#ifndef __VCGLIB_IMPORTERDAE #define __VCGLIB_IMPORTERDAE //importer for collada's files #include namespace vcg { namespace tri { namespace io { template class ImporterDAE : public UtilDAE { private: static int WedgeNormalAttribute(OpenMeshType& m,const QStringList face,const QStringList wn,const QDomNode wnsrc,const int meshfaceind,const int faceind,const int component) { int indnm = -1; if (!wnsrc.isNull()) { indnm = face.at(faceind).toInt(); assert(indnm * 3 < wn.size()); m.face[meshfaceind].WN(component) = vcg::Point3f(wn.at(indnm * 3).toFloat(),wn.at(indnm * 3 + 1).toFloat(),wn.at(indnm * 3 + 2).toFloat()); } return indnm; } static int WedgeTextureAttribute(OpenMeshType& m,const QStringList face,int ind_txt,const QStringList wt,const QDomNode wtsrc,const int meshfaceind,const int faceind,const int component,const int stride = 2) { int indtx = -1; if (!wtsrc.isNull()) { indtx = face.at(faceind).toInt(); int num = wt.size(); assert(indtx * stride < wt.size()); m.face[meshfaceind].WT(component) = vcg::TexCoord2(); m.face[meshfaceind].WT(component).U() = wt.at(indtx * stride).toFloat(); m.face[meshfaceind].WT(component).V() = wt.at(indtx * stride + 1).toFloat(); m.face[meshfaceind].WT(component).N() = ind_txt; } return indtx; } static int WedgeColorAttribute(OpenMeshType& m,const QStringList face,const QStringList wc,const QDomNode wcsrc,const int meshfaceind,const int faceind,const int component) { int indcl; if (!wcsrc.isNull()) { indcl = face.at(faceind).toInt(); assert(indcl * 4 < wc.size()); m.face[meshfaceind].WC(component) = vcg::Color4b(wc.at(indcl * 4).toFloat(),wc.at(indcl * 4 + 1).toFloat(),wc.at(indcl * 4 + 2).toFloat(),wc.at(indcl * 4 + 3).toFloat()); } return indcl; } static void FindStandardWedgeAttributes(WedgeAttribute& wed,const QDomNode nd,const QDomDocument doc) { wed.wnsrc = findNodeBySpecificAttributeValue(nd,"input","semantic","NORMAL"); wed.offnm = findStringListAttribute(wed.wn,wed.wnsrc,nd,doc,"NORMAL"); wed.wtsrc = findNodeBySpecificAttributeValue(nd,"input","semantic","TEXCOORD"); if (!wed.wtsrc.isNull()) { QDomNode src = attributeSourcePerSimplex(nd,doc,"TEXCOORD"); if (isThereTag(src,"accessor")) { QDomNodeList wedatts = src.toElement().elementsByTagName("accessor"); wed.stride = wedatts.at(0).toElement().attribute("stride").toInt(); } else wed.stride = 2; } else wed.stride = 2; wed.offtx = findStringListAttribute(wed.wt,wed.wtsrc,nd,doc,"TEXCOORD"); wed.wcsrc = findNodeBySpecificAttributeValue(nd,"input","semantic","COLOR"); wed.offcl = findStringListAttribute(wed.wc,wed.wcsrc,nd,doc,"COLOR"); } static DAEError LoadPolygonalMesh(QDomNodeList& polypatch,OpenMeshType& m,const size_t offset,AdditionalInfoDAE* info) { return E_NOERROR; } static DAEError LoadPolygonalListMesh(QDomNodeList& polylist,OpenMeshType& m,const size_t offset,AdditionalInfoDAE* info) { typedef PolygonalMesh< MyPolygon > PolyMesh; PolyMesh pm; //copying vertices for(typename OpenMeshType::VertexIterator itv = m.vert.begin();itv != m.vert.end();++itv) { vcg::Point3f p(itv->P().X(),itv->P().Y(),itv->P().Z()); typename PolyMesh::VertexType v; v.P() = p; pm.vert.push_back(v); } int polylist_size = polylist.size(); for(int pl = 0; pl < polylist_size;++pl) { QString mat = polylist.at(pl).toElement().attribute(QString("material")); QDomNode txt_node = textureFinder(mat,*(info->dae->doc)); int ind_txt = -1; if (!txt_node.isNull()) ind_txt = indexTextureByImgNode(*(info->dae->doc),txt_node); //PolyMesh::PERWEDGEATTRIBUTETYPE att = PolyMesh::NONE; WedgeAttribute wa; FindStandardWedgeAttributes(wa,polylist.at(pl),*(info->dae->doc)); QStringList vertcount; valueStringList(vertcount,polylist.at(pl),"vcount"); int indforpol = findOffSetForASingleSimplex(polylist.at(pl)); int offpols = 0; int npolig = vertcount.size(); QStringList polyind; valueStringList(polyind,polylist.at(pl),"p"); for(int ii = 0;ii < npolig;++ii) { int nvert = vertcount.at(ii).toInt(); typename PolyMesh::FaceType p(nvert); for(int iv = 0;iv < nvert;++iv) { int index = offset + polyind.at(offpols + iv * indforpol).toInt(); p._pv[iv] = &(pm.vert[index]); int nmindex = -1; if (!wa.wnsrc.isNull()) nmindex = offset + polyind.at(offpols + iv * indforpol + wa.offnm).toInt(); int txindex = -1; if (!wa.wtsrc.isNull()) { txindex = offset + polyind.at(offpols + iv * indforpol + wa.offtx).toInt(); /*p._txc[iv].U() = wa.wt.at(txindex * 2).toFloat(); p._txc[iv].V() = wa.wt.at(txindex * 2 + 1).toFloat(); p._txc[iv].N() = ind_txt;*/ } } pm._pols.push_back(p); offpols += nvert * indforpol; } } pm.triangulate(m); return E_NOERROR; } static DAEError LoadTriangularMesh(QDomNodeList& tripatch,OpenMeshType& m,const size_t offset,AdditionalInfoDAE* info) { int tripatch_size = tripatch.size(); for(int tript = 0; tript < tripatch_size;++tript) { QString mat = tripatch.at(tript).toElement().attribute(QString("material")); QDomNode txt_node = textureFinder(mat,*(info->dae->doc)); int ind_txt = -1; if (!txt_node.isNull()) ind_txt = indexTextureByImgNode(*(info->dae->doc),txt_node); int nfcatt = tripatch.at(tript).toElement().elementsByTagName("input").size(); QStringList face; valueStringList(face,tripatch.at(tript),"p"); int face_size = face.size(); int offsetface = (int)m.face.size(); if (face_size != 0) { vcg::tri::Allocator::AddFaces(m,face_size / (nfcatt * 3)); WedgeAttribute wa; FindStandardWedgeAttributes(wa,tripatch.at(tript),*(info->dae->doc)); int jj = 0; //int dd = m.face.size(); for(int ff = offsetface;ff < (int) m.face.size();++ff) { for(unsigned int tt = 0;tt < 3;++tt) { int indvt = face.at(jj).toInt(); assert(indvt + offset < m.vert.size()); m.face[ff].V(tt) = &(m.vert[indvt + offset]); if(tri::HasPerWedgeNormal(m)) WedgeNormalAttribute(m,face,wa.wn,wa.wnsrc,ff,jj + wa.offnm,tt); if(tri::HasPerWedgeTexCoord(m) && ind_txt != -1) { WedgeTextureAttribute(m,face,ind_txt,wa.wt,wa.wtsrc,ff,jj + wa.offtx,tt,wa.stride); } if(tri::HasPerWedgeColor(m)) WedgeColorAttribute(m,face,wa.wc,wa.wcsrc,ff,jj + wa.offcl,tt); jj += nfcatt; } } } } return E_NOERROR; } static int LoadMesh(OpenMeshType& m,AdditionalInfoDAE* info,const QDomNode& geo,const vcg::Matrix44f& t, CallBackPos *cb=0) { if (isThereTag(geo,"mesh")) { if ((cb !=NULL) && (((info->numvert + info->numface)%100)==0) && !(*cb)((100*(info->numvert + info->numface))/(info->numvert + info->numface), "Vertex Loading")) return E_CANTOPEN; /*QDomNodeList geosrc = geo.toElement().elementsByTagName("source"); int geosrc_size = geosrc.size(); if (geosrc_size < 1) return E_NOVERTEXPOSITION;*/ QDomNodeList vertices = geo.toElement().elementsByTagName("vertices"); int vertices_size = vertices.size(); if (vertices_size != 1) return E_INCOMPATIBLECOLLADA141FORMAT; QDomNode srcnode = attributeSourcePerSimplex(vertices.at(0),*(info->dae->doc),"POSITION"); if (srcnode.isNull()) return E_NOVERTEXPOSITION; QStringList geosrcposarr; valueStringList(geosrcposarr,srcnode,"float_array"); int geosrcposarr_size = geosrcposarr.size(); if ((geosrcposarr_size % 3) != 0) return E_CANTOPEN; int nvert = geosrcposarr_size / 3; size_t offset = m.vert.size(); if (geosrcposarr_size != 0) { vcg::tri::Allocator::AddVertices(m,nvert); QDomNode srcnodenorm = attributeSourcePerSimplex(vertices.at(0),*(info->dae->doc),"NORMAL"); QStringList geosrcvertnorm; if (!srcnodenorm.isNull()) valueStringList(geosrcvertnorm,srcnodenorm,"float_array"); QDomNode srcnodetext = attributeSourcePerSimplex(vertices.at(0),*(info->dae->doc),"TEXCOORD"); QStringList geosrcverttext; if (!srcnodetext.isNull()) valueStringList(geosrcverttext,srcnodetext,"float_array"); QDomNode srcnodecolor = attributeSourcePerSimplex(vertices.at(0),*(info->dae->doc),"COLOR"); QStringList geosrcvertcol; if (!srcnodecolor.isNull()) valueStringList(geosrcvertcol,srcnodecolor,"float_array"); int ii = 0; for(size_t vv = offset;vv < m.vert.size();++vv) { assert((ii * 3 < geosrcposarr_size) && (ii * 3 + 1 < geosrcposarr_size) && (ii * 3 + 2 < geosrcposarr_size)); vcg::Point4f tmp = t * vcg::Point4f(geosrcposarr[ii * 3].toFloat(),geosrcposarr[ii * 3 + 1].toFloat(),geosrcposarr[ii * 3 + 2].toFloat(),1.0f); m.vert[vv].P() = vcg::Point3f(tmp.X(),tmp.Y(),tmp.Z()); if (!srcnodenorm.isNull()) { assert((ii * 3 < geosrcvertnorm.size()) && (ii * 3 + 1 < geosrcvertnorm.size()) && (ii * 3 + 2 < geosrcvertnorm.size())); vcg::Matrix44f intr44 = vcg::Inverse(t); vcg::Transpose(intr44); Matrix33f intr33; for(unsigned int rr = 0; rr < 2; ++rr) { for(unsigned int cc = 0;cc < 2;++cc) intr33[rr][cc] = intr44[rr][cc]; } m.vert[vv].N() = (intr33 * vcg::Point3f(geosrcvertnorm[ii * 3].toFloat(),geosrcvertnorm[ii * 3 + 1].toFloat(),geosrcvertnorm[ii * 3 + 2].toFloat())).Normalize(); } /*if (!srcnodecolor.isNull()) { assert((ii * 4 < geosrcvertcol.size()) && (ii * 4 + 1 < geosrcvertcol.size()) && (ii * 4 + 2 < geosrcvertcol.size()) && (ii * 4 + 1 < geosrcvertcol.size())); m.vert[vv].C() = vcg::Color4b(geosrcvertcol[ii * 4].toFloat(),geosrcvertcol[ii * 4 + 1].toFloat(),geosrcvertcol[ii * 4 + 2].toFloat(),geosrcvertcol[ii * 4 + 3].toFloat()); }*/ if (!srcnodetext.isNull()) { assert((ii * 2 < geosrcverttext.size()) && (ii * 2 + 1 < geosrcverttext.size())); m.vert[vv].T() = vcg::TexCoord2(); m.vert[vv].T().u() = geosrcverttext[ii * 2].toFloat(); m.vert[vv].T().v() = geosrcverttext[ii * 2 + 1].toFloat(); } ++ii; } QDomNodeList tripatch = geo.toElement().elementsByTagName("triangles"); int tripatch_size = tripatch.size(); QDomNodeList polypatch = geo.toElement().elementsByTagName("polygons"); int polypatch_size = polypatch.size(); QDomNodeList polylist = geo.toElement().elementsByTagName("polylist"); int polylist_size = polylist.size(); if ((tripatch_size == 0) && (polypatch_size == 0) && (polylist_size == 0)) return E_NOPOLYGONALMESH; DAEError err = E_NOERROR; if (tripatch_size != 0) err = LoadTriangularMesh(tripatch,m,offset,info); else if (polypatch_size != 0) err = LoadPolygonalMesh(polypatch,m,offset,info); else if (polylist_size != 0) err = LoadPolygonalListMesh(polylist,m,offset,info); if (err != E_NOERROR) return err; } return E_NOERROR; } else return E_NOMESH; } static void GetTexCoord(const QDomDocument& doc,AdditionalInfoDAE* inf) { QDomNodeList txlst = doc.elementsByTagName("library_images"); for(int img = 0;img < txlst.at(0).childNodes().size();++img) { QDomNodeList nlst = txlst.at(0).childNodes().at(img).toElement().elementsByTagName("init_from"); if (nlst.size() > 0) { inf->texturefile.push_back(nlst.at(0).firstChild().nodeValue()); } } } public: //merge all meshes in the collada's file in the templeted mesh m //I assume the mesh static int Open(OpenMeshType& m,const char* filename,AdditionalInfo*& info, CallBackPos *cb=0) { AdditionalInfoDAE* inf = new AdditionalInfoDAE(); inf->dae = new InfoDAE(); QDomDocument* doc = new QDomDocument(filename); QFile file(filename); if (!file.open(QIODevice::ReadOnly)) return E_CANTOPEN; if (!doc->setContent(&file)) { file.close(); return E_CANTOPEN; } file.close(); inf->dae->doc = doc; //GetTexture(*(info->doc),inf); //scene->instance_visual_scene QDomNodeList scenes = inf->dae->doc->elementsByTagName("scene"); int scn_size = scenes.size(); if (scn_size == 0) return E_NO3DSCENE; int problem = E_NOERROR; bool found_a_mesh = false; //Is there geometry in the file? bool geoinst_found = false; //for each scene in COLLADA FILE for(int scn = 0;scn < scn_size;++scn) { QDomNodeList instscenes = scenes.at(scn).toElement().elementsByTagName("instance_visual_scene"); int instscn_size = instscenes.size(); if (instscn_size == 0) return E_INCOMPATIBLECOLLADA141FORMAT; //for each scene instance in a COLLADA scene for(int instscn = 0;instscn < instscn_size; ++instscn) { QString libscn_url; referenceToANodeAttribute(instscenes.at(instscn),"url",libscn_url); QDomNode nd = QDomNode(*(inf->dae->doc)); QDomNode visscn = findNodeBySpecificAttributeValue(*(inf->dae->doc),"visual_scene","id",libscn_url); if(visscn.isNull()) return E_UNREFERENCEBLEDCOLLADAATTRIBUTE; //for each node in the libscn_url visual scene QDomNodeList visscn_child = visscn.childNodes(); //for each direct child of a libscn_url visual scene find if there is some geometry instance for(int chdind = 0; chdind < visscn_child.size();++chdind) { QDomNodeList geoinst = visscn_child.at(chdind).toElement().elementsByTagName("instance_geometry"); int geoinst_size = geoinst.size(); if (geoinst_size != 0) { geoinst_found |= true; QDomNodeList geolib = inf->dae->doc->elementsByTagName("library_geometries"); assert(geolib.size() == 1); //!!!!!!!!!!!!!!!!!here will be the code for geometry transformations!!!!!!!!!!!!!!!!!!!!!! for(int geoinst_ind = 0;geoinst_ind < geoinst_size;++geoinst_ind) { QString geo_url; referenceToANodeAttribute(geoinst.at(geoinst_ind),"url",geo_url); QDomNode geo = findNodeBySpecificAttributeValue(geolib.at(0),"geometry","id",geo_url); if (geo.isNull()) return E_UNREFERENCEBLEDCOLLADAATTRIBUTE; vcg::Matrix44f tr; tr.SetIdentity(); TransfMatrix(visscn,geoinst.at(geoinst_ind),tr); problem |= LoadMesh(m,inf,geo,tr); if (problem & E_NOMESH) found_a_mesh |= false; else found_a_mesh = true; } } } //if there is at least a mesh I clean the problem status variable from E_NOMESH ERROR if (((problem & E_NOMESH) || (problem & E_NOPOLYGONALMESH)) && (found_a_mesh)) { if (problem & E_NOMESH) problem = problem & ~E_NOMESH; if (problem & E_NOPOLYGONALMESH) problem = problem & ~E_NOPOLYGONALMESH; } } } if (!geoinst_found) { QDomNodeList geolib = inf->dae->doc->elementsByTagName("library_geometries"); assert(geolib.size() == 1); QDomNodeList geochild = geolib.at(0).childNodes(); int geochild_size = geochild.size(); int problem = 0; for(int chd = 0;chd < geochild_size;++chd) { vcg::Matrix44f tmp; tmp.SetIdentity(); problem |= LoadMesh(m,inf,geochild.at(chd),tmp); } } //if there is at least a mesh I clean the problem status variable from E_NOMESH or E_NOPOLYGONALMESH ERROR if (((problem & E_NOMESH) || (problem & E_NOPOLYGONALMESH)) && (found_a_mesh)) { if (problem & E_NOMESH) problem = problem & ~E_NOMESH; if (problem & E_NOPOLYGONALMESH) problem = problem & ~E_NOPOLYGONALMESH; } info = inf; return problem; } static bool LoadMask(const char * filename, AdditionalInfoDAE*& addinfo) { bool bHasPerWedgeTexCoord = false; bool bHasPerWedgeNormal = false; bool bHasPerVertexColor = false; bool bHasPerFaceColor = false; bool bHasPerVertexNormal = false; bool bHasPerVertexText = false; AdditionalInfoDAE* info = new AdditionalInfoDAE(); info->dae = new InfoDAE(); QDomDocument* doc = new QDomDocument(filename); QFile file(filename); if (!file.open(QIODevice::ReadOnly)) return false; if (!doc->setContent(&file)) { file.close(); return false; } file.close(); info->dae->doc = doc; GetTexCoord(*(info->dae->doc),info); QDomNodeList scenes = info->dae->doc->elementsByTagName("scene"); int scn_size = scenes.size(); //Is there geometry in the file? bool geoinst_found = false; //for each scene in COLLADA FILE for(int scn = 0;scn < scn_size;++scn) { QDomNodeList instscenes = scenes.at(scn).toElement().elementsByTagName("instance_visual_scene"); int instscn_size = instscenes.size(); if (instscn_size == 0) return false; //for each scene instance in a COLLADA scene for(int instscn = 0;instscn < instscn_size; ++instscn) { QString libscn_url; referenceToANodeAttribute(instscenes.at(instscn),"url",libscn_url); QDomNode nd = QDomNode(*(info->dae->doc)); QDomNode visscn = findNodeBySpecificAttributeValue(*(info->dae->doc),"visual_scene","id",libscn_url); if(visscn.isNull()) return false; //for each node in the libscn_url visual scene //QDomNodeList& visscn_child = visscn.childNodes(); QDomNodeList visscn_child = visscn.childNodes(); //for each direct child of a libscn_url visual scene find if there is some geometry instance for(int chdind = 0; chdind < visscn_child.size();++chdind) { //QDomNodeList& geoinst = visscn_child.at(chdind).toElement().elementsByTagName("instance_geometry"); QDomNodeList geoinst = visscn_child.at(chdind).toElement().elementsByTagName("instance_geometry"); int geoinst_size = geoinst.size(); if (geoinst_size != 0) { geoinst_found |= true; QDomNodeList geolib = info->dae->doc->elementsByTagName("library_geometries"); assert(geolib.size() == 1); //!!!!!!!!!!!!!!!!!here will be the code for geometry transformations!!!!!!!!!!!!!!!!!!!!!! info->numvert = 0; info->numface = 0; for(int geoinst_ind = 0;geoinst_ind < geoinst_size;++geoinst_ind) { QString geo_url; referenceToANodeAttribute(geoinst.at(geoinst_ind),"url",geo_url); QDomNode geo = findNodeBySpecificAttributeValue(geolib.at(0),"geometry","id",geo_url); if (geo.isNull()) return false; QDomNodeList vertlist = geo.toElement().elementsByTagName("vertices"); for(int vert = 0;vert < vertlist.size();++vert) { QDomNode no; no = findNodeBySpecificAttributeValue(vertlist.at(vert),"input","semantic","POSITION"); QString srcurl; referenceToANodeAttribute(no,"source",srcurl); no = findNodeBySpecificAttributeValue(geo,"source","id",srcurl); QDomNodeList fa = no.toElement().elementsByTagName("float_array"); assert(fa.size() == 1); info->numvert += (fa.at(0).toElement().attribute("count").toInt() / 3); no = findNodeBySpecificAttributeValue(vertlist.at(vert),"input","semantic","COLOR"); if (!no.isNull()) bHasPerVertexColor = true; no = findNodeBySpecificAttributeValue(vertlist.at(vert),"input","semantic","NORMAL"); if (!no.isNull()) bHasPerVertexNormal = true; no = findNodeBySpecificAttributeValue(vertlist.at(vert),"input","semantic","TEXCOORD"); if (!no.isNull()) bHasPerVertexText = true; } const char* arr[] = {"triangles","polylist","polygons"}; for(unsigned int tt= 0;tt < 3;++tt) { QDomNodeList facelist = geo.toElement().elementsByTagName(arr[tt]); for(int face = 0;face < facelist.size();++face) { info->numface += facelist.at(face).toElement().attribute("count").toInt() ; QDomNode no; no = findNodeBySpecificAttributeValue(facelist.at(face),"input","semantic","NORMAL"); if (!no.isNull()) bHasPerWedgeNormal = true; no = findNodeBySpecificAttributeValue(facelist.at(face),"input","semantic","TEXCOORD"); if (!no.isNull()) bHasPerWedgeTexCoord = true; } } } } } } } if (!geoinst_found) { QDomNodeList geolib = info->dae->doc->elementsByTagName("library_geometries"); assert(geolib.size() == 1); QDomNodeList geochild = geolib.at(0).toElement().elementsByTagName("geometry"); //!!!!!!!!!!!!!!!!!here will be the code for geometry transformations!!!!!!!!!!!!!!!!!!!!!! info->numvert = 0; info->numface = 0; for(int geoinst_ind = 0;geoinst_ind < geochild.size();++geoinst_ind) { QDomNodeList vertlist = geochild.at(geoinst_ind).toElement().elementsByTagName("vertices"); for(int vert = 0;vert < vertlist.size();++vert) { QDomNode no; no = findNodeBySpecificAttributeValue(vertlist.at(vert),"input","semantic","POSITION"); QString srcurl; referenceToANodeAttribute(no,"source",srcurl); no = findNodeBySpecificAttributeValue(geochild.at(geoinst_ind),"source","id",srcurl); QDomNodeList fa = no.toElement().elementsByTagName("float_array"); assert(fa.size() == 1); info->numvert += (fa.at(0).toElement().attribute("count").toInt() / 3); no = findNodeBySpecificAttributeValue(vertlist.at(vert),"input","semantic","COLOR"); if (!no.isNull()) bHasPerVertexColor = true; no = findNodeBySpecificAttributeValue(vertlist.at(vert),"input","semantic","NORMAL"); if (!no.isNull()) bHasPerVertexNormal = true; no = findNodeBySpecificAttributeValue(vertlist.at(vert),"input","semantic","TEXCOORD"); if (!no.isNull()) bHasPerVertexText = true; } QDomNodeList facelist = geochild.at(geoinst_ind).toElement().elementsByTagName("triangles"); for(int face = 0;face < facelist.size();++face) { info->numface += facelist.at(face).toElement().attribute("count").toInt() ; QDomNode no; no = findNodeBySpecificAttributeValue(facelist.at(face),"input","semantic","NORMAL"); if (!no.isNull()) bHasPerWedgeNormal = true; no = findNodeBySpecificAttributeValue(facelist.at(face),"input","semantic","TEXCOORD"); if (!no.isNull()) bHasPerWedgeTexCoord = true; } } } info->mask = 0; if (bHasPerWedgeTexCoord) info->mask |= vcg::tri::io::Mask::IOM_WEDGTEXCOORD; if (bHasPerWedgeNormal) info->mask |= vcg::tri::io::Mask::IOM_WEDGNORMAL; if (bHasPerVertexColor) info->mask |= vcg::tri::io::Mask::IOM_VERTCOLOR; if (bHasPerFaceColor) info->mask |= vcg::tri::io::Mask::IOM_FACECOLOR; if (bHasPerVertexNormal) info->mask |= vcg::tri::io::Mask::IOM_VERTNORMAL; if (bHasPerVertexText) info->mask |= vcg::tri::io::Mask::IOM_VERTTEXCOORD; delete (info->dae->doc); info->dae->doc = NULL; addinfo = info; return true; } }; } } } #endif