScalarType dist=fabs(uv0.V(Dir)-uv1.V(Dir));
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if (dist<tolerance) return false;
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alpha=(1.0-fabs(uv0.V(Dir)-lineF)/dist);
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return true;
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}
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///return true if the edge has to be splitted,
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///by considering the tolerance to the closest integer
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static bool ToSplit(const vcg::face::Pos<TriFaceType> &ep,
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ScalarType &alpha,
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ScalarType factor=1.0,
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ScalarType tolerance=0.0001)
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{
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//TriFaceType *f=ep.f;
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//int z=ep.z;
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TriVertexType* v0=ep.f->V(ep.z);
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TriVertexType* v1=ep.f->V1(ep.z);
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vcg::Point2<ScalarType> uv0=v0->T().P()*factor;
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vcg::Point2<ScalarType> uv1=v1->T().P()*factor;
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///then test integer for each direction
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for (int dir=0;dir<2;dir++)
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{
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int Int0=std::min((int)uv0.V(dir),(int)uv1.V(dir));
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int Int1=std::max((int)uv0.V(dir),(int)uv1.V(dir));
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for (int i=Int0;i<=Int1;i++)
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{
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bool to_split=ToSplit(uv0,uv1,dir,i,alpha,tolerance);
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if (to_split)return true;
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}
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}
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return false;
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}
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// Basic subdivision class
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// This class must provide methods for finding the position of the newly created vertices
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// In this implemenation we simply put the new vertex in the MidPoint position.
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// Color and TexCoords are interpolated accordingly.
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template<class MESH_TYPE>
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struct SplitMidPoint : public std::unary_function<vcg::face::Pos<typename MESH_TYPE::FaceType> , typename MESH_TYPE::CoordType >
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{
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typedef typename MESH_TYPE::VertexType VertexType;
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typedef typename MESH_TYPE::FaceType FaceType;
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typedef typename MESH_TYPE::CoordType CoordType;
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ScalarType factor;
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ScalarType tolerance;
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ScalarType alpha;
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void operator()(typename MESH_TYPE::VertexType &nv,
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vcg::face::Pos<typename MESH_TYPE::FaceType> ep)
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{
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bool to_split=ToSplit(ep,alpha,factor,tolerance);
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assert(to_split);
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///get the value on which the edge must be splitted
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VertexType* v0=ep.f->V(ep.z);
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VertexType* v1=ep.f->V1(ep.z);
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nv.P()= v0->P()*alpha+v1->P()*(1.0-alpha);
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//nv.N()= v0->N()*alpha+v1->N()*(1.0-alpha);
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nv.T().P()=v0->T().P()*alpha+v1->T().P()*(1.0-alpha);
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}
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vcg::TexCoord2<ScalarType> WedgeInterp(vcg::TexCoord2<ScalarType> &t0,
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vcg::TexCoord2<ScalarType> &t1)
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{
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vcg::TexCoord2<ScalarType> tmp;
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if (t0.n() != t1.n())
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cerr << "Failed assertion: Quadrangulator::WedgeInterp1" << endl;
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// assert(t0.n()== t1.n()); TODO put back
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tmp.n()=t0.n();
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// assert(alpha>=0); TODO put back
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if (alpha<0)
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cerr << "Failed assertion: Quadrangulator::WedgeInterp2" << endl;
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tmp.t()=(alpha*t0.t()+(1.0-alpha)*t1.t());
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return tmp;
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}
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SplitMidPoint(){alpha=-1;}
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};
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template <class MESH_TYPE>
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class EdgePredicate
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{
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typedef typename MESH_TYPE::VertexType VertexType;
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typedef typename MESH_TYPE::FaceType FaceType;
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typedef typename MESH_TYPE::ScalarType ScalarType;
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public:
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ScalarType factor;
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ScalarType tolerance;
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bool operator()(vcg::face::Pos<typename MESH_TYPE::FaceType> ep) const
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{
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ScalarType alpha;
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return(ToSplit(ep,alpha,factor,tolerance));
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}
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};
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void SplitTris(TriMesh &to_split,
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ScalarType factor=1.0,
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ScalarType tolerance=0.0001)
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{
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bool done=true;
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SplitMidPoint<TriMesh> splMd;
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EdgePredicate<TriMesh> eP;
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splMd.tolerance=tolerance;
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splMd.factor=factor;
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eP.tolerance=tolerance;
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eP.factor=factor;
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while (done)
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done=vcg::tri::RefineE<TriMesh,SplitMidPoint<TriMesh>,EdgePredicate<TriMesh> >(to_split,splMd,eP);
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for (unsigned int i=0;i<to_split.face.size();i++)
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for (int j=0;j<3;j++) to_split.face[i].WT(j).P()=to_split.face[i].V(j)->T().P();
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}
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bool IsOnIntegerLine(vcg::Point2<ScalarType> uv0,
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vcg::Point2<ScalarType> uv1,
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ScalarType tolerance=0.0001)
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{
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for (int dir=0;dir<2;dir++)
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{
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ScalarType val0=uv0.V(dir);
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ScalarType val1=uv1.V(dir);
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int integer0=floor(uv0.V(dir)+0.5);
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int integer1=floor(uv1.V(dir)+0.5);
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if (integer0!=integer1)continue;
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if ((fabs(val0-(ScalarType)integer0))>tolerance)continue;
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if ((fabs(val1-(ScalarType)integer1))>tolerance)continue;
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return true;
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}
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return false;
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}
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bool IsOnIntegerVertex(vcg::Point2<ScalarType> uv,
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ScalarType tolerance=0.0001)
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{
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for (int dir=0;dir<2;dir++)
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{
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ScalarType val0=uv.V(dir);
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int integer0=floor(val0+0.5);
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if ((fabs(val0-(ScalarType)integer0))>tolerance)return false;
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}
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return true;
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}
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void InitIntegerVectors()
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{
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IntegerLines=std::vector<std::pair<TriFaceType*,int> >(IntegerEdges.begin(),IntegerEdges.end());
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IntegerVertex=std::vector<TriVertexType* > (IntegerVertices.begin(),IntegerVertices.end());
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}
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void EraseIntegerEdge(const vcg::face::Pos<TriFaceType> &ep)
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{
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std::pair<TriFaceType*,int> edge(ep.F(),ep.E());
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assert(IntegerEdges.count(edge)!=0);
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IntegerEdges.erase(edge);
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}
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void EraseIntegerEdge(const std::vector<std::pair<TriFaceType*,int> > &to_erase)
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{
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for (unsigned int i=0;i<to_erase.size();i++)
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IntegerEdges.erase(to_erase[i]);
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}
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void TestIntegerEdges()
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{
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typedef typename std::pair<TriFaceType*,int> pair_type;
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typedef typename std::vector< pair_type > vect_type;
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typename vect_type::iterator IteIntl;
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for (IteIntl=IntegerLines.begin();
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IteIntl!=IntegerLines.end();
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IteIntl++)
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{
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int E=(*IteIntl).second;
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TriFaceType *F=(*IteIntl).first;
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TriFaceType *F1=F->FFp(E);
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if (F==F1) continue;
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int E1=F->FFi(E);
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std::pair<TriFaceType*,int> curr_edge(F1,E1);
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assert(IntegerEdges.count(curr_edge)!=0);
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}
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}
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void InitIntegerEdgesVert(TriMesh &Tmesh,
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ScalarType factor=1.0,
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ScalarType tolerance=0.0001)
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{
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IntegerEdges.clear();
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for (unsigned int i=0;i<Tmesh.face.size();i++)
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{
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TriFaceType *f=&Tmesh.face[i];
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if (f->IsD())continue;
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for (int j=0;j<3;j++)
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{
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TriFaceType *f1=f->FFp(j);
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int e1=f->FFi(j);
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bool IsBorder=f->IsB(j);
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TriVertexType *v0=f->V0(j);
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TriVertexType *v1=f->V1(j);
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vcg::Point2<ScalarType> uv0=f->WT(j).P()*factor;
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vcg::Point2<ScalarType> uv1=f->WT((j+1)%3).P()*factor;
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if (IsOnIntegerLine(uv0,uv1,tolerance)||IsBorder)
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{
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//IntegerEdges.insert(std::pair<TriVertexType*,TriVertexType*>(v0,v1));
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IntegerEdges.insert(std::pair<TriFaceType*,int>(f,j));
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if (!IsBorder)
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IntegerEdges.insert(std::pair<TriFaceType*,int>(f1,e1));
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else
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{
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IntegerVertices.insert(v0);
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IntegerVertices.insert(v1);
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}
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}
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if (IsOnIntegerVertex(uv0))
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IntegerVertices.insert(v0);
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if (IsOnIntegerVertex(uv1))
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IntegerVertices.insert(v1);
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}
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}
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//InitIntegerNeigh(Tmesh);
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InitIntegerVectors();
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TestIntegerEdges();
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}
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///return the first and the last edge
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///following an integer line
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///until if reach anothe integer edge
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bool OneIntegerStep(vcg::face::Pos<TriFaceType> &ep)
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{
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TriFaceType *f_init=ep.f;
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TriFaceType *currF=f_init;
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//int edge_init=ep.z;
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//ep.V()=f_init->V(edge_init);
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TriVertexType* v_init=ep.V();
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bool complete_turn=false;
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do
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{
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ep.FlipE();
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///see if found an integer vert
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currF=ep.F();
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int currE=ep.E();
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assert((currE>=0)&&(currE<=4));
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std::pair<TriFaceType*,int> curr_edge(currF,currE);
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if (IntegerEdges.count(curr_edge)!=0)
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{
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///go to the other side
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ep.FlipV();
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assert(ep.V()!=v_init);
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return true;
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}
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ep.FlipF();
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///see if there's a border
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bool jumped=(currF==ep.F());
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if (jumped)
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return false;
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///test the complete turn
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complete_turn=(ep.F()==f_init);
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}while (!complete_turn);
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return false;
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}
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///find a polygon starting from half edge ep, return true if found
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bool FindPolygon(vcg::face::Pos<TriFaceType> &ep,
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std::vector<TriVertexType*> &poly)
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{
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poly.clear();
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TriVertexType* v_init=ep.V();
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///it must start from an integer vert
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assert(IntegerVertices.count(v_init)!=0);
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poly.push_back(v_init);
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std::vector<std::pair<TriFaceType*,int> > to_erase;
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to_erase.push_back(std::pair<TriFaceType*,int>(ep.F(),ep.E()));
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do
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{
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bool done=OneIntegerStep(ep);
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if (!done)
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{
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EraseIntegerEdge(to_erase);
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return false;
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}
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to_erase.push_back(std::pair<TriFaceType*,int>(ep.F(),ep.E()));
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TriVertexType* v_curr=ep.V();
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if ((IntegerVertices.count(v_curr)!=0)&&
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(v_curr!=v_init))
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poly.push_back(v_curr);
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}while(ep.V()!=v_init);
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EraseIntegerEdge(to_erase);
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return true;
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}
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void FindPolygons(TriMesh &Tmesh,
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std::vector<std::vector<TriVertexType *> > &polygons)
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{
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//int limit=2;
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for (unsigned int i=0;i<Tmesh.face.size();i++)
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{
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TriFaceType * f=&Tmesh.face[i];
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for (int j=0;j<3;j++)
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{
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TriVertexType* v0=f->V0(j);
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//TriVertexType* v1=f->V1(j);
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//std::pair<TriVertexType*,TriVertexType*> edge(v0,v1);*/
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std::pair<TriFaceType*,int> edge(f,j);
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if (IntegerEdges.count(edge)==0)continue;///edge already used or not integer
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if (IntegerVertices.count(v0)==0)continue; ///must start from integer vert
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///create the pos
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vcg::face::Pos<TriFaceType> ep(f,j);
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std::vector<TriVertexType *> poly;
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bool found=FindPolygon(ep,poly);
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if (found)
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{
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std::reverse(poly.begin(),poly.end());///REVERSE ORDER
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polygons.push_back(poly);
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}
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}
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}
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}
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void InitVertexQuadMesh(TriMesh &Tmesh)
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{
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FindPolygons(Tmesh,polygons);
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}
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public:
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void TestIsProper(TriMesh &Tmesh)
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{
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///test manifoldness
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int test=vcg::tri::Clean<TriMesh>::CountNonManifoldVertexFF(Tmesh);
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//assert(test==0);
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if (test != 0)
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cerr << "Assertion failed: TestIsProper NonManifoldVertices!" << endl;
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test=vcg::tri::Clean<TriMesh>::CountNonManifoldEdgeFF(Tmesh);
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//assert(test==0);
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if (test != 0)
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cerr << "Assertion failed: TestIsProper NonManifoldEdges" << endl;
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for (unsigned int i=0;i<Tmesh.face.size();i++)
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{
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TriFaceType *f=&Tmesh.face[i];
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assert (!f->IsD());
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for (int z=0;z<3;z++)
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{
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//int indexOpp=f->FFi(z);
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TriFaceType *Fopp=f->FFp(z);
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if (Fopp==f) continue;
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//assert( f->FFp(z)->FFp(f->FFi(z))==f );
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if (f->FFp(z)->FFp(f->FFi(z))!=f)
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cerr << "Assertion failed: TestIsProper f->FFp(z)->FFp(f->FFi(z))!=f " << endl;
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}
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}
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}
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void Quadrangulate(TriMesh &Tmesh,
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PolyMesh &Pmesh,
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ScalarType factor=1.0,
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ScalarType tolerance=0.000001)
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{
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TestIsProper(Tmesh);
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vcg::tri::AttributeSeam::SplitVertex(Tmesh, ExtractVertex<TriMesh>, CompareVertex<TriMesh>);
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vcg::tri::Allocator<TriMesh>::CompactVertexVector(Tmesh);
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vcg::tri::Allocator<TriMesh>::CompactFaceVector(Tmesh);
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vcg::tri::UpdateTopology<TriMesh>::FaceFace(Tmesh);
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(void)Pmesh;
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TestIsProper(Tmesh);
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///then split the tris
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SplitTris(Tmesh,factor,tolerance);
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///join the vertices back!
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ScalarType EPS=(ScalarType)0.00000001;
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vcg::tri::Clean<TriMesh>::MergeCloseVertex(Tmesh,EPS);
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vcg::tri::UpdateNormal<TriMesh>::PerFaceNormalized(Tmesh); // update Normals
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vcg::tri::UpdateNormal<TriMesh>::PerVertexNormalized(Tmesh);// update Normals
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///compact the mesh
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vcg::tri::Allocator<TriMesh>::CompactVertexVector(Tmesh);
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vcg::tri::Allocator<TriMesh>::CompactFaceVector(Tmesh);
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vcg::tri::UpdateTopology<TriMesh>::FaceFace(Tmesh); // update Topology
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vcg::tri::UpdateTopology<TriMesh>::TestFaceFace(Tmesh); //and test it
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///set flags
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vcg::tri::UpdateFlags<TriMesh>::VertexClearV(Tmesh);
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vcg::tri::UpdateFlags<TriMesh>::FaceBorderFromFF(Tmesh);
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vcg::tri::UpdateFlags<TriMesh>::VertexBorderFromFace(Tmesh);
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///test manifoldness
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TestIsProper(Tmesh);
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vcg::tri::UpdateFlags<TriMesh>::VertexClearV(Tmesh);
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InitIntegerEdgesVert(Tmesh,factor,tolerance);
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InitVertexQuadMesh(Tmesh);
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///then add to the polygonal mesh
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Pmesh.Clear();
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///first create vertices
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vcg::tri::Allocator<PolyMesh>::AddVertices(Pmesh,IntegerVertex.size());
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std::map<TriVertexType*,int> VertMap;
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for(unsigned int i=0;i<IntegerVertex.size();i++)
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{
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CoordType pos=IntegerVertex[i]->P();
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CoordType norm=IntegerVertex[i]->N();
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Pmesh.vert[i].P()=typename PolyMesh::CoordType(pos.X(),pos.Y(),pos.Z());
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Pmesh.vert[i].N()=typename PolyMesh::CoordType(norm.X(),norm.Y(),norm.Z());
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VertMap[IntegerVertex[i]]=i;
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}
|
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///then add polygonal mesh
|
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vcg::tri::Allocator<PolyMesh>::AddFaces(Pmesh,polygons.size());
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for (unsigned int i=0;i<polygons.size();i++)
|
|
{
|
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int size=polygons[i].size();
|
|
Pmesh.face[i].Alloc(size);
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for (int j=0;j<size;j++)
|
|
{
|
|
TriVertexType* v=polygons[i][j];
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int index=VertMap[v];
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Pmesh.face[i].V(j)=&(Pmesh.vert[index]);
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}
|
|
}
|
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}
|
|
};
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#endif
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