/**************************************************************************** * VCGLib o o * * Visual and Computer Graphics Library o o * * _ O _ * * Copyright(C) 2004 \/)\/ * * Visual Computing Lab /\/| * * ISTI - Italian National Research Council | * * \ * * All rights reserved. * * * * This program is free software; you can redistribute it and/or modify * * it under the terms of the GNU General Public License as published by * * the Free Software Foundation; either version 2 of the License, or * * (at your option) any later version. * * * * This program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU General Public License (http://www.gnu.org/licenses/gpl.txt) * * for more details. * * * ****************************************************************************/ #ifndef __VCGLIB_IMPORTERFIELD #define __VCGLIB_IMPORTERFIELD #include namespace vcg { namespace tri { namespace io { /** This class encapsulate a filter for opening field formats */ template class ImporterFIELD { typedef typename MeshType::ScalarType ScalarType; typedef typename MeshType::FaceType FaceType; typedef typename MeshType::VertexType VertexType; typedef typename MeshType::CoordType CoordType; public: static bool LoadGrad(MeshType &mesh, const char *path) { FILE *f = fopen(path,"rt"); if (!f) { return false; } int numF; fscanf(f,"%d\n",&numF); assert(numF==mesh.fn); char skipstr[200]; //int readed0; for (int i=0;i<9;i++) fscanf(f,"%s",&skipstr[0]); for (int i=0;i UV[3]; UV[0]= vcg::Point2(u0,v0); UV[1]= vcg::Point2(u1,v1); UV[2]= vcg::Point2(u2,v2); CoordType dir1; CoordType dir2; vcg::tri::CrossField::GradientToCross(mesh.face[i],UV[0],UV[1],UV[2],dir1,dir2); dir1.Normalize(); dir2.Normalize(); mesh.face[i].PD1()=dir1; mesh.face[i].PD2()=dir2; } fclose(f); return true; } static bool LoadNDF(MeshType &mesh, const char *path) { FILE *f = fopen(path,"rt"); if (!f) { fflush(stdout); return false; } char skipstr[200]; //int readed0; do{ fscanf(f,"%s\n",&skipstr[0]); printf("%s\n",skipstr); }while(strcmp(skipstr,"[Pjumps]")!=0); // fscanf(f,"%s\"",skipstr); // printf("%s\n",skipstr); fseek(f, 7, SEEK_CUR); char final[1]; do{ int period; fscanf(f,"%d;",&period); printf("%d\n",period); fscanf(f,"%c",&final); fseek(f, -1, SEEK_CUR); printf("%s\n",&final[0]); }while(strcmp(final,"\"")!=0); // printf("%s\n",skipstr); fflush(stdout); // for (int i=0;i UV[3]; // UV[0]= vcg::Point2(u0,v0); // UV[1]= vcg::Point2(u1,v1); // UV[2]= vcg::Point2(u2,v2); // CoordType dir1; // CoordType dir2; // vcg::tri::CrossField::GradientToCross(mesh.face[i],UV[0],UV[1],UV[2],dir1,dir2); // dir1.Normalize(); // dir2.Normalize(); // mesh.face[i].PD1()=dir1; // mesh.face[i].PD2()=dir2; // } // fclose(f); // return true; } ///load a field on the mesh, it could be a vfield file (per vertex) ///or an ffield file (per face) static bool LoadFFIELD(MeshType &mesh, const char *path, bool per_vertex=false) { FILE *f = fopen(path,"rt"); if (!f) { return false; } { char word[512]; word[0]=0; fscanf(f,"%s",word); char c=0; if (word[0]=='#') { // skip comment line while (fscanf(f,"%c",&c)!=EOF) if (c=='\n') break; } else { return false; } while (fscanf(f,"%c",&c)!=EOF) if (c=='\n') break; int nnv = -1; if (fscanf(f,"%d",&nnv)!=1) { while (fscanf(f,"%c",&c)!=EOF) if (c=='\n') break; // skip fscanf(f,"%d",&nnv); } int targetnum=mesh.fn; if (per_vertex) targetnum=mesh.vn; if (nnv != (int)targetnum) { //if (errorMsg) sprintf(errorMsg,"Wrong element number. Found: %d. Expected: %d.",nnv,mesh->vn); return false; } if( per_vertex && !HasPerVertexCurvatureDir(mesh)) throw vcg::MissingComponentException("PerVertexCurvatureDir"); if(!per_vertex && !HasPerFaceCurvatureDir(mesh)) throw vcg::MissingComponentException("PerFaceCurvatureDir"); while (fscanf(f,"%c",&c)!=EOF) if (c=='\n') break; // skip // skip strange string line while (fscanf(f,"%c",&c)!=EOF) if (c=='\n') break; for (int i=0; i u,v; float a,b; if (fscanf(f, "%f %f %f %f %f %f %f %f", &a,&b, &(v.X()),&(v.Y()),&(v.Z()), &(u.X()),&(u.Y()),&(u.Z()) )!=8) { //if (errorMsg) sprintf(errorMsg,"Format error reading vertex n. %d",i); return false; } u.Normalize(); v.Normalize(); if (per_vertex) { mesh.vert[i].PD1().Import(u); mesh.vert[i].PD2().Import(v); } else { mesh.face[i].PD1().Import(u); mesh.face[i].PD2().Import(v); } } } fclose(f); return true; } ///Load a 4 rosy format file as used by ///Interactive Visualization of Rotational Symmetry Fields on Surfaces ///Jonathan Palacios and Eugene Zhang static void Load4ROSY(MeshType &mesh, const char *path) { FILE *f = fopen(path,"rt"); int num,symm; fscanf(f,"%d",&num); assert(num==mesh.vn); fscanf(f,"%d\n",&symm); assert(symm==4); for (unsigned int i=0;i Handle_MMatch; ///seam per face typename MeshType::template PerFaceAttributeHandle > Handle_Seams; bool HasHandleMMatch=vcg::tri::HasPerFaceAttribute(mesh,std::string("MissMatch")); if (!HasHandleMMatch) Handle_MMatch = vcg::tri::Allocator::template AddPerFaceAttribute(mesh,std::string("MissMatch")); else Handle_MMatch = vcg::tri::Allocator::template FindPerFaceAttribute(mesh,std::string("MissMatch")); bool HasHandleSeams=vcg::tri::HasPerFaceAttribute(mesh,std::string("Seams")); if (!HasHandleSeams) Handle_Seams=vcg::tri::Allocator::template AddPerFaceAttribute >(mesh,std::string("Seams")); else Handle_Seams=vcg::tri::Allocator::template FindPerFaceAttribute >(mesh,std::string("Seams")); FILE *f = fopen(PathOBJ.c_str(),"rt"); if (!f) return false; for (unsigned int i=0;iV(0)==v)e0=0; if (f0->V(1)==v)e0=1; if (f0->V(2)==v)e0=2; e0=(e0+2)%3; assert(e0!=-1); FaceType *f1; int e1; f1=f0->FFp(e0); e1=f0->FFi(e0); Handle_Seams[f0][e0]=true; Handle_Seams[f1][e1]=true; Handle_MMatch[f0][e0]=rot; int rot1; if (rot==0)rot1=0; if (rot==1)rot1=3; if (rot==2)rot1=2; if (rot==3)rot1=1; Handle_MMatch[f1][e1]=rot1; } } //printf("NEED %d LINES\n",i); return true; } //Load a 4 rosy format file as pair of angles static bool Load2AngleFace(MeshType &mesh, const char *path) { FILE *f = fopen(path,"rt"); if (f==NULL)return false; int num; fscanf(f,"#%d param_field\n",&num); if (num!=mesh.face.size())return false; for (unsigned int i=0;i::AnglesToCrossField(mesh.face[i],(ScalarType)alpha1,(ScalarType)alpha2,1); } fclose(f); return true; } }; // end class } // end namespace tri } // end namespace io } // end namespace vcg #endif