/* The interface between the GUI and the netgen library */ #include #include #include #include #include #include #include #ifdef OCCGEOMETRY #include #endif #include "../libsrc/meshing/bcfunctions.hpp" #include #include #ifdef SOCKETS #include "../libsrc/sockets/sockets.hpp" #include "../libsrc/sockets/socketmanager.hpp" #endif // #include // to be sure to include the 'right' togl-version #include "togl_1_7.h" // #include "Togl2/togl.h" extern bool nodisplay; #include #ifdef _MSC_VER // Philippose - 30/01/2009 // MSVC Express Edition Support #ifdef MSVC_EXPRESS // #include static pthread_t meshingthread; void RunParallel ( void * (*fun)(void *), void * in) { if (netgen::mparam.parthread) { pthread_attr_t attr; pthread_attr_init (&attr); // the following call can be removed if not available: pthread_attr_setstacksize(&attr, 1000000); //pthread_create (&meshingthread, &attr, fun, NULL); pthread_create (&meshingthread, &attr, fun, in); } else fun (in); } #else // Using MS VC++ Standard / Enterprise / Professional edition // Afx - Threads need different return - value: static void* (*sfun)(void *); unsigned int fun2 (void * val) { sfun (val); return 0; } void RunParallel ( void* (*fun)(void *), void * in) { sfun = fun; if (netgen::mparam.parthread) AfxBeginThread (fun2, in); //AfxBeginThread (fun2, NULL); else fun (in); } #endif // #ifdef MSVC_EXPRESS #else // For #ifdef _MSC_VER // #include static pthread_t meshingthread; void RunParallel ( void * (*fun)(void *), void * in) { if (netgen::mparam.parthread) { pthread_attr_t attr; pthread_attr_init (&attr); // the following call can be removed if not available: pthread_attr_setstacksize(&attr, 1000000); //pthread_create (&meshingthread, &attr, fun, NULL); pthread_create (&meshingthread, &attr, fun, in); } else fun (in); } #endif // #ifdef _MSC_VER namespace netgen { #include "../libsrc/interface/writeuser.hpp" #include "demoview.hpp" } #ifdef ACIS #include "ng_acis.hpp" #endif #ifdef JPEGLIB #include #endif #ifdef FFMPEG extern "C" { /* #include #include #include */ #include #include #include } #endif #ifdef NGSOLVE extern "C" void NGSolve_Exit(); #endif // extern void * ngsolve_handle; namespace netgen { NetgenOutStream operator<< ( ostream & ost, Imp imp ) { return ( NetgenOutStream ( &ost, imp ) ); } NetgenOutStream operator<< ( ostream & ost, Proc proc ) { return ( NetgenOutStream ( &ost, proc ) ); } NetgenOutStream operator<< ( ostream & ost, Procs & procs ) { return ( NetgenOutStream ( &ost, procs ) ); } // global variable mesh (should not be used in libraries) AutoPtr mesh; // geometry: either CSG, or, if an other is non-null, // then the other AutoPtr geometry (new CSGeometry("")); STLGeometry * stlgeometry = NULL; AutoPtr geometry2d (0); #ifdef OCCGEOMETRY OCCGeometry * occgeometry = NULL; #endif NetgenGeometry * ng_geometry; Tcl_Interp * tcl_interp; #ifdef SOCKETS AutoPtr clientsocket; ServerSocketManager serversocketmanager; //Array< AutoPtr < ServerInfo > > servers; Array< ServerInfo* > servers; AutoPtr serversocketusernetgen; #endif // OpenGL near and far clipping planes extern double pnear; extern double pfar; // visualization scenes, pointer vs selects which one is drawn: static VisualScene vscross; static VisualSceneGeometry vsgeom; static VisualSceneGeometry2d vsgeom2d; #ifdef OPENGL static VisualSceneSTLGeometry vsstlgeom; extern VisualSceneSTLMeshing vsstlmeshing; #endif #ifdef OCCGEOMETRY static VisualSceneOCCGeometry vsoccgeom; #endif #ifdef OPENGL extern VisualSceneSurfaceMeshing vssurfacemeshing; #endif extern VisualSceneMesh vsmesh; extern VisualSceneMeshDoctor vsmeshdoc; static VisualSceneSpecPoints vsspecpoints; VisualSceneSolution vssolution; #ifdef STEP static VisualSceneSTEPGeometry vsstepgeom; #endif VisualScene *vs = &vscross; static char * err_needsmesh = (char*) "This operation needs a mesh"; static char * err_needsstlgeometry = (char*) "This operation needs an STL geometry"; static char * err_jobrunning = (char*) "Meshing Job already running"; #ifndef SMALLLIB // Destination for messages, errors, ... void Ng_PrintDest(const char * s) { #ifdef PARALLEL int id, ntasks; MPI_Comm_size(MPI_COMM_WORLD, &ntasks); MPI_Comm_rank(MPI_COMM_WORLD, &id); #else int id = 0; int ntasks = 1; #endif if ( ntasks == 1 ) (*mycout) << s << flush; else (*mycout) << "p" << id << ": " << s << flush ; } void MyError(const char * ch) { cout << ch; (*testout) << "Error !!! " << ch << endl << flush; } #endif static clock_t starttimea; void ResetTime () { starttimea = clock(); } #ifndef SMALLLIB double GetTime () { return double(clock() - starttimea) / CLOCKS_PER_SEC; } #endif // file handling .. int Ng_New (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (strcmp (argv[1], "mesh") == 0) mesh.Reset(); if (strcmp (argv[1], "geom") == 0) { geometry.Reset (new CSGeometry ("")); if (stlgeometry) { delete stlgeometry; stlgeometry = NULL; } #ifdef OCCGEOMETRY if (occgeometry) { delete occgeometry; occgeometry = NULL; } #endif } return TCL_OK; } int Ng_ImportMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]); int Ng_LoadMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { string filename (argv[1]); if ( (strlen (filename.c_str()) > 4) && strcmp (&filename[strlen (filename.c_str())-4], ".vol") != 0 ) { return Ng_ImportMesh(clientData,interp,argc,argv); } PrintMessage (1, "load mesh from file ", filename); mesh.Reset (new Mesh()); try { //mesh -> Load (filename); ifstream infile(filename.c_str()); mesh -> Load(infile); string auxstring; if(infile.good()) { infile >> auxstring; if(auxstring == "csgsurfaces") { if (geometry) geometry.Reset (new CSGeometry ("")); if (stlgeometry) { delete stlgeometry; stlgeometry = NULL; } #ifdef OCCGEOMETRY if (occgeometry) { delete occgeometry; occgeometry = NULL; } #endif geometry2d.Reset (0); geometry -> LoadSurfaces(infile); } } } catch (NgException e) { PrintMessage (3, e.What()); return TCL_ERROR; } PrintMessage (2, mesh->GetNP(), " Points, ", mesh->GetNE(), " Elements."); return TCL_OK; } int Ng_SaveMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } const string filename (argv[1]); PrintMessage (1, "Save mesh to file ", filename); ofstream outfile(filename.c_str()); mesh -> Save (outfile); outfile << endl << endl << "endmesh" << endl << endl; if (geometry && geometry->GetNSurf()) geometry->SaveSurfaces(outfile); return TCL_OK; } int Ng_MergeMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { string filename (argv[1]); PrintMessage (1, "merge with mesh from file ", filename); try { //mesh -> Merge (filename); ifstream infile(filename.c_str()); const int offset = (geometry) ? geometry->GetNSurf() : 0; mesh -> Merge(infile,offset); string auxstring; if(infile.good()) { infile >> auxstring; if(auxstring == "csgsurfaces") geometry -> LoadSurfaces(infile); } } catch (NgException e) { PrintMessage (3, e.What()); return TCL_ERROR; } PrintMessage (2, mesh->GetNP(), " Points, ", mesh->GetNSE(), " Surface Elements."); return TCL_OK; } int Ng_ExportMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } string filename (argv[1]); string filetype (argv[2]); if (WriteUserFormat (filetype, *mesh, *geometry, filename)) { ostringstream ost; ost << "Sorry, nothing known about file format " << filetype << endl; Tcl_SetResult (interp, (char*)ost.str().c_str(), TCL_VOLATILE); return TCL_ERROR; } return TCL_OK; } int Ng_ImportMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { const string filename (argv[1]); PrintMessage (1, "import mesh from ", filename); mesh.Reset (new Mesh()); ReadFile (*mesh, filename); PrintMessage (2, mesh->GetNP(), " Points, ", mesh->GetNE(), " Elements."); mesh->SetGlobalH (mparam.maxh); mesh->CalcLocalH(); return TCL_OK; } int Ng_ImportSolution (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } const char * filename = argv[1]; PrintMessage (1, "Import solution from file ", filename); ImportSolution (filename); return TCL_OK; } static DemoView * demoview = 0; int Ng_ShowDemo (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { const char * filename = argv[1]; PrintMessage (1, "Show demo ", filename); demoview = new DemoView (filename); return TCL_OK; } int Ng_DemoSetTime (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { cout << "demosettime, time = " << argv[1] << endl; int result = -1; static char strminusone[] = "-1"; static char str0[] = "0"; if (demoview) result = demoview->SetTime (atof (argv[1])); if (result == -1) Tcl_SetResult (interp, strminusone, TCL_STATIC); else Tcl_SetResult (interp, str0, TCL_STATIC); return TCL_OK; } int Ng_SaveSolution (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } const char * filename = argv[1]; PrintMessage (1, "Save solution to file ", filename); vssolution.SaveSolutionData (filename); return TCL_OK; } int Ng_LoadGeometry (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } tcl_const char * lgfilename = argv[1]; #ifdef LOG_STREAM (*logout) << "Load geometry file: " << lgfilename << endl; #endif #ifdef STAT_STREAM (*statout) << lgfilename << " & " << endl; #endif if (geometry) geometry.Reset (new CSGeometry ("")); if (stlgeometry) { delete stlgeometry; stlgeometry = NULL; } #ifdef OCCGEOMETRY if (occgeometry) { delete occgeometry; occgeometry = NULL; } #endif geometry2d.Reset (0); try { ifstream infile(lgfilename); if (strlen(lgfilename) < 4) { cout << "ERROR: cannot recognise file format!" << endl; } else { if (strcmp (&lgfilename[strlen(lgfilename)-3], "geo") == 0) { // strcpy (geomfilename, lgfilename); PrintMessage (1, "Load geometry file ", lgfilename); extern CSGeometry * ParseCSG (istream & istr); // ifstream infile(lgfilename); CSGeometry * hgeom = ParseCSG (infile); ng_geometry = hgeom; if (hgeom) geometry.Reset (hgeom); else { geometry.Reset (new CSGeometry ("")); Tcl_SetResult (interp, (char*)"geo-file should start with 'algebraic3d'", TCL_STATIC); return TCL_ERROR; } //geometry -> FindIdenticSurfaces(geometry->GetIdEps() * geometry->MaxSize()); // 1e-8*geometry->MaxSize() geometry -> FindIdenticSurfaces(1e-8 * geometry->MaxSize()); // 1e-8*geometry->MaxSize() } else if (strcmp (&lgfilename[strlen(lgfilename)-3], "ngg") == 0) { // strcpy (geomfilename, lgfilename); PrintMessage (1, "Load new geometry file ", lgfilename); geometry.Reset (new CSGeometry("")); geometry -> Load (infile); } // strcpy (geomfilename, lgfilename); // (*mycout) << "Load geometry file " << lgfilename << endl; else if (strcmp (&lgfilename[strlen(lgfilename)-3], "stl") == 0) { // strcpy (geomfilename, lgfilename); PrintMessage (1, "Load stl geometry file ", lgfilename); stlgeometry = STLGeometry :: Load (infile); ng_geometry = stlgeometry; stlgeometry->edgesfound = 0; } else if ((strcmp (&lgfilename[strlen(lgfilename)-4], "iges") == 0) || (strcmp (&lgfilename[strlen(lgfilename)-3], "igs") == 0) || (strcmp (&lgfilename[strlen(lgfilename)-3], "IGS") == 0) || (strcmp (&lgfilename[strlen(lgfilename)-4], "IGES") == 0)) { #ifdef OCCGEOMETRY // strcpy (geomfilename, lgfilename); PrintMessage (1, "Load IGES geometry file ", lgfilename); occgeometry = LoadOCC_IGES (lgfilename); ng_geometry = occgeometry; #else Tcl_SetResult (interp, (char*)"IGES import requires the OpenCascade geometry kernel. " "Please install OpenCascade as described in the Netgen-website", TCL_STATIC); return TCL_ERROR; #endif } else if (strcmp (&lgfilename[strlen(lgfilename)-3], "sat") == 0) { #ifdef ACIS PrintMessage (1, "Load ACIS geometry file ", lgfilename); acisgeometry = netgen::LoadACIS_SAT (lgfilename); #endif } else if ((strcmp (&lgfilename[strlen(lgfilename)-4], "step") == 0) || (strcmp (&lgfilename[strlen(lgfilename)-3], "stp") == 0) || (strcmp (&lgfilename[strlen(lgfilename)-3], "STP") == 0) || (strcmp (&lgfilename[strlen(lgfilename)-4], "STEP") == 0)) { #ifdef ACISxxx PrintMessage (1, "Load STEP geometry file ", lgfilename); acisgeometry = netgen::LoadACIS_STEP (lgfilename); #else #ifdef OCCGEOMETRY // strcpy (geomfilename, lgfilename); PrintMessage (1, "Load STEP geometry file ", lgfilename); occgeometry = LoadOCC_STEP (lgfilename); ng_geometry = occgeometry; #else Tcl_SetResult (interp, (char*)"IGES import requires the OpenCascade geometry kernel. " "Please install OpenCascade as described in the Netgen-website", TCL_STATIC); return TCL_ERROR; #endif #endif } else if ((strcmp (&lgfilename[strlen(lgfilename)-4], "brep") == 0) || (strcmp (&lgfilename[strlen(lgfilename)-4], "Brep") == 0) || (strcmp (&lgfilename[strlen(lgfilename)-4], "BREP") == 0)) { #ifdef OCCGEOMETRY // strcpy (geomfilename, lgfilename); PrintMessage (1, "Load BREP geometry file ", lgfilename); occgeometry = LoadOCC_BREP (lgfilename); ng_geometry = occgeometry; #else Tcl_SetResult (interp, (char*)"BREP import requires the OpenCascade geometry kernel. " "Please install OpenCascade as described in the Netgen-website", TCL_STATIC); return TCL_ERROR; #endif } else if (strcmp (&lgfilename[strlen(lgfilename)-4], "stlb") == 0) { // strcpy (geomfilename, lgfilename); PrintMessage (1, "Load stl geometry file ", lgfilename, " in binary format"); stlgeometry = STLGeometry :: LoadBinary (infile); ng_geometry = stlgeometry; stlgeometry->edgesfound = 0; } else if (strcmp (&lgfilename[strlen(lgfilename)-3], "nao") == 0) { // strcpy (geomfilename, lgfilename); PrintMessage (1, "Load naomi (F. Kickinger) geometry file ", lgfilename); stlgeometry = STLGeometry :: LoadNaomi (infile); ng_geometry = stlgeometry; stlgeometry->edgesfound = 0; } else if (strcmp (&lgfilename[strlen(lgfilename)-4], "in2d") == 0) { // strcpy (geomfilename, lgfilename); geometry2d.Reset (new SplineGeometry2d()); geometry2d -> Load (lgfilename); ng_geometry = geometry2d.Ptr(); } } } catch (NgException e) { Tcl_SetResult (interp, const_cast (e.What().c_str()), TCL_VOLATILE); return TCL_ERROR; } mesh.Reset(); return TCL_OK; } int Ng_SaveGeometry (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (argc == 2) { const char * cfilename = argv[1]; PrintMessage (1, "Save geometry to file ", cfilename); if (strlen(cfilename) < 4) {cout << "ERROR: can not recognise file format!!!" << endl;} else { #ifdef ACIS if (acisgeometry) { char * filename = const_cast (argv[1]); if (strcmp (&filename[strlen(filename)-3], "sat") == 0) { acisgeometry -> SaveSATFile (filename); } } #endif #ifdef OCCGEOMETRY if (occgeometry) { char * filename = const_cast (argv[1]); if (strcmp (&filename[strlen(filename)-3], "igs") == 0) { IGESControl_Writer writer("millimeters", 1); writer.AddShape (occgeometry->shape); writer.Write (filename); } else if (strcmp (&filename[strlen(filename)-3], "stp") == 0) { STEPControl_Writer writer; writer.Transfer (occgeometry->shape, STEPControl_AsIs); writer.Write (filename); } else if (strcmp (&filename[strlen(filename)-3], "stl") == 0) { StlAPI_Writer writer; writer.ASCIIMode() = Standard_True; writer.Write (occgeometry->shape, filename); } else if (strcmp (&filename[strlen(filename)-4], "stlb") == 0) { StlAPI_Writer writer; writer.ASCIIMode() = Standard_False; writer.Write (occgeometry->shape, filename); } } else #endif if (strcmp (&cfilename[strlen(cfilename)-3], "ngg") == 0) { if (geometry) { ofstream of(cfilename); geometry->Save (of); } } else if (strlen(cfilename) > 3 && strcmp (&cfilename[strlen(cfilename)-3], "stl") == 0) { if (stlgeometry) stlgeometry->Save (cfilename); } else if (strlen(cfilename) > 4 && strcmp (&cfilename[strlen(cfilename)-4], "stlb") == 0) { if (stlgeometry) stlgeometry->SaveBinary (cfilename,"Binary STL Geometry"); } else if (strlen(cfilename) > 4 && strcmp (&cfilename[strlen(cfilename)-4], "stle") == 0) { if (stlgeometry) stlgeometry->SaveSTLE (cfilename); } } } else { if (geometry) geometry->Save (cout); } return TCL_OK; } int Ng_ParseGeometry (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { #ifdef OCCGEOMETRY if (!stlgeometry && !geometry2d && !occgeometry) #else if (!stlgeometry && !geometry2d) #endif { double detail = atof (Tcl_GetVar (interp, "::geooptions.detail", 0)); double facets = atof (Tcl_GetVar (interp, "::geooptions.facets", 0)); Box<3> box (geometry->BoundingBox()); if (atoi (Tcl_GetVar (interp, "::geooptions.drawcsg", 0))) geometry->CalcTriangleApproximation(box, detail, facets); } return TCL_OK; } /* NgLock * ngpkg_lock = NULL; int Ng_Lock (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { delete ngpkg_lock; ngpkg_lock = NULL; if(strcmp (argv[1], "mesh") == 0) { ngpkg_lock = new NgLock(mesh->Mutex()); } else if(strcmp (argv[1], "unlock") == 0) { ; } return TCL_OK; } */ int Ng_GeometryOptions (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { const char * command = argv[1]; if (strcmp (command, "get") == 0) { char buf[20]; Point3d pmin = geometry->BoundingBox ().PMin(); Point3d pmax = geometry->BoundingBox ().PMax(); sprintf (buf, "%5.1lf", pmin.X()); Tcl_SetVar (interp, "::geooptions.minx", buf, 0); sprintf (buf, "%5.1lf", pmin.Y()); Tcl_SetVar (interp, "::geooptions.miny", buf, 0); sprintf (buf, "%5.1lf", pmin.Z()); Tcl_SetVar (interp, "::geooptions.minz", buf, 0); sprintf (buf, "%5.1lf", pmax.X()); Tcl_SetVar (interp, "::geooptions.maxx", buf, 0); sprintf (buf, "%5.1lf", pmax.Y()); Tcl_SetVar (interp, "::geooptions.maxy", buf, 0); sprintf (buf, "%5.1lf", pmax.Z()); Tcl_SetVar (interp, "::geooptions.maxz", buf, 0); } else if (strcmp (command, "set") == 0) { Point<3> pmin (atof (Tcl_GetVar (interp, "::geooptions.minx", 0)), atof (Tcl_GetVar (interp, "::geooptions.miny", 0)), atof (Tcl_GetVar (interp, "::geooptions.minz", 0))); Point<3> pmax (atof (Tcl_GetVar (interp, "::geooptions.maxx", 0)), atof (Tcl_GetVar (interp, "::geooptions.maxy", 0)), atof (Tcl_GetVar (interp, "::geooptions.maxz", 0))); Box<3> box (pmin, pmax); geometry -> SetBoundingBox (box); CSGeometry::SetDefaultBoundingBox (box); } return TCL_OK; } // attempt of a simple modeller int Ng_CreatePrimitive (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { tcl_const char * classname = argv[1]; tcl_const char * name = argv[2]; cout << "Create primitive, class = " << classname << ", name = " << name << endl; Primitive * nprim = Primitive::CreatePrimitive (classname); Solid * nsol = new Solid (nprim); char sname[100]; for (int j = 1; j <= nprim->GetNSurfaces(); j++) { sprintf (sname, "%s,%d", name, j); geometry -> AddSurface (sname, &nprim->GetSurface(j)); nprim -> SetSurfaceId (j, geometry->GetNSurf()); } geometry->SetSolid (name, nsol); return TCL_OK; } int Ng_SetPrimitiveData (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { tcl_const char * name = argv[1]; tcl_const char * value = argv[2]; Array coeffs; cout << "Set primitive data, name = " << name << ", value = " << value << endl; istringstream vst (value); double val; while (!vst.eof()) { vst >> val; coeffs.Append (val); } ((Primitive*) geometry->GetSolid (name)->GetPrimitive())->SetPrimitiveData (coeffs); return TCL_OK; } int Ng_SetSolidData (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { tcl_const char * name = argv[1]; tcl_const char * val = argv[2]; cout << "Set Solid Data, name = " << name << ", value = " << val << endl; istringstream vst (val); Solid * nsol = Solid::CreateSolid (vst, geometry->GetSolids()); geometry->SetSolid (name, nsol); return TCL_OK; } int Ng_GetPrimitiveData (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { tcl_const char * name = argv[1]; tcl_const char * classnamevar = argv[2]; tcl_const char * valuevar = argv[3]; const char * classname; Array coeffs; geometry->GetSolid (name)->GetPrimitive()->GetPrimitiveData (classname, coeffs); ostringstream vst; for (int i = 1; i <= coeffs.Size(); i++) vst << coeffs.Get(i) << " "; cout << "GetPrimitiveData, name = " << name << ", classnamevar = " << classnamevar << ", classname = " << classname << endl << " valuevar = " << valuevar << ", values = " << vst.str() << endl; Tcl_SetVar (interp, classnamevar, (char*)classname, 0); Tcl_SetVar (interp, valuevar, (char*)vst.str().c_str(), 0); return TCL_OK; } int Ng_GetSolidData (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { tcl_const char * name = argv[1]; tcl_const char * valuevar = argv[2]; ostringstream vst; const Solid * sol = geometry->GetSolid (name); sol->GetSolidData (vst); cout << "GetSolidData, name = " << name << ", data = " << vst.str() << endl; Tcl_SetVar (interp, valuevar, (char*)vst.str().c_str(), 0); return TCL_OK; } int Ng_GetPrimitiveList (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { tcl_const char * valuevar = argv[1]; int i; stringstream vst; for (i = 1; i <= geometry->GetNSolids(); i++) { const Solid * sol = geometry->GetSolid(i); if (sol->GetPrimitive()) vst << sol->Name() << " "; } cout << "primnames = " << vst.str() << endl; Tcl_SetVar (interp, valuevar, (char*)vst.str().c_str(), 0); return TCL_OK; } int Ng_GetSurfaceList (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { tcl_const char * valuevar = argv[1]; int i; stringstream vst; for (i = 1; i <= geometry->GetNSurf(); i++) { const Surface * surf = geometry->GetSurface(i); vst << surf->Name() << " "; } cout << "surfnames = " << vst.str() << endl; Tcl_SetVar (interp, valuevar, (char*)vst.str().c_str(), 0); return TCL_OK; } int Ng_GetSolidList (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { tcl_const char * valuevar = argv[1]; int i; stringstream vst; for (i = 1; i <= geometry->GetNSolids(); i++) { const Solid * sol = geometry->GetSolid(i); if (!sol->GetPrimitive()) vst << sol->Name() << " "; } cout << "solnames = " << vst.str() << endl; Tcl_SetVar (interp, valuevar, (char*)vst.str().c_str(), 0); return TCL_OK; } int Ng_TopLevel (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { int i; /* for (i = 0; i < argc; i++) cout << argv[i] << ", "; cout << endl; */ if (strcmp (argv[1], "getlist") == 0) { stringstream vst; for (i = 0; i < geometry->GetNTopLevelObjects(); i++) { const Solid * sol; const Surface * surf; geometry->GetTopLevelObject (i, sol, surf); if (!surf) vst << "{ " << sol->Name() << " } "; else vst << "{ " << sol->Name() << " " << surf->Name() << " } "; } tcl_const char * valuevar = argv[2]; Tcl_SetVar (interp, valuevar, (char*)vst.str().c_str(), 0); } if (strcmp (argv[1], "set") == 0) { tcl_const char * solname = argv[2]; tcl_const char * surfname = argv[3]; Solid * sol = (Solid*)geometry->GetSolid (solname); Surface * surf = (Surface*)geometry->GetSurface (surfname); geometry->SetTopLevelObject (sol, surf); } if (strcmp (argv[1], "remove") == 0) { tcl_const char * solname = argv[2]; tcl_const char * surfname = argv[3]; Solid * sol = (Solid*)geometry->GetSolid (solname); Surface * surf = (Surface*)geometry->GetSurface (surfname); geometry->RemoveTopLevelObject (sol, surf); } if (strcmp (argv[1], "setprop") == 0) { tcl_const char * solname = argv[2]; tcl_const char * surfname = argv[3]; tcl_const char * propvar = argv[4]; Solid * sol = (Solid*)geometry->GetSolid (solname); Surface * surf = (Surface*)geometry->GetSurface (surfname); TopLevelObject * tlo = geometry->GetTopLevelObject (sol, surf); if (!tlo) return TCL_OK; char varname[50]; sprintf (varname, "%s(red)", propvar); double red = atof (Tcl_GetVar (interp, varname, 0)); sprintf (varname, "%s(blue)", propvar); double blue = atof (Tcl_GetVar (interp, varname, 0)); sprintf (varname, "%s(green)", propvar); double green = atof (Tcl_GetVar (interp, varname, 0)); tlo -> SetRGB (red, green, blue); sprintf (varname, "%s(visible)", propvar); tlo -> SetVisible (bool(atoi (Tcl_GetVar (interp, varname, 0)))); sprintf (varname, "%s(transp)", propvar); tlo -> SetTransparent (bool(atoi (Tcl_GetVar (interp, varname, 0)))); } if (strcmp (argv[1], "getprop") == 0) { tcl_const char * solname = argv[2]; tcl_const char * surfname = argv[3]; tcl_const char * propvar = argv[4]; Solid * sol = (Solid*)geometry->GetSolid (solname); Surface * surf = (Surface*)geometry->GetSurface (surfname); TopLevelObject * tlo = geometry->GetTopLevelObject (sol, surf); if (!tlo) return TCL_OK; char varname[50], varval[10]; sprintf (varname, "%s(red)", propvar); sprintf (varval, "%lf", tlo->GetRed()); Tcl_SetVar (interp, varname, varval, 0); sprintf (varname, "%s(green)", propvar); sprintf (varval, "%lf", tlo->GetGreen()); Tcl_SetVar (interp, varname, varval, 0); sprintf (varname, "%s(blue)", propvar); sprintf (varval, "%lf", tlo->GetBlue()); Tcl_SetVar (interp, varname, varval, 0); sprintf (varname, "%s(visible)", propvar); sprintf (varval, "%d", tlo->GetVisible()); Tcl_SetVar (interp, varname, varval, 0); sprintf (varname, "%s(transp)", propvar); sprintf (varval, "%d", tlo->GetTransparent()); Tcl_SetVar (interp, varname, varval, 0); } return TCL_OK; } int Ng_ReadStatus (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { char buf[20], lstring[200]; if (mesh.Ptr()) { sprintf (buf, "%d", mesh->GetNP()); Tcl_SetVar (interp, "::status_np", buf, 0); sprintf (buf, "%d", mesh->GetNE()); Tcl_SetVar (interp, "::status_ne", buf, 0); sprintf (buf, "%d", mesh->GetNSE()); Tcl_SetVar (interp, "::status_nse", buf, 0); } else { Tcl_SetVar (interp, "::status_np", "0", 0); Tcl_SetVar (interp, "::status_ne", "0", 0); Tcl_SetVar (interp, "::status_nse", "0", 0); } if (multithread.running) Tcl_SetVar (interp, "::status_working", "working", 0); else Tcl_SetVar (interp, "::status_working", " ", 0); Tcl_SetVar (interp, "::status_task", const_cast(multithread.task), 0); sprintf (buf, "%lf", multithread.percent); Tcl_SetVar (interp, "::status_percent", buf, 0); int i; lstring[0] = 0; for (i = 1; i <= tets_in_qualclass.Size(); i++) { sprintf (buf, " %d", tets_in_qualclass.Get(i)); strcat (lstring, buf); } for (i = tets_in_qualclass.Size()+1; i <= 20; i++) strcat (lstring, " 0"); Tcl_SetVar (interp, "::status_tetqualclasses", lstring, 0); return TCL_OK; } int Ng_MemInfo (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (argc < 2) return TCL_ERROR; if (strcmp (argv[1], "usedmb") == 0) { // returns string of 512 '0' or '1' static char usedmb[513]; for (int i = 0; i < 512; i++) usedmb[i] = (i % 7 == 0) ? '1' : '0'; usedmb[512] = 0; BaseDynamicMem::GetUsed (512, usedmb); Tcl_SetResult (interp, usedmb, TCL_STATIC); return TCL_OK; } return TCL_ERROR; } int Ng_BCProp (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { static char buf[100]; if (argc < 2) { Tcl_SetResult (interp, (char*)"Ng_BCProp needs arguments", TCL_STATIC); return TCL_ERROR; } if (strcmp (argv[1], "setbc") == 0) { int facenr = atoi (argv[2]); int bcnr = atoi (argv[3]); if (mesh.Ptr() && facenr >= 1 && facenr <= mesh->GetNFD()) mesh->GetFaceDescriptor (facenr).SetBCProperty (bcnr); } if (strcmp (argv[1], "setall") == 0) { int bcnr = atoi (argv[2]); if (mesh.Ptr()) { int nfd = mesh->GetNFD(); for (int i = 1; i <= nfd; i++) mesh->GetFaceDescriptor (i).SetBCProperty (bcnr); } } if (strcmp (argv[1], "getbc") == 0) { int facenr = atoi (argv[2]); if (mesh.Ptr() && facenr >= 1 && facenr <= mesh->GetNFD()) { sprintf (buf, "%d", mesh->GetFaceDescriptor(facenr).BCProperty()); } else { strcpy (buf, "0"); } Tcl_SetResult (interp, buf, TCL_STATIC); } if (strcmp (argv[1], "getbcname") == 0) { int facenr = atoi (argv[2]); if (mesh.Ptr() && facenr >= 1 && facenr <= mesh->GetNFD()) { sprintf (buf, "%s", mesh->GetFaceDescriptor(facenr).GetBCName().c_str()); } else { strcpy (buf, "-"); } Tcl_SetResult (interp, buf, TCL_STATIC); } if (strcmp (argv[1], "getactive") == 0) { sprintf (buf, "%d", vsmesh.SelectedFace()); Tcl_SetResult (interp, buf, TCL_STATIC); } if (strcmp (argv[1], "setactive") == 0) { int facenr = atoi (argv[2]); if (mesh.Ptr() && facenr >= 1 && facenr <= mesh->GetNFD()) { vsmesh.SetSelectedFace (facenr); } } if (strcmp (argv[1], "getnfd") == 0) { if (mesh.Ptr()) sprintf (buf, "%d", mesh->GetNFD()); else sprintf (buf, "0"); Tcl_SetResult (interp, buf, TCL_STATIC); } return TCL_OK; } // Philippose - 30/01/2009 // TCL interface function for the Local Face Mesh size // definition functionality int Ng_SurfaceMeshSize (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { #ifdef OCCGEOMETRY static char buf[100]; if (argc < 2) { Tcl_SetResult (interp, (char *)"Ng_SurfaceMeshSize needs arguments", TCL_STATIC); return TCL_ERROR; } if (!occgeometry) { Tcl_SetResult (interp, (char *)"Ng_SurfaceMeshSize currently supports only OCC (STEP/IGES) Files", TCL_STATIC); return TCL_ERROR; } // Update the face mesh sizes to reflect the global maximum mesh size for(int i = 1; i <= occgeometry->NrFaces(); i++) { occgeometry->SetFaceMaxH(i, min(mparam.maxh,occgeometry->GetFaceMaxH(i))); } if (strcmp (argv[1], "setsurfms") == 0) { int facenr = atoi (argv[2]); double surfms = atof (argv[3]); if (occgeometry && facenr >= 1 && facenr <= occgeometry->NrFaces()) occgeometry->SetFaceMaxH(facenr, surfms); } if (strcmp (argv[1], "setall") == 0) { double surfms = atof (argv[2]); if (occgeometry) { int nrFaces = occgeometry->NrFaces(); for (int i = 1; i <= nrFaces; i++) occgeometry->SetFaceMaxH(i, surfms); } } if (strcmp (argv[1], "getsurfms") == 0) { int facenr = atoi (argv[2]); if (occgeometry && facenr >= 1 && facenr <= occgeometry->NrFaces()) { sprintf (buf, "%5.2f", occgeometry->GetFaceMaxH(facenr)); } else { sprintf (buf, "%5.2f", mparam.maxh); } Tcl_SetResult (interp, buf, TCL_STATIC); } if (strcmp (argv[1], "getactive") == 0) { sprintf (buf, "%d", occgeometry->SelectedFace()); Tcl_SetResult (interp, buf, TCL_STATIC); } if (strcmp (argv[1], "setactive") == 0) { int facenr = atoi (argv[2]); if (occgeometry && facenr >= 1 && facenr <= occgeometry->NrFaces()) { occgeometry->SetSelectedFace (facenr); occgeometry->LowLightAll(); occgeometry->fvispar[facenr-1].Highlight(); occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } } if (strcmp (argv[1], "getnfd") == 0) { if (occgeometry) sprintf (buf, "%d", occgeometry->NrFaces()); else sprintf (buf, "0"); Tcl_SetResult (interp, buf, TCL_STATIC); } return TCL_OK; #else // No OCCGEOMETRY Tcl_SetResult (interp, (char *)"Ng_SurfaceMeshSize currently supports only OCC (STEP/IGES) Files", TCL_STATIC); return TCL_ERROR; #endif // OCCGEOMETRY } // Philippose - 10/03/2009 // TCL interface function for the Automatic Colour-based // definition of boundary conditions for OCC Geometry int Ng_AutoColourBcProps (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if(argc < 1) { Tcl_SetResult (interp, (char *)"Ng_AutoColourBcProps needs arguments", TCL_STATIC); return TCL_ERROR; } if(!mesh.Ptr()) { Tcl_SetResult (interp, (char *)"Ng_AutoColourBcProps: Valid netgen mesh required...please mesh the Geometry first", TCL_STATIC); return TCL_ERROR; } if(strcmp(argv[1], "auto") == 0) { AutoColourBcProps(*mesh, 0); } if(strcmp(argv[1], "profile") == 0) { AutoColourBcProps(*mesh, argv[2]); } return TCL_OK; } int Ng_SetNextTimeStamp (ClientData clientData, Tcl_Interp * interp, int argqc, tcl_const char *argv[]) { if (mesh.Ptr()) mesh -> SetNextTimeStamp(); return TCL_OK; } int Ng_Refine (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } #ifdef ACIS if (acisgeometry) { ACISRefinementSurfaces ref (*acisgeometry); ACISMeshOptimize2dSurfaces opt(*acisgeometry); ref.Set2dOptimizer(&opt); ref.Refine (*mesh); } #endif else { ng_geometry -> GetRefinement().Refine(*mesh); } return TCL_OK; } int Ng_SecondOrder (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } const_cast (ng_geometry -> GetRefinement()).MakeSecondOrder (*mesh); return TCL_OK; } void * HighOrderDummy (void *) { // mparam.elementorder = atoi (Tcl_GetVar (interp, "options.elementorder", 0)); const char * savetask = multithread.task; Refinement & ref = const_cast (ng_geometry -> GetRefinement()); mesh -> GetCurvedElements().BuildCurvedElements (&ref, mparam.elementorder); multithread.task = savetask; multithread.running = 0; multithread.terminate = 1; mesh -> SetNextMajorTimeStamp(); return 0; } int Ng_HighOrder (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } multithread.running = 1; multithread.terminate = 0; mparam.elementorder = atoi(argv[1]); HighOrderDummy(NULL); return TCL_OK; } void * ValidateDummy (void *) { RefinementSTLGeometry ref (*stlgeometry); ref.ValidateSecondOrder (*mesh); multithread.running = 0; return NULL; } int Ng_ValidateSecondOrder (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } multithread.running = 1; RunParallel (ValidateDummy, NULL); return TCL_OK; } int Ng_ZRefinement (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } ZRefinementOptions opt; opt.minref = 5; if (argc >= 2) opt.minref = atoi (argv[1]); ZRefinement (*mesh, geometry.Ptr(), opt); return TCL_OK; } int Ng_HPRefinement (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } int levels = atoi (argv[1]); Refinement & ref = const_cast (ng_geometry -> GetRefinement()); HPRefinement (*mesh, &ref, levels); return TCL_OK; } int Ng_LoadMeshSize (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } mesh->LoadLocalMeshSize(argv[1]); return TCL_OK; } int Ng_MeshSizeFromSurfaceMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } mesh->SetGlobalH (mparam.maxh); mesh->CalcLocalH(); return TCL_OK; } int Ng_SingularPointMS (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { double globh = mparam.maxh; for (int i = 1; i <= geometry->singpoints.Size(); i++) geometry->singpoints.Get(i)->SetMeshSize (*mesh, globh); return TCL_OK; } int Ng_SingularEdgeMS (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } double globh = mparam.maxh; for (int i = 1; i <= geometry->singedges.Size(); i++) geometry->singedges.Get(i)->SetMeshSize (*mesh, globh); return TCL_OK; } // Philippose Rajan - 13 June 2009 // Added a new TCL function call for the generation // of prismatic boundary layers int Ng_GenerateBoundaryLayer (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if(multithread.running) { Tcl_SetResult(interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } GenerateBoundaryLayer (*mesh); return TCL_OK; } int Ng_InsertVirtualBL (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } InsertVirtualBoundaryLayer (*mesh); return TCL_OK; } int Ng_CutOffAndCombine (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { Mesh othermesh; othermesh.Load (argv[1]); othermesh.SetGlobalH (mparam.maxh); othermesh.CalcLocalH(); CutOffAndCombine (*mesh, othermesh); return TCL_OK; } int Ng_HelmholtzMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { HelmholtzMesh (*mesh); return TCL_OK; } int Ng_SetMeshingParameters (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { mparam.maxh = atof (Tcl_GetVar (interp, "::options.meshsize", 0)); mparam.minh = atof (Tcl_GetVar (interp, "::options.minmeshsize", 0)); mparam.meshsizefilename = Tcl_GetVar (interp, "::options.meshsizefilename", 0); if (!strlen (mparam.meshsizefilename)) mparam.meshsizefilename = NULL; mparam.curvaturesafety = atof (Tcl_GetVar (interp, "::options.curvaturesafety", 0)); mparam.segmentsperedge = atof (Tcl_GetVar (interp, "::options.segmentsperedge", 0)); mparam.badellimit = atof (Tcl_GetVar (interp, "::options.badellimit", 0)); mparam.secondorder = atoi (Tcl_GetVar (interp, "::options.secondorder", 0)); mparam.elementorder = atoi (Tcl_GetVar (interp, "::options.elementorder", 0)); mparam.quad = atoi (Tcl_GetVar (interp, "::options.quad", 0)); mparam.inverttets = atoi (Tcl_GetVar (interp, "::options.inverttets", 0)); mparam.inverttrigs = atoi (Tcl_GetVar (interp, "::options.inverttrigs", 0)); mparam.uselocalh = atoi (Tcl_GetVar (interp, "::options.localh", 0)); mparam.grading = atof (Tcl_GetVar (interp, "::options.grading", 0)); mparam.delaunay = atoi (Tcl_GetVar (interp, "::options.delaunay", 0)); mparam.checkoverlap = atoi (Tcl_GetVar (interp, "::options.checkoverlap", 0)); mparam.checkoverlappingboundary = atoi (Tcl_GetVar (interp, "::options.checkoverlappingboundary", 0)); mparam.checkchartboundary = atoi (Tcl_GetVar (interp, "::options.checkchartboundary", 0)); mparam.optsteps3d = atoi (Tcl_GetVar (interp, "::options.optsteps3d", 0)); mparam.optsteps2d = atoi (Tcl_GetVar (interp, "::options.optsteps2d", 0)); mparam.opterrpow = atof (Tcl_GetVar (interp, "::options.opterrpow", 0)); mparam.parthread = atoi (Tcl_GetVar (interp, "::options.parthread", 0)); mparam.elsizeweight = atof (Tcl_GetVar (interp, "::options.elsizeweight", 0)); mparam.autozrefine = atoi (Tcl_GetVar (interp, "::options.autozrefine", 0)); extern int printmessage_importance; extern int printdots; printmessage_importance = atoi (Tcl_GetVar (interp, "::options.printmsg", 0)); printdots = (printmessage_importance >= 4); //BaseMoveableMem::totalsize = 0; // 1048576 * atoi (Tcl_GetVar (interp, "::options.memory", 0)); if (mesh.Ptr()) { mesh->SetGlobalH (mparam.maxh); mesh->SetMinimalH (mparam.minh); } return TCL_OK; } int Ng_SetDebugParameters (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { debugparam.slowchecks = atoi (Tcl_GetVar (interp, "::debug.slowchecks", 0)); debugparam.debugoutput = atoi (Tcl_GetVar (interp, "::debug.debugoutput", 0)); debugparam.haltexistingline = atoi (Tcl_GetVar (interp, "::debug.haltexistingline", 0)); debugparam.haltoverlap = atoi (Tcl_GetVar (interp, "::debug.haltoverlap", 0)); debugparam.haltsuccess = atoi (Tcl_GetVar (interp, "::debug.haltsuccess", 0)); debugparam.haltnosuccess = atoi (Tcl_GetVar (interp, "::debug.haltnosuccess", 0)); debugparam.haltlargequalclass = atoi (Tcl_GetVar (interp, "::debug.haltlargequalclass", 0)); debugparam.haltsegment = atoi (Tcl_GetVar (interp, "::debug.haltsegment", 0)); debugparam.haltnode = atoi (Tcl_GetVar (interp, "::debug.haltnode", 0)); debugparam.haltface = atoi (Tcl_GetVar (interp, "::debug.haltface", 0)); debugparam.haltsegmentp1 = atoi (Tcl_GetVar (interp, "::debug.haltsegmentp1", 0)); debugparam.haltsegmentp2 = atoi (Tcl_GetVar (interp, "::debug.haltsegmentp2", 0)); debugparam.haltfacenr = atoi (Tcl_GetVar (interp, "::debug.haltfacenr", 0)); return TCL_OK; } int Ng_SetSTLParameters (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { stlparam.yangle = atof (Tcl_GetVar (interp, "::stloptions.yangle", 0)); stlparam.contyangle = atof (Tcl_GetVar (interp, "::stloptions.contyangle", 0)); stlparam.edgecornerangle = atof (Tcl_GetVar (interp, "::stloptions.edgecornerangle", 0)); stlparam.chartangle = atof (Tcl_GetVar (interp, "::stloptions.chartangle", 0)); stlparam.outerchartangle = atof (Tcl_GetVar (interp, "::stloptions.outerchartangle", 0)); stlparam.usesearchtree = atoi (Tcl_GetVar (interp, "::stloptions.usesearchtree", 0)); stlparam.atlasminh = atof (Tcl_GetVar (interp, "::stloptions.atlasminh", 0)); stlparam.resthsurfcurvfac = atof (Tcl_GetVar (interp, "::stloptions.resthsurfcurvfac", 0)); stlparam.resthsurfcurvenable = atoi (Tcl_GetVar (interp, "::stloptions.resthsurfcurvenable", 0)); stlparam.resthatlasfac = atof (Tcl_GetVar (interp, "::stloptions.resthatlasfac", 0)); stlparam.resthatlasenable = atoi (Tcl_GetVar (interp, "::stloptions.resthatlasenable", 0)); stlparam.resthchartdistfac = atof (Tcl_GetVar (interp, "::stloptions.resthchartdistfac", 0)); stlparam.resthchartdistenable = atoi (Tcl_GetVar (interp, "::stloptions.resthchartdistenable", 0)); stlparam.resthlinelengthfac = atof (Tcl_GetVar (interp, "::stloptions.resthlinelengthfac", 0)); stlparam.resthlinelengthenable = atoi (Tcl_GetVar (interp, "::stloptions.resthlinelengthenable", 0)); stlparam.resthcloseedgefac = atof (Tcl_GetVar (interp, "::stloptions.resthcloseedgefac", 0)); stlparam.resthcloseedgeenable = atoi (Tcl_GetVar (interp, "::stloptions.resthcloseedgeenable", 0)); stlparam.resthedgeanglefac = atof (Tcl_GetVar (interp, "::stloptions.resthedgeanglefac", 0)); stlparam.resthedgeangleenable = atoi (Tcl_GetVar (interp, "::stloptions.resthedgeangleenable", 0)); stlparam.resthsurfmeshcurvfac = atof (Tcl_GetVar (interp, "::stloptions.resthsurfmeshcurvfac", 0)); stlparam.resthsurfmeshcurvenable = atoi (Tcl_GetVar (interp, "::stloptions.resthsurfmeshcurvenable", 0)); stlparam.recalc_h_opt = atoi (Tcl_GetVar (interp, "::stloptions.recalchopt", 0)); // stlparam.Print (cout); return TCL_OK; } #ifdef OCCGEOMETRY int Ng_SetOCCParameters (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { occparam.resthcloseedgefac = atof (Tcl_GetVar (interp, "::stloptions.resthcloseedgefac", 0)); occparam.resthcloseedgeenable = atoi (Tcl_GetVar (interp, "::stloptions.resthcloseedgeenable", 0)); return TCL_OK; } #endif // OCCGEOMETRY int Ng_GetCommandLineParameter (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (argc != 2) { Tcl_SetResult (interp, (char*)"Ng_GetCommandLineParameter needs 1 parameter", TCL_STATIC); return TCL_ERROR; } static char buf[10]; if (parameters.StringFlagDefined (argv[1])) Tcl_SetResult (interp, (char*)parameters.GetStringFlag (argv[1], NULL), TCL_STATIC); else if (parameters.NumFlagDefined (argv[1])) { sprintf (buf, "%lf", parameters.GetNumFlag (argv[1], 0)); Tcl_SetResult (interp, buf, TCL_STATIC); } else if (parameters.GetDefineFlag (argv[1])) Tcl_SetResult (interp, (char*)"defined", TCL_STATIC); else Tcl_SetResult (interp, (char*)"undefined", TCL_STATIC); return TCL_OK; } static int perfstepsstart; static int perfstepsend; static char* optstring = NULL; static char* optstringcsg = NULL; void * MeshingDummy (void *) { const char * savetask = multithread.task; multithread.task = "Generate Mesh"; ResetTime(); try { #ifdef LOG_STREAM (*logout) << "Start meshing" << endl; (*logout) << "Meshing parameters:" << endl; mparam.Print (*logout); #endif #ifdef ACIS if (acisgeometry) { ACISGenerateMesh(*acisgeometry, mesh.Ptr(), perfstepsstart, perfstepsend, optstring); } else #endif if (geometry2d) { extern void MeshFromSpline2D (SplineGeometry2d & geometry2d, Mesh *& mesh, MeshingParameters & mp); MeshFromSpline2D (*geometry2d, mesh.Ptr(), mparam); } else { int res = ng_geometry -> GenerateMesh (mesh.Ptr(), perfstepsstart, perfstepsend, optstringcsg); if (res != MESHING3_OK) return 0; } if (mparam.autozrefine && ( (NetgenGeometry*)geometry.Ptr() == ng_geometry)) { ZRefinementOptions opt; opt.minref = 5; ZRefinement (*mesh, geometry.Ptr(), opt); mesh -> SetNextMajorTimeStamp(); } if (mparam.secondorder) { const_cast (ng_geometry -> GetRefinement()).MakeSecondOrder (*mesh); mesh -> SetNextMajorTimeStamp(); } if (mparam.elementorder > 1) { mesh -> GetCurvedElements().BuildCurvedElements (&const_cast (ng_geometry -> GetRefinement()), mparam.elementorder); mesh -> SetNextMajorTimeStamp(); } PrintMessage (1, "Meshing done, time = ", GetTime(), " sec"); } catch (NgException e) { cout << e.What() << endl; } multithread.task = savetask; multithread.running = 0; #ifdef OCCGEOMETRY if (occgeometry) { if (occgeometry->ErrorInSurfaceMeshing()) { char script[] = "rebuildoccdialog"; int errcode = Tcl_GlobalEval (tcl_interp, script); } } #endif return NULL; } int MeshingVal(tcl_const char* str) { if (strcmp(str, "ag") == 0) {return MESHCONST_ANALYSE;} if (strcmp(str, "me") == 0) {return MESHCONST_MESHEDGES;} if (strcmp(str, "ms") == 0) {return MESHCONST_MESHSURFACE;} if (strcmp(str, "os") == 0) {return MESHCONST_OPTSURFACE;} if (strcmp(str, "mv") == 0) {return MESHCONST_MESHVOLUME;} if (strcmp(str, "ov") == 0) {return MESHCONST_OPTVOLUME;} cout << "TCL TK ERROR, wrong meshing value, return='" << str << "'" << endl; return 0; } int Ng_GenerateMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } multithread.running = 1; multithread.terminate = 0; Ng_SetSTLParameters (clientData, interp, 0, argv); #ifdef OCCGEOMETRY Ng_SetOCCParameters (clientData, interp, 0, argv); #endif // OCCGEOMETRY Ng_SetMeshingParameters (clientData, interp, 0, argv); perfstepsstart = 1; perfstepsend = 6; if (optstringcsg) delete optstringcsg; optstringcsg = NULL; if (optstring) delete optstring; optstring = NULL; if (argc == 2) { perfstepsstart = 1; perfstepsend = MeshingVal(argv[1]); } else if (argc == 3) { perfstepsstart = MeshingVal(argv[1]); perfstepsend = MeshingVal(argv[2]); } else if (argc == 4) { perfstepsstart = MeshingVal(argv[1]); perfstepsend = MeshingVal(argv[2]); optstring = new char[strlen(argv[3])+1]; strcpy(optstring, argv[3]); optstringcsg = new char[strlen(argv[3])+1]; strcpy(optstringcsg, argv[3]); } RunParallel (MeshingDummy, NULL); return TCL_OK; } int Ng_StopMeshing (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { multithread.terminate = 1; return TCL_OK; } int Ng_MeshInfo (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } ostringstream str; if (argc >= 2 && strcmp (argv[1], "dim") == 0) str << mesh->GetDimension(); else if (argc >= 2 && strcmp (argv[1], "np") == 0) str << mesh->GetNP(); else if (argc >= 2 && strcmp (argv[1], "ne") == 0) str << mesh->GetNE(); else if (argc >= 2 && strcmp (argv[1], "nse") == 0) str << mesh->GetNSE(); else if (argc >= 2 && strcmp (argv[1], "nseg") == 0) str << mesh->GetNSeg(); else if (argc >= 2 && strcmp (argv[1], "bbox") == 0) { Point3d pmin, pmax; mesh->GetBox (pmin, pmax); str << pmin.X() << " " << pmax.X() << " " << pmin.Y() << " " << pmax.Y() << " " << pmin.Z() << " " << pmax.Z() << endl; } else { cout << "argv[1] = " << argv[1] << endl; Tcl_SetResult (interp, (char*)"Ng_MeshInfo requires an argument out of \n dim np ne", TCL_STATIC); return TCL_ERROR; } Tcl_SetResult (interp, (char*)str.str().c_str(), TCL_VOLATILE); return TCL_OK; } int Ng_MeshQuality (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } double angles[4]; char buf[10]; if (mesh.Ptr()) mesh->CalcMinMaxAngle(mparam.badellimit, angles); else { angles[0] = angles[1] = angles[2] = angles[3] = 0; } sprintf (buf, "%5.1lf", angles[0]); Tcl_SetVar (interp, argv[1], buf, 0); sprintf (buf, "%5.1lf", angles[1]); Tcl_SetVar (interp, argv[2], buf, 0); sprintf (buf, "%5.1lf", angles[2]); Tcl_SetVar (interp, argv[3], buf, 0); sprintf (buf, "%5.1lf", angles[3]); Tcl_SetVar (interp, argv[4], buf, 0); return TCL_OK; } int Ng_CheckSurfaceMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } mesh->FindOpenElements(); if (mesh->CheckConsistentBoundary()) { PrintMessage (1, "surface mesh not consistent, trying orientation"); mesh->SurfaceMeshOrientation(); } else { PrintMessage (1, "surface mesh consistent"); } mesh->CheckOverlappingBoundary(); return TCL_OK; } int Ng_CheckVolumeMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } mesh->CheckVolumeMesh(); return TCL_OK; } int Ng_DeleteVolMesh (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (mesh.Ptr()) mesh->ClearVolumeElements(); return TCL_OK; } int Ng_SplitSeparatedFaces (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (mesh.Ptr()) mesh->SplitSeparatedFaces (); return TCL_OK; } int Ng_RestrictH (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } if (argc != 3) return TCL_OK; if (!mesh.Ptr()) return TCL_OK; double loch = atof (argv[2]); if (strcmp (argv[1], "face") == 0) { cout << "Restrict h at face to " << loch << endl; mesh -> RestrictLocalH (RESTRICTH_FACE, vsmesh.SelectedFace(), loch); } if (strcmp (argv[1], "edge") == 0) { cout << "Restrict h at edge to " << loch << endl; mesh -> RestrictLocalH (RESTRICTH_EDGE, vsmesh.SelectedEdge(), loch); } if (strcmp (argv[1], "point") == 0) { cout << "Restrict h at point to " << loch << endl; mesh -> RestrictLocalH (RESTRICTH_POINT, vsmesh.SelectedPoint(), loch); } return TCL_OK; } int Ng_Anisotropy (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } if (argc != 2) return TCL_OK; if (!mesh.Ptr()) return TCL_OK; if (strcmp (argv[1], "edge") == 0) { int edgenr = vsmesh.SelectedEdge(); for (int i = 1; i <= mesh->GetNSeg(); i++) { Segment & seg = mesh->LineSegment(i); if (seg.edgenr == edgenr) { seg.singedge_left = 1 - seg.singedge_left; seg.singedge_right = 1 - seg.singedge_right; } } } return TCL_OK; } BisectionOptions biopt; void * BisectDummy (void *) { Refinement * ref; MeshOptimize2d * opt = NULL; if (stlgeometry) ref = new RefinementSTLGeometry(*stlgeometry); #ifdef OCCGEOMETRY else if (occgeometry) ref = new OCCRefinementSurfaces (*occgeometry); #endif #ifdef ACIS else if (acisgeometry) { ref = new ACISRefinementSurfaces(*acisgeometry); opt = new ACISMeshOptimize2dSurfaces(*acisgeometry); ref->Set2dOptimizer(opt); } #endif else { ref = new RefinementSurfaces(*geometry); opt = new MeshOptimize2dSurfaces(*geometry); ref->Set2dOptimizer(opt); } if(!mesh->LocalHFunctionGenerated()) mesh->CalcLocalH(); mesh->LocalHFunction().SetGrading (mparam.grading); ref -> Bisect (*mesh, biopt); mesh -> UpdateTopology(); mesh -> GetCurvedElements().BuildCurvedElements (ref, mparam.elementorder); multithread.running = 0; delete ref; delete opt; return NULL; } int Ng_Bisect (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { cout << "Thread alrad running" << endl; return TCL_OK; } multithread.running = 1; biopt.outfilename = NULL; // "ngfepp.vol"; biopt.femcode = "fepp"; biopt.refinementfilename = NULL; if (argc >= 2) biopt.refinementfilename = argv[1]; // pthread_create (&meshingthread, NULL, &BisectDummy, NULL); BisectDummy (0); /* extern void BisectTets (Mesh &, const CSGeometry *); BisectTets (*mesh, geometry); */ return TCL_OK; } // int Ng_BisectCopyMesh (ClientData clientData, // Tcl_Interp * interp, // int argc, tcl_const char *argv[]) // { // if (!mesh.Ptr()) // { // Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); // return TCL_ERROR; // } // if (multithread.running) // { // Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); // return TCL_ERROR; // } // BisectTetsCopyMesh (*mesh, geometry.Ptr(), biopt); // return TCL_OK; // } int Ng_Split2Tets (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!mesh.Ptr()) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } if (multithread.running) { Tcl_SetResult (interp, err_jobrunning, TCL_STATIC); return TCL_ERROR; } mesh->Split2Tets (); return TCL_OK; } int Ng_STLDoctor (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { //cout << "STL doctor" << endl; stldoctor.drawmeshededges = atoi (Tcl_GetVar (interp, "::stldoctor.drawmeshededges", 0)); stldoctor.geom_tol_fact = atof (Tcl_GetVar (interp, "::stldoctor.geom_tol_fact", 0)); stldoctor.useexternaledges = atoi (Tcl_GetVar (interp, "::stldoctor.useexternaledges", 0)); stldoctor.showfaces = atoi (Tcl_GetVar (interp, "::stldoctor.showfaces", 0)); stldoctor.conecheck = atoi (Tcl_GetVar (interp, "::stldoctor.conecheck", 0)); stldoctor.spiralcheck = atoi (Tcl_GetVar (interp, "::stldoctor.spiralcheck", 0)); stldoctor.selectwithmouse = atoi (Tcl_GetVar (interp, "::stldoctor.selectwithmouse", 0)); stldoctor.showedgecornerpoints = atoi (Tcl_GetVar (interp, "::stldoctor.showedgecornerpoints", 0)); stldoctor.showmarkedtrigs = atoi (Tcl_GetVar (interp, "::stldoctor.showmarkedtrigs", 0)); stldoctor.showtouchedtrigchart = atoi (Tcl_GetVar (interp, "::stldoctor.showtouchedtrigchart", 0)); //cout << "smt=" << stldoctor.showmarkedtrigs << endl; stldoctor.dirtytrigfact = atof (Tcl_GetVar (interp, "::stldoctor.dirtytrigfact", 0)); stldoctor.smoothnormalsweight = atof (Tcl_GetVar (interp, "::stldoctor.smoothnormalsweight", 0)); stldoctor.smoothangle = atof (Tcl_GetVar (interp, "::stldoctor.smoothangle", 0)); stldoctor.selectmode = atoi (Tcl_GetVar (interp, "::stldoctor.selectmode", 0)); stldoctor.edgeselectmode = atoi (Tcl_GetVar (interp, "::stldoctor.edgeselectmode", 0)); stldoctor.longlinefact = atoi (Tcl_GetVar (interp, "::stldoctor.longlinefact", 0)); stldoctor.showexcluded = atoi (Tcl_GetVar (interp, "::stldoctor.showexcluded", 0)); if (!stldoctor.selectwithmouse) { stldoctor.selecttrig = atoi (Tcl_GetVar (interp, "::stldoctor.selecttrig", 0)); stldoctor.nodeofseltrig = atoi (Tcl_GetVar (interp, "::stldoctor.nodeofseltrig", 0)); } stldoctor.showvicinity = atoi (Tcl_GetVar (interp, "::stldoctor.showvicinity", 0)); stldoctor.vicinity = atoi (Tcl_GetVar (interp, "::stldoctor.vicinity", 0)); if (argc >= 2) { if (!stlgeometry) { Tcl_SetResult (interp, err_needsstlgeometry, TCL_STATIC); return TCL_ERROR; } if (strcmp (argv[1], "destroy0trigs") == 0) { stlgeometry->DestroyDirtyTrigs(); } else if (strcmp (argv[1], "movepointtomiddle") == 0) { stlgeometry->MoveSelectedPointToMiddle(); } else if (strcmp (argv[1], "calcnormals") == 0) { stlgeometry->CalcNormalsFromGeometry(); } else if (strcmp (argv[1], "showchartnum") == 0) { stlgeometry->ShowSelectedTrigChartnum(); } else if (strcmp (argv[1], "showcoords") == 0) { stlgeometry->ShowSelectedTrigCoords(); } else if (strcmp (argv[1], "loadmarkedtrigs") == 0) { stlgeometry->LoadMarkedTrigs(); } else if (strcmp (argv[1], "savemarkedtrigs") == 0) { stlgeometry->SaveMarkedTrigs(); } else if (strcmp (argv[1], "neighbourangles") == 0) { stlgeometry->NeighbourAnglesOfSelectedTrig(); } else if (strcmp (argv[1], "vicinity") == 0) { stlgeometry->CalcVicinity(stldoctor.selecttrig); } else if (strcmp (argv[1], "markdirtytrigs") == 0) { stlgeometry->MarkDirtyTrigs(); } else if (strcmp (argv[1], "smoothdirtytrigs") == 0) { stlgeometry->SmoothDirtyTrigs(); } else if (strcmp (argv[1], "smoothrevertedtrigs") == 0) { stlgeometry->GeomSmoothRevertedTrigs(); } else if (strcmp (argv[1], "invertselectedtrig") == 0) { stlgeometry->InvertTrig(stlgeometry->GetSelectTrig()); } else if (strcmp (argv[1], "deleteselectedtrig") == 0) { stlgeometry->DeleteTrig(stlgeometry->GetSelectTrig()); } else if (strcmp (argv[1], "smoothgeometry") == 0) { stlgeometry->SmoothGeometry(); } else if (strcmp (argv[1], "orientafterselectedtrig") == 0) { stlgeometry->OrientAfterTrig(stlgeometry->GetSelectTrig()); } else if (strcmp (argv[1], "marktoperrortrigs") == 0) { stlgeometry->MarkTopErrorTrigs(); } else if (strcmp (argv[1], "exportedges") == 0) { stlgeometry->ExportEdges(); } else if (strcmp (argv[1], "importedges") == 0) { stlgeometry->ImportEdges(); } else if (strcmp (argv[1], "importexternaledges") == 0) { stlgeometry->ImportExternalEdges(argv[2]); } else if (strcmp (argv[1], "loadedgedata") == 0) { if (argc >= 3) { stlgeometry->LoadEdgeData(argv[2]); } } else if (strcmp (argv[1], "saveedgedata") == 0) { if (argc >= 3) { stlgeometry->SaveEdgeData(argv[2]); } } else if (strcmp (argv[1], "buildexternaledges") == 0) { stlgeometry->BuildExternalEdgesFromEdges(); } else if (strcmp (argv[1], "smoothnormals") == 0) { stlgeometry->SmoothNormals(); } else if (strcmp (argv[1], "marknonsmoothnormals") == 0) { stlgeometry->MarkNonSmoothNormals(); } else if (strcmp (argv[1], "addexternaledge") == 0) { stlgeometry->AddExternalEdgeAtSelected(); } else if (strcmp (argv[1], "addgeomline") == 0) { stlgeometry->AddExternalEdgesFromGeomLine(); } else if (strcmp (argv[1], "addlonglines") == 0) { stlgeometry->AddLongLinesToExternalEdges(); } else if (strcmp (argv[1], "addclosedlines") == 0) { stlgeometry->AddClosedLinesToExternalEdges(); } else if (strcmp (argv[1], "addnotsinglelines") == 0) { stlgeometry->AddAllNotSingleLinesToExternalEdges(); } else if (strcmp (argv[1], "deletedirtyexternaledges") == 0) { stlgeometry->DeleteDirtyExternalEdges(); } else if (strcmp (argv[1], "deleteexternaledge") == 0) { stlgeometry->DeleteExternalEdgeAtSelected(); } else if (strcmp (argv[1], "deletevicexternaledge") == 0) { stlgeometry->DeleteExternalEdgeInVicinity(); } else if (strcmp (argv[1], "addlonglines") == 0) { stlgeometry->STLDoctorLongLinesToCandidates(); } else if (strcmp (argv[1], "deletedirtyedges") == 0) { stlgeometry->STLDoctorDirtyEdgesToCandidates(); } else if (strcmp (argv[1], "undoedgechange") == 0) { stlgeometry->UndoEdgeChange(); } else if (strcmp (argv[1], "buildedges") == 0) { stlgeometry->STLDoctorBuildEdges(); } else if (strcmp (argv[1], "confirmedge") == 0) { stlgeometry->STLDoctorConfirmEdge(); } else if (strcmp (argv[1], "candidateedge") == 0) { stlgeometry->STLDoctorCandidateEdge(); } else if (strcmp (argv[1], "excludeedge") == 0) { stlgeometry->STLDoctorExcludeEdge(); } else if (strcmp (argv[1], "undefinededge") == 0) { stlgeometry->STLDoctorUndefinedEdge(); } else if (strcmp (argv[1], "setallundefinededges") == 0) { stlgeometry->STLDoctorSetAllUndefinedEdges(); } else if (strcmp (argv[1], "erasecandidateedges") == 0) { stlgeometry->STLDoctorEraseCandidateEdges(); } else if (strcmp (argv[1], "confirmcandidateedges") == 0) { stlgeometry->STLDoctorConfirmCandidateEdges(); } else if (strcmp (argv[1], "confirmedtocandidateedges") == 0) { stlgeometry->STLDoctorConfirmedToCandidateEdges(); } } return TCL_OK; } extern int Ng_MeshDoctor (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]); int Ng_STLInfo (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { double data[10]; static char buf[20]; if (!stlgeometry) { Tcl_SetResult (interp, err_needsstlgeometry, TCL_STATIC); return TCL_ERROR; } if (stlgeometry) { stlgeometry->STLInfo(data); // cout << "NT=" << data[0] << endl; if (argc == 2) { if (strcmp (argv[1], "status") == 0) { switch (stlgeometry->GetStatus()) { case STLGeometry::STL_GOOD: strcpy (buf, "GOOD"); break; case STLGeometry::STL_WARNING: strcpy (buf, "WARNING"); break; case STLGeometry::STL_ERROR: strcpy (buf, "ERROR"); break; } Tcl_SetResult (interp, buf, TCL_STATIC); return TCL_OK; } if (strcmp (argv[1], "statustext") == 0) { Tcl_SetResult (interp, (char*)stlgeometry->GetStatusText().c_str(), TCL_STATIC); return TCL_OK; } if (strcmp (argv[1], "topology_ok") == 0) { sprintf (buf, "%d", stlgeometry->Topology_Ok()); Tcl_SetResult (interp, buf, TCL_STATIC); } if (strcmp (argv[1], "orientation_ok") == 0) { sprintf (buf, "%d", stlgeometry->Orientation_Ok()); Tcl_SetResult (interp, buf, TCL_STATIC); } } } else { data[0] = 0; data[1] = 0; data[2] = 0; data[3] = 0; data[4] = 0; data[5] = 0; data[6] = 0; data[7] = 0; } sprintf (buf, "%i", (int)data[0]); Tcl_SetVar (interp, argv[1], buf, 0); sprintf (buf, "%5.3g", data[1]); Tcl_SetVar (interp, argv[2], buf, 0); sprintf (buf, "%5.3g", data[2]); Tcl_SetVar (interp, argv[3], buf, 0); sprintf (buf, "%5.3g", data[3]); Tcl_SetVar (interp, argv[4], buf, 0); sprintf (buf, "%5.3g", data[4]); Tcl_SetVar (interp, argv[5], buf, 0); sprintf (buf, "%5.3g", data[5]); Tcl_SetVar (interp, argv[6], buf, 0); sprintf (buf, "%5.3g", data[6]); Tcl_SetVar (interp, argv[7], buf, 0); sprintf (buf, "%i", (int)data[7]); Tcl_SetVar (interp, argv[8], buf, 0); return TCL_OK; } int Ng_STLCalcLocalH (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { Ng_SetSTLParameters (clientData, interp, argc, argv); #ifdef OCCGEOMETRY Ng_SetOCCParameters (clientData, interp, argc, argv); #endif // OCCGEOMETRY Ng_SetMeshingParameters (clientData, interp, argc, argv); if (mesh.Ptr() && stlgeometry) { mesh -> SetLocalH (stlgeometry->GetBoundingBox().PMin() - Vec3d(10, 10, 10), stlgeometry->GetBoundingBox().PMax() + Vec3d(10, 10, 10), mparam.grading); stlgeometry -> RestrictLocalH(*mesh, mparam.maxh); if (stlparam.resthsurfmeshcurvenable) mesh -> CalcLocalHFromSurfaceCurvature (stlparam.resthsurfmeshcurvfac); } return TCL_OK; } SYMBOLTABLE & GetVisualizationScenes () { static SYMBOLTABLE vss; return vss; } void AddVisualizationScene (const string & name, VisualScene * avs) { GetVisualizationScenes().Set (name.c_str(), avs); } void SetVisualScene (Tcl_Interp * interp) { const char * vismode = vispar.selectvisual; // Tcl_GetVar (interp, "selectvisual", 0); vs = &vscross; if (GetVisualizationScenes().Used(vismode)) { vs = GetVisualizationScenes().Get(vismode); } else if (vismode) { if (strcmp (vismode, "geometry") == 0) { if (stlgeometry != NULL) vs = &vsstlmeshing; else if (geometry2d) vs = &vsgeom2d; #ifdef OCCGEOMETRY else if (occgeometry) vs = &vsoccgeom; #endif // OCCGEOMETRY #ifdef ACIS else if (acisgeometry) vs = &vsacisgeom; #endif // ACIS else vs = &vsgeom; // vs = &vsstlgeom; } if (strcmp (vismode, "mesh") == 0) { if (!meshdoctor.active) vs = &vsmesh; else vs = &vsmeshdoc; } // if (strcmp (vismode, "surfmeshing") == 0) vs = &vssurfacemeshing; if (strcmp (vismode, "specpoints") == 0) vs = &vsspecpoints; // if (strcmp (vismode, "solution") == 0) vs = &vssolution; } } #if TOGL_MAJOR_VERSION==1 // Togl static int fontbase = 0; void MyOpenGLText (const char * text) { glListBase (fontbase); glCallLists (GLsizei(strlen(text)), GL_UNSIGNED_BYTE, text); } static void init( struct Togl *togl ) { fontbase = Togl_LoadBitmapFont( togl, TOGL_BITMAP_8_BY_13 ); glMatrixMode(GL_PROJECTION); glLoadIdentity(); glMatrixMode(GL_MODELVIEW); SetVisualScene (Togl_Interp(togl)); vs->DrawScene(); } static void zap( struct Togl *togl ) { ; } static void draw( struct Togl *togl ) { Tcl_Interp * interp = Togl_Interp(togl); SetVisualScene (interp); #ifdef STEREO if (1) // vispar.stereo) { glMatrixMode (GL_MODELVIEW); glPushMatrix(); glLoadIdentity (); // glTranslatef (0.1, 0, 0); gluLookAt (0.3, 0, 6, 0, 0, 0, 0, 1, 0); Togl_StereoDrawBuffer(GL_BACK_RIGHT); vs->DrawScene(); glLoadIdentity (); // glTranslatef (-0.1, 0, 0); gluLookAt (-0.3, 0, 6, 0, 0, 0, 0, 1, 0); Togl_StereoDrawBuffer(GL_BACK_LEFT); vs->DrawScene(); glPopMatrix(); Togl_SwapBuffers(togl); } else #endif { glPushMatrix(); glLoadIdentity(); // gluLookAt (0, 0, 6, 0, 0, 0, 0, 1, 0); vs->DrawScene(); Togl_SwapBuffers(togl); glPopMatrix(); } } static void reshape( struct Togl *togl) { int w = Togl_Width (togl); int h = Togl_Height (togl); glViewport(0, 0, w, h); glMatrixMode(GL_PROJECTION); glLoadIdentity(); gluPerspective(20.0f, double(w) / h, pnear, pfar); glMatrixMode(GL_MODELVIEW); draw (togl); } #else // Sorry, Togl 2.0 not supported Tcl_Obj * togl_font; void MyOpenGLText (const char * text) { cout << "togl - text" << endl; } static int init(ClientData clientData, Tcl_Interp *interp, int objc, Tcl_Obj *const *objv) { cout << "call init" << endl; Togl * togl = NULL; if (Togl_GetToglFromObj(interp, objv[1], &togl) != TCL_OK) return TCL_ERROR; cout << "call Togl - load font (crash on my Linux64)" << endl; // togl_font = Togl_LoadBitmapFont( togl, "Times"); // TOGL_BITMAP_8_BY_13 ); // togl_font = Togl_LoadBitmapFont( togl, TOGL_BITMAP_8_BY_13 ); // togl_font = Togl_LoadBitmapFont( togl, NULL ); // cout << "success" << endl; glMatrixMode(GL_PROJECTION); glLoadIdentity(); glMatrixMode(GL_MODELVIEW); SetVisualScene (Togl_Interp(togl)); vs->DrawScene(); return TCL_OK; } static int zap(ClientData clientData, Tcl_Interp *interp, int objc, Tcl_Obj *const *objv) { return TCL_OK; } static int draw(ClientData clientData, Tcl_Interp *interp, int objc, Tcl_Obj *const *objv) { Togl * togl; if (Togl_GetToglFromObj(interp, objv[1], &togl) != TCL_OK) return TCL_ERROR; SetVisualScene (interp); glPushMatrix(); glLoadIdentity(); // gluLookAt (0, 0, 6, 0, 0, 0, 0, 1, 0); vs->DrawScene(); Togl_SwapBuffers(togl); glPopMatrix(); return TCL_OK; } static int reshape(ClientData clientData, Tcl_Interp *interp, int objc, Tcl_Obj *const *objv) { Togl * togl; if (Togl_GetToglFromObj(interp, objv[1], &togl) != TCL_OK) return TCL_ERROR; int w = Togl_Width (togl); int h = Togl_Height (togl); glViewport(0, 0, w, h); glMatrixMode(GL_PROJECTION); glLoadIdentity(); gluPerspective(20.0f, double(w) / h, pnear, pfar); glMatrixMode(GL_MODELVIEW); // draw (togl); return TCL_OK; } #endif #if TOGL_MAJOR_VERSION==1 #ifndef JPEGLIB static int Ng_SnapShot (struct Togl * togl, int argc, tcl_const char *argv[]) { const char * filename = argv[2]; char str[250]; char filename2[250]; int len = strlen(filename); strcpy (filename2, filename); filename2[len-3] = 'p'; filename2[len-2] = 'p'; filename2[len-1] = 'm'; filename2[len] = 0; cout << "Snapshot to file '" << filename << endl; int w = Togl_Width (togl); w = int((w + 1) / 4) * 4 + 4; int h = Togl_Height (togl); // unsigned char * buffer = new unsigned char[w*h*4]; unsigned char * buffer = new unsigned char[w*h*3]; glReadPixels (0, 0, w, h, GL_RGB, GL_UNSIGNED_BYTE, buffer); ofstream outfile(filename2); outfile << "P6" << endl << "# CREATOR: Netgen" << endl << w << " " << h << endl << "255" << endl; for (int i = 0; i < h; i++) for (int j = 0; j < w; j++) for (int k = 0; k < 3; k++) outfile.put (buffer[k+3*j+3*w*(h-i-1)]); outfile << flush; delete[] buffer; // convert image file (Unix/Linux only): sprintf(str,"convert -quality 100 %s %s", filename2, filename); int err = system(str); if (err != 0) { Tcl_SetResult (Togl_Interp(togl), (char*)"Cannot convert image file", TCL_VOLATILE); return TCL_ERROR; } sprintf(str,"rm %s", filename2); system(str); return TCL_OK; } #else static int Ng_SnapShot (struct Togl * togl, int argc, tcl_const char *argv[]) { const char * filename = argv[2]; int len = strlen(filename); if (strcmp ("jpg", filename+len-3) == 0) { cout << "Snapshot to file '" << filename << "'" << endl; int w = Togl_Width (togl); w = int((w + 1) / 4) * 4 + 4; int h = Togl_Height (togl); // unsigned char * buffer = new unsigned char[w*h*4]; unsigned char * buffer = new unsigned char[w*h*3]; glReadPixels (0, 0, w, h, GL_RGB, GL_UNSIGNED_BYTE, buffer); struct jpeg_compress_struct cinfo; struct jpeg_error_mgr jerr; FILE *outfile = fopen(filename,"wb"); JSAMPROW row_pointer[1]; int row_stride, quality = 85; // 1...100 cinfo.err = jpeg_std_error( &jerr ); jpeg_create_compress( &cinfo ); jpeg_stdio_dest( &cinfo, outfile ); cinfo.image_width = w; cinfo.image_height = h; cinfo.input_components = 3; cinfo.in_color_space = JCS_RGB; jpeg_set_defaults( &cinfo ); jpeg_set_quality( &cinfo, quality, TRUE ); jpeg_start_compress( &cinfo, TRUE ); row_stride = 3*w; while( cinfo.next_scanline < cinfo.image_height ) { row_pointer[0] = &buffer[ (h-1-cinfo.next_scanline) * row_stride ]; (void)jpeg_write_scanlines( &cinfo, row_pointer, 1 ); } jpeg_finish_compress( &cinfo ); fclose( outfile ); jpeg_destroy_compress( &cinfo ); fprintf( stdout, "done [ok]\n" ); fflush( stdout ); free( buffer ); return TCL_OK; } else { cout << "Snapshot to " << filename << " not supported" << endl; return TCL_ERROR; } } #endif #ifdef FFMPEG // thanks to Mikko Lyly @ CSC, Helsinki #define STATE_READY 0 #define STATE_STARTED 1 #define INBUF_SIZE 4096 #define DEFAULT_B_FRAMES 3 // #define DEFAULT_B_FRAMES 0 #define DEFAULT_GOP_SIZE 200 // #define DEFAULT_GOP_SIZE 10 // #define DEFAULT_BITRATE 500000 #define DEFAULT_BITRATE 5000000 // #define DEFAULT_MPG_BUFSIZE 500000 #define DEFAULT_MPG_BUFSIZE 500000 typedef struct buffer_s { uint8_t *MPG; uint8_t *YUV; uint8_t *RGB; uint8_t *ROW; } buffer_t; void free_buffers( buffer_t *buff ) { free( buff->MPG ); free( buff->YUV ); free( buff->RGB ); free( buff->ROW ); } static double psnr( double d ) { if( d==0 ) return INFINITY; return -10.0*log( d )/log( 10.0 ); } void print_info( int count_frames, AVCodecContext *context, int bytes ) { double tmp = context->width * context->height * 255.0 * 255.0; double Ypsnr = psnr( context->coded_frame->error[0] / tmp ); double quality = context->coded_frame->quality/(double)FF_QP2LAMBDA; char pict_type = av_get_pict_type_char(context->coded_frame->pict_type); cout << "video: frame=" << count_frames << " type=" << pict_type; cout << " size=" << bytes << " PSNR(Y)=" << Ypsnr << " dB q=" << (float)quality << endl; } static int Ng_VideoClip (struct Togl * togl, int argc, tcl_const char *argv[]) { static AVCodec *codec = NULL; static AVCodecContext *context = NULL; static AVFrame *YUVpicture = NULL; static AVFrame *RGBpicture = NULL; static int bytes, PIXsize, stride; static int y, nx, ny, ox, oy, viewp[4]; static int i_state = STATE_READY; static int initialized = 0; static int count_frames = 0; static int bitrate = DEFAULT_BITRATE; static int gopsize = DEFAULT_GOP_SIZE; static int bframes = DEFAULT_B_FRAMES; static int MPGbufsize = DEFAULT_MPG_BUFSIZE; static CodecID codec_id = CODEC_ID_MPEG1VIDEO; static FILE *MPGfile; static buffer_t buff; static struct SwsContext *img_convert_ctx; if (strcmp (argv[2], "init") == 0) { // Can't initialize when running: //------------------------------- if( i_state != STATE_READY ) { cout << "cannot initialize: already running" << endl; return TCL_ERROR; } // Open output file: //------------------- const char * filename = argv[3]; cout << "Saving videoclip to file '" << filename << "'" << endl; MPGfile = fopen(filename, "wb"); // Determine picture size: //------------------------ nx = Togl_Width (togl); nx = int((nx + 1) / 4) * 4 + 4; ny = Togl_Height (togl); ny = 2 * (ny/2); cout << "Width=" << nx << ", height=" << ny << endl; // Allocate buffers: //------------------ PIXsize = nx*ny; stride = 3*nx; buff.RGB = (uint8_t*)malloc(stride*ny); buff.ROW = (uint8_t*)malloc(stride); buff.YUV = (uint8_t*)malloc(3*(PIXsize/2)); buff.MPG = (uint8_t*)malloc(MPGbufsize); // Initialize libavcodec: //----------------------- if( !initialized ) { av_register_all(); initialized = 1; } // Choose codec: //-------------- codec = avcodec_find_encoder( codec_id ); if( !codec ) { free_buffers( &buff ); fclose( MPGfile ); cout << "can't find codec" << endl; return TCL_ERROR; } // Init codec context etc.: //-------------------------- context = avcodec_alloc_context(); context->bit_rate = bitrate; context->width = nx; context->height = ny; context->time_base = (AVRational){ 1, 25 }; context->gop_size = gopsize; context->max_b_frames = bframes; context->pix_fmt = PIX_FMT_YUV420P; context->flags |= CODEC_FLAG_PSNR; if( avcodec_open( context, codec ) < 0 ) { cout << "can't open codec" << endl; avcodec_close( context ); av_free( context ); free_buffers( &buff ); fclose( MPGfile ); return TCL_ERROR; } YUVpicture = avcodec_alloc_frame(); YUVpicture->data[0] = buff.YUV; YUVpicture->data[1] = buff.YUV + PIXsize; YUVpicture->data[2] = buff.YUV + PIXsize + PIXsize / 4; YUVpicture->linesize[0] = nx; YUVpicture->linesize[1] = nx / 2; YUVpicture->linesize[2] = nx / 2; RGBpicture = avcodec_alloc_frame(); RGBpicture->data[0] = buff.RGB; RGBpicture->data[1] = buff.RGB; RGBpicture->data[2] = buff.RGB; RGBpicture->linesize[0] = stride; RGBpicture->linesize[1] = stride; RGBpicture->linesize[2] = stride; // Set state "started": //---------------------- i_state = STATE_STARTED; cout << "savempg: state: started" << endl; return TCL_OK; } else if (strcmp (argv[2], "addframe") == 0) { // Can't compress if status != started: //------------------------------------- if( i_state != STATE_STARTED ) { cout << "cannot add frame: codec not initialized" << endl; return TCL_ERROR; } // Read RGB data: //--------------- glReadPixels (0, 0, nx, ny, GL_RGB, GL_UNSIGNED_BYTE, buff.RGB ); // The picture is upside down - flip it: //--------------------------------------- for( y=0; ydata, RGBpicture->linesize, 0, ny, YUVpicture->data, YUVpicture->linesize ); // Encode frame: //-------------- bytes = avcodec_encode_video( context, buff.MPG, MPGbufsize, YUVpicture ); count_frames++; print_info( count_frames, context, bytes ); fwrite( buff.MPG, 1, bytes, MPGfile ); return TCL_OK; } else if (strcmp (argv[2], "finalize") == 0) { // Can't stop if status != started: //--------------------------------- if( i_state != STATE_STARTED ) { cout << "cannot finalize: codec not initialized" << endl; return TCL_ERROR; } // Get the delayed frames, if any: //-------------------------------- for( ; bytes; ) { bytes = avcodec_encode_video( context, buff.MPG, MPGbufsize, NULL ); count_frames++; print_info( count_frames, context, bytes ); fwrite( buff.MPG, 1, bytes, MPGfile ); } // Add sequence end code: //----------------------- if( codec_id == CODEC_ID_MPEG1VIDEO ) { buff.MPG[0] = 0x00; buff.MPG[1] = 0x00; buff.MPG[2] = 0x01; buff.MPG[3] = 0xb7; fwrite( buff.MPG, 1, 4, MPGfile ); } // Finalize: //----------- avcodec_close( context ); av_free( context ); av_free( YUVpicture ); av_free( RGBpicture ); free_buffers( &buff ); fclose( MPGfile ); i_state = STATE_READY; cout << "finalized" << endl; return TCL_OK; } } #else static int Ng_VideoClip (struct Togl * togl, int argc, tcl_const char *argv[]) { return TCL_OK; } #endif #endif int Ng_MouseMove (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { int oldx, oldy; int newx, newy; oldx = atoi (argv[1]); oldy = atoi (argv[2]); newx = atoi (argv[3]); newy = atoi (argv[4]); SetVisualScene(interp); vs->MouseMove (oldx, oldy, newx, newy, argv[5][0]); return TCL_OK; } int Ng_MouseDblClick (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { int px, py; px = atoi (argv[1]); py = atoi (argv[2]); SetVisualScene(interp); vs->MouseDblClick (px, py); return TCL_OK; } int Ng_ZoomAll (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { SetVisualScene(interp); vs->BuildScene (1); return TCL_OK; } int Ng_Center (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { SetVisualScene(interp); vs->BuildScene (2); return TCL_OK; } int Ng_StandardRotation (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { SetVisualScene(interp); vs->StandardRotation (argv[1]); return TCL_OK; } int Ng_ArbitraryRotation (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { SetVisualScene(interp); Array alpha; Array vec; for(int i=1; iArbitraryRotation (alpha,vec); return TCL_OK; } int Ng_Metis (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { #ifdef METISold if (!mesh) { Tcl_SetResult (interp, err_needsmesh, TCL_STATIC); return TCL_ERROR; } // METIS Partitioning if (mesh->GetDimension() == 3) { using namespace metis; int ne = mesh->GetNE(); if (ne < 3) { Tcl_SetResult (interp, "This operation needs a volume mesh", TCL_STATIC); return TCL_ERROR; } int nn = mesh->GetNP(); ELEMENT_TYPE elementtype = mesh->VolumeElement(1).GetType(); int npe = mesh->VolumeElement(1).GetNP(); for (int i = 2; i<=ne; i++) if (mesh->VolumeElement(i).GetType() != elementtype) { Tcl_SetResult (interp, "Works in 3D only uniformal tet or hex meshes", TCL_STATIC); return TCL_ERROR; } idxtype *elmnts; elmnts = new idxtype[ne*npe]; int etype; if (elementtype == TET) etype = 2; else if (elementtype == HEX) etype = 3; else { Tcl_SetResult (interp, "Works in 3D only uniformal tet or hex meshes", TCL_STATIC); return TCL_ERROR; } for (int i=1; i<=ne; i++) for (int j=1; j<=npe; j++) elmnts[(i-1)*npe+(j-1)] = mesh->VolumeElement(i).PNum(j)-1; int numflag = 0; int nparts = atoi (argv[1]); int edgecut; idxtype *epart, *npart; epart = new idxtype[ne]; npart = new idxtype[nn]; cout << "Starting Metis (" << ne << " Elements, " << nn << " Nodes, " << nparts << " Partitions) ... " << flush; METIS_PartMeshNodal (&ne, &nn, elmnts, &etype, &numflag, &nparts, &edgecut, epart, npart); cout << "done" << endl; cout << "edge-cut: " << edgecut << ", balance: " << ComputeElementBalance(ne, nparts, epart) << endl; for (int i=1; i<=ne; i++) mesh->VolumeElement(i).SetPartition(epart[i-1]); mesh->SetNextTimeStamp(); } #endif return TCL_OK; } int Ng_SetOCCVisParameters (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { #ifdef OCCGEOMETRY int showvolume; showvolume = atoi (Tcl_GetVar (interp, "::occoptions.showvolumenr", 0)); if (showvolume != vispar.occshowvolumenr) { if (showvolume < 0 || showvolume > occgeometry->NrSolids()) { char buf[20]; sprintf (buf, "%5i", vispar.occshowvolumenr); Tcl_SetVar (interp, "::occoptions.showvolumenr", buf, 0); } else { vispar.occshowvolumenr = showvolume; if (occgeometry) occgeometry -> changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } } int temp; temp = atoi (Tcl_GetVar (interp, "::occoptions.visproblemfaces", 0)); if ((bool) temp != vispar.occvisproblemfaces) { vispar.occvisproblemfaces = temp; if (occgeometry) occgeometry -> changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } vispar.occshowsurfaces = atoi (Tcl_GetVar (interp, "::occoptions.showsurfaces", 0)); vispar.occshowedges = atoi (Tcl_GetVar (interp, "::occoptions.showedges", 0)); vispar.occzoomtohighlightedentity = atoi (Tcl_GetVar (interp, "::occoptions.zoomtohighlightedentity", 0)); vispar.occdeflection = pow(10.0,-1-atof (Tcl_GetVar (interp, "::occoptions.deflection", 0))); #endif #ifdef ACIS vispar.ACISshowfaces = atoi (Tcl_GetVar (interp, "::occoptions.showsurfaces", 0)); vispar.ACISshowedges = atoi (Tcl_GetVar (interp, "::occoptions.showedges", 0)); vispar.ACISshowsolidnr = atoi (Tcl_GetVar (interp, "::occoptions.showsolidnr", 0)); vispar.ACISshowsolidnr2 = atoi (Tcl_GetVar (interp, "::occoptions.showsolidnr2", 0)); #endif return TCL_OK; } void SelectFaceInOCCDialogTree (int facenr) { char script[50]; sprintf (script, "selectentity {Face %i}", facenr); Tcl_GlobalEval (tcl_interp, script); } int Ng_GetOCCData (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { #ifdef OCCGEOMETRY static char buf[1000]; buf[0] = 0; stringstream str; if (argc >= 2) { if (strcmp (argv[1], "getentities") == 0) { if (occgeometry) { occgeometry->GetTopologyTree(str); } } } Tcl_SetResult (interp, (char*)str.str().c_str(), TCL_VOLATILE); #endif return TCL_OK; } int Ng_OCCCommand (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { #ifdef OCCGEOMETRY stringstream str; if (argc >= 2) { if (strcmp (argv[1], "isoccgeometryloaded") == 0) { if (occgeometry) str << "1 " << flush; else str << "0 " << flush; Tcl_SetResult (interp, (char*)str.str().c_str(), TCL_VOLATILE); } if (occgeometry) { if (strcmp (argv[1], "buildvisualizationmesh") == 0) { occgeometry->BuildVisualizationMesh(vispar.occdeflection); occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } if (strcmp (argv[1], "mesherror") == 0) { if (occgeometry->ErrorInSurfaceMeshing()) str << 1; else str << 0; } if (strcmp (argv[1], "sewfaces") == 0) { cout << "Before operation:" << endl; occgeometry->PrintNrShapes(); occgeometry->SewFaces(); occgeometry->BuildFMap(); cout << endl << "After operation:" << endl; occgeometry->PrintNrShapes(); occgeometry->BuildVisualizationMesh(vispar.occdeflection); occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } if (strcmp (argv[1], "makesolid") == 0) { cout << "Before operation:" << endl; occgeometry->PrintNrShapes(); occgeometry->MakeSolid(); occgeometry->BuildFMap(); cout << endl << "After operation:" << endl; occgeometry->PrintNrShapes(); occgeometry->BuildVisualizationMesh(vispar.occdeflection); occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } if (strcmp (argv[1], "upgradetopology") == 0) { cout << "Before operation:" << endl; occgeometry->PrintNrShapes(); occgeometry->SewFaces(); occgeometry->MakeSolid(); occgeometry->BuildFMap(); cout << endl << "After operation:" << endl; occgeometry->PrintNrShapes(); occgeometry->BuildVisualizationMesh(vispar.occdeflection); occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } if (strcmp (argv[1], "shapehealing") == 0) { occgeometry->tolerance = atof (Tcl_GetVar (interp, "::occoptions.tolerance", 0)); occgeometry->fixsmalledges = atoi (Tcl_GetVar (interp, "::occoptions.fixsmalledges", 0)); occgeometry->fixspotstripfaces = atoi (Tcl_GetVar (interp, "::occoptions.fixspotstripfaces", 0)); occgeometry->sewfaces = atoi (Tcl_GetVar (interp, "::occoptions.sewfaces", 0)); occgeometry->makesolids = atoi (Tcl_GetVar (interp, "::occoptions.makesolids", 0)); occgeometry->splitpartitions = atoi (Tcl_GetVar (interp, "::occoptions.splitpartitions", 0)); // cout << "Before operation:" << endl; // occgeometry->PrintNrShapes(); occgeometry->HealGeometry(); occgeometry->BuildFMap(); // cout << endl << "After operation:" << endl; // occgeometry->PrintNrShapes(); occgeometry->BuildVisualizationMesh(vispar.occdeflection); occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } if (strcmp (argv[1], "highlightentity") == 0) { if (strcmp (argv[2], "Face") == 0) { int nr = atoi (argv[3]); occgeometry->LowLightAll(); occgeometry->fvispar[nr-1].Highlight(); if (vispar.occzoomtohighlightedentity) occgeometry->changed = OCCGEOMETRYVISUALIZATIONFULLCHANGE; else occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } if (strcmp (argv[2], "Shell") == 0) { int nr = atoi (argv[3]); occgeometry->LowLightAll(); TopExp_Explorer exp; for (exp.Init (occgeometry->shmap(nr), TopAbs_FACE); exp.More(); exp.Next()) { int i = occgeometry->fmap.FindIndex (TopoDS::Face(exp.Current())); occgeometry->fvispar[i-1].Highlight(); } if (vispar.occzoomtohighlightedentity) occgeometry->changed = OCCGEOMETRYVISUALIZATIONFULLCHANGE; else occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } if (strcmp (argv[2], "Solid") == 0) { int nr = atoi (argv[3]); occgeometry->LowLightAll(); TopExp_Explorer exp; for (exp.Init (occgeometry->somap(nr), TopAbs_FACE); exp.More(); exp.Next()) { int i = occgeometry->fmap.FindIndex (TopoDS::Face(exp.Current())); occgeometry->fvispar[i-1].Highlight(); } if (vispar.occzoomtohighlightedentity) occgeometry->changed = OCCGEOMETRYVISUALIZATIONFULLCHANGE; else occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } /* if (strcmp (argv[2], "CompSolid") == 0) { int nr = atoi (argv[3]); occgeometry->LowLightAll(); TopExp_Explorer exp; for (exp.Init (occgeometry->cmap(nr), TopAbs_FACE); exp.More(); exp.Next()) { int i = occgeometry->fmap.FindIndex (TopoDS::Face(exp.Current())); occgeometry->fvispar[i-1].Highlight(); } occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } */ if (strcmp (argv[2], "Edge") == 0) { int nr = atoi (argv[3]); occgeometry->LowLightAll(); occgeometry->evispar[nr-1].Highlight(); if (vispar.occzoomtohighlightedentity) occgeometry->changed = OCCGEOMETRYVISUALIZATIONFULLCHANGE; else occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } if (strcmp (argv[2], "Wire") == 0) { int nr = atoi (argv[3]); occgeometry->LowLightAll(); TopExp_Explorer exp; for (exp.Init (occgeometry->wmap(nr), TopAbs_EDGE); exp.More(); exp.Next()) { int i = occgeometry->emap.FindIndex (TopoDS::Edge(exp.Current())); occgeometry->evispar[i-1].Highlight(); } if (vispar.occzoomtohighlightedentity) occgeometry->changed = OCCGEOMETRYVISUALIZATIONFULLCHANGE; else occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } if (strcmp (argv[2], "Vertex") == 0) { int nr = atoi (argv[3]); occgeometry->LowLightAll(); occgeometry->vvispar[nr-1].Highlight(); if (vispar.occzoomtohighlightedentity) occgeometry->changed = OCCGEOMETRYVISUALIZATIONFULLCHANGE; else occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; } } if (strcmp (argv[1], "show") == 0) { int nr = atoi (argv[3]); occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; if (strcmp (argv[2], "Face") == 0) { occgeometry->fvispar[nr-1].Show(); } if (strcmp (argv[2], "Shell") == 0) { TopExp_Explorer exp; for (exp.Init (occgeometry->shmap(nr), TopAbs_FACE); exp.More(); exp.Next()) { int i = occgeometry->fmap.FindIndex (TopoDS::Face(exp.Current())); occgeometry->fvispar[i-1].Show(); } } if (strcmp (argv[2], "Solid") == 0) { TopExp_Explorer exp; for (exp.Init (occgeometry->somap(nr), TopAbs_FACE); exp.More(); exp.Next()) { int i = occgeometry->fmap.FindIndex (TopoDS::Face(exp.Current())); occgeometry->fvispar[i-1].Show(); } } if (strcmp (argv[2], "Edge") == 0) { occgeometry->evispar[nr-1].Show(); } if (strcmp (argv[2], "Wire") == 0) { TopExp_Explorer exp; for (exp.Init (occgeometry->wmap(nr), TopAbs_EDGE); exp.More(); exp.Next()) { int i = occgeometry->emap.FindIndex (TopoDS::Edge(exp.Current())); occgeometry->evispar[i-1].Show(); } } } if (strcmp (argv[1], "hide") == 0) { int nr = atoi (argv[3]); occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; if (strcmp (argv[2], "Face") == 0) { occgeometry->fvispar[nr-1].Hide(); } if (strcmp (argv[2], "Shell") == 0) { TopExp_Explorer exp; for (exp.Init (occgeometry->shmap(nr), TopAbs_FACE); exp.More(); exp.Next()) { int i = occgeometry->fmap.FindIndex (TopoDS::Face(exp.Current())); occgeometry->fvispar[i-1].Hide(); } } if (strcmp (argv[2], "Solid") == 0) { TopExp_Explorer exp; for (exp.Init (occgeometry->somap(nr), TopAbs_FACE); exp.More(); exp.Next()) { int i = occgeometry->fmap.FindIndex (TopoDS::Face(exp.Current())); occgeometry->fvispar[i-1].Hide(); } } if (strcmp (argv[2], "Edge") == 0) { occgeometry->evispar[nr-1].Hide(); } if (strcmp (argv[2], "Wire") == 0) { TopExp_Explorer exp; for (exp.Init (occgeometry->wmap(nr), TopAbs_EDGE); exp.More(); exp.Next()) { int i = occgeometry->emap.FindIndex (TopoDS::Edge(exp.Current())); occgeometry->evispar[i-1].Hide(); } } } if (strcmp (argv[1], "findsmallentities") == 0) { stringstream str(""); occgeometry->CheckIrregularEntities(str); Tcl_SetResult (interp, (char*)str.str().c_str(), TCL_VOLATILE); } if (strcmp (argv[1], "getunmeshedfaceinfo") == 0) { occgeometry->GetUnmeshedFaceInfo(str); Tcl_SetResult (interp, (char*)str.str().c_str(), TCL_VOLATILE); } if (strcmp (argv[1], "getnotdrawablefaces") == 0) { occgeometry->GetNotDrawableFaces(str); Tcl_SetResult (interp, (char*)str.str().c_str(), TCL_VOLATILE); } if (strcmp (argv[1], "redrawstatus") == 0) { int i = atoi (argv[2]); occgeometry->changed = i; } if (strcmp (argv[1], "swaporientation") == 0) { IGESControl_Writer writer("millimeters", 1); writer.AddShape (occgeometry->shape); writer.Write ("1.igs"); /* int nr = atoi (argv[3]); // const_cast (occgeometry->fmap(nr)).Reverse(); Handle_ShapeBuild_ReShape rebuild = new ShapeBuild_ReShape; rebuild->Apply(occgeometry->shape); TopoDS_Shape sh; // if (strcmp (argv[2], "CompSolid") == 0) sh = occgeometry->cmap(nr); if (strcmp (argv[2], "Solid") == 0) sh = occgeometry->somap(nr); if (strcmp (argv[2], "Shell") == 0) sh = occgeometry->shmap(nr); if (strcmp (argv[2], "Face") == 0) sh = occgeometry->fmap(nr); if (strcmp (argv[2], "Wire") == 0) sh = occgeometry->wmap(nr); if (strcmp (argv[2], "Edge") == 0) sh = occgeometry->emap(nr); rebuild->Replace(sh, sh.Reversed(), Standard_False); TopoDS_Shape newshape = rebuild->Apply(occgeometry->shape, TopAbs_SHELL, 1); occgeometry->shape = newshape; occgeometry->BuildFMap(); occgeometry->BuildVisualizationMesh(); occgeometry->changed = OCCGEOMETRYVISUALIZATIONHALFCHANGE; */ } if (strcmp (argv[1], "marksingular") == 0) { int nr = atoi (argv[3]); cout << "marking " << argv[2] << " " << nr << endl; char buf[2]; buf[0] = '0'; buf[1] = 0; bool sing = false; if (strcmp (argv[2], "Face") == 0) sing = occgeometry->fsingular[nr-1] = !occgeometry->fsingular[nr-1]; if (strcmp (argv[2], "Edge") == 0) sing = occgeometry->esingular[nr-1] = !occgeometry->esingular[nr-1]; if (strcmp (argv[2], "Vertex") == 0) sing = occgeometry->vsingular[nr-1] = !occgeometry->vsingular[nr-1]; if (sing) buf[0] = '1'; Tcl_SetVar (interp, "::ismarkedsingular", buf, 0); stringstream str; occgeometry->GetTopologyTree (str); char* cstr = (char*)str.str().c_str(); (*testout) << cstr << endl; char helpstr[1000]; while (strchr (cstr, '}')) { strncpy (helpstr, cstr+2, strlen(strchr(cstr+2, '}'))); (*testout) << "***" << cstr << "***" << endl; cstr = strchr (cstr, '}'); } } } } #endif return TCL_OK; } #ifdef OCCGEOMETRY void OCCConstructGeometry (OCCGeometry & geom); int Ng_OCCConstruction (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (occgeometry) OCCConstructGeometry (*occgeometry); return TCL_OK; } #endif #ifndef ACIS int Ng_ACISCommand (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (argc >= 2) { if (strcmp (argv[1], "isACISavailable") == 0) { Tcl_SetResult (interp, (char*)"no", TCL_STATIC); return TCL_OK; } } Tcl_SetResult (interp, (char*)"undefined ACiS command", TCL_STATIC); return TCL_ERROR; } #endif int Ng_SetVisParameters (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { if (!Tcl_GetVar (interp, "::viewoptions.light.amb", TCL_GLOBAL_ONLY)) return TCL_ERROR; vispar.lightamb = atof (Tcl_GetVar (interp, "::viewoptions.light.amb", TCL_GLOBAL_ONLY)); vispar.lightdiff = atof (Tcl_GetVar (interp, "::viewoptions.light.diff", TCL_GLOBAL_ONLY)); vispar.lightspec = atof (Tcl_GetVar (interp, "::viewoptions.light.spec", TCL_GLOBAL_ONLY)); vispar.shininess = atof (Tcl_GetVar (interp, "::viewoptions.mat.shininess", TCL_GLOBAL_ONLY)); vispar.locviewer = atoi (Tcl_GetVar (interp, "::viewoptions.light.locviewer", TCL_GLOBAL_ONLY)); vispar.transp = atof (Tcl_GetVar (interp, "::viewoptions.mat.transp", TCL_GLOBAL_ONLY)); vispar.clipnormal.X() = atof (Tcl_GetVar (interp, "::viewoptions.clipping.nx", TCL_GLOBAL_ONLY)); vispar.clipnormal.Y() = atof (Tcl_GetVar (interp, "::viewoptions.clipping.ny", TCL_GLOBAL_ONLY)); vispar.clipnormal.Z() = atof (Tcl_GetVar (interp, "::viewoptions.clipping.nz", TCL_GLOBAL_ONLY)); vispar.clipdist = atof (Tcl_GetVar (interp, "::viewoptions.clipping.dist", TCL_GLOBAL_ONLY)); vispar.clipenable = atoi (Tcl_GetVar (interp, "::viewoptions.clipping.enable", TCL_GLOBAL_ONLY)); vispar.clipdomain = atoi (Tcl_GetVar (interp, "::viewoptions.clipping.onlydomain", TCL_GLOBAL_ONLY)); vispar.donotclipdomain = atoi (Tcl_GetVar (interp, "::viewoptions.clipping.notdomain", TCL_GLOBAL_ONLY)); vispar.clipplanetimestamp = NextTimeStamp(); vispar.whitebackground = atoi (Tcl_GetVar (interp, "::viewoptions.whitebackground", TCL_GLOBAL_ONLY)); vispar.drawcoordinatecross = atoi (Tcl_GetVar (interp, "::viewoptions.drawcoordinatecross", TCL_GLOBAL_ONLY)); vispar.drawcolorbar = atoi (Tcl_GetVar (interp, "::viewoptions.drawcolorbar", TCL_GLOBAL_ONLY)); vispar.drawnetgenlogo = atoi (Tcl_GetVar (interp, "::viewoptions.drawnetgenlogo", TCL_GLOBAL_ONLY)); vispar.stereo = atoi (Tcl_GetVar (interp, "::viewoptions.stereo", TCL_GLOBAL_ONLY)); vispar.colormeshsize = atoi (Tcl_GetVar (interp, "::viewoptions.colormeshsize", TCL_GLOBAL_ONLY)); VisualScene :: SetBackGroundColor (vispar.whitebackground ? 1 : 0); strcpy (vispar.selectvisual, Tcl_GetVar (interp, "::selectvisual", TCL_GLOBAL_ONLY)); // vispar.showstltrias = atoi (Tcl_GetVar (interp, "::viewoptions.stl.showtrias", TCL_GLOBAL_ONLY)); vispar.stlshowtrias = atoi (Tcl_GetVar (interp, "::stloptions.showtrias", TCL_GLOBAL_ONLY)); vispar.stlshowfilledtrias = atoi (Tcl_GetVar (interp, "::stloptions.showfilledtrias", TCL_GLOBAL_ONLY)); vispar.stlshowedges = atoi (Tcl_GetVar (interp, "::stloptions.showedges", TCL_GLOBAL_ONLY)); vispar.stlshowmarktrias = atoi (Tcl_GetVar (interp, "::stloptions.showmarktrias", TCL_GLOBAL_ONLY)); vispar.stlshowactivechart = atoi (Tcl_GetVar (interp, "::stloptions.showactivechart", TCL_GLOBAL_ONLY)); vispar.stlchartnumber = atoi (Tcl_GetVar (interp, "::stloptions.chartnumber", TCL_GLOBAL_ONLY)); vispar.stlchartnumberoffset = atoi (Tcl_GetVar (interp, "::stloptions.chartnumberoffset", TCL_GLOBAL_ONLY)); vispar.occshowsurfaces = atoi (Tcl_GetVar (interp, "::occoptions.showsurfaces", TCL_GLOBAL_ONLY)); vispar.occshowedges = atoi (Tcl_GetVar (interp, "::occoptions.showedges", TCL_GLOBAL_ONLY)); vispar.drawoutline = atoi (Tcl_GetVar (interp, "::viewoptions.drawoutline", TCL_GLOBAL_ONLY)); vispar.drawfilledtrigs = atoi (Tcl_GetVar (interp, "::viewoptions.drawfilledtrigs", TCL_GLOBAL_ONLY)); vispar.subdivisions = atoi (Tcl_GetVar (interp, "::visoptions.subdivisions", TCL_GLOBAL_ONLY)); vispar.drawbadels = atoi (Tcl_GetVar (interp, "::viewoptions.drawbadels", TCL_GLOBAL_ONLY)); vispar.drawedges = atoi (Tcl_GetVar (interp, "::viewoptions.drawedges", TCL_GLOBAL_ONLY)); vispar.drawtetsdomain = atoi (Tcl_GetVar (interp, "::viewoptions.drawtetsdomain", TCL_GLOBAL_ONLY)); vispar.drawtets = atoi (Tcl_GetVar (interp, "::viewoptions.drawtets", TCL_GLOBAL_ONLY)); vispar.drawprisms = atoi (Tcl_GetVar (interp, "::viewoptions.drawprisms", TCL_GLOBAL_ONLY)); vispar.drawpyramids = atoi (Tcl_GetVar (interp, "::viewoptions.drawpyramids", TCL_GLOBAL_ONLY)); vispar.drawhexes = atoi (Tcl_GetVar (interp, "::viewoptions.drawhexes", TCL_GLOBAL_ONLY)); vispar.shrink = atof (Tcl_GetVar (interp, "::viewoptions.shrink", TCL_GLOBAL_ONLY)); vispar.drawidentified = atoi (Tcl_GetVar (interp, "::viewoptions.drawidentified", TCL_GLOBAL_ONLY)); vispar.drawpointnumbers = atoi (Tcl_GetVar (interp, "::viewoptions.drawpointnumbers", TCL_GLOBAL_ONLY)); vispar.drawedgenumbers = atoi (Tcl_GetVar (interp, "::viewoptions.drawedgenumbers", TCL_GLOBAL_ONLY)); vispar.drawfacenumbers = atoi (Tcl_GetVar (interp, "::viewoptions.drawfacenumbers", TCL_GLOBAL_ONLY)); vispar.drawelementnumbers = atoi (Tcl_GetVar (interp, "::viewoptions.drawelementnumbers", TCL_GLOBAL_ONLY)); vispar.drawdomainsurf = atoi (Tcl_GetVar (interp, "::viewoptions.drawdomainsurf", TCL_GLOBAL_ONLY)); vispar.drawededges = atoi (Tcl_GetVar (interp, "::viewoptions.drawededges", TCL_GLOBAL_ONLY)); vispar.drawedpoints = atoi (Tcl_GetVar (interp, "::viewoptions.drawedpoints", TCL_GLOBAL_ONLY)); vispar.drawedpointnrs = atoi (Tcl_GetVar (interp, "::viewoptions.drawedpointnrs", TCL_GLOBAL_ONLY)); vispar.drawedtangents = atoi (Tcl_GetVar (interp, "::viewoptions.drawedtangents", TCL_GLOBAL_ONLY)); vispar.drawededgenrs = atoi (Tcl_GetVar (interp, "::viewoptions.drawededgenrs", TCL_GLOBAL_ONLY)); vispar.drawcurveproj = atoi (Tcl_GetVar (interp, "::viewoptions.drawcurveproj", TCL_GLOBAL_ONLY)); vispar.drawcurveprojedge = atoi (Tcl_GetVar (interp, "::viewoptions.drawcurveprojedge", TCL_GLOBAL_ONLY)); vispar.centerpoint = atoi (Tcl_GetVar (interp, "::viewoptions.centerpoint", TCL_GLOBAL_ONLY)); vispar.use_center_coords = atoi (Tcl_GetVar (interp, "::viewoptions.usecentercoords", TCL_GLOBAL_ONLY)) > 0; vispar.centerx = atof (Tcl_GetVar (interp, "::viewoptions.centerx", TCL_GLOBAL_ONLY)); vispar.centery = atof (Tcl_GetVar (interp, "::viewoptions.centery", TCL_GLOBAL_ONLY)); vispar.centerz = atof (Tcl_GetVar (interp, "::viewoptions.centerz", TCL_GLOBAL_ONLY)); vispar.drawelement = atoi (Tcl_GetVar (interp, "::viewoptions.drawelement", TCL_GLOBAL_ONLY)); vispar.drawmetispartition = atoi (Tcl_GetVar (interp, "::viewoptions.drawmetispartition", TCL_GLOBAL_ONLY)); vispar.drawspecpoint = atoi (Tcl_GetVar (interp, "::viewoptions.drawspecpoint", TCL_GLOBAL_ONLY)); vispar.specpointx = atof (Tcl_GetVar (interp, "::viewoptions.specpointx", TCL_GLOBAL_ONLY)); vispar.specpointy = atof (Tcl_GetVar (interp, "::viewoptions.specpointy", TCL_GLOBAL_ONLY)); vispar.specpointz = atof (Tcl_GetVar (interp, "::viewoptions.specpointz", TCL_GLOBAL_ONLY)); vsspecpoints.len = atof (Tcl_GetVar (interp, "::viewoptions.specpointvlen", TCL_GLOBAL_ONLY)); #ifdef OCCGEOMETRY vispar.occdeflection = pow(10.0,-1-atof (Tcl_GetVar (interp, "::occoptions.deflection", TCL_GLOBAL_ONLY))); #endif #ifdef PARALLELGL vsmesh.Broadcast (); #endif return TCL_OK; } int Ng_SelectSurface (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { int surfnr = atoi (argv[1]); vsgeom.SelectSurface (surfnr); return TCL_OK; } int Ng_BuildFieldLines (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { vssolution.BuildFieldLinesPlot(); return TCL_OK; } #ifdef PARALLEL int Ng_VisualizeAll (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { int id, rc, ntasks; MPI_Comm_size(MPI_COMM_WORLD, &ntasks); MPI_Comm_rank(MPI_COMM_WORLD, &id); string visualizationmode = Tcl_GetVar (interp, "::selectvisual", 0); string scalfun = Tcl_GetVar (interp, "::visoptions.scalfunction", 0); for ( int dest = 1; dest < ntasks; dest++) { MyMPI_Send ( "visualize", dest ); MyMPI_Send ( visualizationmode, dest); if ( visualizationmode == "solution" ) MyMPI_Send ( scalfun, dest); } return TCL_OK; } int Ng_VisualizeOne (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { int id, rc, ntasks; MPI_Comm_size(MPI_COMM_WORLD, &ntasks); MPI_Comm_rank(MPI_COMM_WORLD, &id); string visualizationmode = Tcl_GetVar (interp, "::selectvisual", 0); string scalfun = Tcl_GetVar (interp, "::visoptions.scalfunction", 0); MyMPI_Send ( "visualize", 1 ); MyMPI_Send ( visualizationmode, 1); if ( visualizationmode == "solution" ) MyMPI_Send ( scalfun, 1); return TCL_OK; } int Ng_IncrOverlap ( ClientData clientDate, Tcl_Interp * interp, int argc, tcl_const char * argv[] ) { int id, rc, ntasks; MPI_Comm_size(MPI_COMM_WORLD, &ntasks); MPI_Comm_rank(MPI_COMM_WORLD, &id); for ( int dest = 1; dest < ntasks; dest++) { MyMPI_Send ( "overlap++", dest ); } mesh->UpdateOverlap(); return TCL_OK; } int Ng_SetSelectVisual ( ClientData clientDate, Tcl_Interp * interp, int argc, tcl_const char * argv[] ) { string visualizationmode; MyMPI_Recv ( visualizationmode, 0); Tcl_SetVar (interp, "::selectvisual", visualizationmode.c_str(), 0); return TCL_OK; } int Ng_SetScalarFunction ( ClientData clientDate, Tcl_Interp * interp, int argc, tcl_const char * argv[] ) { string visualizationmode; string scalarfun; visualizationmode = Tcl_GetVar (interp, "::selectvisual", 0); if ( visualizationmode == "solution" ) { MyMPI_Recv ( scalarfun, 0); Tcl_SetVar (interp, "::visoptions.scalfunction", scalarfun.c_str(), 0); } return TCL_OK; } #endif int Ng_IsParallel (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { #ifdef PARALLEL int id, rc, ntasks; MPI_Comm_size(MPI_COMM_WORLD, &ntasks); MPI_Comm_rank(MPI_COMM_WORLD, &id); if ( ntasks > 1 ) Tcl_SetVar (interp, "::parallel_netgen", "1", 0); else Tcl_SetVar (interp, "::parallel_netgen", "0", 0); #else Tcl_SetVar (interp, "::parallel_netgen", "0", 0); #endif return TCL_OK; } int Ng_Exit (ClientData clientData, Tcl_Interp * interp, int argc, tcl_const char *argv[]) { #ifdef PARALLEL int id, rc, ntasks; MPI_Comm_size(MPI_COMM_WORLD, &ntasks); MPI_Comm_rank(MPI_COMM_WORLD, &id); if ( id != 0 ) return TCL_OK; #endif /* if (ngsolve_handle) { void (*ngs_exit)(); ngs_exit = ( void (*)() ) dlsym (ngsolve_handle, "NGSolve_Exit"); if (ngs_exit) (*ngs_exit)(); } */ #ifdef NGSOLVE NGSolve_Exit (); #endif delete stlgeometry; stlgeometry = NULL; geometry.Reset (0); geometry2d.Reset (0); #ifdef ACIS outcome res; res = api_terminate_faceter(); if(!res.ok()) cerr << "problem with terminating acis faceter" << endl; res = api_terminate_constructors(); if(!res.ok()) cerr << "problem with terminating acis constructors" << endl; res = api_terminate_kernel(); if(!res.ok()) cerr << "problem with terminating acis kernel" << endl; res = api_stop_modeller(); if(!res.ok()) cerr << "problem with terminating acis modeller" << endl; //cout << "stopped acis, outcome = " << res.ok() << endl; #endif #ifdef PARALLEL for ( int dest = 1; dest < ntasks; dest++) MyMPI_Send ( "end", dest ); #endif if (testout != &cout) delete testout; return TCL_OK; } #ifdef SOCKETS void * ServerSocketManagerRunDummy ( void * nix ) { serversocketmanager.Run(); return NULL; } extern "C" int Ng_ServerSocketManagerRun( void ); int Ng_ServerSocketManagerRun( void ) { if(mparam.parthread) RunParallel(ServerSocketManagerRunDummy,NULL); else serversocketmanager.Run(); return TCL_OK; } extern "C" int Ng_ServerSocketManagerInit(int port); int Ng_ServerSocketManagerInit(int port) { serversocketmanager.Init(port); return TCL_OK; } #endif //SOCKETS extern "C" int Ng_Init (Tcl_Interp * interp); // int main_Eero (ClientData clientData, // Tcl_Interp * interp, // int argc, tcl_const char *argv[]); int Ng_Init (Tcl_Interp * interp) { #ifdef SOCKETS if(serversocketmanager.Good()) serversocketusernetgen.Reset(new ServerSocketUserNetgen (serversocketmanager, mesh, geometry)); #endif tcl_interp = interp; // Tcl_CreateCommand (interp, "Ng_Eero", main_Eero, // (ClientData)NULL, // (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_New", Ng_New, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); // Tcl_CreateCommand (interp, "Ng_Lock", Ng_Lock, // (ClientData)NULL, // (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_LoadGeometry", Ng_LoadGeometry, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SaveGeometry", Ng_SaveGeometry, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ParseGeometry", Ng_ParseGeometry, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_LoadMesh", Ng_LoadMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SaveMesh", Ng_SaveMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_MergeMesh", Ng_MergeMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ExportMesh", Ng_ExportMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ImportMesh", Ng_ImportMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ImportSolution", Ng_ImportSolution, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ShowDemo", Ng_ShowDemo, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_DemoSetTime", Ng_DemoSetTime, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SaveSolution", Ng_SaveSolution, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_GeometryOptions", Ng_GeometryOptions, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); // geometry Tcl_CreateCommand (interp, "Ng_CreatePrimitive", Ng_CreatePrimitive, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SetPrimitiveData", Ng_SetPrimitiveData, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_GetPrimitiveData", Ng_GetPrimitiveData, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_GetPrimitiveList", Ng_GetPrimitiveList, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_GetSurfaceList", Ng_GetSurfaceList, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SetSolidData", Ng_SetSolidData, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_GetSolidData", Ng_GetSolidData, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_GetSolidList", Ng_GetSolidList, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_TopLevel", Ng_TopLevel, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); // Philippose - 30/01/2009 // Register the TCL Interface Command for local face mesh size // definition Tcl_CreateCommand (interp, "Ng_SurfaceMeshSize", Ng_SurfaceMeshSize, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_AutoColourBcProps", Ng_AutoColourBcProps, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); // meshing Tcl_CreateCommand (interp, "Ng_GenerateMesh", Ng_GenerateMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_StopMeshing", Ng_StopMeshing, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_MeshInfo", Ng_MeshInfo, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_MeshQuality", Ng_MeshQuality, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_CheckSurfaceMesh", Ng_CheckSurfaceMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_CheckVolumeMesh", Ng_CheckVolumeMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_DeleteVolMesh", Ng_DeleteVolMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SplitSeparatedFaces", Ng_SplitSeparatedFaces, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SetNextTimeStamp", Ng_SetNextTimeStamp, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_Refine", Ng_Refine, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SecondOrder", Ng_SecondOrder, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_HighOrder", Ng_HighOrder, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ValidateSecondOrder", Ng_ValidateSecondOrder, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_RestrictH", Ng_RestrictH, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_Anisotropy", Ng_Anisotropy, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_Bisect", Ng_Bisect, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); // Tcl_CreateCommand (interp, "Ng_BisectCopyMesh", Ng_BisectCopyMesh, // (ClientData)NULL, // (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_Split2Tets", Ng_Split2Tets, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ZRefinement", Ng_ZRefinement, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_HPRefinement", Ng_HPRefinement, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_LoadMeshSize", Ng_LoadMeshSize, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_MeshSizeFromSurfaceMesh", Ng_MeshSizeFromSurfaceMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SingularEdgeMS", Ng_SingularEdgeMS, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SingularPointMS", Ng_SingularPointMS, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_GenerateBoundaryLayer", Ng_GenerateBoundaryLayer, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_InsertVirtualBL", Ng_InsertVirtualBL, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_CutOffAndCombine", Ng_CutOffAndCombine, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_HelmholtzMesh", Ng_HelmholtzMesh, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ReadStatus", Ng_ReadStatus, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_MemInfo", Ng_MemInfo, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_STLDoctor", Ng_STLDoctor, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_MeshDoctor", Ng_MeshDoctor, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_BCProp", Ng_BCProp, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_STLInfo", Ng_STLInfo, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_STLCalcLocalH", Ng_STLCalcLocalH, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SetOCCVisParameters", Ng_SetOCCVisParameters, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_GetOCCData", Ng_GetOCCData, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); #ifdef OCCGEOMETRY Tcl_CreateCommand (interp, "Ng_OCCConstruction", Ng_OCCConstruction, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); #endif Tcl_CreateCommand (interp, "Ng_OCCCommand", Ng_OCCCommand, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ACISCommand", Ng_ACISCommand, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_MouseMove", Ng_MouseMove, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_MouseDblClick", Ng_MouseDblClick, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ZoomAll", Ng_ZoomAll, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_Center", Ng_Center, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_StandardRotation", Ng_StandardRotation, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_ArbitraryRotation", Ng_ArbitraryRotation, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SetVisParameters", Ng_SetVisParameters, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SetMeshingParameters", Ng_SetMeshingParameters, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SetDebugParameters", Ng_SetDebugParameters, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SetSTLParameters", Ng_SetSTLParameters, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); #ifdef OCCGEOMETRY Tcl_CreateCommand (interp, "Ng_SetOCCParameters", Ng_SetOCCParameters, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); #endif //OCCGEOMETRY Tcl_CreateCommand (interp, "Ng_SelectSurface", Ng_SelectSurface, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_GetCommandLineParameter", Ng_GetCommandLineParameter, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_Exit", Ng_Exit, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_Metis", Ng_Metis, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_BuildFieldLines", Ng_BuildFieldLines, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); #ifdef PARALLEL Tcl_CreateCommand (interp, "Ng_VisualizeAll", Ng_VisualizeAll, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_VisualizeOne", Ng_VisualizeOne, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_IncrOverlap", Ng_IncrOverlap, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SetSelectVisual", Ng_SetSelectVisual, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand (interp, "Ng_SetScalarFunction", Ng_SetScalarFunction, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); #endif Tcl_CreateCommand (interp, "Ng_IsParallel", Ng_IsParallel, (ClientData)NULL, (Tcl_CmdDeleteProc*) NULL); /* * Specify the C callback functions for widget creation, display, * and reshape. */ #if TOGL_MAJOR_VERSION==1 if (!nodisplay) { if (Togl_Init(interp) == TCL_ERROR) return TCL_ERROR; Togl_CreateFunc( init ); Togl_DestroyFunc( zap ); Togl_DisplayFunc( draw ); Togl_ReshapeFunc( reshape ); // Togl_TimerFunc( idle ); Togl_CreateCommand( (char*)"Ng_SnapShot", Ng_SnapShot); Togl_CreateCommand( (char*)"Ng_VideoClip", Ng_VideoClip); // Togl_CreateCommand("position",position); } #else if (!nodisplay) { if (Togl_Init(interp) == TCL_ERROR) return TCL_ERROR; Tcl_CreateObjCommand(interp, "init", init, NULL, NULL); Tcl_CreateObjCommand(interp, "zap", zap, NULL, NULL); Tcl_CreateObjCommand(interp, "draw", draw, NULL, NULL); Tcl_CreateObjCommand(interp, "reshape", reshape, NULL, NULL); // Togl_TimerFunc( idle ); // Togl_CreateCommand( (char*)"Ng_SnapShot", Ng_SnapShot); // Togl_CreateCommand( (char*)"Ng_VideoClip", Ng_VideoClip); // Togl_CreateCommand("position",position); } #endif multithread.pause = 0; multithread.testmode = 0; multithread.redraw = 0; multithread.drawing = 1; multithread.terminate = 0; multithread.running = 0; multithread.task = ""; multithread.percent = 20; Tcl_LinkVar (interp, "multithread_pause", (char*)&multithread.pause, TCL_LINK_INT); Tcl_LinkVar (interp, "multithread_testmode", (char*)&multithread.testmode, TCL_LINK_INT); Tcl_LinkVar (interp, "multithread_redraw", (char*)&multithread.redraw, TCL_LINK_INT); Tcl_LinkVar (interp, "multithread_drawing", (char*)&multithread.drawing, TCL_LINK_INT); Tcl_LinkVar (interp, "multithread_terminate", (char*)&multithread.terminate, TCL_LINK_INT); Tcl_LinkVar (interp, "multithread_running", (char*)&multithread.running, TCL_LINK_INT); //testout->setstate(ios_base::badbit); myerr = &cerr; extern ostream * mycout; mycout = &cout; testmode = 0; #ifdef ACIS outcome res; res = api_start_modeller (0); if(!res.ok()) cerr << "problem with starting acis modeller" << endl; #ifdef ACIS_R17 unlock_spatial_products_661(); #endif res = api_initialize_kernel(); if(!res.ok()) cerr << "problem with starting acis kernel" << endl; res = api_initialize_constructors(); if(!res.ok()) cerr << "problem with starting acis constructors" << endl; res = api_initialize_faceter(); if(!res.ok()) cerr << "problem with starting acis faceter" << endl; #endif return TCL_OK; } }