#ifdef OCCGEOMETRY #include #include #include #include #include "occ_vertex.hpp" #include "occ_edge.hpp" #include "occ_face.hpp" #include "occ_solid.hpp" #include "occgeom.hpp" #include "Partition_Spliter.hxx" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if OCC_VERSION_HEX < 0x070000 // pass #elif OCC_VERSION_HEX < 0x070200 #include #include #else #include #endif namespace netgen { void LoadOCCInto(OCCGeometry* occgeo, const filesystem::path & filename); void PrintContents (OCCGeometry * geom); std::map OCCGeometry::global_shape_properties; std::map> OCCGeometry::identifications; TopoDS_Shape ListOfShapes::Max(gp_Vec dir) { double maxval = -1e99; TopoDS_Shape maxshape; for (auto shape : *this) { GProp_GProps props; gp_Pnt center; switch (shape.ShapeType()) { case TopAbs_VERTEX: center = BRep_Tool::Pnt (TopoDS::Vertex(shape)); break; case TopAbs_FACE: BRepGProp::SurfaceProperties (shape, props); center = props.CentreOfMass(); break; default: BRepGProp::LinearProperties(shape, props); center = props.CentreOfMass(); } double val = center.X()*dir.X() + center.Y()*dir.Y() + center.Z() * dir.Z(); if (val > maxval) { maxval = val; maxshape = shape; } } return maxshape; } TopoDS_Shape ListOfShapes::Nearest(gp_Pnt pnt) { double mindist = 1e99; TopoDS_Shape nearestshape; auto vertex = BRepBuilderAPI_MakeVertex (pnt).Vertex(); for (auto shape : *this) { double dist = BRepExtrema_DistShapeShape(shape, vertex).Value(); if (dist < mindist) { nearestshape = shape; mindist = dist; } } return nearestshape; } ListOfShapes ListOfShapes::SubShapes(TopAbs_ShapeEnum type) const { std::set unique_shapes; for(const auto& shape : *this) for(TopExp_Explorer e(shape, type); e.More(); e.Next()) unique_shapes.insert(e.Current()); ListOfShapes sub; for(const auto& shape : unique_shapes) sub.push_back(shape); return sub; } OCCGeometry::OCCGeometry(const TopoDS_Shape& _shape, int aoccdim, bool copy) { if(copy) { auto filename = GetTempFilename(); step_utils::WriteSTEP(_shape, filename); LoadOCCInto(this, filename); dimension = aoccdim; filesystem::remove(filename); } else { shape = _shape; changed = 1; dimension = aoccdim; BuildFMap(); CalcBoundingBox(); PrintContents (this); } } const GeometryShape & OCCGeometry :: GetShape(const TopoDS_Shape & shape) const { switch (shape.ShapeType()) { case TopAbs_VERTEX: return GetVertex(shape); case TopAbs_EDGE: return GetEdge(shape); case TopAbs_FACE: return GetFace(shape); default: throw Exception("unknown shape type"); } } const GeometryVertex & OCCGeometry :: GetVertex(const TopoDS_Shape & shape) const { return *vertices[vmap.FindIndex(shape)-1]; } const GeometryEdge & OCCGeometry :: GetEdge(const TopoDS_Shape & shape) const { return *edges[emap.FindIndex(shape)-1]; } const GeometryFace & OCCGeometry :: GetFace(const TopoDS_Shape & shape) const { return *faces[fmap.FindIndex(shape)-1]; } string STEP_GetEntityName(const TopoDS_Shape & theShape, STEPCAFControl_Reader * aReader) { const Handle(XSControl_WorkSession)& theSession = aReader->Reader().WS(); const Handle(XSControl_TransferReader)& aTransferReader = theSession->TransferReader(); Handle(Standard_Transient) anEntity = aTransferReader->EntityFromShapeResult(theShape, 1); if (anEntity.IsNull()) // as just mapped anEntity = aTransferReader->EntityFromShapeResult (theShape,-1); if (anEntity.IsNull()) // as anything anEntity = aTransferReader->EntityFromShapeResult (theShape,4); if (anEntity.IsNull()) { cout<<"Warning: cannot get entity from shape" <Name()->ToCString();; auto bReprItem = Handle(StepBasic_ProductDefinitionRelationship)::DownCast(anEntity); if (!bReprItem.IsNull()) return bReprItem->Description()->ToCString(); cout<<"Warning: unknown entity type " << anEntity->DynamicType() << endl; return "none"; } void OCCGeometry :: Analyse(Mesh& mesh, const MeshingParameters& mparam) const { OCCSetLocalMeshSize(*this, mesh, mparam, occparam); } bool OCCGeometry :: MeshFace(Mesh& mesh, const MeshingParameters& mparam, int nr, FlatArray glob2loc) const { MeshingParameters local_mp = mparam; auto face = TopoDS::Face(fmap(nr+1)); if(auto quad_dominated = OCCGeometry::global_shape_properties[face].quad_dominated; quad_dominated.has_value()) local_mp.quad = *quad_dominated; bool failed = OCCMeshFace(*this, mesh, glob2loc, local_mp, nr, PARAMETERSPACE, true); if(failed) failed = OCCMeshFace(*this, mesh, glob2loc, local_mp, nr, PLANESPACE, false); if(failed) { facemeshstatus[nr] = -1; PrintError ("Problem in Surface mesh generation"); } else { facemeshstatus[nr] = 1; } return failed; } void OCCGeometry :: PrintNrShapes () { TopExp_Explorer e; int count = 0; for (e.Init(shape, TopAbs_COMPSOLID); e.More(); e.Next()) count++; cout << "CompSolids: " << count << endl; cout << "Solids : " << somap.Extent() << endl; cout << "Shells : " << shmap.Extent() << endl; cout << "Faces : " << fmap.Extent() << endl; cout << "Edges : " << emap.Extent() << endl; cout << "Vertices : " << vmap.Extent() << endl; } void PrintContents (OCCGeometry * geom) { ShapeAnalysis_ShapeContents cont; cont.Clear(); cont.Perform(geom->shape); (*testout) << "OCC CONTENTS" << endl; (*testout) << "============" << endl; (*testout) << "SOLIDS : " << cont.NbSolids() << endl; (*testout) << "SHELLS : " << cont.NbShells() << endl; (*testout) << "FACES : " << cont.NbFaces() << endl; (*testout) << "WIRES : " << cont.NbWires() << endl; (*testout) << "EDGES : " << cont.NbEdges() << endl; (*testout) << "VERTICES : " << cont.NbVertices() << endl; TopExp_Explorer e; int count = 0; for (e.Init(geom->shape, TopAbs_COMPOUND); e.More(); e.Next()) count++; (*testout) << "Compounds: " << count << endl; count = 0; for (e.Init(geom->shape, TopAbs_COMPSOLID); e.More(); e.Next()) count++; (*testout) << "CompSolids: " << count << endl; (*testout) << endl; cout << IM(3) << "Highest entry in topology hierarchy: " << endl; if (count) cout << IM(3) << count << " composite solid(s)" << endl; else if (geom->somap.Extent()) cout << IM(3) << geom->somap.Extent() << " solid(s)" << endl; else if (geom->shmap.Extent()) cout << IM(3) << geom->shmap.Extent() << " shells(s)" << endl; else if (geom->fmap.Extent()) cout << IM(3) << geom->fmap.Extent() << " face(s)" << endl; else if (geom->wmap.Extent()) cout << IM(3) << geom->wmap.Extent() << " wire(s)" << endl; else if (geom->emap.Extent()) cout << IM(3) << geom->emap.Extent() << " edge(s)" << endl; else if (geom->vmap.Extent()) cout << IM(3) << geom->vmap.Extent() << " vertices(s)" << endl; else cout << IM(3) << "no entities" << endl; } void OCCGeometry :: GlueGeometry() { PrintMessage(1, "OCC Glue Geometry"); /* // BRep_Builder builder; TopoDS_Shape my_fuse; int cnt = 0; for (TopExp_Explorer exp_solid(shape, TopAbs_SOLID); exp_solid.More(); exp_solid.Next()) { cout << "cnt = " << cnt << endl; if (cnt == 0) my_fuse = exp_solid.Current(); else // my_fuse = BRepAlgoAPI_Fuse (my_fuse, exp_solid.Current()); my_fuse = QANewModTopOpe_Glue::QANewModTopOpe_Glue(my_fuse, exp_solid.Current()); cnt++; } cout << "remove" << endl; // for (int i = 1; i <= somap.Size(); i++) // builder.Remove (shape, somap(i)); cout << "now add" << endl; // builder.Add (shape, my_fuse); shape = my_fuse; cout << "build fmap" << endl; BuildFMap(); */ // from // https://www.opencascade.com/doc/occt-7.4.0/overview/html/occt_user_guides__boolean_operations.html BOPAlgo_Builder aBuilder; // Setting arguments TopTools_ListOfShape aLSObjects; for (TopExp_Explorer exp_solid(shape, TopAbs_SOLID); exp_solid.More(); exp_solid.Next()) aLSObjects.Append (exp_solid.Current()); aBuilder.SetArguments(aLSObjects); // Setting options for GF // Set parallel processing mode (default is false) // Standard_Boolean bRunParallel = Standard_True; // aBuilder.SetRunParallel(bRunParallel); // Set Fuzzy value (default is Precision::Confusion()) // Standard_Real aFuzzyValue = 1.e-5; // aBuilder.SetFuzzyValue(aFuzzyValue); // Set safe processing mode (default is false) // Standard_Boolean bSafeMode = Standard_True; // aBuilder.SetNonDestructive(bSafeMode); // Set Gluing mode for coinciding arguments (default is off) // BOPAlgo_GlueEnum aGlue = BOPAlgo_GlueShift; // aBuilder.SetGlue(aGlue); // Disabling/Enabling the check for inverted solids (default is true) // Standard Boolean bCheckInverted = Standard_False; // aBuilder.SetCheckInverted(bCheckInverted); // Set OBB usage (default is false) // Standard_Boolean bUseOBB = Standard_True; // aBuilder.SetUseOBB(buseobb); // Perform the operation aBuilder.Perform(); // Check for the errors #if OCC_VERSION_HEX >= 0x070200 if (aBuilder.HasErrors()) { cout << "builder has errors" << endl; return; } // Check for the warnings if (aBuilder.HasWarnings()) { // treatment of the warnings ; } #endif #ifdef OCC_HAVE_HISTORY Handle(BRepTools_History) history = aBuilder.History (); for (TopExp_Explorer e(shape, TopAbs_SOLID); e.More(); e.Next()) { if (auto name = OCCGeometry::global_shape_properties[e.Current()].name) for (auto mods : history->Modified(e.Current())) OCCGeometry::global_shape_properties[mods].name = *name; } #endif // OCC_HAVE_HISTORY // result of the operation shape = aBuilder.Shape(); BuildFMap(); } void OCCGeometry :: HealGeometry () { int nrc = 0, nrcs = 0, nrso = somap.Extent(), nrsh = shmap.Extent(), nrf = fmap.Extent(), nrw = wmap.Extent(), nre = emap.Extent(), nrv = vmap.Extent(); TopExp_Explorer exp0; TopExp_Explorer exp1; for (exp0.Init(shape, TopAbs_COMPOUND); exp0.More(); exp0.Next()) nrc++; for (exp0.Init(shape, TopAbs_COMPSOLID); exp0.More(); exp0.Next()) nrcs++; double surfacecont = 0; { Handle(ShapeBuild_ReShape) rebuild = new ShapeBuild_ReShape; rebuild->Apply(shape); for (exp1.Init (shape, TopAbs_EDGE); exp1.More(); exp1.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp1.Current()); if ( BRep_Tool::Degenerated(edge) ) rebuild->Remove(edge); } shape = rebuild->Apply(shape); } BuildFMap(); for (exp0.Init (shape, TopAbs_FACE); exp0.More(); exp0.Next()) { TopoDS_Face face = TopoDS::Face(exp0.Current()); GProp_GProps system; BRepGProp::SurfaceProperties(face, system); surfacecont += system.Mass(); } cout << "Starting geometry healing procedure (tolerance: " << tolerance << ")" << endl << "-----------------------------------" << endl; { cout << endl << "- repairing faces" << endl; Handle(ShapeFix_Face) sff; Handle(ShapeBuild_ReShape) rebuild = new ShapeBuild_ReShape; rebuild->Apply(shape); for (exp0.Init (shape, TopAbs_FACE); exp0.More(); exp0.Next()) { TopoDS_Face face = TopoDS::Face (exp0.Current()); auto props = global_shape_properties[face]; sff = new ShapeFix_Face (face); sff->FixAddNaturalBoundMode() = Standard_True; sff->FixSmallAreaWireMode() = Standard_True; sff->Perform(); if(sff->Status(ShapeExtend_DONE1) || sff->Status(ShapeExtend_DONE2) || sff->Status(ShapeExtend_DONE3) || sff->Status(ShapeExtend_DONE4) || sff->Status(ShapeExtend_DONE5)) { cout << "repaired face " << fmap.FindIndex(face) << " "; if(sff->Status(ShapeExtend_DONE1)) cout << "(some wires are fixed)" <Status(ShapeExtend_DONE2)) cout << "(orientation of wires fixed)" <Status(ShapeExtend_DONE3)) cout << "(missing seam added)" <Status(ShapeExtend_DONE4)) cout << "(small area wire removed)" <Status(ShapeExtend_DONE5)) cout << "(natural bounds added)" <Face(); rebuild->Replace(face, newface); } // Set the original properties of the face to the newly created // face (after the healing process) global_shape_properties[face]; } shape = rebuild->Apply(shape); } { Handle(ShapeBuild_ReShape) rebuild = new ShapeBuild_ReShape; rebuild->Apply(shape); for (exp1.Init (shape, TopAbs_EDGE); exp1.More(); exp1.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp1.Current()); if ( BRep_Tool::Degenerated(edge) ) rebuild->Remove(edge); } shape = rebuild->Apply(shape); } if (fixsmalledges) { cout << endl << "- fixing small edges" << endl; Handle(ShapeFix_Wire) sfw; Handle(ShapeBuild_ReShape) rebuild = new ShapeBuild_ReShape; rebuild->Apply(shape); for (exp0.Init (shape, TopAbs_FACE); exp0.More(); exp0.Next()) { TopoDS_Face face = TopoDS::Face(exp0.Current()); for (exp1.Init (face, TopAbs_WIRE); exp1.More(); exp1.Next()) { TopoDS_Wire oldwire = TopoDS::Wire(exp1.Current()); sfw = new ShapeFix_Wire (oldwire, face ,tolerance); sfw->ModifyTopologyMode() = Standard_True; sfw->ClosedWireMode() = Standard_True; bool replace = false; replace = sfw->FixReorder() || replace; replace = sfw->FixConnected() || replace; if (sfw->FixSmall (Standard_False, tolerance) && ! (sfw->StatusSmall(ShapeExtend_FAIL1) || sfw->StatusSmall(ShapeExtend_FAIL2) || sfw->StatusSmall(ShapeExtend_FAIL3))) { cout << "Fixed small edge in wire " << wmap.FindIndex (oldwire) << endl; replace = true; } else if (sfw->StatusSmall(ShapeExtend_FAIL1)) cerr << "Failed to fix small edge in wire " << wmap.FindIndex (oldwire) << ", edge cannot be checked (no 3d curve and no pcurve)" << endl; else if (sfw->StatusSmall(ShapeExtend_FAIL2)) cerr << "Failed to fix small edge in wire " << wmap.FindIndex (oldwire) << ", edge is null-length and has different vertives at begin and end, and lockvtx is True or ModifiyTopologyMode is False" << endl; else if (sfw->StatusSmall(ShapeExtend_FAIL3)) cerr << "Failed to fix small edge in wire " << wmap.FindIndex (oldwire) << ", CheckConnected has failed" << endl; replace = sfw->FixEdgeCurves() || replace; replace = sfw->FixDegenerated() || replace; replace = sfw->FixSelfIntersection() || replace; replace = sfw->FixLacking(Standard_True) || replace; if(replace) { TopoDS_Wire newwire = sfw->Wire(); rebuild->Replace(oldwire, newwire); } //delete sfw; sfw = NULL; } } shape = rebuild->Apply(shape); { BuildFMap(); Handle(ShapeBuild_ReShape) rebuild = new ShapeBuild_ReShape; rebuild->Apply(shape); for (exp1.Init (shape, TopAbs_EDGE); exp1.More(); exp1.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp1.Current()); if (vmap.FindIndex(TopExp::FirstVertex (edge)) == vmap.FindIndex(TopExp::LastVertex (edge))) { GProp_GProps system; BRepGProp::LinearProperties(edge, system); if (system.Mass() < tolerance) { cout << "removing degenerated edge " << emap.FindIndex(edge) << " from vertex " << vmap.FindIndex(TopExp::FirstVertex (edge)) << " to vertex " << vmap.FindIndex(TopExp::LastVertex (edge)) << endl; rebuild->Remove(edge); } } } shape = rebuild->Apply(shape); //delete rebuild; rebuild = NULL; } { Handle(ShapeBuild_ReShape) rebuild = new ShapeBuild_ReShape; rebuild->Apply(shape); for (exp1.Init (shape, TopAbs_EDGE); exp1.More(); exp1.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp1.Current()); if ( BRep_Tool::Degenerated(edge) ) rebuild->Remove(edge); } shape = rebuild->Apply(shape); } Handle(ShapeFix_Wireframe) sfwf = new ShapeFix_Wireframe; sfwf->SetPrecision(tolerance); sfwf->Load (shape); sfwf->ModeDropSmallEdges() = Standard_True; sfwf->SetPrecision(boundingbox.Diam()); if (sfwf->FixWireGaps()) { cout << endl << "- fixing wire gaps" << endl; if (sfwf->StatusWireGaps(ShapeExtend_OK)) cout << "no gaps found" << endl; if (sfwf->StatusWireGaps(ShapeExtend_DONE1)) cout << "some 2D gaps fixed" << endl; if (sfwf->StatusWireGaps(ShapeExtend_DONE2)) cout << "some 3D gaps fixed" << endl; if (sfwf->StatusWireGaps(ShapeExtend_FAIL1)) cout << "failed to fix some 2D gaps" << endl; if (sfwf->StatusWireGaps(ShapeExtend_FAIL2)) cout << "failed to fix some 3D gaps" << endl; } sfwf->SetPrecision(tolerance); { for (exp1.Init (shape, TopAbs_EDGE); exp1.More(); exp1.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp1.Current()); if ( BRep_Tool::Degenerated(edge) ) cout << "degenerated edge at position 4" << endl; } } if (sfwf->FixSmallEdges()) { cout << endl << "- fixing wire frames" << endl; if (sfwf->StatusSmallEdges(ShapeExtend_OK)) cout << "no small edges found" << endl; if (sfwf->StatusSmallEdges(ShapeExtend_DONE1)) cout << "some small edges fixed" << endl; if (sfwf->StatusSmallEdges(ShapeExtend_FAIL1)) cout << "failed to fix some small edges" << endl; } shape = sfwf->Shape(); //delete sfwf; sfwf = NULL; //delete rebuild; rebuild = NULL; } { for (exp1.Init (shape, TopAbs_EDGE); exp1.More(); exp1.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp1.Current()); if ( BRep_Tool::Degenerated(edge) ) cout << "degenerated edge at position 5" << endl; } } if (fixspotstripfaces) { cout << endl << "- fixing spot and strip faces" << endl; Handle(ShapeFix_FixSmallFace) sffsm = new ShapeFix_FixSmallFace(); sffsm -> Init (shape); sffsm -> SetPrecision (tolerance); sffsm -> Perform(); shape = sffsm -> FixShape(); //delete sffsm; sffsm = NULL; } { for (exp1.Init (shape, TopAbs_EDGE); exp1.More(); exp1.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp1.Current()); if ( BRep_Tool::Degenerated(edge) ) cout << "degenerated edge at position 6" << endl; } } if (sewfaces) { cout << endl << "- sewing faces" << endl; BRepOffsetAPI_Sewing sewedObj(tolerance); for (exp0.Init (shape, TopAbs_FACE); exp0.More(); exp0.Next()) { TopoDS_Face face = TopoDS::Face (exp0.Current()); sewedObj.Add (face); } sewedObj.Perform(); if (!sewedObj.SewedShape().IsNull()) shape = sewedObj.SewedShape(); else cout << " not possible"; } { Handle(ShapeBuild_ReShape) rebuild = new ShapeBuild_ReShape; rebuild->Apply(shape); for (exp1.Init (shape, TopAbs_EDGE); exp1.More(); exp1.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp1.Current()); if ( BRep_Tool::Degenerated(edge) ) rebuild->Remove(edge); } shape = rebuild->Apply(shape); } if (makesolids) { cout << endl << "- making solids" << endl; BRepBuilderAPI_MakeSolid ms; int count = 0; for (exp0.Init(shape, TopAbs_SHELL); exp0.More(); exp0.Next()) { count++; ms.Add (TopoDS::Shell(exp0.Current())); } if (!count) { cout << " not possible (no shells)" << endl; } else { BRepCheck_Analyzer ba(ms); if (ba.IsValid ()) { Handle(ShapeFix_Shape) sfs = new ShapeFix_Shape; sfs->Init (ms); sfs->SetPrecision(tolerance); sfs->SetMaxTolerance(tolerance); sfs->Perform(); shape = sfs->Shape(); for (exp0.Init(shape, TopAbs_SOLID); exp0.More(); exp0.Next()) { TopoDS_Solid solid = TopoDS::Solid(exp0.Current()); TopoDS_Solid newsolid = solid; BRepLib::OrientClosedSolid (newsolid); Handle(ShapeBuild_ReShape) rebuild = new ShapeBuild_ReShape; // rebuild->Apply(shape); rebuild->Replace(solid, newsolid); TopoDS_Shape newshape = rebuild->Apply(shape, TopAbs_COMPSOLID);//, 1); // TopoDS_Shape newshape = rebuild->Apply(shape); shape = newshape; } //delete sfs; sfs = NULL; } else cout << " not possible" << endl; } } if (splitpartitions) { cout << "- running SALOME partition splitter" << endl; TopExp_Explorer e2; Partition_Spliter ps; int count = 0; for (e2.Init (shape, TopAbs_SOLID); e2.More(); e2.Next()) { count++; ps.AddShape (e2.Current()); } ps.Compute(); shape = ps.Shape(); cout << " before: " << count << " solids" << endl; count = 0; for (e2.Init (shape, TopAbs_SOLID); e2.More(); e2.Next()) count++; cout << " after : " << count << " solids" << endl; } BuildFMap(); { for (exp1.Init (shape, TopAbs_EDGE); exp1.More(); exp1.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp1.Current()); if ( BRep_Tool::Degenerated(edge) ) cout << "degenerated edge at position 8" << endl; } } double newsurfacecont = 0; for (exp0.Init (shape, TopAbs_FACE); exp0.More(); exp0.Next()) { TopoDS_Face face = TopoDS::Face(exp0.Current()); GProp_GProps system; BRepGProp::SurfaceProperties(face, system); newsurfacecont += system.Mass(); } int nnrc = 0, nnrcs = 0, nnrso = somap.Extent(), nnrsh = shmap.Extent(), nnrf = fmap.Extent(), nnrw = wmap.Extent(), nnre = emap.Extent(), nnrv = vmap.Extent(); for (exp0.Init(shape, TopAbs_COMPOUND); exp0.More(); exp0.Next()) nnrc++; for (exp0.Init(shape, TopAbs_COMPSOLID); exp0.More(); exp0.Next()) nnrcs++; cout << "-----------------------------------" << endl; cout << "Compounds : " << nnrc << " (" << nrc << ")" << endl; cout << "Composite solids: " << nnrcs << " (" << nrcs << ")" << endl; cout << "Solids : " << nnrso << " (" << nrso << ")" << endl; cout << "Shells : " << nnrsh << " (" << nrsh << ")" << endl; cout << "Wires : " << nnrw << " (" << nrw << ")" << endl; cout << "Faces : " << nnrf << " (" << nrf << ")" << endl; cout << "Edges : " << nnre << " (" << nre << ")" << endl; cout << "Vertices : " << nnrv << " (" << nrv << ")" << endl; cout << endl; cout << "Total surface area : " << newsurfacecont << " (" << surfacecont << ")" << endl; cout << endl; } void OCCGeometry :: BuildFMap() { somap.Clear(); shmap.Clear(); fmap.Clear(); wmap.Clear(); emap.Clear(); vmap.Clear(); TopExp_Explorer exp0, exp1, exp2, exp3, exp4, exp5; for (exp0.Init(shape, TopAbs_COMPOUND); exp0.More(); exp0.Next()) { TopoDS_Compound compound = TopoDS::Compound (exp0.Current()); (*testout) << "compound" << endl; int i = 0; for (exp1.Init(compound, TopAbs_SHELL); exp1.More(); exp1.Next()) { (*testout) << "shell " << ++i << endl; } } for (exp0.Init(shape, TopAbs_SOLID); exp0.More(); exp0.Next()) { TopoDS_Solid solid = TopoDS::Solid (exp0.Current()); if (somap.FindIndex(solid) < 1) { somap.Add (solid); for (exp1.Init(solid, TopAbs_SHELL); exp1.More(); exp1.Next()) { TopoDS_Shell shell = TopoDS::Shell (exp1.Current()); if (shmap.FindIndex(shell) < 1) { shmap.Add (shell); for (exp2.Init(shell, TopAbs_FACE); exp2.More(); exp2.Next()) { TopoDS_Face face = TopoDS::Face(exp2.Current()); if (fmap.FindIndex(face) < 1) { fmap.Add (face); (*testout) << "face " << fmap.FindIndex(face) << " "; (*testout) << ((face.Orientation() == TopAbs_REVERSED) ? "-" : "+") << ", "; (*testout) << ((exp2.Current().Orientation() == TopAbs_REVERSED) ? "-" : "+") << endl; for (exp3.Init(exp2.Current(), TopAbs_WIRE); exp3.More(); exp3.Next()) { TopoDS_Wire wire = TopoDS::Wire (exp3.Current()); if (wmap.FindIndex(wire) < 1) { wmap.Add (wire); for (exp4.Init(exp3.Current(), TopAbs_EDGE); exp4.More(); exp4.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp4.Current()); if (emap.FindIndex(edge) < 1) { emap.Add (edge); for (exp5.Init(exp4.Current(), TopAbs_VERTEX); exp5.More(); exp5.Next()) { TopoDS_Vertex vertex = TopoDS::Vertex(exp5.Current()); if (vmap.FindIndex(vertex) < 1) vmap.Add (vertex); } } } } } } } } } } } // Free Shells for (exp1.Init(shape, TopAbs_SHELL, TopAbs_SOLID); exp1.More(); exp1.Next()) { TopoDS_Shell shell = TopoDS::Shell(exp1.Current()); if (shmap.FindIndex(shell) < 1) { shmap.Add (shell); (*testout) << "shell " << shmap.FindIndex(shell) << " "; (*testout) << ((shell.Orientation() == TopAbs_REVERSED) ? "-" : "+") << ", "; (*testout) << ((exp1.Current().Orientation() == TopAbs_REVERSED) ? "-" : "+") << endl; for (exp2.Init(shell, TopAbs_FACE); exp2.More(); exp2.Next()) { TopoDS_Face face = TopoDS::Face(exp2.Current()); if (fmap.FindIndex(face) < 1) { fmap.Add (face); for (exp3.Init(face, TopAbs_WIRE); exp3.More(); exp3.Next()) { TopoDS_Wire wire = TopoDS::Wire (exp3.Current()); if (wmap.FindIndex(wire) < 1) { wmap.Add (wire); for (exp4.Init(wire, TopAbs_EDGE); exp4.More(); exp4.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp4.Current()); if (emap.FindIndex(edge) < 1) { emap.Add (edge); for (exp5.Init(edge, TopAbs_VERTEX); exp5.More(); exp5.Next()) { TopoDS_Vertex vertex = TopoDS::Vertex(exp5.Current()); if (vmap.FindIndex(vertex) < 1) vmap.Add (vertex); } } } } } } } } } // Free Faces for (auto face : MyExplorer(shape, TopAbs_FACE, TopAbs_SHELL)) if (!fmap.Contains(face)) { fmap.Add (face); for (auto wire : MyExplorer(face, TopAbs_WIRE)) if (!wmap.Contains(wire)) { wmap.Add (wire); for (auto edge : MyExplorer(wire, TopAbs_EDGE)) if (!emap.Contains(edge)) { emap.Add (edge); for (auto vertex : MyExplorer(edge, TopAbs_VERTEX)) if (!vmap.Contains(vertex)) vmap.Add (vertex); } } } // Free Wires for (exp3.Init(shape, TopAbs_WIRE, TopAbs_FACE); exp3.More(); exp3.Next()) { TopoDS_Wire wire = TopoDS::Wire (exp3.Current()); if (wmap.FindIndex(wire) < 1) { wmap.Add (wire); for (exp4.Init(exp3.Current(), TopAbs_EDGE); exp4.More(); exp4.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp4.Current()); if (emap.FindIndex(edge) < 1) { emap.Add (edge); for (exp5.Init(exp4.Current(), TopAbs_VERTEX); exp5.More(); exp5.Next()) { TopoDS_Vertex vertex = TopoDS::Vertex(exp5.Current()); if (vmap.FindIndex(vertex) < 1) vmap.Add (vertex); } } } } } // Free Edges /* for (exp4.Init(shape, TopAbs_EDGE, TopAbs_WIRE); exp4.More(); exp4.Next()) { TopoDS_Edge edge = TopoDS::Edge(exp4.Current()); if (emap.FindIndex(edge) < 1) { emap.Add (edge); for (exp5.Init(exp4.Current(), TopAbs_VERTEX); exp5.More(); exp5.Next()) { TopoDS_Vertex vertex = TopoDS::Vertex(exp5.Current()); if (vmap.FindIndex(vertex) < 1) vmap.Add (vertex); } } } */ for (auto edge : MyExplorer(shape, TopAbs_EDGE, TopAbs_WIRE)) if (!emap.Contains(edge)) { emap.Add (edge); for (auto vertex : MyExplorer(edge, TopAbs_VERTEX)) if (!vmap.Contains(vertex)) vmap.Add (vertex); } // Free Vertices /* for (exp5.Init(shape, TopAbs_VERTEX, TopAbs_EDGE); exp5.More(); exp5.Next()) { TopoDS_Vertex vertex = TopoDS::Vertex(exp5.Current()); if (vmap.FindIndex(vertex) < 1) vmap.Add (vertex); } */ for (auto vertex : MyExplorer(shape, TopAbs_VERTEX, TopAbs_EDGE)) if (!vmap.Contains(vertex)) vmap.Add (vertex); facemeshstatus.DeleteAll(); facemeshstatus.SetSize (fmap.Extent()); facemeshstatus = 0; // Philippose - 15/01/2009 face_maxh.DeleteAll(); face_maxh.SetSize (fmap.Extent()); face_maxh = 1e99; // mparam.maxh; // Philippose - 15/01/2010 face_maxh_modified.DeleteAll(); face_maxh_modified.SetSize(fmap.Extent()); face_maxh_modified = 0; // Philippose - 17/01/2009 face_sel_status.DeleteAll(); face_sel_status.SetSize (fmap.Extent()); face_sel_status = 0; fvispar.SetSize (fmap.Extent()); evispar.SetSize (emap.Extent()); vvispar.SetSize (vmap.Extent()); fsingular.SetSize (fmap.Extent()); esingular.SetSize (emap.Extent()); vsingular.SetSize (vmap.Extent()); fsingular = esingular = vsingular = false; NetgenGeometry::Clear(); // Add shapes for(auto i1 : Range(1, vmap.Extent()+1)) { auto v = vmap(i1); auto occ_vertex = make_unique(TopoDS::Vertex(v)); occ_vertex->nr = vertices.Size(); if(global_shape_properties.count(v)>0) occ_vertex->properties = global_shape_properties[v]; vertices.Append(std::move(occ_vertex)); } for(auto i1 : Range(1, emap.Extent()+1)) { auto e = emap(i1); auto edge = TopoDS::Edge(e); auto verts = GetVertices(e); auto occ_edge = make_unique(edge, GetVertex(verts[0]), GetVertex(verts[1]) ); occ_edge->properties = global_shape_properties[e]; edges.Append(std::move(occ_edge)); } for(auto i1 : Range(1, fmap.Extent()+1)) { auto f = fmap(i1); auto k = faces.Size(); auto occ_face = make_unique(f); for(auto e : GetEdges(f)) occ_face->edges.Append( &GetEdge(e) ); if(global_shape_properties.count(f)>0) occ_face->properties = global_shape_properties[f]; faces.Append(std::move(occ_face)); if(dimension==2) for(auto e : GetEdges(f)) { auto & edge = GetEdge(e); if(e.Orientation() == TopAbs_REVERSED) edge.domout = k; else edge.domin = k; } } for(auto i1 : Range(1, somap.Extent()+1)) { auto s = somap(i1); int k = solids.Size(); auto occ_solid = make_unique(s); if(global_shape_properties.count(s)>0) occ_solid->properties = global_shape_properties[s]; solids.Append(std::move(occ_solid)); for(auto f : GetFaces(s)) { auto & face = GetFace(f); if(face.domin==-1) face.domin = k; else face.domout = k; } } // Add identifications auto add_identifications = [&](auto & shapes, auto & shape_map) { for(auto i1 : Range(1, shape_map.Extent()+1)) { auto shape = shape_map(i1); if(identifications.count(shape)) for(auto & ident : identifications[shape]) { if(!shape_map.Contains(ident.from) || !shape_map.Contains(ident.to)) continue; ShapeIdentification si{ &GetShape(ident.from), &GetShape(ident.to), ident.trafo, ident.type, ident.name }; shapes[i1-1]->identifications.Append(si); } } }; add_identifications( vertices, vmap ); add_identifications( edges, emap ); add_identifications( faces, fmap ); bounding_box = ::netgen::GetBoundingBox( shape ); ProcessIdentifications(); } void OCCGeometry :: SewFaces () { (*testout) << "Trying to sew faces ..." << endl; cout << "Trying to sew faces ..." << flush; BRepOffsetAPI_Sewing sewedObj(1); for (int i = 1; i <= fmap.Extent(); i++) { TopoDS_Face face = TopoDS::Face (fmap(i)); sewedObj.Add (face); } sewedObj.Perform(); if (!sewedObj.SewedShape().IsNull()) { shape = sewedObj.SewedShape(); cout << " done" << endl; } else cout << " not possible"; } void OCCGeometry :: MakeSolid () { TopExp_Explorer exp0; (*testout) << "Trying to build solids ..." << endl; cout << "Trying to build solids ..." << flush; BRepBuilderAPI_MakeSolid ms; int count = 0; for (exp0.Init(shape, TopAbs_SHELL); exp0.More(); exp0.Next()) { count++; ms.Add (TopoDS::Shell(exp0.Current())); } if (!count) { cout << " not possible (no shells)" << endl; return; } BRepCheck_Analyzer ba(ms); if (ba.IsValid ()) { Handle(ShapeFix_Shape) sfs = new ShapeFix_Shape; sfs->Init (ms); sfs->SetPrecision(1e-5); sfs->SetMaxTolerance(1e-5); sfs->Perform(); shape = sfs->Shape(); for (exp0.Init(shape, TopAbs_SOLID); exp0.More(); exp0.Next()) { TopoDS_Solid solid = TopoDS::Solid(exp0.Current()); TopoDS_Solid newsolid = solid; BRepLib::OrientClosedSolid (newsolid); Handle(ShapeBuild_ReShape) rebuild = new ShapeBuild_ReShape; rebuild->Replace(solid, newsolid); TopoDS_Shape newshape = rebuild->Apply(shape, TopAbs_SHAPE, 1); shape = newshape; } cout << " done" << endl; } else cout << " not possible" << endl; } Array OCCGeometry :: GetFaceVertices(const GeometryFace& face) const { Array verts; const auto& occface = dynamic_cast(face); for(auto& vert : GetVertices(occface.Shape())) verts.Append(&GetVertex(vert)); return move(verts); } void OCCGeometry :: BuildVisualizationMesh (double deflection) { cout << "Preparing visualization (deflection = " << deflection << ") ... " << flush; BRepTools::Clean (shape); // BRepMesh_IncrementalMesh:: BRepMesh_IncrementalMesh (shape, deflection, true); cout << "done" << endl; } void OCCGeometry :: CalcBoundingBox () { boundingbox = ::netgen::GetBoundingBox(shape); (*testout) << "Bounding Box = [" << boundingbox.PMin() << " - " << boundingbox.PMax() << "]" << endl; SetCenter(); } // void OCCGeometry :: WriteOCC_STL(char * filename) // { // cout << "writing stl..."; cout.flush(); // StlAPI_Writer writer; // writer.RelativeMode() = Standard_False; // // writer.SetDeflection(0.02); // writer.Write(shape,filename); // // cout << "done" << endl; // } void LoadOCCInto(OCCGeometry* occgeo, const filesystem::path & filename) { static Timer timer_all("LoadOCC"); RegionTimer rtall(timer_all); static Timer timer_readfile("LoadOCC-ReadFile"); static Timer timer_transfer("LoadOCC-Transfer"); static Timer timer_getnames("LoadOCC-get names"); // Initiate a dummy XCAF Application to handle the STEP XCAF Document static Handle(XCAFApp_Application) dummy_app = XCAFApp_Application::GetApplication(); // Create an XCAF Document to contain the STEP file itself Handle(TDocStd_Document) step_doc; // Check if a STEP File is already open under this handle, if so, close it to prevent // Segmentation Faults when trying to create a new document if(dummy_app->NbDocuments() > 0) { dummy_app->GetDocument(1,step_doc); dummy_app->Close(step_doc); } dummy_app->NewDocument ("STEP-XCAF",step_doc); timer_readfile.Start(); STEPCAFControl_Reader reader; // Enable transfer of colours reader.SetColorMode(Standard_True); reader.SetNameMode(Standard_True); Standard_Integer stat = reader.ReadFile(filename.string().c_str()); timer_readfile.Stop(); timer_transfer.Start(); if(stat != IFSelect_RetDone) { throw NgException("Couldn't load OCC geometry"); } reader.Transfer(step_doc); timer_transfer.Stop(); // Read in the shape(s) and the colours present in the STEP File auto step_shape_contents = XCAFDoc_DocumentTool::ShapeTool(step_doc->Main()); TDF_LabelSequence step_shapes; step_shape_contents->GetShapes(step_shapes); // For the STEP File Reader in OCC, the 1st Shape contains the entire // compound geometry as one shape auto main_shape = step_shape_contents->GetShape(step_shapes.Value(1)); step_utils::LoadProperties(main_shape, reader, step_doc); occgeo->shape = main_shape; occgeo->changed = 1; occgeo->BuildFMap(); occgeo->CalcBoundingBox(); PrintContents (occgeo); } // Philippose - 23/02/2009 /* Special IGES File load function including the ability to extract individual surface colours via the extended OpenCascade XDE and XCAF Feature set. */ OCCGeometry *LoadOCC_IGES(const filesystem::path & filename) { OCCGeometry *occgeo; occgeo = new OCCGeometry; // Initiate a dummy XCAF Application to handle the IGES XCAF Document static Handle(XCAFApp_Application) dummy_app = XCAFApp_Application::GetApplication(); // Create an XCAF Document to contain the IGES file itself Handle(TDocStd_Document) iges_doc; // Check if a IGES File is already open under this handle, if so, close it to prevent // Segmentation Faults when trying to create a new document if(dummy_app->NbDocuments() > 0) { dummy_app->GetDocument(1,iges_doc); dummy_app->Close(iges_doc); } dummy_app->NewDocument ("IGES-XCAF",iges_doc); IGESCAFControl_Reader reader; Standard_Integer stat = reader.ReadFile(filename.string().c_str()); if(stat != IFSelect_RetDone) { throw NgException("Couldn't load occ"); } // Enable transfer of colours reader.SetColorMode(Standard_True); reader.Transfer(iges_doc); // Read in the shape(s) and the colours present in the IGES File Handle(XCAFDoc_ShapeTool) iges_shape_contents = XCAFDoc_DocumentTool::ShapeTool(iges_doc->Main()); Handle(XCAFDoc_ColorTool) iges_colour_contents = XCAFDoc_DocumentTool::ColorTool(iges_doc->Main()); TDF_LabelSequence iges_shapes; iges_shape_contents->GetShapes(iges_shapes); // List out the available colours in the IGES File as Colour Names TDF_LabelSequence all_colours; iges_colour_contents->GetColors(all_colours); PrintMessage(1,"Number of colours in IGES File: ",all_colours.Length()); for(int i = 1; i <= all_colours.Length(); i++) { Quantity_Color col; stringstream col_rgb; iges_colour_contents->GetColor(all_colours.Value(i),col); col_rgb << " : (" << col.Red() << "," << col.Green() << "," << col.Blue() << ")"; PrintMessage(1, "Colour [", i, "] = ",col.StringName(col.Name()),col_rgb.str()); } // For the IGES Reader, all the shapes can be exported as one compound shape // using the "OneShape" member occgeo->shape = reader.OneShape(); occgeo->changed = 1; occgeo->BuildFMap(); occgeo->CalcBoundingBox(); PrintContents (occgeo); return occgeo; } // Philippose - 29/01/2009 /* Special STEP File load function including the ability to extract individual surface colours via the extended OpenCascade XDE and XCAF Feature set. */ OCCGeometry * LoadOCC_STEP (const filesystem::path & filename) { OCCGeometry * occgeo; occgeo = new OCCGeometry; LoadOCCInto(occgeo, filename); return occgeo; } OCCGeometry *LoadOCC_BREP (const filesystem::path & filename) { OCCGeometry * occgeo; occgeo = new OCCGeometry; BRep_Builder aBuilder; Standard_Boolean result = BRepTools::Read(occgeo->shape, filename.string().c_str(), aBuilder); if(!result) { delete occgeo; return NULL; } occgeo->changed = 1; occgeo->BuildFMap(); occgeo->CalcBoundingBox(); PrintContents (occgeo); return occgeo; } void OCCGeometry :: Save (const filesystem::path & filename) const { string ext = ToLower(filename.extension()); auto s_filename = filename.string(); auto c_filename = s_filename.c_str(); if (ext == ".igs") { IGESControl_Writer writer("millimeters", 1); writer.AddShape (shape); writer.Write (c_filename); } else if (ext == ".stp") { step_utils::WriteSTEP(*this, filename); } else if (ext == ".stl") { StlAPI_Writer writer; writer.ASCIIMode() = Standard_True; writer.Write (shape, c_filename); } else if (ext == ".stlb") { StlAPI_Writer writer; writer.ASCIIMode() = Standard_False; writer.Write (shape, c_filename); } throw NgException ("Unknown target format: " + filename); } void OCCGeometry :: SaveToMeshFile (ostream & ost) const { auto ss = make_shared(); TextOutArchive out(ss); NetgenGeometry *geo = const_cast(this); out & geo; ost << "TextOutArchive" << endl; ost << ss->str().size() << endl; ost << ss->str(); } void OCCGeometry :: DoArchive(Archive& ar) { constexpr int current_format_version = 0; int format_version = current_format_version; auto netgen_version = GetLibraryVersion("netgen"); ar & netgen_version & format_version; if(ar.Output()) { std::stringstream ss; #if OCC_VERSION_HEX < 0x070600 BRepTools::Write(shape, ss); #else BRepTools::Write(shape, ss, false, false, TopTools_FormatVersion_VERSION_1); #endif ar << ss.str(); } else { if(format_version>current_format_version) throw Exception("Loading OCCGeometry from archive: unknown format version " + ToString(format_version) + ", written by netgen version " + ToString(netgen_version)); std::string str; ar & str; stringstream ss(str); BRep_Builder builder; BRepTools::Read(shape, ss, builder); } // enumerate shapes and archive only integers auto my_hash = [](const TopoDS_Shape & key) { auto occ_hash = key.HashCode(1<<31UL); return std::hash()(occ_hash); }; std::map shape_map; Array shape_list; ar & dimension; for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE }) for (TopExp_Explorer e(shape, typ); e.More(); e.Next()) { auto ds = e.Current(); if(shape_map.count(ds)==0) { shape_map[ds] = shape_list.Size(); shape_list.Append(ds); } } for (auto s : shape_list) { bool has_properties = global_shape_properties.count(s); ar & has_properties; if(has_properties) ar & global_shape_properties[s]; bool has_identifications = identifications.count(s); ar & has_identifications; if(has_identifications) { auto & idents = identifications[s]; auto n_idents = idents.size(); ar & n_idents; idents.resize(n_idents); for(auto i : Range(n_idents)) { auto & id = idents[i]; int id_from, id_to; if(ar.Output()) { id_from = shape_map[id.from]; id_to = shape_map[id.to]; } ar & id_from & id_to & id.trafo & id.name; if(ar.Input()) { id.from = shape_list[id_from]; id.to = shape_list[id_to]; } } } } if(ar.Input()) { changed = 1; BuildFMap(); CalcBoundingBox(); } } const char * shapesname[] = {" ", "CompSolids", "Solids", "Shells", "Faces", "Wires", "Edges", "Vertices"}; const char * shapename[] = {" ", "CompSolid", "Solid", "Shell", "Face", "Wire", "Edge", "Vertex"}; const char * orientationstring[] = {"+", "-"}; void OCCGeometry :: RecursiveTopologyTree (const TopoDS_Shape & sh, stringstream & str, TopAbs_ShapeEnum l, bool isfree, const char * lname) { if (l > TopAbs_VERTEX) return; TopExp_Explorer e; int count = 0; int count2 = 0; if (isfree) e.Init(sh, l, TopAbs_ShapeEnum(l-1)); else e.Init(sh, l); for (; e.More(); e.Next()) { count++; stringstream lname2; lname2 << lname << "/" << shapename[l] << count; str << lname2.str() << " "; switch (e.Current().ShapeType()) { case TopAbs_SOLID: count2 = somap.FindIndex(TopoDS::Solid(e.Current())); break; case TopAbs_SHELL: count2 = shmap.FindIndex(TopoDS::Shell(e.Current())); break; case TopAbs_FACE: count2 = fmap.FindIndex(TopoDS::Face(e.Current())); break; case TopAbs_WIRE: count2 = wmap.FindIndex(TopoDS::Wire(e.Current())); break; case TopAbs_EDGE: count2 = emap.FindIndex(TopoDS::Edge(e.Current())); break; case TopAbs_VERTEX: count2 = vmap.FindIndex(TopoDS::Vertex(e.Current())); break; default: cout << "RecursiveTopologyTree: Case " << e.Current().ShapeType() << " not handled" << endl; } int nrsubshapes = 0; if (l <= TopAbs_WIRE) { TopExp_Explorer e2; for (e2.Init (e.Current(), TopAbs_ShapeEnum (l+1)); e2.More(); e2.Next()) nrsubshapes++; } str << "{" << shapename[l] << " " << count2; if (l <= TopAbs_EDGE) { str << " (" << orientationstring[e.Current().Orientation()]; if (nrsubshapes != 0) str << ", " << nrsubshapes; str << ") } "; } else str << " } "; RecursiveTopologyTree (e.Current(), str, TopAbs_ShapeEnum (l+1), false, (char*)lname2.str().c_str()); } } void OCCGeometry :: GetTopologyTree (stringstream & str) { cout << "Building topology tree ... " << flush; RecursiveTopologyTree (shape, str, TopAbs_COMPSOLID, false, "CompSolids"); RecursiveTopologyTree (shape, str, TopAbs_SOLID, true, "FreeSolids"); RecursiveTopologyTree (shape, str, TopAbs_SHELL, true, "FreeShells"); RecursiveTopologyTree (shape, str, TopAbs_FACE, true, "FreeFaces"); RecursiveTopologyTree (shape, str, TopAbs_WIRE, true, "FreeWires"); RecursiveTopologyTree (shape, str, TopAbs_EDGE, true, "FreeEdges"); RecursiveTopologyTree (shape, str, TopAbs_VERTEX, true, "FreeVertices"); str << flush; // cout << "done" << endl; } void OCCGeometry :: CheckIrregularEntities(stringstream & str) { ShapeAnalysis_CheckSmallFace csm; csm.SetTolerance (1e-6); TopTools_DataMapOfShapeListOfShape mapEdges; ShapeAnalysis_DataMapOfShapeListOfReal mapParam; TopoDS_Compound theAllVert; int spotfaces = 0; int stripsupportfaces = 0; int singlestripfaces = 0; int stripfaces = 0; int facessplitbyvertices = 0; int stretchedpinfaces = 0; int smoothpinfaces = 0; int twistedfaces = 0; // int edgessamebutnotidentified = 0; cout << "checking faces ... " << flush; int i; for (i = 1; i <= fmap.Extent(); i++) { TopoDS_Face face = TopoDS::Face (fmap(i)); TopoDS_Edge e1, e2; if (csm.CheckSpotFace (face)) { if (!spotfaces++) str << "SpotFace {Spot face} "; (*testout) << "Face " << i << " is a spot face" << endl; str << "SpotFace/Face" << i << " "; str << "{Face " << i << " } "; } if (csm.IsStripSupport (face)) { if (!stripsupportfaces++) str << "StripSupportFace {Strip support face} "; (*testout) << "Face " << i << " has strip support" << endl; str << "StripSupportFace/Face" << i << " "; str << "{Face " << i << " } "; } if (csm.CheckSingleStrip(face, e1, e2)) { if (!singlestripfaces++) str << "SingleStripFace {Single strip face} "; (*testout) << "Face " << i << " is a single strip (edge " << emap.FindIndex(e1) << " and edge " << emap.FindIndex(e2) << " are identical)" << endl; str << "SingleStripFace/Face" << i << " "; str << "{Face " << i << " (edge " << emap.FindIndex(e1) << " and edge " << emap.FindIndex(e2) << " are identical)} "; } if (csm.CheckStripFace(face, e1, e2)) { if (!stripfaces++) str << "StripFace {Strip face} "; (*testout) << "Face " << i << " is a strip (edge " << emap.FindIndex(e1) << " and edge " << emap.FindIndex(e2) << " are identical)" << endl; str << "StripFace/Face" << i << " "; str << "{Face " << i << " (edge " << emap.FindIndex(e1) << " and edge " << emap.FindIndex(e2) << " are identical)} "; } if (int count = csm.CheckSplittingVertices(face, mapEdges, mapParam, theAllVert)) { if (!facessplitbyvertices++) str << "FaceSplitByVertices {Face split by vertices} "; (*testout) << "Face " << i << " is split by " << count << " vertex/vertices " << endl; str << "FaceSplitByVertices/Face" << i << " "; str << "{Face " << i << " (split by " << count << "vertex/vertices)} "; } int whatrow, sens; if (int type = csm.CheckPin (face, whatrow, sens)) { if (type == 1) { if (!smoothpinfaces++) str << "SmoothPinFace {Smooth pin face} "; (*testout) << "Face " << i << " is a smooth pin" << endl; str << "SmoothPinFace/Face" << i << " "; str << "{Face " << i << " } "; } else { if (!stretchedpinfaces++) str << "StretchedPinFace {Stretched pin face} "; (*testout) << "Face " << i << " is a stretched pin" << endl; str << "StretchedPinFace/Face" << i << " "; str << "{Face " << i << " } "; } } double paramu, paramv; if (csm.CheckTwisted (face, paramu, paramv)) { if (!twistedfaces++) str << "TwistedFace {Twisted face} "; (*testout) << "Face " << i << " is twisted" << endl; str << "TwistedFace/Face" << i << " "; str << "{Face " << i << " } "; } } cout << "done" << endl; cout << "checking edges ... " << flush; // double dmax; // int cnt = 0; NgArray edgeLengths; NgArray order; edgeLengths.SetSize (emap.Extent()); order.SetSize (emap.Extent()); for (i = 1; i <= emap.Extent(); i++) { TopoDS_Edge edge1 = TopoDS::Edge (emap(i)); GProp_GProps system; BRepGProp::LinearProperties(edge1, system); edgeLengths[i-1] = system.Mass(); } Sort (edgeLengths, order); str << "ShortestEdges {Shortest edges} "; for (i = 1; i <= min(20, emap.Extent()); i++) { str << "ShortestEdges/Edge" << i; str << " {Edge " << order[i-1] << " (L=" << edgeLengths[order[i-1]-1] << ")} "; } str << flush; cout << "done" << endl; } void OCCGeometry :: GetUnmeshedFaceInfo (stringstream & str) { for (int i = 1; i <= fmap.Extent(); i++) { if (facemeshstatus[i-1] == -1) str << "Face" << i << " {Face " << i << " } "; } str << flush; } void OCCGeometry :: GetNotDrawableFaces (stringstream & str) { for (int i = 1; i <= fmap.Extent(); i++) { if (!fvispar[i-1].IsDrawable()) str << "Face" << i << " {Face " << i << " } "; } str << flush; } bool OCCGeometry :: ErrorInSurfaceMeshing () { for (int i = 1; i <= fmap.Extent(); i++) if (facemeshstatus[i-1] == -1) return true; return false; } bool IsMappedShape(const Transformation<3> & trafo, const TopoDS_Shape & me, const TopoDS_Shape & you) { if(me.ShapeType() != you.ShapeType()) return false; Bnd_Box bbox; BRepBndLib::Add(me, bbox); BRepBndLib::Add(you, bbox); BoxTree<3> tree( occ2ng(bbox.CornerMin()), occ2ng(bbox.CornerMax()) ); Point<3> c_me = occ2ng(Center(me)); Point<3> c_you = occ2ng(Center(you)); if(tree.GetTolerance() < Dist(trafo(c_me), c_you)) return false; std::map> vmap; auto verts_me = GetVertices(me); auto verts_you = GetVertices(you); if(verts_me.size() != verts_you.size()) return false; for (auto i : Range(verts_me.size())) { auto s = verts_me[i]; if(vmap.count(s)>0) continue; auto p = trafo(occ2ng(s)); tree.Insert( p, i ); vmap[s] = nullopt; } for (auto vert : verts_you) { auto s = vert; auto p = occ2ng(s); bool vert_mapped = false; tree.GetFirstIntersecting( p, p, [&](size_t i ) { vmap[verts_me[i]] = s; vert_mapped = true; return true; }); if(!vert_mapped) return false; } return true; } void Identify(const TopoDS_Shape & me, const TopoDS_Shape & you, string name, Identifications::ID_TYPE type, std::optional> opt_trafo) { Transformation<3> trafo; if(opt_trafo) { trafo = occ2ng(*opt_trafo); } else { auto v = occ2ng(Center(you)) - occ2ng(Center(me)); trafo = Transformation<3>(v); } ListOfShapes list_me, list_you; list_me.push_back(me); list_you.push_back(you); Identify(list_me, list_you, name, type, trafo); } void Identify(const ListOfShapes & me, const ListOfShapes & you, string name, Identifications::ID_TYPE type, Transformation<3> trafo) { ListOfShapes id_me; ListOfShapes id_you; if(auto faces_me = me.Faces(); faces_me.size()>0) { id_me = faces_me; id_you = you.Faces(); } else if(auto edges_me = me.Edges(); edges_me.size()>0) { id_me = edges_me; id_you = you.Edges(); } else { id_me = me.Vertices(); id_you = you.Vertices(); } for(auto shape_me : id_me) for(auto shape_you : id_you) { if(!IsMappedShape(trafo, shape_me, shape_you)) continue; OCCGeometry::identifications[shape_me].push_back (OCCIdentification { shape_me, shape_you, trafo, name, type }); } } void OCCParameters :: Print(ostream & ost) const { ost << "OCC Parameters:" << endl << "minimum edge length: " << resthminedgelenenable << ", min len = " << resthminedgelen << endl; } DLL_HEADER extern OCCParameters occparam; OCCParameters occparam; // int OCCGeometry :: GenerateMesh (shared_ptr & mesh, MeshingParameters & mparam) // { // return OCCGenerateMesh (*this, mesh, mparam, occparam); // } static RegisterClassForArchive regnggeo; namespace step_utils { void LoadProperties(const TopoDS_Shape & shape, const STEPCAFControl_Reader & reader, const Handle(TDocStd_Document) step_doc) { static Timer t("step_utils::LoadProperties"); RegionTimer rt(t); auto workSession = reader.Reader().WS(); auto model = workSession->Model(); auto transferReader = workSession->TransferReader(); auto transProc = transferReader->TransientProcess(); auto shapeTool = XCAFDoc_DocumentTool::ShapeTool(step_doc->Main()); // load colors for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE }) for (TopExp_Explorer e(shape, typ); e.More(); e.Next()) { TDF_Label label; shapeTool->Search(e.Current(), label); if(label.IsNull()) continue; XCAFPrs_IndexedDataMapOfShapeStyle set; TopLoc_Location loc; XCAFPrs::CollectStyleSettings(label, loc, set); XCAFPrs_Style aStyle; set.FindFromKey(e.Current(), aStyle); auto & prop = OCCGeometry::global_shape_properties[e.Current()]; if(aStyle.IsSetColorSurf()) prop.col = step_utils::ReadColor(aStyle.GetColorSurfRGBA()); } // load names Standard_Integer nb = model->NbEntities(); for (Standard_Integer i = 1; i <= nb; i++) { Handle(Standard_Transient) entity = model->Value(i); auto item = Handle(StepRepr_RepresentationItem)::DownCast(entity); if(item.IsNull()) continue; TopoDS_Shape shape = TransferBRep::ShapeResult(transProc->Find(item)); string name = item->Name()->ToCString(); if (!transProc->IsBound(item)) continue; OCCGeometry::global_shape_properties[shape].name = name; } // load custom data (maxh etc.) for (Standard_Integer i = 1; i <= nb; i++) { Handle(Standard_Transient) entity = model->Value(i); auto item = Handle(StepRepr_CompoundRepresentationItem)::DownCast(entity); if(item.IsNull()) continue; auto shape_item = item->ItemElementValue(1); TopoDS_Shape shape = TransferBRep::ShapeResult(transProc->Find(shape_item)); string name = item->Name()->ToCString(); if(name == "netgen_geometry_identification") ReadIdentifications(item, transProc); if(name != "netgen_geometry_properties") continue; auto & prop = OCCGeometry::global_shape_properties[shape]; auto nprops = item->NbItemElement(); for(auto i : Range(2, nprops+1)) { auto prop_item = item->ItemElementValue(i); string prop_name = prop_item->Name()->ToCString(); if(prop_name=="maxh") prop.maxh = Handle(StepRepr_ValueRepresentationItem)::DownCast(prop_item) ->ValueComponentMember()->Real(); if(prop_name=="hpref") prop.hpref = Handle(StepRepr_ValueRepresentationItem)::DownCast(prop_item) ->ValueComponentMember()->Real(); } } } void WriteProperties(const Handle(Interface_InterfaceModel) model, const Handle(Transfer_FinderProcess) finder, const TopoDS_Shape & shape) { static const ShapeProperties default_props; Handle(StepRepr_RepresentationItem) item = STEPConstruct::FindEntity(finder, shape); if(!item) return; auto prop = OCCGeometry::global_shape_properties[shape]; if(auto n = prop.name) item->SetName(MakeName(*n)); Array props; props.Append(item); if(auto maxh = prop.maxh; maxh != default_props.maxh) props.Append( MakeReal(maxh, "maxh") ); if(auto hpref = prop.hpref; hpref != default_props.hpref) props.Append( MakeReal(hpref, "hpref") ); if(props.Size()>1) { for(auto & item : props.Range(1, props.Size())) model->AddEntity(item); auto compound = MakeCompound(props, "netgen_geometry_properties"); model->AddEntity(compound); } WriteIdentifications(model, shape, finder); } void WriteIdentifications(const Handle(Interface_InterfaceModel) model, const TopoDS_Shape & shape, const Handle(Transfer_FinderProcess) finder) { Handle(StepRepr_RepresentationItem) item = STEPConstruct::FindEntity(finder, shape); auto & identifications = OCCGeometry::identifications[shape]; if(identifications.size()==0) return; auto n = identifications.size(); Array ident_items; ident_items.Append(item); for(auto & ident : identifications) { Array items; // items.Append(STEPConstruct::FindEntity(finder, ident.other)); // TODO! auto & m = ident.trafo.GetMatrix(); for(auto i : Range(9)) items.Append(MakeReal(m(i))); auto & v = ident.trafo.GetVector(); for(auto i : Range(3)) items.Append(MakeReal(v(i))); for(auto & item : items.Range(1,items.Size())) model->AddEntity(item); ident_items.Append(MakeCompound(items, ident.name)); } for(auto & item : ident_items.Range(1,ident_items.Size())) model->AddEntity(item); auto comp = MakeCompound(ident_items, "netgen_geometry_identification"); model->AddEntity(comp); } void ReadIdentifications(Handle(StepRepr_RepresentationItem) item, Handle(Transfer_TransientProcess) transProc) { auto idents = Handle(StepRepr_CompoundRepresentationItem)::DownCast(item); auto n = idents->NbItemElement(); std::vector result; auto shape_origin = TransferBRep::ShapeResult(transProc->Find(idents->ItemElementValue(1))); for(auto i : Range(2,n+1)) { auto id_item = Handle(StepRepr_CompoundRepresentationItem)::DownCast(idents->ItemElementValue(i)); OCCIdentification ident; ident.name = id_item->Name()->ToCString(); // ident.other = TransferBRep::ShapeResult(transProc->Find(id_item->ItemElementValue(1))); /TODO! auto & m = ident.trafo.GetMatrix(); for(auto i : Range(9)) m(i) = ReadReal(id_item->ItemElementValue(3+i)); auto & v = ident.trafo.GetVector(); for(auto i : Range(3)) v(i) = ReadReal(id_item->ItemElementValue(12+i)); result.push_back(ident); } OCCGeometry::identifications[shape_origin] = result; } void WriteSTEP(const TopoDS_Shape & shape, const filesystem::path & filename) { Interface_Static::SetCVal("write.step.schema", "AP242IS"); Interface_Static::SetIVal("write.step.assembly",1); Handle(XCAFApp_Application) app = XCAFApp_Application::GetApplication(); Handle(TDocStd_Document) doc; app->NewDocument("STEP-XCAF", doc); Handle(XCAFDoc_ShapeTool) shapetool = XCAFDoc_DocumentTool::ShapeTool(doc->Main()); Handle(XCAFDoc_ColorTool) colortool = XCAFDoc_DocumentTool::ColorTool(doc->Main()); TDF_Label label = shapetool->NewShape(); shapetool->SetShape(label, shape); Handle(XSControl_WorkSession) session = new XSControl_WorkSession; STEPCAFControl_Writer writer(session); const Handle(Interface_InterfaceModel) model = session->Model(); // Set colors (BEFORE transferring shape into step data structures) for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE }) for (TopExp_Explorer e(shape, typ); e.More(); e.Next()) { auto prop = OCCGeometry::global_shape_properties[e.Current()]; if(auto col = prop.col) colortool->SetColor(e.Current(), step_utils::MakeColor(*col), XCAFDoc_ColorGen); } // Transfer shape into step data structures -> now we can manipulate/add step representation items writer.Transfer(doc, STEPControl_AsIs); // Write all other properties auto finder = session->TransferWriter()->FinderProcess(); for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE }) for (TopExp_Explorer e(shape, typ); e.More(); e.Next()) WriteProperties(model, finder, e.Current()); writer.Write(filename.string().c_str()); } } // namespace step_utils } #endif