OCCEdge.cpp

// Gmsh - Copyright (C) 1997-2013 C. Geuzaine, J.-F. Remacle
//
// See the LICENSE.txt file for license information. Please report all
// bugs and problems to the public mailing list <gmsh@geuz.org>.

#include <limits>
#include "GmshConfig.h"
#include "GmshMessage.h"
#include "GModel.h"
#include "OCCEdge.h"
#include "OCCFace.h"
#include "Context.h"

#if defined(HAVE_OCC)
#include "GModelIO_OCC.h"
#include <Standard_Version.hxx>
#include <Geom2dLProp_CLProps2d.hxx>
#include <Geom_BezierCurve.hxx>
#include <Geom_OffsetCurve.hxx>
#include <Geom_Ellipse.hxx>
#include <Geom_Parabola.hxx>
#include <Geom_Hyperbola.hxx>
#include <Geom_TrimmedCurve.hxx>
#include <Geom_Circle.hxx>
#include <Geom_Line.hxx>
#include <Geom_Conic.hxx>
#if (OCC_VERSION_MAJOR == 6) && (OCC_VERSION_MINOR < 6)
#include <BOPTools_Tools.hxx>
#else
#include <BOPTools_AlgoTools.hxx>
#endif

OCCEdge::OCCEdge(GModel *m, TopoDS_Edge edge, int num, GVertex *v1, GVertex *v2)
  : GEdge(m, num, v1, v2), c(edge), trimmed(0)
{
  curve = BRep_Tool::Curve(c, s0, s1);
  // build the reverse curve
  c_rev = c;
  c_rev.Reverse();
  model()->getOCCInternals()->bind(c, num);
}

OCCEdge::~OCCEdge()
{
  model()->getOCCInternals()->unbind(c);
}

Range<double> OCCEdge::parBounds(int i) const
{
  return Range<double>(s0, s1);
}

void OCCEdge::setTrimmed(OCCFace *f)
{
  if (!trimmed){
    trimmed = f;
    const TopoDS_Face *s = (TopoDS_Face*) trimmed->getNativePtr();
    curve2d = BRep_Tool::CurveOnSurface(c, *s, s0, s1);
    if(curve2d.IsNull()) trimmed = 0;
  }
}

SPoint2 OCCEdge::reparamOnFace(const GFace *face, double epar, int dir) const
{

  if (face->getNativeType() != GEntity::OpenCascadeModel){
    const GPoint pt = point(epar);
    SPoint3 sp(pt.x(), pt.y(), pt.z());
    return face->parFromPoint(sp);
  }
  else{
    const TopoDS_Face *s = (TopoDS_Face*) face->getNativePtr();
    double t0, t1;
    Handle(Geom2d_Curve) c2d;

    if(dir == 1){
      c2d = BRep_Tool::CurveOnSurface(c, *s, t0, t1);
    }
    else{
      c2d = BRep_Tool::CurveOnSurface(c_rev, *s, t0, t1);
    }

    if(c2d.IsNull()){
      Msg::Error("Reparam on face failed: curve %d is not on surface %d",
		 tag(), face->tag());
      const GPoint pt = point(epar);
      SPoint3 sp(pt.x(), pt.y(), pt.z());
      return face->parFromPoint(sp);
    }

    double u, v;
    gp_Pnt2d pnt = c2d->Value(epar);
    pnt.Coord(u, v);

    // sometimes OCC miserably fails ...
    GPoint p1 = point(epar);
    GPoint p2 = face->point(u, v);
    const double dx = p1.x()-p2.x();
    const double dy = p1.y()-p2.y();
    const double dz = p1.z()-p2.z();
    if(sqrt(dx * dx + dy * dy + dz * dz) > 1.e-2 * CTX::instance()->lc){
      Msg::Warning("Reparam on face was inaccurate for curve %d on surface %d at point %g",
		   tag(), face->tag(), epar);
      Msg::Warning("On the face %d local (%g %g) global (%g %g %g)",
		   face->tag(), u, v, p2.x(), p2.y(), p2.z());
      Msg::Warning("On the edge %d local (%g) global (%g %g %g)",
		   tag(), epar, p1.x(), p1.y(), p1.z());
    }
    return SPoint2(u, v);
  }

}

GPoint OCCEdge::closestPoint(const SPoint3 &qp, double &param) const
{
  if(curve.IsNull()){
    Msg::Error("OCC curve is null in closestPoint");
    return GPoint(0, 0);
  }

  gp_Pnt pnt(qp.x(), qp.y(), qp.z());
  GeomAPI_ProjectPointOnCurve proj(pnt, curve, s0, s1);

  if(!proj.NbPoints()){
    Msg::Error("OCC ProjectPointOnCurve failed");
    return GPoint(0, 0);
  }

  param = proj.LowerDistanceParameter();

  if(param < s0 || param > s1){
    Msg::Error("Point projection is out of edge bounds");
    return GPoint(0, 0);
  }

  pnt = proj.NearestPoint();
  return GPoint(pnt.X(), pnt.Y(), pnt.Z(), this, param);
}

// True if the edge is a seam for the given face
bool OCCEdge::isSeam(const GFace *face) const
{
  if (face->geomType() == GEntity::CompoundSurface) return false;
  if (face->getNativeType() != GEntity::OpenCascadeModel) return false;

  bool ret;
  const TopoDS_Face *s = (TopoDS_Face*) face->getNativePtr();
  BRepAdaptor_Surface surface(*s);
  ret =  BRep_Tool::IsClosed(c, *s);
  return ret;
}

GPoint OCCEdge::point(double par) const
{
  if(trimmed){
    double u, v;
    curve2d->Value(par).Coord(u, v);
    return trimmed->point(u, v);
  }
  else if(!curve.IsNull()){
    gp_Pnt pnt = curve->Value(par);
    return GPoint(pnt.X(), pnt.Y(), pnt.Z(),this,par);
  }
  else{
    Msg::Warning("OCC Curve %d is neither a 3D curve not a trimmed curve", tag());
    return GPoint(0, 0, 0);
  }
}

SVector3 OCCEdge::firstDer(double par) const
{
  BRepAdaptor_Curve brepc(c);
  BRepLProp_CLProps prop(brepc, 1, 1e-5);
  prop.SetParameter(par);
  gp_Vec d1 = prop.D1();
  return SVector3(d1.X(), d1.Y(), d1.Z());
}

GEntity::GeomType OCCEdge::geomType() const
{
  if(curve.IsNull()){
    if (curve2d->DynamicType() == STANDARD_TYPE(Geom_Circle))
      return Circle;
    else if (curve2d->DynamicType() == STANDARD_TYPE(Geom_Line))
      return Line;
    else if (curve2d->DynamicType() == STANDARD_TYPE(Geom_Ellipse))
      return Ellipse;
    else if (curve2d->DynamicType() == STANDARD_TYPE(Geom_Parabola))
      return Parabola;
    else if (curve2d->DynamicType() == STANDARD_TYPE(Geom_Hyperbola))
      return Hyperbola;
    else if (curve2d->DynamicType() == STANDARD_TYPE(Geom_TrimmedCurve))
      return TrimmedCurve;
    else if (curve2d->DynamicType() == STANDARD_TYPE(Geom_OffsetCurve))
      return OffsetCurve;
    else if (curve2d->DynamicType() == STANDARD_TYPE(Geom_BSplineCurve))
      return BSpline;
    else if (curve2d->DynamicType() == STANDARD_TYPE(Geom_BezierCurve))
      return Bezier;
    else if (curve2d->DynamicType() == STANDARD_TYPE(Geom_Conic))
      return Conic;
    return Unknown;
  }
  else{
    if (curve->DynamicType() == STANDARD_TYPE(Geom_Circle))
      return Circle;
    else if (curve->DynamicType() == STANDARD_TYPE(Geom_Line))
      return Line;
    else if (curve->DynamicType() == STANDARD_TYPE(Geom_Parabola))
      return Parabola;
    else if (curve->DynamicType() == STANDARD_TYPE(Geom_Hyperbola))
      return Hyperbola;
    else if (curve->DynamicType() == STANDARD_TYPE(Geom_TrimmedCurve))
      return TrimmedCurve;
    else if (curve->DynamicType() == STANDARD_TYPE(Geom_OffsetCurve))
      return OffsetCurve;
    else if (curve->DynamicType() == STANDARD_TYPE(Geom_Ellipse))
      return Ellipse;
    else if (curve->DynamicType() == STANDARD_TYPE(Geom_BSplineCurve))
      return BSpline;
    else if (curve->DynamicType() == STANDARD_TYPE(Geom_BezierCurve))
      return Bezier;
    else if (curve2d->DynamicType() == STANDARD_TYPE(Geom_Conic))
      return Conic;
    return Unknown;
  }
}

int OCCEdge::minimumMeshSegments() const
{
  int np;
  if(geomType() == Line)
    np = GEdge::minimumMeshSegments();
  else
    np = CTX::instance()->mesh.minCurvPoints - 1;

  // if the edge is closed, ensure that at least 3 points are
  // generated in the 1D mesh (4 segments, one of which is
  // degenerated)
  if (getBeginVertex() == getEndVertex()) np = std::max(4, np);

  return std::max(np, meshAttributes.minimumMeshSegments);
}

int OCCEdge::minimumDrawSegments() const
{
  if(geomType() == Line)
    return GEdge::minimumDrawSegments();
  else
    return CTX::instance()->geom.numSubEdges * GEdge::minimumDrawSegments();
}

double OCCEdge::curvature(double par) const
{
  const double eps = 1.e-15;

  Standard_Real Crv;
  if (curve.IsNull()){
    Geom2dLProp_CLProps2d aCLProps(curve2d, 2, eps);
    aCLProps.SetParameter(par);
    if(!aCLProps.IsTangentDefined())
      Crv = eps;
    else
      Crv = aCLProps.Curvature();
  }
  else{
    BRepAdaptor_Curve brepc(c);
    BRepLProp_CLProps prop(brepc, 2, eps);
    prop.SetParameter(par);
    if(!prop.IsTangentDefined())
      Crv = eps;
    else
      Crv = prop.Curvature();
  }
  if(Crv <= eps) Crv = eps;
  return Crv;
}

void OCCEdge::writeGEO(FILE *fp)
{
  if(geomType() == Circle){
    gp_Pnt center;
    if(curve.IsNull()){
      center = Handle(Geom_Circle)::DownCast(curve2d)->Location();
    }
    else{
      center = Handle(Geom_Circle)::DownCast(curve)->Location();
    }
    // GEO supports only circle arcs < Pi
    if(s1 - s0 < M_PI){
      fprintf(fp, "p%d = newp;\n", tag());
      fprintf(fp, "Point(p%d + 1) = {%.16g, %.16g, %.16g};\n",
              tag(), center.X(), center.Y(), center.Z());
      fprintf(fp, "Circle(%d) = {%d, p%d + 1, %d};\n",
              tag(), getBeginVertex()->tag(), tag(), getEndVertex()->tag());
    }
    else
      GEdge::writeGEO(fp);
  }
  else
    GEdge::writeGEO(fp);
}

// sometimes, we ask to replace the ending points of the curve
// in gluing operations for example
void OCCEdge::replaceEndingPointsInternals(GVertex *g0, GVertex *g1)
{
  TopoDS_Vertex aV1 = *((TopoDS_Vertex*)v0->getNativePtr());
  TopoDS_Vertex aV2 = *((TopoDS_Vertex*)v1->getNativePtr());
  TopoDS_Vertex aVR1 = *((TopoDS_Vertex*)g0->getNativePtr());
  TopoDS_Vertex aVR2 = *((TopoDS_Vertex*)g1->getNativePtr());

  //  printf("%p %p --- %p %p replacing %d %d by %d %d in occedge %d\n",
  //	 v0,v1,g0,g1,v0->tag(),v1->tag(),g0->tag(),g1->tag(),tag());

  Standard_Boolean bIsDE = BRep_Tool::Degenerated(c);

  TopoDS_Edge aEx = c;
  aEx.Orientation(TopAbs_FORWARD);

  Standard_Real t1=s0;
  Standard_Real t2=s1;

  aVR1.Orientation(TopAbs_FORWARD);
  aVR2.Orientation(TopAbs_REVERSED);

  if (bIsDE) {
    Standard_Real aTol;
    BRep_Builder aBB;
    TopoDS_Edge E;
    //TopAbs_Orientation anOrE;
    //anOrE = c.Orientation();
    aTol = BRep_Tool::Tolerance(c);
    E = aEx;
    E.EmptyCopy();
    aBB.Add(E, aVR1);
    aBB.Add(E, aVR2);
    aBB.Range(E, t1, t2);
    aBB.Degenerated(E, Standard_True);
    aBB.UpdateEdge(E, aTol);
    _replacement=E;
  }
  else {
#if (OCC_VERSION_MAJOR == 6) && (OCC_VERSION_MINOR < 6)
    BOPTools_Tools::MakeSplitEdge(aEx, aVR1, t1, aVR2, t2, _replacement);
#else
    BOPTools_AlgoTools::MakeSplitEdge(aEx, aVR1, t1, aVR2, t2, _replacement);
#endif
  }
  TopoDS_Edge temp = c;
  c = _replacement;
  _replacement = temp;
  curve = BRep_Tool::Curve(c, s0, s1);
  //build the reverse curve
  c_rev = c;
  c_rev.Reverse();
}

#endif