netgen/libsrc/occ/occgeom.cpp

#ifdef OCCGEOMETRY

#include <mystdlib.h>
#include <occgeom.hpp>  
#include "ShapeAnalysis_ShapeTolerance.hxx"
#include "ShapeAnalysis_ShapeContents.hxx"
#include "ShapeAnalysis_CheckSmallFace.hxx"
#include "ShapeAnalysis_DataMapOfShapeListOfReal.hxx"
#include "ShapeAnalysis_Surface.hxx"
#include "BRepAlgoAPI_Fuse.hxx"
#include "BRepCheck_Analyzer.hxx"
#include "BRepLib.hxx"
#include "ShapeBuild_ReShape.hxx"
#include "ShapeFix.hxx"
#include "ShapeFix_FixSmallFace.hxx"
#include "Partition_Spliter.hxx"
//#include "VrmlAPI.hxx"
//#include "StlAPI.hxx"


namespace netgen
{

  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 << "Highest entry in topology hierarchy: " << endl;
    if (count)
      cout << count << " composite solid(s)" << endl;
    else
      if (geom->somap.Extent())
	cout << geom->somap.Extent() << " solid(s)" << endl;
      else
	if (geom->shmap.Extent())
	  cout << geom->shmap.Extent() << " shells(s)" << endl;
	else
	  if (geom->fmap.Extent())
	    cout << geom->fmap.Extent() << " face(s)" << endl;
	  else
	    if (geom->wmap.Extent())
	      cout << geom->wmap.Extent() << " wire(s)" << endl;
	    else
	      if (geom->emap.Extent())
		cout << geom->emap.Extent() << " edge(s)" << endl;
	      else
		if (geom->vmap.Extent())
		  cout << geom->vmap.Extent() << " vertices(s)" << endl;
		else
		  cout << "no entities" << endl;

  }



  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, false);
	}
      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());
	    	    
	    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)" <<endl;
		else if(sff->Status(ShapeExtend_DONE2))
		  cout << "(orientation of wires fixed)" <<endl;
		else if(sff->Status(ShapeExtend_DONE3))
		  cout << "(missing seam added)" <<endl;
		else if(sff->Status(ShapeExtend_DONE4))
		  cout << "(small area wire removed)" <<endl;
		else if(sff->Status(ShapeExtend_DONE5))
		  cout << "(natural bounds added)" <<endl;
		TopoDS_Face newface = sff->Face();
		
		rebuild->Replace(face, newface, Standard_False);
	      }

	    //delete sff; sff = NULL;
	  }
	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, false);
	}
      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, Standard_False);
		  }

		//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, false);
		    }
		}
	    }
	  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, false);
	    }
	  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, false);
	}
      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, Standard_False);
		    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 << "Totol surface area : " << newsurfacecont << " (" << surfacecont << ")" << endl;
    cout << endl;

//     cout << "Write: " << flush;
//     char answer;
//     cin >> answer;
//     if(answer == 'y')
//       {
// 	cout << "Writing VRML" << endl;
// 	VrmlAPI::Write(shape,"test2.vrml");
// 	cout << "Writing STL" << endl;
// 	StlAPI::Write(shape,"test2.stl");
//       }

  }
 



  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().Composed (exp0.Current().Orientation()));
		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().Composed(shell.Orientation()));
			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().Composed(face.Orientation()));
				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().Composed(wire.Orientation()));
					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);
	 // for (exp1.Init(exp0.Current(), TopAbs_SHELL, TopAbs_SOLID);
	 exp1.More(); exp1.Next())
      {
	//      TopoDS_Shape shell = exp1.Current().Composed (exp0.Current().Orientation());
	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());
		//	      TopoDS_Face face = TopoDS::Face(exp2.Current().Composed(shell.Orientation()));
		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().Composed(face.Orientation()));
			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().Composed(wire.Orientation()));
				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().Composed(edge.Orientation()));
					TopoDS_Vertex vertex = TopoDS::Vertex(exp5.Current());
					if (vmap.FindIndex(vertex) < 1)
					  vmap.Add (vertex);
				      }
				  }
			      }
			  }
		      }
		  }
	      }
	  }
      }
  
  
    // Free Faces
  
    for (exp2.Init(shape, TopAbs_FACE, TopAbs_SHELL);
	 exp2.More(); exp2.Next())
      {
	//      TopoDS_Face face = TopoDS::Face(exp2.Current().Composed(shape.Orientation()));
	TopoDS_Face face = TopoDS::Face(exp2.Current());
	if (fmap.FindIndex(face) < 1)
	  {
	    fmap.Add (face);
	  
	    for (exp3.Init(exp2.Current(), TopAbs_WIRE);
		 exp3.More(); exp3.Next())
	      {
		//	      TopoDS_Wire wire = TopoDS::Wire (exp3.Current().Composed(face.Orientation()));
		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().Composed(wire.Orientation()));
			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().Composed(edge.Orientation()));
				TopoDS_Vertex vertex = TopoDS::Vertex(exp5.Current());
				if (vmap.FindIndex(vertex) < 1)
				  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);
	      }
	  }
      }


    // 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);
      }



  
    facemeshstatus.SetSize (fmap.Extent());
    facemeshstatus = 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;
  }



  void OCCGeometry :: SewFaces ()
  {
    (*testout) << "Trying to sew faces ..." << endl;
    cout << "Trying to sew faces ..." << flush;

    BRepOffsetAPI_Sewing sewedObj(1);
    //  BRepOffsetAPI_Sewing sewedObj(healingtolerance);

    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";
  
    /*
      ShapeUpgrade_ShellSewing sewing;
      TopoDS_Shape sh = sewing.ApplySewing (shape);
      shape = sh;
    */
  }





  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->Apply(shape);
	    rebuild->Replace(solid, newsolid, Standard_False);
	    //	  TopoDS_Shape newshape = rebuild->Apply(shape);
	  
	    TopoDS_Shape newshape = rebuild->Apply(shape, TopAbs_SHAPE, 1);
	    shape = newshape;
	  }

	//delete sfs; sfs = NULL;
      
	cout << " done" << endl;
      }
    else
      cout << " not possible" << endl;
  }


  void OCCGeometry :: BuildVisualizationMesh ()
  {

    cout << "Preparing visualization (deflection = " << vispar.occdeflection << ") ... " << flush;


    BRepTools::Clean (shape);
    //WriteOCC_STL("test.stl");
    BRepMesh_IncrementalMesh::BRepMesh_IncrementalMesh (shape, vispar.occdeflection, true);
    cout << "done" << endl;



    Bnd_Box bb;
    BRepBndLib::Add (shape, bb);
  
    double x1,y1,z1,x2,y2,z2;
    bb.Get (x1,y1,z1,x2,y2,z2);
    Point<3> p1 = Point<3> (x1,y1,z1);
    Point<3> p2 = Point<3> (x2,y2,z2);
  
    (*testout) << "Bounding Box = [" << p1 << " - " << p2 << "]" << endl;
    boundingbox = Box<3> (p1,p2);
    SetCenter();

  
  }


  void OCCGeometry :: Project (int surfi, Point<3> & p) const
  {
    static int cnt = 0;
    if (++cnt % 1000 == 0) cout << "Project cnt = " << cnt << endl;
    
    gp_Pnt pnt(p(0), p(1), p(2));

    //(*testout) << "before " << pnt.X() << " "<< pnt.Y() << " "<< pnt.Z() << " " << endl;


    /*
    GeomAPI_ProjectPointOnSurf proj(pnt, BRep_Tool::Surface(TopoDS::Face(fmap(surfi))));
    if (proj.NbPoints() == 0)
      {
	cout << "Projection fails" << endl;
      }
    else
      {
	pnt = proj.NearestPoint();
	//(*testout) << "after " << pnt.X() << " "<< pnt.Y() << " "<< pnt.Z() << " " << endl;

	p = Point<3> (pnt.X(), pnt.Y(), pnt.Z());
      }
    */

    
    double u,v;
    Handle( Geom_Surface ) thesurf = BRep_Tool::Surface(TopoDS::Face(fmap(surfi)));
    Handle( ShapeAnalysis_Surface ) su = new ShapeAnalysis_Surface( thesurf );
    gp_Pnt2d suval = su->ValueOfUV ( pnt, BRep_Tool::Tolerance( TopoDS::Face(fmap(surfi)) ) );
    suval.Coord( u, v);
    pnt = thesurf->Value( u, v );

    
    p = Point<3> (pnt.X(), pnt.Y(), pnt.Z());
    
  }


  bool OCCGeometry :: FastProject (int surfi, Point<3> & ap, double& u, double& v) const
  {
    gp_Pnt p(ap(0), ap(1), ap(2));
  
    Handle(Geom_Surface) surface = BRep_Tool::Surface(TopoDS::Face(fmap(surfi)));
  
    gp_Pnt x = surface->Value (u,v);
  
    if (p.SquareDistance(x) <= sqr(PROJECTION_TOLERANCE)) return true;
  
    gp_Vec du, dv;
  
    surface->D1(u,v,x,du,dv);
  
    int count = 0;
  
    gp_Pnt xold;
    gp_Vec n;
    double det, lambda, mu;
  
    do {
      count++;
  
      n = du^dv;
      
      det = Det3 (n.X(), du.X(), dv.X(),
		  n.Y(), du.Y(), dv.Y(),
		  n.Z(), du.Z(), dv.Z());
  
      if (det < 1e-15) return false; 
  
      lambda = Det3 (n.X(), p.X()-x.X(), dv.X(),
		     n.Y(), p.Y()-x.Y(), dv.Y(),
		     n.Z(), p.Z()-x.Z(), dv.Z())/det;
  
      mu     = Det3 (n.X(), du.X(), p.X()-x.X(),
		     n.Y(), du.Y(), p.Y()-x.Y(),
		     n.Z(), du.Z(), p.Z()-x.Z())/det;
    
      u += lambda;
      v += mu;
  
      xold = x;
      surface->D1(u,v,x,du,dv);
  
    } while (xold.SquareDistance(x) > sqr(PROJECTION_TOLERANCE) && count < 50);

    //    (*testout) << "FastProject count: " << count << endl;
  
    if (count == 50) return false;
  
    ap = Point<3> (x.X(), x.Y(), x.Z());
  
    return true;
  }


   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;
   }
  

  OCCGeometry * LoadOCC_IGES (const char * filename)
  {
    OCCGeometry * occgeo;
    occgeo = new OCCGeometry;
  
    IGESControl_Reader reader;
  
    Standard_Integer stat = reader.ReadFile((char*)filename);

    // pre OCC52-times:
    // Standard_Integer stat = reader.LoadFile((char*)filename);
    // reader.Clear();
      
  
    reader.TransferRoots(); // Tranlate IGES -> OCC

    // pre OCC52-times:
    // reader.TransferRoots(Standard_False); // Tranlate IGES -> OCC

    //reader.PrintTransferInfo(IFSelect_FailAndWarn,IFSelect_ListByItem);

    occgeo->shape = reader.OneShape();
    occgeo->changed = 1;
    occgeo->BuildFMap();
  
    //
    //   Handle(ShapeFix_Shape) sfs = new ShapeFix_Shape;
    //   sfs->Init(occgeo->shape);
    //   sfs->Perform();
    //   Handle(ShapeFix_Wireframe) sfwf = new ShapeFix_Wireframe(occgeo->shape);
    //   //sfwf->DropSmallEdgesMode() = Standard_True;
    //   sfwf->FixSmallEdges();
    //   sfwf->FixWireGaps();

    //


    occgeo->BuildVisualizationMesh();
    PrintContents (occgeo);

    return occgeo;
  }

  OCCGeometry * LoadOCC_STEP (const char * filename)
  {
    OCCGeometry * occgeo;
    occgeo = new OCCGeometry;
  
    STEPControl_Reader reader;
    Standard_Integer stat = reader.ReadFile((char*)filename);
    Standard_Integer nb = reader.NbRootsForTransfer();
    reader.TransferRoots (); // Tranlate STEP -> OCC



    occgeo->shape = reader.OneShape();
    occgeo->changed = 1;
    occgeo->BuildFMap();
    //
    //Handle(ShapeFix_Shape) sfs = new ShapeFix_Shape;
    //sfs->Init(occgeo->shape);
    //sfs->Perform();
    //Handle(ShapeFix_Wireframe) sfwf = new ShapeFix_Wireframe(occgeo->shape);
    //sfwf->FixSmallEdges();
    //sfwf->FixWireGaps();



    /*
      // JS
    TopoDS_Compound aRes;
    BRep_Builder aBuilder;
    aBuilder.MakeCompound (aRes);

    for (TopExp_Explorer exp(occgeo->shape, TopAbs_SOLID); exp.More(); exp.Next())
      {
	aBuilder.Add (aRes, exp.Current());
	cout << "solid" << endl;
      }

    for (TopExp_Explorer exp(aRes, TopAbs_SOLID); exp.More(); exp.Next())
      {
	cout << "compound has shapes solid" << endl;
      }
    occgeo->shape = aRes;
    occgeo->changed = 1;
    occgeo->BuildFMap();
    */


    //
    occgeo->BuildVisualizationMesh();
    PrintContents (occgeo);

    return occgeo;
  } 

  OCCGeometry * LoadOCC_BREP (const char * filename)
  {
    OCCGeometry * occgeo;
    occgeo = new OCCGeometry;
  
    BRep_Builder aBuilder;
    Standard_Boolean result = BRepTools::Read(occgeo->shape, const_cast<char*> (filename),aBuilder);
    
    
//     cout << "Writing VRML" << endl;
//     VrmlAPI::Write(occgeo->shape,"test.vrml");
//     cout << "Writing STL" << endl;
//     StlAPI::Write(occgeo->shape,"test.stl");


    occgeo->changed = 1;
    occgeo->BuildFMap();
    occgeo->BuildVisualizationMesh();
    PrintContents (occgeo);

    return occgeo;
  } 

  char * shapesname[] =
    {" ", "CompSolids", "Solids", "Shells",

     "Faces", "Wires", "Edges", "Vertices"};

  char * shapename[] =
    {" ", "CompSolid", "Solid", "Shell",
     "Face", "Wire", "Edge", "Vertex"};

  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;

    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;
	  }
      
	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 streched 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;
    ARRAY <double> edgeLengths;
    ARRAY <int> 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();
	/*
	  int j;
	  for (j = i+1; j <= emap.Extent(); j++)
	  {
	  TopoDS_Edge edge2 = TopoDS::Edge (emap(j));

	  if (csm.CheckStripEdges(edge1, edge2, csm.Tolerance(), dmax))
	  {
	  if (!edgessamebutnotidentified++)
	  str << "EdgesSameButNotIdentified {Edges same but not identified} ";

	  cnt++;
	  (*testout) << "Edge " << i << " and edge " << j
	  << " are on one strip (same but not identified)" << endl;
	  str << "EdgesSameButNotIdentified/Edge" << cnt << " ";
	  str << "{Edge " << i << " and Edge " << j << "} ";
	  }
	  }
	*/
      }

    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;

    /*
      for (i = 1; i <= shmap.Extent(); i++)
      {
      TopoDS_Shell shell = TopoDS::Shell (shmap(i));
      if (!shell.Closed()) 
      cout << "Shell " << i << " is not closed" << endl;
      if (shell.Infinite()) 
      cout << "Shell " << i << " is infinite" << endl;

      BRepCheck_Analyzer ba(shell);
      if (!ba.IsValid ())
      cout << "Shell " << i << " is not valid" << endl;
      }

      for (i = 1; i <= somap.Extent(); i++)
      {
      TopoDS_Solid solid = TopoDS::Solid (somap(i));
      if (!solid.Closed()) 
      cout << "Solid " << i << " is not closed" << endl;
      if (solid.Infinite()) 
      cout << "Solid " << i << " is infinite" << endl;

      BRepCheck_Analyzer ba(solid);
      if (!ba.IsValid ())
      cout << "Solid " << i << " is not valid" << 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;
  }

}


#endif