void BRepOffsetAPI_MakeOffsetFix::MakeWire(TopoDS_Shape& wire)
{
    // get the edges of the wire and check which of the stored edges
    // serve as input of the wire
    TopTools_MapOfShape aMap;
    TopExp_Explorer xp(wire, TopAbs_EDGE);
    while (xp.More()) {
        aMap.Add(xp.Current());
        xp.Next();
    }

    std::list<TopoDS_Edge> edgeList;
    for (auto itLoc : myLocations) {
        const TopTools_ListOfShape& newShapes = mkOffset.Generated(itLoc.first);
        for (TopTools_ListIteratorOfListOfShape it(newShapes); it.More(); it.Next()) {
            TopoDS_Shape newShape = it.Value();

            if (aMap.Contains(newShape)) {
                newShape.Move(itLoc.second);
                edgeList.push_back(TopoDS::Edge(newShape));
            }
        }
    }

    if (!edgeList.empty()) {
        BRepBuilderAPI_MakeWire mkWire;
        mkWire.Add(edgeList.front());
        edgeList.pop_front();
        wire = mkWire.Wire();

        bool found = false;
        do {
            found = false;
            for (std::list<TopoDS_Edge>::iterator pE = edgeList.begin(); pE != edgeList.end(); ++pE) {
                mkWire.Add(*pE);
                if (mkWire.Error() != BRepBuilderAPI_DisconnectedWire) {
                    // edge added ==> remove it from list
                    found = true;
                    edgeList.erase(pE);
                    wire = mkWire.Wire();
                    break;
                }
            }
        }
        while (found);
    }
}
Ejemplo n.º 2
0
//=======================================================================
// function: FillSameDomainFaces
// purpose:
//=======================================================================
void GEOMAlgo_Builder::FillSameDomainFaces()
{
  Standard_Boolean bIsSDF, bHasImage1, bHasImage2, bForward;
  Standard_Integer i, j, aNbFF, nF1, nF2, aNbPBInOn, aNbC, aNbSE;
  Standard_Integer aNbF1, aNbF2, i2s, aNbSD;
  TopTools_MapOfShape aMFence;
  TopTools_ListOfShape aLX1, aLX2;
  TopTools_ListIteratorOfListOfShape aItF1, aItF2;
  NMTTools_ListOfCoupleOfShape aLCS;
  //
  const NMTDS_ShapesDataStructure& aDS=*myPaveFiller->DS();
  NMTTools_PaveFiller* pPF=myPaveFiller;
  NMTDS_InterfPool* pIP=pPF->IP();
  BOPTools_CArray1OfSSInterference& aFFs=pIP->SSInterferences();
  const Handle(IntTools_Context)& aCtx= pPF->Context();
  //
  //
  //mySameDomainShapes.Clear();
  //
  // 1. For each FF find among images of faces
  //    all pairs of same domain faces (SDF) [=> aLCS]
  aNbFF=aFFs.Extent();
  for (i=1; i<=aNbFF; ++i) {
    BOPTools_SSInterference& aFF=aFFs(i);
    aFF.Indices(nF1, nF2);
    //
    const TopoDS_Face& aF1=TopoDS::Face(aDS.Shape(nF1));
    const TopoDS_Face& aF2=TopoDS::Face(aDS.Shape(nF2));
    //
    // if there are no in/on 2D split parts the faces nF1, nF2
    // can not be SDF
    const BOPTools_ListOfPaveBlock& aLPBInOn=aFF.PaveBlocks();
    aNbPBInOn=aLPBInOn.Extent();
    //
    //===
    const TColStd_ListOfInteger& aLSE=aFF.SharedEdges();
    aNbSE=aLSE.Extent();
    if (!aNbPBInOn && !aNbSE) {
      continue;
    }
    //===
    //
    // if there is at least one section edge between faces nF1, nF2
    // they can not be SDF
    BOPTools_SequenceOfCurves& aSC=aFF.Curves();
    aNbC=aSC.Length();
    if (aNbC) {
      continue;
    }
    //
    // the faces are suspected to be SDF.
    // Try to find SDF among images of nF1, nF2
    aMFence.Clear();
    //
    //--------------------------------------------------------
    bHasImage1=mySplitFaces.HasImage(aF1);
    bHasImage2=mySplitFaces.HasImage(aF2);
    //
    aLX1.Clear();
    if (!bHasImage1) {
      aLX1.Append(aF1);
    }
    //
    aLX2.Clear();
    if (!bHasImage2) {
      aLX2.Append(aF2);
    }
    //
    const TopTools_ListOfShape& aLF1r=(bHasImage1)? mySplitFaces.Image(aF1) : aLX1;
    const TopTools_ListOfShape& aLF2r=(bHasImage2)? mySplitFaces.Image(aF2) : aLX2;
    //
    TopTools_DataMapOfIntegerShape aMIS;
    TColStd_ListIteratorOfListOfInteger aItLI;
    NMTDS_BoxBndTreeSelector aSelector;
    NMTDS_BoxBndTree aBBTree;
    NCollection_UBTreeFiller <Standard_Integer, Bnd_Box> aTreeFiller(aBBTree);
    //
    aNbF1=aLF1r.Extent();
    aNbF2=aLF2r.Extent();
    bForward=(aNbF1<aNbF2);
    //
    const TopTools_ListOfShape& aLF1=bForward ? aLF1r : aLF2r;
    const TopTools_ListOfShape& aLF2=bForward ? aLF2r : aLF1r;
    //
    // 1. aTreeFiller
    aItF2.Initialize(aLF2);
    for (i2s=1; aItF2.More(); aItF2.Next(), ++i2s) {
      Bnd_Box aBoxF2s;
      //
      const TopoDS_Face& aF2s=*((TopoDS_Face*)(&aItF2.Value()));
      //
      BRepBndLib::Add(aF2s, aBoxF2s);
      //
      aMIS.Bind(i2s, aF2s);
      //
      aTreeFiller.Add(i2s, aBoxF2s);
    }//for (i2s=1; aItF2.More(); aItF2.Next(), ++i2s) {
    //
    aTreeFiller.Fill();
    //
    // 2.
    aItF1.Initialize(aLF1);
    for (j=1; aItF1.More(); aItF1.Next(), ++j) {
      Bnd_Box aBoxF1x;
      //
      const TopoDS_Face& aF1x=*((TopoDS_Face*)(&aItF1.Value()));
      //
      BRepBndLib::Add(aF1x, aBoxF1x);
      //
      aSelector.Clear();
      aSelector.SetBox(aBoxF1x);
      aNbSD=aBBTree.Select(aSelector);
      if (!aNbSD) {
        continue;
      }
      //
      const TColStd_ListOfInteger& aLI=aSelector.Indices();
      aItLI.Initialize(aLI);
      for (; aItLI.More(); aItLI.Next()) {
        i2s=aItLI.Value();
        const TopoDS_Face& aF2y=*((TopoDS_Face*)(&aMIS.Find(i2s)));
        //
        bIsSDF=NMTTools_Tools::AreFacesSameDomain(aF1x, aF2y, aCtx);
        if (bIsSDF) {
          if (aMFence.Contains(aF1x) || aMFence.Contains(aF2y)) {
            continue;
          }
          aMFence.Add(aF1x);
          aMFence.Add(aF2y);
          //
          NMTTools_CoupleOfShape aCS;
          //
          aCS.SetShape1(aF1x);
          aCS.SetShape2(aF2y);
          aLCS.Append(aCS);
          //
          if (bForward) {
            if (aF1x==aF1) {
              if (!mySplitFaces.HasImage(aF1)) {
                mySplitFaces.Bind(aF1, aF1);
              }
            }
            if (aF2y==aF2) {
              if (!mySplitFaces.HasImage(aF2)) {
                mySplitFaces.Bind(aF2, aF2);
              }
            }
          }
          else {
            if (aF1x==aF2) {
              if (!mySplitFaces.HasImage(aF2)) {
                mySplitFaces.Bind(aF2, aF2);
              }
            }
            if (aF2y==aF1) {
              if (!mySplitFaces.HasImage(aF1)) {
                mySplitFaces.Bind(aF1, aF1);
              }
            }
          }
          //
          break;
        }//if (bIsSDF) {
      }//for (; aItLI.More(); aItLI.Next()) {
    }//for (; aItF1.More(); aItF1.Next()) {
  }//for (i=1; i<=aNbFF; ++i)
  //-------------------------------------------------------------
  aNbC=aLCS.Extent();
  if (!aNbC) {
    return;
  }
  //
  // 2. Find Chains
  NMTTools_IndexedDataMapOfShapeIndexedMapOfShape aMC;
  //
  NMTTools_Tools::FindChains(aLCS, aMC);
  //
  Standard_Boolean bIsImage;
  Standard_Integer aIx, aIxMin, aNbMSDF, k, aNbMFj;
  TopoDS_Shape aFOld, aFSDmin;
  TopTools_IndexedMapOfShape aMFj;
  TopTools_DataMapOfShapeInteger aDMSI;
  //
  aItF1.Initialize(myShapes);
  for (j=1; aItF1.More(); aItF1.Next(), ++j) {
    const TopoDS_Shape& aSj=aItF1.Value();
    aMFj.Clear();
    TopExp::MapShapes(aSj, TopAbs_FACE, aMFj);
    aNbMFj=aMFj.Extent();
    for (k=1; k<=aNbMFj; ++k) {
      const TopoDS_Shape& aFk=aMFj(k);
      if (!aDMSI.IsBound(aFk)) {
	aDMSI.Bind(aFk, j);
      }
    }
  }
  //
  // 3. Fill the map of SDF mySameDomainFaces
  aNbC=aMC.Extent();
  for (i=1; i<=aNbC; ++i) {
   // const TopoDS_Shape& aF=aMC.FindKey(i);
    const TopTools_IndexedMapOfShape& aMSDF=aMC(i);
    //
    aNbMSDF=aMSDF.Extent();
    for (j=1; j<=aNbMSDF; ++j) {
      const TopoDS_Shape& aFSD=aMSDF(j);
      bIsImage=mySplitFaces.IsImage(aFSD);
      aFOld=aFSD;
      if (bIsImage) {
	aFOld=mySplitFaces.ImageFrom(aFSD);
      }
      //
      aIx=aDMSI.Find(aFOld);
      if (j==1) {
	aIxMin=aIx;
	aFSDmin=aFSD;
	continue;
      }
      else {
	if (aIx<aIxMin) {
	  aIxMin=aIx;
	  aFSDmin=aFSD;
	}
      }
    }
    //
    for (j=1; j<=aNbMSDF; ++j) {
      const TopoDS_Shape& aFSD=aMSDF(j);
      mySameDomainShapes.Add(aFSD, aFSDmin);
    }
  }
  //
}
Ejemplo n.º 3
0
bool NETGENPlugin_NETGEN_3D::Evaluate(SMESH_Mesh& aMesh,
                                      const TopoDS_Shape& aShape,
                                      MapShapeNbElems& aResMap)
{
    int nbtri = 0, nbqua = 0;
    double fullArea = 0.0;
    for (TopExp_Explorer exp(aShape, TopAbs_FACE); exp.More(); exp.Next()) {
        TopoDS_Face F = TopoDS::Face( exp.Current() );
        SMESH_subMesh *sm = aMesh.GetSubMesh(F);
        MapShapeNbElemsItr anIt = aResMap.find(sm);
        if( anIt==aResMap.end() ) {
            SMESH_ComputeErrorPtr& smError = sm->GetComputeError();
            smError.reset( new SMESH_ComputeError(COMPERR_ALGO_FAILED,"Submesh can not be evaluated",this));
            return false;
        }
        std::vector<int> aVec = (*anIt).second;
        nbtri += Max(aVec[SMDSEntity_Triangle],aVec[SMDSEntity_Quad_Triangle]);
        nbqua += Max(aVec[SMDSEntity_Quadrangle],aVec[SMDSEntity_Quad_Quadrangle]);
        GProp_GProps G;
        BRepGProp::SurfaceProperties(F,G);
        double anArea = G.Mass();
        fullArea += anArea;
    }

    // collect info from edges
    int nb0d_e = 0, nb1d_e = 0;
    bool IsQuadratic = false;
    bool IsFirst = true;
    TopTools_MapOfShape tmpMap;
    for (TopExp_Explorer exp(aShape, TopAbs_EDGE); exp.More(); exp.Next()) {
        TopoDS_Edge E = TopoDS::Edge(exp.Current());
        if( tmpMap.Contains(E) )
            continue;
        tmpMap.Add(E);
        SMESH_subMesh *aSubMesh = aMesh.GetSubMesh(exp.Current());
        MapShapeNbElemsItr anIt = aResMap.find(aSubMesh);
        if( anIt==aResMap.end() ) {
            SMESH_ComputeErrorPtr& smError = aSubMesh->GetComputeError();
            smError.reset( new SMESH_ComputeError(COMPERR_ALGO_FAILED,
                                                  "Submesh can not be evaluated",this));
            return false;
        }
        std::vector<int> aVec = (*anIt).second;
        nb0d_e += aVec[SMDSEntity_Node];
        nb1d_e += Max(aVec[SMDSEntity_Edge],aVec[SMDSEntity_Quad_Edge]);
        if(IsFirst) {
            IsQuadratic = (aVec[SMDSEntity_Quad_Edge] > aVec[SMDSEntity_Edge]);
            IsFirst = false;
        }
    }
    tmpMap.Clear();

    double ELen_face = sqrt(2.* ( fullArea/(nbtri+nbqua*2) ) / sqrt(3.0) );
    double ELen_vol = pow( 72, 1/6. ) * pow( _maxElementVolume, 1/3. );
    double ELen = Min(ELen_vol,ELen_face*2);

    GProp_GProps G;
    BRepGProp::VolumeProperties(aShape,G);
    double aVolume = G.Mass();
    double tetrVol = 0.1179*ELen*ELen*ELen;
    double CoeffQuality = 0.9;
    int nbVols = (int)aVolume/tetrVol/CoeffQuality;
    int nb1d_f = (nbtri*3 + nbqua*4 - nb1d_e) / 2;
    int nb1d_in = (int) ( nbVols*6 - nb1d_e - nb1d_f ) / 5;
    std::vector<int> aVec(SMDSEntity_Last);
    for(int i=SMDSEntity_Node; i<SMDSEntity_Last; i++) aVec[i]=0;
    if( IsQuadratic ) {
        aVec[SMDSEntity_Node] = nb1d_in/6 + 1 + nb1d_in;
        aVec[SMDSEntity_Quad_Tetra] = nbVols - nbqua*2;
        aVec[SMDSEntity_Quad_Pyramid] = nbqua;
    }
    else {
        aVec[SMDSEntity_Node] = nb1d_in/6 + 1;
        aVec[SMDSEntity_Tetra] = nbVols - nbqua*2;
        aVec[SMDSEntity_Pyramid] = nbqua;
    }
    SMESH_subMesh *sm = aMesh.GetSubMesh(aShape);
    aResMap.insert(std::make_pair(sm,aVec));

    return true;
}
//=======================================================================
//function : Execute
//purpose  :
//=======================================================================
Standard_Integer GEOMImpl_ChamferDriver::Execute(TFunction_Logbook& log) const
{
  if (Label().IsNull()) return 0;
  Handle(GEOM_Function) aFunction = GEOM_Function::GetFunction(Label());

  GEOMImpl_IChamfer aCI (aFunction);
  Standard_Integer aType = aFunction->GetType();

  TopoDS_Shape aShape;

  Handle(GEOM_Function) aRefShape = aCI.GetShape();
  TopoDS_Shape aShapeBase = aRefShape->GetValue();

  // Check the shape type. It have to be shell
  // or solid, or compsolid, or compound of these shapes.
  if (!isGoodForChamfer(aShapeBase)) {
    StdFail_NotDone::Raise
      ("Wrong shape. Must be shell or solid, or compsolid or compound of these shapes");
  }

  BRepFilletAPI_MakeChamfer fill (aShapeBase);

  if (aType == CHAMFER_SHAPE_ALL) {
    // symmetric chamfer on all edges
    double aD = aCI.GetD();
    TopTools_IndexedDataMapOfShapeListOfShape M;
    GEOMImpl_Block6Explorer::MapShapesAndAncestors(aShapeBase, TopAbs_EDGE, TopAbs_FACE, M);
    for (int i = 1; i <= M.Extent(); i++) {
      TopoDS_Edge E = TopoDS::Edge(M.FindKey(i));
      TopoDS_Face F = TopoDS::Face(M.FindFromIndex(i).First());
      if (!BRepTools::IsReallyClosed(E, F) &&
          !BRep_Tool::Degenerated(E) &&
          M.FindFromIndex(i).Extent() == 2)
        fill.Add(aD, E, F);
    }
  }
  else if (aType == CHAMFER_SHAPE_EDGE || aType == CHAMFER_SHAPE_EDGE_AD) {
    // chamfer on edges, common to two faces, with D1 on the first face

    TopoDS_Shape aFace1, aFace2;
    if (GEOMImpl_ILocalOperations::GetSubShape(aShapeBase, aCI.GetFace1(), aFace1) &&
        GEOMImpl_ILocalOperations::GetSubShape(aShapeBase, aCI.GetFace2(), aFace2))
    {
      TopoDS_Face F = TopoDS::Face(aFace1);

      // fill map of edges of the second face
      TopTools_MapOfShape aMap;
      TopExp_Explorer Exp2 (aFace2, TopAbs_EDGE);
      for (; Exp2.More(); Exp2.Next()) {
        aMap.Add(Exp2.Current());
      }

      // find edges of the first face, common with the second face
      TopExp_Explorer Exp (aFace1, TopAbs_EDGE);
      for (; Exp.More(); Exp.Next()) {
        if (aMap.Contains(Exp.Current())) {
          TopoDS_Edge E = TopoDS::Edge(Exp.Current());
          if (!BRepTools::IsReallyClosed(E, F) && !BRep_Tool::Degenerated(E))
          {
            if ( aType == CHAMFER_SHAPE_EDGE )
            {
              double aD1 = aCI.GetD1();
              double aD2 = aCI.GetD2();
              fill.Add(aD1, aD2, E, F);
            }
            else
            {
              double aD = aCI.GetD();
              double anAngle = aCI.GetAngle();
              if ( (anAngle > 0) && (anAngle < (M_PI/2.)) )
                fill.AddDA(aD, anAngle, E, F);
            }
          }
        }
      }
    }
  }
  else if (aType == CHAMFER_SHAPE_FACES || aType == CHAMFER_SHAPE_FACES_AD) {
    // chamfer on all edges of the selected faces, with D1 on the selected face
    // (on first selected face, if the edge belongs to two selected faces)

    int aLen = aCI.GetLength();
    int ind = 1;
    TopTools_MapOfShape aMap;
    TopTools_IndexedDataMapOfShapeListOfShape M;
    GEOMImpl_Block6Explorer::MapShapesAndAncestors(aShapeBase, TopAbs_EDGE, TopAbs_FACE, M);
    for (; ind <= aLen; ind++)
    {
      TopoDS_Shape aShapeFace;
      if (GEOMImpl_ILocalOperations::GetSubShape(aShapeBase, aCI.GetFace(ind), aShapeFace))
      {
        TopoDS_Face F = TopoDS::Face(aShapeFace);
        TopExp_Explorer Exp (F, TopAbs_EDGE);
        for (; Exp.More(); Exp.Next()) {
          if (!aMap.Contains(Exp.Current()))
          {
            TopoDS_Edge E = TopoDS::Edge(Exp.Current());
            if (!BRepTools::IsReallyClosed(E, F) &&
                !BRep_Tool::Degenerated(E) &&
                M.FindFromKey(E).Extent() == 2)
            {
              if (aType == CHAMFER_SHAPE_FACES)
              {
                double aD1 = aCI.GetD1();
                double aD2 = aCI.GetD2();
                fill.Add(aD1, aD2, E, F);
              }
              else
              {
                double aD = aCI.GetD();
                double anAngle = aCI.GetAngle();
                if ( (anAngle > 0) && (anAngle < (M_PI/2.)) )
                  fill.AddDA(aD, anAngle, E, F);
              }
            }
          }
        }
      }
    }
  }
  else if (aType == CHAMFER_SHAPE_EDGES || aType == CHAMFER_SHAPE_EDGES_AD)
  {
    // chamfer on selected edges with lenght param D1 & D2.

    int aLen = aCI.GetLength();
    int ind = 1;
    TopTools_MapOfShape aMap;
    TopTools_IndexedDataMapOfShapeListOfShape M;
    GEOMImpl_Block6Explorer::MapShapesAndAncestors(aShapeBase, TopAbs_EDGE, TopAbs_FACE, M);
    for (; ind <= aLen; ind++)
    {
      TopoDS_Shape aShapeEdge;
      if (GEOMImpl_ILocalOperations::GetSubShape(aShapeBase, aCI.GetEdge(ind), aShapeEdge))
      {
        TopoDS_Edge E = TopoDS::Edge(aShapeEdge);
        const TopTools_ListOfShape& aFacesList = M.FindFromKey(E);
        TopoDS_Face F = TopoDS::Face( aFacesList.First() );
        if (aType == CHAMFER_SHAPE_EDGES)
        {
          double aD1 = aCI.GetD1();
          double aD2 = aCI.GetD2();
          fill.Add(aD1, aD2, E, F);
        }
        else
        {
          double aD = aCI.GetD();
          double anAngle = aCI.GetAngle();
          if ( (anAngle > 0) && (anAngle < (M_PI/2.)) )
            fill.AddDA(aD, anAngle, E, F);
        }
      }
    }
  }
  else {
  }

  fill.Build();
  if (!fill.IsDone()) {
    StdFail_NotDone::Raise("Chamfer can not be computed on the given shape with the given parameters");
  }
  aShape = fill.Shape();

  if (aShape.IsNull()) return 0;

  // reduce tolerances
  ShapeFix_ShapeTolerance aSFT;
  aSFT.LimitTolerance(aShape, Precision::Confusion(),
                      Precision::Confusion(), TopAbs_SHAPE);
  Handle(ShapeFix_Shape) aSfs = new ShapeFix_Shape(aShape);
  aSfs->Perform();
  aShape = aSfs->Shape();

  // fix SameParameter flag
  BRepLib::SameParameter(aShape, 1.E-5, Standard_True);

  aFunction->SetValue(aShape);

  log.SetTouched(Label());

  return 1;
}
Ejemplo n.º 5
0
//=======================================================================
//function : FillIn3DParts
//purpose  :
//=======================================================================
  void GEOMAlgo_Builder::FillIn3DParts()
{
  myErrorStatus=0;
  //
  const NMTDS_ShapesDataStructure& aDS=*myPaveFiller->DS();
  NMTTools_PaveFiller* pPF=myPaveFiller;
  const Handle(IntTools_Context)& aCtx= pPF->Context();
  //
  Standard_Boolean bIsIN, bHasImage;
  Standard_Integer aNbS, aNbSolids, i, j, aNbFaces, aNbFP, aNbFPx, aNbFIN, aNbLIF;
  TopAbs_ShapeEnum aType;
  TopAbs_State aState;
  TopTools_IndexedMapOfShape aMSolids, aMS, aMFaces, aMFIN;
  TopTools_MapOfShape aMFDone;
  TopTools_IndexedDataMapOfShapeListOfShape aMEF;
  TopTools_ListIteratorOfListOfShape aItS;
  TopoDS_Iterator aIt, aItF;
  BRep_Builder aBB;
  TopoDS_Solid aSolidSp;
  TopoDS_Face aFP;
  //
  myDraftSolids.Clear();
  //
  aNbS=aDS.NumberOfShapesOfTheObject();
  for (i=1; i<=aNbS; ++i) {
    const TopoDS_Shape& aS=aDS.Shape(i);
    //
    aType=aS.ShapeType();
    if (aType==TopAbs_SOLID) {
      // all solids from DS
      aMSolids.Add(aS);
    }
    else if (aType==TopAbs_FACE) {
      // all faces (originals from DS or theirs images)
      if (myImages.HasImage(aS)) {
        const TopTools_ListOfShape& aLS=myImages.Image(aS);
        aItS.Initialize(aLS);
        for (; aItS.More(); aItS.Next()) {
          const TopoDS_Shape& aFx=aItS.Value();
          //
          if (mySameDomainShapes.Contains(aFx)) {
            const TopoDS_Shape& aFSDx=mySameDomainShapes.FindFromKey(aFx);
            aMFaces.Add(aFSDx);
          }
          else {
            aMFaces.Add(aFx);
          }
        }
      }
      else {
        if (mySameDomainShapes.Contains(aS)) {
          const TopoDS_Shape& aFSDx=mySameDomainShapes.FindFromKey(aS);
          aMFaces.Add(aFSDx);
        }
        else {
          aMFaces.Add(aS);
        }
      }
    }
  }
  //
  aNbFaces=aMFaces.Extent();
  aNbSolids=aMSolids.Extent();
  //
  for (i=1; i<=aNbSolids; ++i) {
    const TopoDS_Solid& aSolid=TopoDS::Solid(aMSolids(i));
    aMFDone.Clear();
    aMFIN.Clear();
    aMEF.Clear();
    //
    aBB.MakeSolid(aSolidSp);
    //
    TopTools_ListOfShape aLIF;
    //
    BuildDraftSolid(aSolid, aSolidSp, aLIF);
    aNbLIF=aLIF.Extent();
    //
    // 1 all faces/edges from aSolid [ aMS ]
    bHasImage=Standard_False;
    aMS.Clear();
    aIt.Initialize(aSolid);
    for (; aIt.More(); aIt.Next()) {
      const TopoDS_Shape& aShell=aIt.Value();
      //
      if (myImages.HasImage(aShell)) {
        bHasImage=Standard_True;
        //
        const TopTools_ListOfShape& aLS=myImages.Image(aShell);
        aItS.Initialize(aLS);
        for (; aItS.More(); aItS.Next()) {
          const TopoDS_Shape& aSx=aItS.Value();
          aMS.Add(aSx);
          TopExp::MapShapes(aSx, TopAbs_FACE, aMS);
          TopExp::MapShapes(aSx, TopAbs_EDGE, aMS);
          TopExp::MapShapesAndAncestors(aSx, TopAbs_EDGE, TopAbs_FACE, aMEF);
        }
      }
      else {
        //aMS.Add(aShell);
        TopExp::MapShapes(aShell, TopAbs_FACE, aMS);
        //modified by NIZNHY-PKV Fri Dec 03 11:18:45 2010f
        TopExp::MapShapes(aShell, TopAbs_EDGE, aMS);
        //modified by NIZNHY-PKV Fri Dec 03 11:18:51 2010t
        TopExp::MapShapesAndAncestors(aShell, TopAbs_EDGE, TopAbs_FACE, aMEF);
      }
    }
    //
    // 2 all faces that are not from aSolid [ aLFP1 ]
    Standard_Integer aNbEFP;
    TopTools_IndexedDataMapOfShapeListOfShape aMEFP;
    TopTools_ListIteratorOfListOfShape aItFP, aItEx;
    TopTools_MapOfShape aMFence;
    TopTools_ListOfShape aLFP1, aLFP2, aLFP, aLCBF, aLFIN, aLEx;//*pLFP,
    //
    // for all non-solid faces build EF map [ aMEFP ]
    for (j=1; j<=aNbFaces; ++j) {
      const TopoDS_Shape& aFace=aMFaces(j);
      if (!aMS.Contains(aFace)) {
        TopExp::MapShapesAndAncestors(aFace, TopAbs_EDGE, TopAbs_FACE, aMEFP);
      }
    }
    //
    // among all faces from aMEFP select these that have same edges
    // with the solid (i.e aMEF). These faces will be treated first
    // to prevent the usage of 3D classifier.
    // The full list of faces to process is aLFP1.
    aNbEFP=aMEFP.Extent();
    for (j=1; j<=aNbEFP; ++j) {
      const TopoDS_Shape& aE=aMEFP.FindKey(j);
      //
      if (aMEF.Contains(aE)) { // !!
        const TopTools_ListOfShape& aLF=aMEFP(j);
        aItFP.Initialize(aLF);
        for (; aItFP.More(); aItFP.Next()) {
          const TopoDS_Shape& aF=aItFP.Value();
          if (aMFence.Add(aF)) {
            aLFP1.Append(aF);
          }
        }
      }
      else {
        aLEx.Append(aE);
      }
    }
    //
    aItEx.Initialize(aLEx);
    for (; aItEx.More(); aItEx.Next()) {
      const TopoDS_Shape& aE=aItEx.Value();
      const TopTools_ListOfShape& aLF=aMEFP.FindFromKey(aE);
      aItFP.Initialize(aLF);
      for (; aItFP.More(); aItFP.Next()) {
        const TopoDS_Shape& aF=aItFP.Value();
        if (aMFence.Add(aF)) {
          aLFP2.Append(aF);
        }
      }
    }
    aLFP1.Append(aLFP2);
    //==========
    //
    // 3 Process faces aLFP1
    aNbFP=aLFP1.Extent();
    aItFP.Initialize(aLFP1);
    for (; aItFP.More(); aItFP.Next()) {
      const TopoDS_Shape& aSP=aItFP.Value();
      if (!aMFDone.Add(aSP)) {
        continue;
      }

      //
      // first face to process
      aFP=TopoDS::Face(aSP);
      bIsIN= GEOMAlgo_Tools3D::IsInternalFace(aFP, aSolidSp, aMEF, 1.e-14, aCtx);
      aState=(bIsIN) ? TopAbs_IN : TopAbs_OUT;
      //
      // collect faces to process [ aFP is the first ]
      aLFP.Clear();
      aLFP.Append(aFP);
      aItS.Initialize(aLFP1);
      for (; aItS.More(); aItS.Next()) {
        const TopoDS_Shape& aSk=aItS.Value();
        if (!aMFDone.Contains(aSk)) {
          aLFP.Append(aSk);
        }
      }
      //
      // Connexity Block that spreads from aFP the Bound
      // or till the end of the block itself
      aLCBF.Clear();
      GEOMAlgo_Tools3D::MakeConnexityBlock(aLFP, aMS, aLCBF);
      //
      // fill states for the Connexity Block
      aItS.Initialize(aLCBF);
      for (; aItS.More(); aItS.Next()) {
        const TopoDS_Shape& aSx=aItS.Value();
        aMFDone.Add(aSx);
        if (aState==TopAbs_IN) {
          aMFIN.Add(aSx);
        }
      }
      //
      aNbFPx=aMFDone.Extent();
      if (aNbFPx==aNbFP) {
        break;
      }
    }//for (; aItFP.More(); aItFP.Next())
    //
    // faces Inside aSolid
    aLFIN.Clear();
    aNbFIN=aMFIN.Extent();
    if (aNbFIN || aNbLIF) {
      for (j=1; j<=aNbFIN; ++j) {
        const TopoDS_Shape& aFIN=aMFIN(j);
        aLFIN.Append(aFIN);
      }
      //
      aItS.Initialize(aLIF);
      for (; aItS.More(); aItS.Next()) {
        const TopoDS_Shape& aFIN=aItS.Value();
        aLFIN.Append(aFIN);
      }
      //
      myInParts.Add(aSolid, aLFIN);
    }
    if (aNbFIN || bHasImage) {
      myDraftSolids.Add(aSolid, aSolidSp);
    }
  }//for (i=1; i<=aNbSolids; ++i) { // next solid
}
bool StdMeshers_RadialPrism_3D::Evaluate(SMESH_Mesh& aMesh,
                                         const TopoDS_Shape& aShape,
                                         MapShapeNbElems& aResMap)
{
  // get 2 shells
  TopoDS_Solid solid = TopoDS::Solid( aShape );
  TopoDS_Shell outerShell = BRepClass3d::OuterShell( solid );
  TopoDS_Shape innerShell;
  int nbShells = 0;
  for ( TopoDS_Iterator It (solid); It.More(); It.Next(), ++nbShells )
    if ( !outerShell.IsSame( It.Value() ))
      innerShell = It.Value();
  if ( nbShells != 2 ) {
    std::vector<int> aResVec(SMDSEntity_Last);
    for(int i=SMDSEntity_Node; i<SMDSEntity_Last; i++) aResVec[i] = 0;
    SMESH_subMesh * sm = aMesh.GetSubMesh(aShape);
    aResMap.insert(std::make_pair(sm,aResVec));
    SMESH_ComputeErrorPtr& smError = sm->GetComputeError();
    smError.reset( new SMESH_ComputeError(COMPERR_ALGO_FAILED,"Submesh can not be evaluated",this));
    return false;
  }

  // Associate sub-shapes of the shells
  ProjectionUtils::TShapeShapeMap shape2ShapeMap;
  if ( !ProjectionUtils::FindSubShapeAssociation( outerShell, &aMesh,
                                                  innerShell, &aMesh,
                                                  shape2ShapeMap) ) {
    std::vector<int> aResVec(SMDSEntity_Last);
    for(int i=SMDSEntity_Node; i<SMDSEntity_Last; i++) aResVec[i] = 0;
    SMESH_subMesh * sm = aMesh.GetSubMesh(aShape);
    aResMap.insert(std::make_pair(sm,aResVec));
    SMESH_ComputeErrorPtr& smError = sm->GetComputeError();
    smError.reset( new SMESH_ComputeError(COMPERR_ALGO_FAILED,"Submesh can not be evaluated",this));
    return false;
  }

  // get info for outer shell
  int nb0d_Out=0, nb2d_3_Out=0, nb2d_4_Out=0;
  //TopTools_SequenceOfShape FacesOut;
  for (TopExp_Explorer exp(outerShell, TopAbs_FACE); exp.More(); exp.Next()) {
    //FacesOut.Append(exp.Current());
    SMESH_subMesh *aSubMesh = aMesh.GetSubMesh(exp.Current());
    MapShapeNbElemsItr anIt = aResMap.find(aSubMesh);
    std::vector<int> aVec = (*anIt).second;
    nb0d_Out += aVec[SMDSEntity_Node];
    nb2d_3_Out += Max(aVec[SMDSEntity_Triangle],aVec[SMDSEntity_Quad_Triangle]);
    nb2d_4_Out += Max(aVec[SMDSEntity_Quadrangle],aVec[SMDSEntity_Quad_Quadrangle]);
  }
  int nb1d_Out = 0;
  TopTools_MapOfShape tmpMap;
  for (TopExp_Explorer exp(outerShell, TopAbs_EDGE); exp.More(); exp.Next()) {
    if( tmpMap.Contains( exp.Current() ) )
      continue;
    tmpMap.Add( exp.Current() );
    SMESH_subMesh *aSubMesh = aMesh.GetSubMesh(exp.Current());
    MapShapeNbElemsItr anIt = aResMap.find(aSubMesh);
    std::vector<int> aVec = (*anIt).second;
    nb0d_Out += aVec[SMDSEntity_Node];
    nb1d_Out += Max(aVec[SMDSEntity_Edge],aVec[SMDSEntity_Quad_Edge]);
  }
  tmpMap.Clear();
  for (TopExp_Explorer exp(outerShell, TopAbs_VERTEX); exp.More(); exp.Next()) {
    if( tmpMap.Contains( exp.Current() ) )
      continue;
    tmpMap.Add( exp.Current() );
    nb0d_Out++;
  }

  // get info for inner shell
  int nb0d_In=0, nb2d_3_In=0, nb2d_4_In=0;
  //TopTools_SequenceOfShape FacesIn;
  for (TopExp_Explorer exp(innerShell, TopAbs_FACE); exp.More(); exp.Next()) {
    //FacesIn.Append(exp.Current());
    SMESH_subMesh *aSubMesh = aMesh.GetSubMesh(exp.Current());
    MapShapeNbElemsItr anIt = aResMap.find(aSubMesh);
    std::vector<int> aVec = (*anIt).second;
    nb0d_In += aVec[SMDSEntity_Node];
    nb2d_3_In += Max(aVec[SMDSEntity_Triangle],aVec[SMDSEntity_Quad_Triangle]);
    nb2d_4_In += Max(aVec[SMDSEntity_Quadrangle],aVec[SMDSEntity_Quad_Quadrangle]);
  }
  int nb1d_In = 0;
  tmpMap.Clear();
  bool IsQuadratic = false;
  bool IsFirst = true;
  for (TopExp_Explorer exp(innerShell, TopAbs_EDGE); exp.More(); exp.Next()) {
    if( tmpMap.Contains( exp.Current() ) )
      continue;
    tmpMap.Add( exp.Current() );
    SMESH_subMesh *aSubMesh = aMesh.GetSubMesh(exp.Current());
    MapShapeNbElemsItr anIt = aResMap.find(aSubMesh);
    std::vector<int> aVec = (*anIt).second;
    nb0d_In += aVec[SMDSEntity_Node];
    nb1d_In += Max(aVec[SMDSEntity_Edge],aVec[SMDSEntity_Quad_Edge]);
    if(IsFirst) {
      IsQuadratic = (aVec[SMDSEntity_Quad_Edge] > aVec[SMDSEntity_Edge]);
      IsFirst = false;
    }
  }
  tmpMap.Clear();
  for (TopExp_Explorer exp(innerShell, TopAbs_VERTEX); exp.More(); exp.Next()) {
    if( tmpMap.Contains( exp.Current() ) )
      continue;
    tmpMap.Add( exp.Current() );
    nb0d_In++;
  }

  bool IsOK = (nb0d_Out==nb0d_In) && (nb1d_Out==nb1d_In) && 
              (nb2d_3_Out==nb2d_3_In) && (nb2d_4_Out==nb2d_4_In);
  if(!IsOK) {
    std::vector<int> aResVec(SMDSEntity_Last);
    for(int i=SMDSEntity_Node; i<SMDSEntity_Last; i++) aResVec[i] = 0;
    SMESH_subMesh * sm = aMesh.GetSubMesh(aShape);
    aResMap.insert(std::make_pair(sm,aResVec));
    SMESH_ComputeErrorPtr& smError = sm->GetComputeError();
    smError.reset( new SMESH_ComputeError(COMPERR_ALGO_FAILED,"Submesh can not be evaluated",this));
    return false;
  }

  int nbLayers = 0;
  if( myNbLayerHypo ) {
    nbLayers = myNbLayerHypo->GetNumberOfLayers();
  }
  if ( myDistributionHypo ) {
    if ( !myDistributionHypo->GetLayerDistribution() ) {
      std::vector<int> aResVec(SMDSEntity_Last);
      for(int i=SMDSEntity_Node; i<SMDSEntity_Last; i++) aResVec[i] = 0;
      SMESH_subMesh * sm = aMesh.GetSubMesh(aShape);
      aResMap.insert(std::make_pair(sm,aResVec));
      SMESH_ComputeErrorPtr& smError = sm->GetComputeError();
      smError.reset( new SMESH_ComputeError(COMPERR_ALGO_FAILED,"Submesh can not be evaluated",this));
      return false;
    }
    TopExp_Explorer exp(outerShell, TopAbs_VERTEX);
    TopoDS_Vertex Vout = TopoDS::Vertex(exp.Current());
    TopoDS_Vertex Vin = TopoDS::Vertex( shape2ShapeMap(Vout) );
    if ( myLayerPositions.empty() ) {
      gp_Pnt pIn = BRep_Tool::Pnt(Vin);
      gp_Pnt pOut = BRep_Tool::Pnt(Vout);
      computeLayerPositions( pIn, pOut );
    }
    nbLayers = myLayerPositions.size() + 1;
  }

  std::vector<int> aResVec(SMDSEntity_Last);
  for(int i=SMDSEntity_Node; i<SMDSEntity_Last; i++) aResVec[i] = 0;
  if(IsQuadratic) {
    aResVec[SMDSEntity_Quad_Penta] = nb2d_3_Out * nbLayers;
    aResVec[SMDSEntity_Quad_Hexa] = nb2d_4_Out * nbLayers;
    int nb1d = ( nb2d_3_Out*3 + nb2d_4_Out*4 ) / 2;
    aResVec[SMDSEntity_Node] = nb0d_Out * ( 2*nbLayers - 1 ) - nb1d * nbLayers;
  }
  else {
    aResVec[SMDSEntity_Node] = nb0d_Out * ( nbLayers - 1 );
    aResVec[SMDSEntity_Penta] = nb2d_3_Out * nbLayers;
    aResVec[SMDSEntity_Hexa] = nb2d_4_Out * nbLayers;
  }
  SMESH_subMesh * sm = aMesh.GetSubMesh(aShape);
  aResMap.insert(std::make_pair(sm,aResVec));

  return true;
}
bool NETGENPlugin_NETGEN_2D_ONLY::Evaluate(SMESH_Mesh& aMesh,
        const TopoDS_Shape& aShape,
        MapShapeNbElems& aResMap)
{
    TopoDS_Face F = TopoDS::Face(aShape);
    if(F.IsNull())
        return false;

    // collect info from edges
    int nb0d = 0, nb1d = 0;
    bool IsQuadratic = false;
    bool IsFirst = true;
    double fullLen = 0.0;
    TopTools_MapOfShape tmpMap;
    for (TopExp_Explorer exp(F, TopAbs_EDGE); exp.More(); exp.Next()) {
        TopoDS_Edge E = TopoDS::Edge(exp.Current());
        if( tmpMap.Contains(E) )
            continue;
        tmpMap.Add(E);
        SMESH_subMesh *aSubMesh = aMesh.GetSubMesh(exp.Current());
        MapShapeNbElemsItr anIt = aResMap.find(aSubMesh);
        if( anIt==aResMap.end() ) {
            SMESH_subMesh *sm = aMesh.GetSubMesh(F);
            SMESH_ComputeErrorPtr& smError = sm->GetComputeError();
            smError.reset( new SMESH_ComputeError(COMPERR_ALGO_FAILED,"Submesh can not be evaluated",this));
            return false;
        }
        std::vector<int> aVec = (*anIt).second;
        nb0d += aVec[SMDSEntity_Node];
        nb1d += Max(aVec[SMDSEntity_Edge],aVec[SMDSEntity_Quad_Edge]);
        double aLen = SMESH_Algo::EdgeLength(E);
        fullLen += aLen;
        if(IsFirst) {
            IsQuadratic = (aVec[SMDSEntity_Quad_Edge] > aVec[SMDSEntity_Edge]);
            IsFirst = false;
        }
    }
    tmpMap.Clear();

    // compute edge length
    double ELen = 0;
    if (_hypLengthFromEdges || (!_hypLengthFromEdges && !_hypMaxElementArea)) {
        if ( nb1d > 0 )
            ELen = fullLen / nb1d;
    }
    if ( _hypMaxElementArea ) {
        double maxArea = _hypMaxElementArea->GetMaxArea();
        ELen = sqrt(2. * maxArea/sqrt(3.0));
    }
    GProp_GProps G;
    BRepGProp::SurfaceProperties(F,G);
    double anArea = G.Mass();

    const int hugeNb = numeric_limits<int>::max()/10;
    if ( anArea / hugeNb > ELen*ELen )
    {
        SMESH_subMesh *sm = aMesh.GetSubMesh(F);
        SMESH_ComputeErrorPtr& smError = sm->GetComputeError();
        smError.reset( new SMESH_ComputeError(COMPERR_ALGO_FAILED,"Submesh can not be evaluated.\nToo small element length",this));
        return false;
    }
    int nbFaces = (int) ( anArea / ( ELen*ELen*sqrt(3.) / 4 ) );
    int nbNodes = (int) ( ( nbFaces*3 - (nb1d-1)*2 ) / 6 + 1 );
    std::vector<int> aVec(SMDSEntity_Last);
    for(int i=SMDSEntity_Node; i<SMDSEntity_Last; i++) aVec[i]=0;
    if( IsQuadratic ) {
        aVec[SMDSEntity_Node] = nbNodes;
        aVec[SMDSEntity_Quad_Triangle] = nbFaces;
    }
    else {
        aVec[SMDSEntity_Node] = nbNodes;
        aVec[SMDSEntity_Triangle] = nbFaces;
    }
    SMESH_subMesh *sm = aMesh.GetSubMesh(F);
    aResMap.insert(std::make_pair(sm,aVec));

    return true;
}
Ejemplo n.º 8
0
//=======================================================================
//function : FindFacePairs
//purpose  : 
//=======================================================================
Standard_Boolean FindFacePairs (const TopoDS_Edge& theE,
                                const TopTools_ListOfShape& thLF,
                                NMTTools_ListOfCoupleOfShape& theLCFF)
{
  Standard_Boolean bFound;
  Standard_Integer i, aNbCEF;
  TopAbs_Orientation aOr, aOrC;
  TopTools_MapOfShape aMFP;
  TopoDS_Face aF1, aF2;
  TopoDS_Edge aEL, aE1;
  TopTools_ListIteratorOfListOfShape aItLF;
  NMTTools_CoupleOfShape aCEF, aCFF;
  NMTTools_ListOfCoupleOfShape aLCEF, aLCEFx;
  NMTTools_ListIteratorOfListOfCoupleOfShape aIt;
  //
  bFound=Standard_True;
  //
  // Preface aLCEF
  aItLF.Initialize(thLF);
  for (; aItLF.More(); aItLF.Next()) { 
    const TopoDS_Face& aFL=TopoDS::Face(aItLF.Value());
    //
    bFound=GEOMAlgo_Tools3D::GetEdgeOnFace(theE, aFL, aEL);
    if (!bFound) {
      return bFound; // it can not be so
    }
    //
    aCEF.SetShape1(aEL);
    aCEF.SetShape2(aFL);
    aLCEF.Append(aCEF);
  }
  //
  aNbCEF=aLCEF.Extent();
  while(aNbCEF) {
    //
    // aLCEFx
    aLCEFx.Clear();
    aIt.Initialize(aLCEF);
    for (i=0; aIt.More(); aIt.Next(), ++i) {
      const NMTTools_CoupleOfShape& aCSx=aIt.Value();
      const TopoDS_Shape& aEx=aCSx.Shape1();
      const TopoDS_Shape& aFx=aCSx.Shape2();
      //
      aOr=aEx.Orientation();
      //
      if (!i) {
        aOrC=TopAbs::Reverse(aOr);
        aE1=TopoDS::Edge(aEx);
        aF1=TopoDS::Face(aFx);
        aMFP.Add(aFx);
        continue;
      }
      //
      if (aOr==aOrC) {
        aLCEFx.Append(aCSx);
        aMFP.Add(aFx);
      }
    }
    //
    // F2
    GEOMAlgo_Tools3D::GetFaceOff(aE1, aF1, aLCEFx, aF2);
    //
    aCFF.SetShape1(aF1);
    aCFF.SetShape2(aF2);
    theLCFF.Append(aCFF);
    //
    aMFP.Add(aF1);
    aMFP.Add(aF2);
    //
    // refine aLCEF
    aLCEFx.Clear();
    aLCEFx=aLCEF;
    aLCEF.Clear();
    aIt.Initialize(aLCEFx);
    for (; aIt.More(); aIt.Next()) {
      const NMTTools_CoupleOfShape& aCSx=aIt.Value();
      const TopoDS_Shape& aFx=aCSx.Shape2();
      if (!aMFP.Contains(aFx)) {
        aLCEF.Append(aCSx);
      }
    }
    //
    aNbCEF=aLCEF.Extent();
  }//while(aNbCEF) {
  //
  return bFound;
}
Ejemplo n.º 9
0
//=======================================================================
//function : DetectVertices
//purpose  : 
//=======================================================================
void GEOMAlgo_GlueDetector::DetectVertices()
{
  Standard_Integer j, i, aNbV, aNbVSD;
  Standard_Real aTolV;
  gp_Pnt aPV;
  TColStd_ListIteratorOfListOfInteger aIt;
  TopoDS_Shape aVF;
  TopTools_IndexedMapOfShape aMV;
  TopTools_MapOfShape aMVProcessed;
  TopTools_ListIteratorOfListOfShape aItS;
  TopTools_DataMapIteratorOfDataMapOfShapeListOfShape aItIm;
  TopTools_DataMapOfShapeListOfShape aMVV;
  GEOMAlgo_IndexedDataMapOfIntegerShape aMIS;
  NMTDS_IndexedDataMapOfShapeBndSphere aMSB;
  //
  NMTDS_BndSphereTreeSelector aSelector;
  NMTDS_BndSphereTree aBBTree;
  NCollection_UBTreeFiller <Standard_Integer, NMTDS_BndSphere> aTreeFiller(aBBTree);
  //
  myErrorStatus=0;
  //
  TopExp::MapShapes(myArgument, TopAbs_VERTEX, aMV);
  aNbV=aMV.Extent();
  if (!aNbV) {
    myErrorStatus=2; // no vertices in source shape
    return;
  }
  //
  for (i=1; i<=aNbV; ++i) {
    NMTDS_BndSphere aBox;
    //
    const TopoDS_Vertex& aV=*((TopoDS_Vertex*)&aMV(i));
    aPV=BRep_Tool::Pnt(aV);
    aTolV=BRep_Tool::Tolerance(aV);
    //
    aBox.SetGap(myTolerance);
    aBox.SetCenter(aPV);
    aBox.SetRadius(aTolV);
    //
    aTreeFiller.Add(i, aBox);
    //
    aMIS.Add(i, aV);
    aMSB.Add(aV, aBox); 
  }
  //
  aTreeFiller.Fill();
  //
  //---------------------------------------------------
  // Chains
  for (i=1; i<=aNbV; ++i) {
    const TopoDS_Shape& aV=aMV(i);
    //
    if (aMVProcessed.Contains(aV)) {
      continue;
    }
    //
    Standard_Integer aNbIP, aIP, aNbIP1, aIP1;
    TopTools_ListOfShape aLVSD;
    TColStd_MapOfInteger aMIP, aMIP1, aMIPC;
    TColStd_MapIteratorOfMapOfInteger aIt1;
    //
    aMIP.Add(i);
    while(1) {
      aNbIP=aMIP.Extent();
      aIt1.Initialize(aMIP);
      for(; aIt1.More(); aIt1.Next()) {
	aIP=aIt1.Key();
	if (aMIPC.Contains(aIP)) {
	  continue;
	}
	//
	const TopoDS_Shape& aVP=aMIS.FindFromKey(aIP);
	const NMTDS_BndSphere& aBoxVP=aMSB.FindFromKey(aVP);
	//
	aSelector.Clear();
	aSelector.SetBox(aBoxVP);
	//
	aNbVSD=aBBTree.Select(aSelector);
	if (!aNbVSD) {
	  continue;  // it shoild not be so [at least IP itself]    
	}
	//
	const TColStd_ListOfInteger& aLI=aSelector.Indices();
	aIt.Initialize(aLI);
	for (; aIt.More(); aIt.Next()) {
	  aIP1=aIt.Value();
	  if (aMIP.Contains(aIP1)) {
	    continue;
	  }
	  aMIP1.Add(aIP1);
	} //for (; aIt.More(); aIt.Next()) {
      }//for(; aIt1.More(); aIt1.Next()) {
      //
      aNbIP1=aMIP1.Extent();
      if (!aNbIP1) {
	break;
      }
      //
      aIt1.Initialize(aMIP);
      for(; aIt1.More(); aIt1.Next()) {
	aIP=aIt1.Key();
	aMIPC.Add(aIP);
      }
      //
      aMIP.Clear();
      aIt1.Initialize(aMIP1);
      for(; aIt1.More(); aIt1.Next()) {
	aIP=aIt1.Key();
	aMIP.Add(aIP);
      }
      aMIP1.Clear();
    }// while(1)
    //
    // Fill myImages
    aNbIP=aMIPC.Extent();
    //
    if (!aNbIP) {// no SD vertices is found
      aMVProcessed.Add(aV);
      continue;
    }
    //else { // SD vertices founded [ aMIPC ]
    aIt1.Initialize(aMIPC);
    for(j=0; aIt1.More(); aIt1.Next(), ++j) {
      aIP=aIt1.Key();
      const TopoDS_Shape& aVP=aMIS.FindFromKey(aIP);
      if (!j) {
	aVF=aVP;
      }
      aLVSD.Append(aVP);
      aMVProcessed.Add(aVP);
    }
    //}
    myImages.Bind(aVF, aLVSD);
  }// for (i=1; i<=aNbV; ++i) {
  //------------------------------
  // Origins
  aItIm.Initialize(myImages);
  for (; aItIm.More(); aItIm.Next()) {
    const TopoDS_Shape& aV=aItIm.Key();
    const TopTools_ListOfShape& aLVSD=aItIm.Value();
    aItS.Initialize(aLVSD);
    for (; aItS.More(); aItS.Next()) {
      const TopoDS_Shape& aVSD=aItS.Value();
      if (!myOrigins.IsBound(aVSD)) {
	myOrigins.Bind(aVSD, aV);
      }
    }
  }
}
Ejemplo n.º 10
0
//=======================================================================
//function : Execute
//purpose  :
//=======================================================================
Standard_Integer GEOMImpl_ChamferDriver::Execute(TFunction_Logbook& log) const
{
  if (Label().IsNull()) return 0;
  Handle(GEOM_Function) aFunction = GEOM_Function::GetFunction(Label());

  GEOMImpl_IChamfer aCI (aFunction);
  Standard_Integer aType = aFunction->GetType();

  TopoDS_Shape aShape;

  Handle(GEOM_Function) aRefShape = aCI.GetShape();
  TopoDS_Shape aShapeBase = aRefShape->GetValue();



  if (aType == CHAMFER_SHAPE_EDGES_2D)
  {
	BRepFilletAPI_MakeFillet2d fill;
	TopoDS_Face aFace;

	Standard_Boolean aWireFlag = Standard_False;
	
	if (aShapeBase.ShapeType() == TopAbs_FACE)
		aFace = TopoDS::Face(aShapeBase);
	else if (aShapeBase.ShapeType() == TopAbs_WIRE)
	{
		TopoDS_Wire aWire = TopoDS::Wire(aShapeBase);
		BRepBuilderAPI_MakeFace aMF(aWire);
		aMF.Build();
		if (!aMF.IsDone()) {
			StdFail_NotDone::Raise("Cannot build initial face from given wire");
		}
		aFace = aMF.Face();
		aWireFlag = Standard_True;
	}
	else
		StdFail_NotDone::Raise("Base shape is neither a face or a wire !");

	fill.Init(aFace);

	double aD1_2D = aCI.GetD1();
	double aD2_2D = aCI.GetD2();

	TopoDS_Shape aShapeFace1, aShapeFace2;

	if (GEOMImpl_ILocalOperations::GetSubShape(aShapeBase, aCI.Get2DEdge1(), aShapeFace1) &&
		GEOMImpl_ILocalOperations::GetSubShape(aShapeBase, aCI.Get2DEdge2(), aShapeFace2))
	{
		fill.AddChamfer(TopoDS::Edge(aShapeFace1), TopoDS::Edge(aShapeFace2), aD1_2D, aD2_2D);
	}
	else
		StdFail_NotDone::Raise("Cannot get 2d egde from sub-shape index!");

	fill.Build();
	if (!fill.IsDone()) {
		StdFail_NotDone::Raise("Chamfer can not be computed on the given shape with the given parameters");
	}
	if (aWireFlag)
	{
		BRepBuilderAPI_MakeWire MW;
		TopExp_Explorer exp (fill.Shape(), TopAbs_EDGE);
		for (; exp.More(); exp.Next())
			MW.Add(TopoDS::Edge(exp.Current()));
		MW.Build();
		if (!MW.IsDone())
			StdFail_NotDone::Raise("Resulting wire cannot be built");
			
		aShape = MW.Shape();
	}
	else
		aShape = fill.Shape();
  }
  else
  {
	  // Check the shape type. It have to be shell
	  // or solid, or compsolid, or compound of these shapes.
	  if (!isGoodForChamfer(aShapeBase)) {
		StdFail_NotDone::Raise
		  ("Wrong shape. Must be shell or solid, or compsolid or compound of these shapes");
	  }

	  BRepFilletAPI_MakeChamfer fill (aShapeBase);

	  if (aType == CHAMFER_SHAPE_ALL) {
		// symmetric chamfer on all edges
		double aD = aCI.GetD();
		TopTools_IndexedDataMapOfShapeListOfShape M;
		GEOMImpl_Block6Explorer::MapShapesAndAncestors(aShapeBase, TopAbs_EDGE, TopAbs_FACE, M);
		for (int i = 1; i <= M.Extent(); i++) {
		  TopoDS_Edge E = TopoDS::Edge(M.FindKey(i));
		  TopoDS_Face F = TopoDS::Face(M.FindFromIndex(i).First());
		  if (!BRepTools::IsReallyClosed(E, F) &&
			  !BRep_Tool::Degenerated(E) &&
			  M.FindFromIndex(i).Extent() == 2)
			fill.Add(aD, E, F);
		}
	  }else if (aType == CHAMFER_SHAPE_EDGE || aType == CHAMFER_SHAPE_EDGE_AD) {
		// chamfer on edges, common to two faces, with D1 on the first face

		TopoDS_Shape aFace1, aFace2;
		if (GEOMImpl_ILocalOperations::GetSubShape(aShapeBase, aCI.GetFace1(), aFace1) &&
			GEOMImpl_ILocalOperations::GetSubShape(aShapeBase, aCI.GetFace2(), aFace2))
		  {
		TopoDS_Face F = TopoDS::Face(aFace1);

		// fill map of edges of the second face
		TopTools_MapOfShape aMap;
		TopExp_Explorer Exp2 (aFace2, TopAbs_EDGE);
		for (; Exp2.More(); Exp2.Next()) {
		  aMap.Add(Exp2.Current());
		}
	
		// find edges of the first face, common with the second face
		TopExp_Explorer Exp (aFace1, TopAbs_EDGE);
		for (; Exp.More(); Exp.Next()) {
		  if (aMap.Contains(Exp.Current())) {
			TopoDS_Edge E = TopoDS::Edge(Exp.Current());
			if (!BRepTools::IsReallyClosed(E, F) && !BRep_Tool::Degenerated(E))
			  {
			if ( aType == CHAMFER_SHAPE_EDGE )
			  {
				double aD1 = aCI.GetD1();
				double aD2 = aCI.GetD2();
				fill.Add(aD1, aD2, E, F);
			  }
			else
			  {
				double aD = aCI.GetD();
				double anAngle = aCI.GetAngle();
				if ( (anAngle > 0) && (anAngle < (Standard_PI/2)) )
				  fill.AddDA(aD, anAngle, E, F);
			  }
			  }
		  }
		}
		  }
	  }
	  else if (aType == CHAMFER_SHAPE_FACES || aType == CHAMFER_SHAPE_FACES_AD) {
		// chamfer on all edges of the selected faces, with D1 on the selected face
		// (on first selected face, if the edge belongs to two selected faces)

		int aLen = aCI.GetLength();
		int ind = 1;
		TopTools_MapOfShape aMap;
		TopTools_IndexedDataMapOfShapeListOfShape M;
		GEOMImpl_Block6Explorer::MapShapesAndAncestors(aShapeBase, TopAbs_EDGE, TopAbs_FACE, M);
		for (; ind <= aLen; ind++)
		{
		  TopoDS_Shape aShapeFace;
		  if (GEOMImpl_ILocalOperations::GetSubShape(aShapeBase, aCI.GetFace(ind), aShapeFace))
		{
		  TopoDS_Face F = TopoDS::Face(aShapeFace);
		  TopExp_Explorer Exp (F, TopAbs_EDGE);
		  for (; Exp.More(); Exp.Next()) {
			if (!aMap.Contains(Exp.Current()))
			  {
			TopoDS_Edge E = TopoDS::Edge(Exp.Current());
			if (!BRepTools::IsReallyClosed(E, F) &&
				!BRep_Tool::Degenerated(E) &&
				M.FindFromKey(E).Extent() == 2)
			  if (aType == CHAMFER_SHAPE_FACES)
				{
				  double aD1 = aCI.GetD1();
				  double aD2 = aCI.GetD2();
				  fill.Add(aD1, aD2, E, F);
				}
			  else
				{
				  double aD = aCI.GetD();
				  double anAngle = aCI.GetAngle();
				  if ( (anAngle > 0) && (anAngle < (Standard_PI/2)) )
				fill.AddDA(aD, anAngle, E, F);
				}
			  }
		  }
		}
		}
	  }
	else if (aType == CHAMFER_SHAPE_EDGES || aType == CHAMFER_SHAPE_EDGES_AD)
	  {
		// chamfer on selected edges with lenght param D1 & D2.

		int aLen = aCI.GetLength();
		int ind = 1;
		TopTools_MapOfShape aMap;
		TopTools_IndexedDataMapOfShapeListOfShape M;
		GEOMImpl_Block6Explorer::MapShapesAndAncestors(aShapeBase, TopAbs_EDGE, TopAbs_FACE, M);
		for (; ind <= aLen; ind++)
		{
		  TopoDS_Shape aShapeEdge;
		  if (GEOMImpl_ILocalOperations::GetSubShape(aShapeBase, aCI.GetEdge(ind), aShapeEdge))
		{
		  TopoDS_Edge E = TopoDS::Edge(aShapeEdge);
		  const TopTools_ListOfShape& aFacesList = M.FindFromKey(E);
		  TopoDS_Face F = TopoDS::Face( aFacesList.First() );
		  if (aType == CHAMFER_SHAPE_EDGES)
			{
			  double aD1 = aCI.GetD1();
			  double aD2 = aCI.GetD2();
			  fill.Add(aD1, aD2, E, F);
			}
		  else
			{
			  double aD = aCI.GetD();
			  double anAngle = aCI.GetAngle();
			  if ( (anAngle > 0) && (anAngle < (Standard_PI/2)) )
			fill.AddDA(aD, anAngle, E, F);
			}
		}
		}
	  }
	  else {
	  }

	  fill.Build();
	  if (!fill.IsDone()) {
		StdFail_NotDone::Raise("Chamfer can not be computed on the given shape with the given parameters");
	  }
	  aShape = fill.Shape();
  }

  if (aShape.IsNull()) return 0;

  // Check shape validity
  BRepCheck_Analyzer ana (aShape, false);
  if (!ana.IsValid()) {
  	// 08.07.2008 added by skl during fixing bug 19761 from Mantis
	ShapeFix_ShapeTolerance aSFT;
	aSFT.LimitTolerance(aShape, Precision::Confusion(),
						Precision::Confusion(), TopAbs_SHAPE);
	Handle(ShapeFix_Shape) aSfs = new ShapeFix_Shape(aShape);
	aSfs->Perform();
	aShape = aSfs->Shape();

    // fix SameParameter flag
    BRepLib::SameParameter(aShape, 1.E-5, Standard_True);

	ana.Init(aShape);
	if (!ana.IsValid()) {
	  Standard_CString anErrStr("Chamfer algorithm has produced an invalid shape result");
	  #ifdef THROW_ON_INVALID_SH
		Standard_ConstructionError::Raise(anErrStr);
	  #else
		MESSAGE(anErrStr);
		//further processing can be performed here
		//...
		//in case of failure of automatic treatment
		//mark the corresponding GEOM_Object as problematic
		TDF_Label aLabel = aFunction->GetOwnerEntry();
		if (!aLabel.IsRoot()) {
		  Handle(GEOM_Object) aMainObj = GEOM_Object::GetObject(aLabel);
		  if (!aMainObj.IsNull())
			aMainObj->SetDirty(Standard_True);
		}
	  #endif
	}
  }

  aFunction->SetValue(aShape);

  log.SetTouched(Label());

  return 1;
}