408 lines
17 KiB
C++
408 lines
17 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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/****************************************************************************
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History
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$Log: not supported by cvs2svn $
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Revision 1.1 2007/02/14 01:20:37 ganovelli
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working draft of VCG Mesh Image importer and exporter. Does not consider optional attributes. The mesh atributes are only vn and fn (no bbox, texture coordiantes)
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****************************************************************************/
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#ifndef __VCGLIB_EXPORT_VMI
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#define __VCGLIB_EXPORT_VMI
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/*
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VMI VCG Mesh Image.
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The vmi image file consists of a header containing the description of the vertex and face type,
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the length of vectors containing vertices of faces and the memory image of the object mesh as it is when
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passed to the function Save(SaveMeshType m).
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NOTE: THIS IS NOT A FILE FORMAT. IT IS ONLY USEFUL FOR DUMPING MESH IMAGES FOR DEBUG PURPOSE.
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Example of use: say you are running a time consuming mesh processing and you want to save intermediate
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state, but no file format support all the attributes you need in your vertex/face type.
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NOTE2: At the present if you add members to your TriMesh these will NOT be saved. More precisely, this file and
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import_vmi must be updated to reflect changes in vcg/complex/trimesh/base.h
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*/
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#include <vcg/simplex/face/component.h>
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#include <vcg/simplex/face/component_ocf.h>
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#include <vcg/simplex/vertex/component.h>
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#include <vcg/simplex/vertex/component_ocf.h>
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namespace vcg {
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namespace tri {
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namespace io {
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template <int N> struct PlaceHolderType{ char A[N];};
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template <class SaveMeshType>
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class ExporterVMI
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{
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static void WriteString(FILE *f,const char * in) { unsigned int l = strlen(in); fwrite(&l,4,1,f); fwrite(in,1,l,f);}
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static void WriteInt(FILE *f,const unsigned int i) { fwrite(&i,1,4,f);}
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static void WriteFloat(FILE *f,const float v) { fwrite(&v,1,sizeof(float),f);}
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/* save Ocf Vertex Components */
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template <typename OpenMeshType,typename CONT>
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struct SaveVertexOcf{
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SaveVertexOcf(FILE*f, const CONT & /*vert*/, bool only_header){
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// do nothing, it is a std::vector
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if(only_header){
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WriteString(f,"NOT_HAS_VERTEX_QUALITY_OCF");
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WriteString(f,"NOT_HAS_VERTEX_COLOR_OCF");
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WriteString(f,"NOT_HAS_VERTEX_NORMAL_OCF");
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WriteString(f,"NOT_HAS_VERTEX_MARK_OCF");
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WriteString(f,"NOT_HAS_VERTEX_TEXCOORD_OCF");
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WriteString(f,"NOT_HAS_VERTEX_VFADJACENCY_OCF");
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WriteString(f,"NOT_HAS_VERTEX_CURVATURE_OCF");
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WriteString(f,"NOT_HAS_VERTEX_CURVATUREDIR_OCF");
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WriteString(f,"NOT_HAS_VERTEX_RADIUS_OCF");
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}
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}
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};
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/* partial specialization for vector_ocf */
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template <typename MeshType>
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struct SaveVertexOcf<MeshType, vertex::vector_ocf<typename MeshType::VertexType> >{
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typedef typename MeshType::VertexType VertexType;
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SaveVertexOcf(FILE * f,const vertex::vector_ocf<VertexType> & vert, bool only_header){
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if( VertexType::HasQualityOcf() && vert.IsQualityEnabled()){
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WriteString(f,"HAS_VERTEX_QUALITY_OCF");
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if(!only_header) fwrite(&vert.QV[0],sizeof(typename VertexType::QualityType),vert.size(),f);
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}else WriteString(f,"NOT_HAS_VERTEX_QUALITY_OCF");
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if( VertexType::HasColorOcf() && vert.IsColorEnabled()){
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WriteString(f,"HAS_VERTEX_COLOR_OCF");
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if(!only_header) fwrite(&vert.CV[0],sizeof(typename VertexType::ColorType),vert.size(),f);
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}else WriteString(f,"NOT_HAS_VERTEX_COLOR_OCF");
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if( VertexType::HasNormalOcf() && vert.IsNormalEnabled()){
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WriteString(f,"HAS_VERTEX_NORMAL_OCF");
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if(!only_header) fwrite(&vert.NV[0],sizeof(typename VertexType::NormalType),vert.size(),f);
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}else WriteString(f,"NOT_HAS_VERTEX_NORMAL_OCF");
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if( VertexType::HasMarkOcf() && vert.IsMarkEnabled()){
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WriteString(f,"HAS_VERTEX_MARK_OCF");
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if(!only_header) fwrite(&vert.MV[0],sizeof(typename VertexType::MarkType),vert.size(),f);
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}else WriteString(f,"NOT_HAS_VERTEX_MARK_OCF");
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if( VertexType::HasTexCoordOcf() && vert.IsTexCoordEnabled()){
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WriteString(f,"HAS_VERTEX_TEXCOORD_OCF");
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if(!only_header) fwrite(&vert.TV[0],sizeof(typename VertexType::TexCoordType),vert.size(),f);
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}else WriteString(f,"NOT_HAS_VERTEX_TEXCOORD_OCF");
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if( VertexType::HasVFAdjacencyOcf() && vert.IsVFAdjacencyEnabled()){
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WriteString(f,"HAS_VERTEX_VFADJACENCY_OCF");
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if(!only_header) fwrite(&vert.AV[0],sizeof(typename vertex::vector_ocf<VertexType>::VFAdjType),vert.size(),f);
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}else WriteString(f,"NOT_HAS_VERTEX_VFADJACENCY_OCF");
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if( VertexType::HasCurvatureOcf() && vert.IsCurvatureEnabled()){
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WriteString(f,"HAS_VERTEX_CURVATURE_OCF");
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if(!only_header) fwrite(&vert.CuV[0],sizeof(typename VertexType::CurvatureType),vert.size(),f);
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}else WriteString(f,"NOT_HAS_VERTEX_CURVATURE_OCF");
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if( VertexType::HasCurvatureDirOcf() && vert.IsCurvatureDirEnabled()){
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WriteString(f,"HAS_VERTEX_CURVATUREDIR_OCF");
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if(!only_header) fwrite(&vert.CuDV[0],sizeof(typename VertexType::CurvatureDirType),vert.size(),f);
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}else WriteString(f,"NOT_HAS_VERTEX_CURVATUREDIR_OCF");
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if( VertexType::HasRadiusOcf() && vert.IsRadiusEnabled()){
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WriteString(f,"HAS_VERTEX_RADIUS_OCF");
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if(!only_header) fwrite(&vert.RadiusV[0],sizeof(typename VertexType::RadiusType),vert.size(),f);
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}else WriteString(f,"NOT_HAS_VERTEX_RADIUS_OCF");
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}
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};
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/* save Ocf Face Components */
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template <typename MeshType,typename CONT>
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struct SaveFaceOcf{
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SaveFaceOcf(FILE * f,const CONT & /*face*/, bool only_header){
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// it is a std::vector
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if(only_header){
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WriteString(f,"NOT_HAS_FACE_QUALITY_OCF");
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WriteString(f,"NOT_HAS_FACE_COLOR_OCF");
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WriteString(f,"NOT_HAS_FACE_NORMAL_OCF");
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WriteString(f,"NOT_HAS_FACE_MARK_OCF");
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WriteString(f,"NOT_HAS_FACE_WEDGETEXCOORD_OCF");
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WriteString(f,"NOT_HAS_FACE_FFADJACENCY_OCF");
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WriteString(f,"NOT_HAS_FACE_VFADJACENCY_OCF");
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WriteString(f,"NOT_HAS_FACE_WEDGECOLOR_OCF");
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WriteString(f,"NOT_HAS_FACE_WEDGENORMAL_OCF");
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}
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}
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};
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/* partial specialization for vector_ocf */
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template <typename MeshType>
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struct SaveFaceOcf< MeshType, face::vector_ocf<typename MeshType::FaceType> >{
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typedef typename MeshType::FaceType FaceType;
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SaveFaceOcf(FILE * f,const face::vector_ocf<FaceType> & face, bool only_header){
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if( FaceType::HasFaceQualityOcf() && face.IsQualityEnabled()){
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WriteString(f,"HAS_FACE_QUALITY_OCF");
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if(!only_header) fwrite(&face.QV[0],sizeof(typename FaceType::QualityType),face.size(),f);
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}else WriteString(f,"NOT_HAS_FACE_QUALITY_OCF");
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if( FaceType::HasFaceColorOcf() && face.IsColorEnabled()){
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WriteString(f,"HAS_FACE_COLOR_OCF");
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if(!only_header) fwrite(&face.CV[0],sizeof(typename FaceType::ColorType),face.size(),f);
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}else WriteString(f,"NOT_HAS_FACE_COLOR_OCF");
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if( FaceType::HasFaceNormalOcf() && face.IsNormalEnabled()){
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WriteString(f,"HAS_FACE_NORMAL_OCF");
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if(!only_header) fwrite(&face.NV[0],sizeof(typename FaceType::NormalType),face.size(),f);
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}else WriteString(f,"NOT_HAS_FACE_NORMAL_OCF");
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if( FaceType::HasFaceMarkOcf() && face.IsMarkEnabled()){
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WriteString(f,"HAS_FACE_MARK_OCF");
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if(!only_header) fwrite(&face.MV[0],sizeof(typename FaceType::MarkType),face.size(),f);
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}else WriteString(f,"NOT_HAS_FACE_MARK_OCF");
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if( FaceType::HasWedgeTexCoordOcf() && face.IsWedgeTexEnabled()){
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WriteString(f,"HAS_FACE_WEDGETEXCOORD_OCF");
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if(!only_header) fwrite(&face.WTV[0],sizeof(typename FaceType::WedgeTexCoordType),face.size(),f);
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}else WriteString(f,"NOT_HAS_FACE_WEDGETEXCOORD_OCF");
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if( FaceType::HasFFAdjacencyOcf() && face.IsFFAdjacencyEnabled()){
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WriteString(f,"HAS_FACE_FFADJACENCY_OCF");
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if(!only_header) fwrite(&face.AF[0],sizeof(typename face::vector_ocf<FaceType>::AdjTypePack),face.size(),f);
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}else WriteString(f,"NOT_HAS_FACE_FFADJACENCY_OCF");
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if( FaceType::HasVFAdjacencyOcf() && face.IsVFAdjacencyEnabled()){
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WriteString(f,"HAS_FACE_VFADJACENCY_OCF");
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if(!only_header) fwrite(&face.AV[0],sizeof(typename face::vector_ocf<FaceType>::AdjTypePack),face.size(),f);
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}else WriteString(f,"NOT_HAS_FACE_VFADJACENCY_OCF");
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if( FaceType::HasWedgeColorOcf() && face.IsWedgeColorEnabled()){
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WriteString(f,"HAS_FACE_WEDGECOLOR_OCF");
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if(!only_header) fwrite(&face.WCV[0],sizeof(typename face::vector_ocf<FaceType>::WedgeColorTypePack),face.size(),f);
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}else WriteString(f,"NOT_HAS_FACE_WEDGECOLOR_OCF");
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if( FaceType::HasWedgeNormalOcf() && face.IsWedgeNormalEnabled()){
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WriteString(f,"HAS_FACE_WEDGENORMAL_OCF");
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if(!only_header) fwrite(&face.WNV[0],sizeof(typename face::vector_ocf<FaceType>::WedgeNormalTypePack),face.size(),f);
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}else WriteString(f,"NOT_HAS_FACE_WEDGENORMAL_OCF");
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}
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};
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static FILE *& F(){static FILE * f; return f;}
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typedef typename SaveMeshType::FaceContainer FaceContainer;
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typedef typename SaveMeshType::FaceIterator FaceIterator;
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typedef typename SaveMeshType::VertContainer VertContainer;
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typedef typename SaveMeshType::VertexIterator VertexIterator;
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typedef typename SaveMeshType::VertexType VertexType;
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typedef typename SaveMeshType::FaceType FaceType;
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typedef SimpleTempDataBase<typename SaveMeshType::VertContainer> STDBv;
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typedef SimpleTempDataBase<typename SaveMeshType::FaceContainer> STDBf;
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// typedef typename SaveMeshType::Attribute <SaveMeshType::FaceContainer> STDBm;
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/* save Ocf Components */
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public:
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static int Save(const SaveMeshType &m,const char * filename){
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unsigned int i;
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unsigned int vertSize,faceSize;
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F() = fopen(filename,"wb");
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if(F()==NULL) return 1; // 1 is the error code for cant'open, see the ErrorMsg function
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std::vector<std::string> nameF,nameV;
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SaveMeshType::FaceType::Name(nameF);
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SaveMeshType::VertexType::Name(nameV);
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vertSize = m.vert.size();
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faceSize = m.face.size();
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/* write header */
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WriteString(F(),"FACE_TYPE");
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WriteInt(F(),nameF.size());
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for(i=0; i < nameF.size(); ++i) WriteString(F(),nameF[i].c_str());
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SaveFaceOcf<SaveMeshType,FaceContainer>(F(),m.face,true);
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WriteString(F(),"SIZE_VECTOR_FACES");
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WriteInt(F(), faceSize );
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WriteString(F(),"VERTEX_TYPE");
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WriteInt(F(),nameV.size());
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for(i=0; i < nameV.size(); ++i) WriteString(F(),nameV[i].c_str());
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SaveVertexOcf<SaveMeshType,VertContainer>(F(),m.vert,true);
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WriteString(F(),"SIZE_VECTOR_VERTS");
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WriteInt(F(),vertSize);
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WriteString(F(),"BOUNDING_BOX");
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float float_value;
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for(unsigned int i =0; i < 2; ++i){float_value = m.bbox.min[i]; WriteFloat(F(),float_value);}
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for(unsigned int i =0; i < 2; ++i){float_value = m.bbox.max[i]; WriteFloat(F(),float_value);}
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WriteString(F(),"end_header");
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/* end header */
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if(vertSize!=0){
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void * offsetV = (void*) &m.vert[0];
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/* write the address of the first vertex */
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fwrite(&offsetV,sizeof(void *),1,F());
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}
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if(faceSize!=0){
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void * offsetF= (void*)&m.face[0];
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/* write the address of the first face */
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fwrite(&offsetF,sizeof( void *),1,F());
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}
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/* save the object mesh */
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fwrite(&m.shot,sizeof(Shot<typename SaveMeshType::ScalarType>),1,F());
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fwrite(&m.vn,sizeof(int),1,F());
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fwrite(&m.fn,sizeof(int),1,F());
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fwrite(&m.imark,sizeof(int),1,F());
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fwrite(&m.bbox,sizeof(Box3<typename SaveMeshType::ScalarType>),1,F());
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fwrite(&m.C(),sizeof(Color4b),1,F());
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unsigned int written;
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if(vertSize!=0){
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/* save the vertices */
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written = fwrite((void*)&m.vert[0],sizeof(typename SaveMeshType::VertexType),m.vert.size(),F());
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assert(written==m.vert.size());
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SaveVertexOcf<SaveMeshType,VertContainer>(F(),m.vert,false);
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}
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if(faceSize!=0){
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/* save the faces */
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written = fwrite((void*)&m.face[0],sizeof(typename SaveMeshType::FaceType),faceSize,F());
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assert(written==m.face.size());
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SaveFaceOcf<SaveMeshType,FaceContainer>(F(),m.face,false);
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}
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/* save the attributes */
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typename std::set< typename SaveMeshType::PointerToAttribute>::const_iterator ai;
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/* save the per vertex attributes */
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{
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typename std::set< typename SaveMeshType::PointerToAttribute>::const_iterator ai;
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unsigned int n_named_attr = 0;
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for(ai = m.vert_attr.begin(); ai != m.vert_attr.end(); ++ai) n_named_attr+=!(*ai)._name.empty();
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WriteString(F(),"N_PER_VERTEX_ATTRIBUTES"); WriteInt (F(),n_named_attr);
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for(ai = m.vert_attr.begin(); ai != m.vert_attr.end(); ++ai)
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if(!(*ai)._name.empty())
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{
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STDBv * stdb = (STDBv *) (*ai)._handle;
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WriteString(F(),"PER_VERTEX_ATTR_NAME");
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WriteString(F(),(*ai)._name.c_str() );
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WriteString(F(),"PER_VERTEX_ATTR_SIZE");
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WriteInt(F(),stdb->SizeOf());
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fwrite(stdb->DataBegin(),m.vert.size(),stdb->SizeOf(),F());
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}
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}
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/* save the per face attributes */
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{
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typename std::set< typename SaveMeshType::PointerToAttribute>::const_iterator ai;
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unsigned int n_named_attr = 0;
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for(ai = m.face_attr.begin(); ai != m.face_attr.end(); ++ai) n_named_attr+=!(*ai)._name.empty();
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WriteString(F(),"N_PER_FACE_ATTRIBUTES");
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WriteInt (F(),n_named_attr);
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for(ai = m.face_attr.begin(); ai != m.face_attr.end(); ++ai)
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if(!(*ai)._name.empty())
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{
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STDBf * stdb = (STDBf *) (*ai)._handle;
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WriteString(F(),"PER_FACE_ATTR_NAME");
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WriteString(F(),(*ai)._name.c_str());
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WriteString(F(),"PER_FACE_ATTR_SIZE");
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WriteInt(F(),stdb->SizeOf());
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fwrite(stdb->DataBegin(),m.face.size(),stdb->SizeOf(),F());
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}
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}
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///* save the per mesh attributes */
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{
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typename std::set< typename SaveMeshType::PointerToAttribute>::const_iterator ai;
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unsigned int n_named_attr = 0;
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for(ai = m.mesh_attr.begin(); ai != m.mesh_attr.end(); ++ai) n_named_attr+=!(*ai)._name.empty();
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WriteString(F(),"N_PER_MESH_ATTRIBUTES"); WriteInt(F(),n_named_attr);
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for(ai = m.mesh_attr.begin(); ai != m.mesh_attr.end(); ++ai)
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if(!(*ai)._name.empty())
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{
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AttributeBase * handle = (AttributeBase *) (*ai)._handle ;
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WriteString(F(),"PER_MESH_ATTR_NAME");
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WriteString(F(),(*ai)._name.c_str());
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WriteString(F(),"PER_MESH_ATTR_SIZE");
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WriteInt(F(),handle->SizeOf());
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fwrite(handle->DataBegin(),1,handle->SizeOf(),F());
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}
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}
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// fflush(F());
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fclose(F());
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return 0;
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}
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static const char *ErrorMsg(int error)
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{
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static std::vector<std::string> off_error_msg;
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if(off_error_msg.empty())
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{
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off_error_msg.resize(2 );
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off_error_msg[0]="No errors";
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off_error_msg[1]="Can't open file";
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}
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if(error>1 || error<0) return "Unknown error";
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else return off_error_msg[error].c_str();
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}
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}; // end class
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} // end Namespace tri
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} // end Namespace io
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} // end Namespace vcg
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#endif
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