-// Copyright (C) 2007-2015 CEA/DEN, EDF R&D, OPEN CASCADE
+// Copyright (C) 2007-2016 CEA/DEN, EDF R&D, OPEN CASCADE
//
// Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
// CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS
#include "SMESH_TypeDefs.hxx"
#include "SMESH_subMesh.hxx"
-#include <Basics_OCCTVersion.hxx>
-
#include <BRepAdaptor_Curve.hxx>
#include <BRepLProp.hxx>
#include <BRep_Tool.hxx>
bool SMESH_Algo::Features::IsCompatible( const SMESH_Algo::Features& algo2 ) const
{
if ( _dim > algo2._dim ) return algo2.IsCompatible( *this );
- // algo2 is of highter dimension
+ // algo2 is of higher dimension
if ( _outElemTypes.empty() || algo2._inElemTypes.empty() )
return false;
bool compatible = true;
//=============================================================================
/*!
- * Usually an algoritm has nothing to save
+ * Usually an algorithm has nothing to save
*/
//=============================================================================
return false;
SMESHDS_SubMesh * eSubMesh = theMesh->MeshElements( theEdge );
- if ( !eSubMesh || ( eSubMesh->NbElements()==0 && eSubMesh->NbNodes() == 0))
+ if ( !eSubMesh || ( eSubMesh->NbElements() == 0 && eSubMesh->NbNodes() == 0))
return false; // edge is not meshed
int nbNodes = 0;
TopExp::Vertices(theEdge, v1, v2);
const SMDS_MeshNode* n1 = VertexNode( v1, eSubMesh, 0 );
const SMDS_MeshNode* n2 = VertexNode( v2, eSubMesh, 0 );
+ const SMDS_MeshNode* nEnd[2] = { nbNodes ? theNodes.begin()->second : 0,
+ nbNodes ? theNodes.rbegin()->second : 0 };
Standard_Real f, l;
BRep_Tool::Range(theEdge, f, l);
if ( v1.Orientation() != TopAbs_FORWARD )
std::swap( f, l );
- if ( n1 && ++nbNodes )
+ if ( n1 && n1 != nEnd[0] && n1 != nEnd[1] && ++nbNodes )
theNodes.insert( make_pair( f, n1 ));
- if ( n2 && ++nbNodes )
+ if ( n2 && n2 != nEnd[0] && n2 != nEnd[1] && ++nbNodes )
theNodes.insert( make_pair( l, n2 ));
- return theNodes.size() == nbNodes;
+ return (int)theNodes.size() == nbNodes;
}
//================================================================================
{
SMESH_HypoFilter* filter = new SMESH_HypoFilter();
filter->Init( filter->HasName( _compatibleHypothesis[0] ));
- for ( int i = 1; i < _compatibleHypothesis.size(); ++i )
+ for ( size_t i = 1; i < _compatibleHypothesis.size(); ++i )
filter->Or( filter->HasName( _compatibleHypothesis[ i ] ));
SMESH_HypoFilter* filterNoAux = new SMESH_HypoFilter( filter );
*/
//================================================================================
-GeomAbs_Shape SMESH_Algo::Continuity(TopoDS_Edge E1,
- TopoDS_Edge E2)
+GeomAbs_Shape SMESH_Algo::Continuity(const TopoDS_Edge& theE1,
+ const TopoDS_Edge& theE2)
{
- //E1.Orientation(TopAbs_FORWARD), E2.Orientation(TopAbs_FORWARD); // avoid pb with internal edges
+ // avoid pb with internal edges
+ TopoDS_Edge E1 = theE1, E2 = theE2;
if (E1.Orientation() > TopAbs_REVERSED) // INTERNAL
E1.Orientation( TopAbs_FORWARD );
if (E2.Orientation() > TopAbs_REVERSED) // INTERNAL
case GeomAbs_Hyperbola:
case GeomAbs_Parabola:
return false;
- // case GeomAbs_BezierCurve:
- // case GeomAbs_BSplineCurve:
- // case GeomAbs_OtherCurve:
+ // case GeomAbs_BezierCurve:
+ // case GeomAbs_BSplineCurve:
+ // case GeomAbs_OtherCurve:
default:;
}
- const double f = curve.FirstParameter();
- const double l = curve.LastParameter();
- const gp_Pnt pf = curve.Value( f );
- const gp_Pnt pl = curve.Value( l );
- const gp_Vec v1( pf, pl );
- const double v1Len = v1.Magnitude();
- if ( v1Len < std::numeric_limits< double >::min() )
+
+ // evaluate how far from a straight line connecting the curve ends
+ // stand internal points of the curve
+ double f = curve.FirstParameter();
+ double l = curve.LastParameter();
+ gp_Pnt pf = curve.Value( f );
+ gp_Pnt pl = curve.Value( l );
+ gp_Vec lineVec( pf, pl );
+ double lineLen2 = lineVec.SquareMagnitude();
+ if ( lineLen2 < std::numeric_limits< double >::min() )
return false; // E seems closed
- const double tol = Min( 10 * curve.Tolerance(), v1Len * 1e-2 );
+
+ double edgeTol = 10 * curve.Tolerance();
+ double lenTol2 = lineLen2 * 1e-4;
+ double tol2 = Min( edgeTol * edgeTol, lenTol2 );
+
const double nbSamples = 7;
for ( int i = 0; i < nbSamples; ++i )
{
- const double r = ( i + 1 ) / nbSamples;
- const gp_Pnt pi = curve.Value( f * r + l * ( 1 - r ));
- const gp_Vec vi( pf, pi );
- const double h = 0.5 * v1.Crossed( vi ).Magnitude() / v1Len;
- if ( h > tol )
+ double r = ( i + 1 ) / nbSamples;
+ gp_Pnt pi = curve.Value( f * r + l * ( 1 - r ));
+ gp_Vec vi( pf, pi );
+ double h2 = lineVec.Crossed( vi ).SquareMagnitude() / lineLen2;
+ if ( h2 > tol2 )
return false;
}
return true;
*/
//================================================================================
-bool SMESH_Algo::isDegenerated( const TopoDS_Edge & E )
+bool SMESH_Algo::isDegenerated( const TopoDS_Edge & E, const bool checkLength )
{
+ if ( checkLength )
+ return EdgeLength( E ) == 0;
double f,l;
TopLoc_Location loc;
Handle(Geom_Curve) C = BRep_Tool::Curve( E, loc, f,l );
if ( !fIt->more() )
return MEr_EMPTY;
- // We check that olny links on EDGEs encouter once, the rest links, twice
+ // We check that only links on EDGEs encouter once, the rest links, twice
set< SMESH_TLink > links;
while ( fIt->more() )
{
return error( COMPERR_BAD_INPUT_MESH, "Mesh built on shape expected");
}
+//=======================================================================
+//function : IsApplicableToShape
+//purpose : Return true if the algorithm can mesh a given shape
+//=======================================================================
+
+bool SMESH_Algo::IsApplicableToShape(const TopoDS_Shape & shape, bool toCheckAll) const
+{
+ return true;
+}
+
//=======================================================================
//function : CancelCompute
//purpose : Sets _computeCanceled to true. It's usage depends on