-// Copyright (C) 2007-2008 CEA/DEN, EDF R&D, OPEN CASCADE
+// Copyright (C) 2007-2013 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
+// Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
+// CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS
//
-// This library is free software; you can redistribute it and/or
-// modify it under the terms of the GNU Lesser General Public
-// License as published by the Free Software Foundation; either
-// version 2.1 of the License.
+// This library is free software; you can redistribute it and/or
+// modify it under the terms of the GNU Lesser General Public
+// License as published by the Free Software Foundation; either
+// version 2.1 of the License.
//
-// This library is distributed in the hope that it will be useful,
-// but WITHOUT ANY WARRANTY; without even the implied warranty of
-// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
-// Lesser General Public License for more details.
+// This library is distributed in the hope that it will be useful,
+// but WITHOUT ANY WARRANTY; without even the implied warranty of
+// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+// Lesser General Public License for more details.
//
-// You should have received a copy of the GNU Lesser General Public
-// License along with this library; if not, write to the Free Software
-// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+// You should have received a copy of the GNU Lesser General Public
+// License along with this library; if not, write to the Free Software
+// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
//
-// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
+// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
//
+
// SMESH SMESH_I : idl implementation based on 'SMESH' unit's calsses
// File : SMESH_Filter_i.cxx
// Author : Alexey Petrov, OCC
// Module : SMESH
-//
-#include "SMESH_Filter_i.hxx"
-#include "SMESH_Gen_i.hxx"
-#include "SMESH_PythonDump.hxx"
+#include "SMESH_Filter_i.hxx"
+#include "SMDS_ElemIterator.hxx"
#include "SMDS_Mesh.hxx"
-#include "SMDS_MeshNode.hxx"
#include "SMDS_MeshElement.hxx"
-
+#include "SMDS_MeshNode.hxx"
#include "SMESHDS_Mesh.hxx"
+#include "SMESH_Gen_i.hxx"
+#include "SMESH_Group_i.hxx"
+#include "SMESH_PythonDump.hxx"
+
+#include <SALOMEDS_wrap.hxx>
+#include <GEOM_wrap.hxx>
#include <BRep_Tool.hxx>
#include <Geom_CylindricalSurface.hxx>
{
if (!myMeshDS || myShape.IsNull()) return;
- // is subshape of main shape?
+ // is sub-shape of main shape?
TopoDS_Shape aMainShape = myMeshDS->ShapeToMesh();
if (aMainShape.IsNull()) {
myIsSubshape = false;
{
if (!myMeshDS || myShape.IsNull()) return;
- // is subshape of main shape?
+ // is sub-shape of main shape?
TopoDS_Shape aMainShape = myMeshDS->ShapeToMesh();
if (aMainShape.IsNull()) {
myIsSubshape = false;
{
if ( theName != 0 )
{
- SMESH_Gen_i* aSMESHGen = SMESH_Gen_i::GetSMESHGen();
- SALOMEDS::Study_ptr aStudy = aSMESHGen->GetCurrentStudy();
- if (!CORBA::is_nil(aStudy))
+ SMESH_Gen_i* aSMESHGen = SMESH_Gen_i::GetSMESHGen();
+ SALOMEDS::Study_var aStudy = aSMESHGen->GetCurrentStudy();
+ if ( !aStudy->_is_nil() )
{
- SALOMEDS::Study::ListOfSObject_var aList =
- aStudy->FindObjectByName( theName, "GEOM" );
+ SALOMEDS::Study::ListOfSObject_var aList = aStudy->FindObjectByName( theName, "GEOM" );
if ( aList->length() > 0 )
{
- GEOM::GEOM_Object_var aGeomObj = GEOM::GEOM_Object::_narrow( aList[ 0 ]->GetObject() );
- if ( !aGeomObj->_is_nil() )
- {
- GEOM::GEOM_Gen_ptr aGEOMGen = SMESH_Gen_i::GetGeomEngine();
- TopoDS_Shape aLocShape = aSMESHGen->GetShapeReader()->GetShape( aGEOMGen, aGeomObj );
- return aLocShape;
- }
+ CORBA::Object_var anObj = aList[ 0 ]->GetObject();
+ GEOM::GEOM_Object_var aGeomObj = GEOM::GEOM_Object::_narrow( anObj );
+ TopoDS_Shape shape = aSMESHGen->GeomObjectToShape( aGeomObj );
+ SALOME::UnRegister( aList ); // UnRegister() objects in aList
+ return shape;
}
}
}
static TopoDS_Shape getShapeByID (const char* theID)
{
- if (theID != 0 && theID != "") {
- SMESH_Gen_i* aSMESHGen = SMESH_Gen_i::GetSMESHGen();
- SALOMEDS::Study_ptr aStudy = aSMESHGen->GetCurrentStudy();
- if (aStudy != 0) {
- SALOMEDS::SObject_var aSObj = aStudy->FindObjectID(theID);
- SALOMEDS::GenericAttribute_var anAttr;
- if (!aSObj->_is_nil() && aSObj->FindAttribute(anAttr, "AttributeIOR")) {
- SALOMEDS::AttributeIOR_var anIOR = SALOMEDS::AttributeIOR::_narrow(anAttr);
- CORBA::String_var aVal = anIOR->Value();
- CORBA::Object_var obj = aStudy->ConvertIORToObject(aVal);
+ if ( theID && strlen( theID ) > 0 ) {
+ SMESH_Gen_i* aSMESHGen = SMESH_Gen_i::GetSMESHGen();
+ SALOMEDS::Study_var aStudy = aSMESHGen->GetCurrentStudy();
+ if ( !aStudy->_is_nil() ) {
+ SALOMEDS::SObject_wrap aSObj = aStudy->FindObjectID(theID);
+ if ( !aSObj->_is_nil() ) {
+ CORBA::Object_var obj = aSObj->GetObject();
GEOM::GEOM_Object_var aGeomObj = GEOM::GEOM_Object::_narrow(obj);
-
- if (!aGeomObj->_is_nil()) {
- GEOM::GEOM_Gen_ptr aGEOMGen = SMESH_Gen_i::GetGeomEngine();
- TopoDS_Shape aLocShape = aSMESHGen->GetShapeReader()->GetShape( aGEOMGen, aGeomObj );
- return aLocShape;
- }
+ return aSMESHGen->GeomObjectToShape( aGeomObj );
}
}
}
return TopoDS_Shape();
}
-static char* getShapeNameByID (const char* theID)
+static std::string getShapeNameByID (const char* theID)
{
- char* aName = "";
-
- if (theID != 0 && theID != "") {
- SMESH_Gen_i* aSMESHGen = SMESH_Gen_i::GetSMESHGen();
- SALOMEDS::Study_ptr aStudy = aSMESHGen->GetCurrentStudy();
- if (aStudy != 0) {
- //SALOMEDS::SObject_var aSObj = aStudy->FindObjectIOR( theID );
- SALOMEDS::SObject_var aSObj = aStudy->FindObjectID(theID);
- SALOMEDS::GenericAttribute_var anAttr;
- if (!aSObj->_is_nil() && aSObj->FindAttribute(anAttr, "AttributeName")) {
- SALOMEDS::AttributeName_var aNameAttr = SALOMEDS::AttributeName::_narrow(anAttr);
- aName = aNameAttr->Value();
+ if ( theID && strlen( theID ) > 0 ) {
+ SMESH_Gen_i* aSMESHGen = SMESH_Gen_i::GetSMESHGen();
+ SALOMEDS::Study_var aStudy = aSMESHGen->GetCurrentStudy();
+ if ( !aStudy->_is_nil() ) {
+ SALOMEDS::SObject_wrap aSObj = aStudy->FindObjectID(theID);
+ if ( !aSObj->_is_nil() ) {
+ CORBA::String_var name = aSObj->GetName();
+ return name.in();
}
}
}
-
- return aName;
+ return "";
}
/*
Functor_i::~Functor_i()
{
- //TPythonDump()<<this<<".Destroy()";
+ //TPythonDump()<<this<<".UnRegister()";
}
void Functor_i::SetMesh( SMESH_Mesh_ptr theMesh )
return myNumericalFunctorPtr->GetValue( theId );
}
+SMESH::Histogram* NumericalFunctor_i::GetHistogram(CORBA::Short nbIntervals, CORBA::Boolean isLogarithmic)
+{
+ std::vector<int> nbEvents;
+ std::vector<double> funValues;
+ std::vector<int> elements;
+ myNumericalFunctorPtr->GetHistogram(nbIntervals,nbEvents,funValues,elements,0,isLogarithmic);
+
+ SMESH::Histogram_var histogram = new SMESH::Histogram;
+
+ nbIntervals = CORBA::Short( Min( int( nbEvents.size()),
+ int( funValues.size() - 1 )));
+ if ( nbIntervals > 0 )
+ {
+ histogram->length( nbIntervals );
+ for ( int i = 0; i < nbIntervals; ++i )
+ {
+ HistogramRectangle& rect = histogram[i];
+ rect.nbEvents = nbEvents[i];
+ rect.min = funValues[i];
+ rect.max = funValues[i+1];
+ }
+ }
+ return histogram._retn();
+}
+
+SMESH::Histogram* NumericalFunctor_i::GetLocalHistogram(CORBA::Short nbIntervals,
+ CORBA::Boolean isLogarithmic,
+ SMESH::SMESH_IDSource_ptr object)
+{
+ SMESH::Histogram_var histogram = new SMESH::Histogram;
+
+ std::vector<int> nbEvents;
+ std::vector<double> funValues;
+ std::vector<int> elements;
+
+ SMDS_ElemIteratorPtr elemIt;
+ if ( SMESH::DownCast< SMESH_GroupOnFilter_i* >( object ) ||
+ SMESH::DownCast< SMESH::Filter_i* >( object ))
+ {
+ elemIt = SMESH_Mesh_i::GetElements( object, GetElementType() );
+ }
+ else
+ {
+ SMESH::SMESH_Mesh_var mesh = object->GetMesh();
+ SMESH::long_array_var objNbElems = object->GetNbElementsByType();
+ SMESH::long_array_var meshNbElems = mesh-> GetNbElementsByType();
+ if ( meshNbElems[ GetElementType() ] !=
+ objNbElems [ GetElementType() ] )
+ {
+ elements.reserve( objNbElems[ GetElementType() ]);
+ elemIt = SMESH_Mesh_i::GetElements( object, GetElementType() );
+ }
+ }
+ if ( elemIt )
+ {
+ while ( elemIt->more() )
+ elements.push_back( elemIt->next()->GetID() );
+ if ( elements.empty() ) return histogram._retn();
+ }
+
+ myNumericalFunctorPtr->GetHistogram(nbIntervals,nbEvents,funValues,elements,0,isLogarithmic);
+
+ nbIntervals = CORBA::Short( Min( int( nbEvents.size()),
+ int( funValues.size() - 1 )));
+ if ( nbIntervals > 0 )
+ {
+ histogram->length( nbIntervals );
+ for ( int i = 0; i < nbIntervals; ++i )
+ {
+ HistogramRectangle& rect = histogram[i];
+ rect.nbEvents = nbEvents[i];
+ rect.min = funValues[i];
+ rect.max = funValues[i+1];
+ }
+ }
+ return histogram._retn();
+}
+
void NumericalFunctor_i::SetPrecision( CORBA::Long thePrecision )
{
myNumericalFunctorPtr->SetPrecision( thePrecision );
return SMESH::FT_Taper;
}
-
/*
Class : Skew_i
Description : Functor for calculating skew in degrees
return SMESH::FT_Volume3D;
}
+/*
+ Class : MaxElementLength2D_i
+ Description : Functor for calculating maximum length of 2D element
+*/
+MaxElementLength2D_i::MaxElementLength2D_i()
+{
+ myNumericalFunctorPtr.reset( new Controls::MaxElementLength2D() );
+ myFunctorPtr = myNumericalFunctorPtr;
+}
+
+FunctorType MaxElementLength2D_i::GetFunctorType()
+{
+ return SMESH::FT_MaxElementLength2D;
+}
+
+/*
+ Class : MaxElementLength3D_i
+ Description : Functor for calculating maximum length of 3D element
+*/
+MaxElementLength3D_i::MaxElementLength3D_i()
+{
+ myNumericalFunctorPtr.reset( new Controls::MaxElementLength3D() );
+ myFunctorPtr = myNumericalFunctorPtr;
+}
+
+FunctorType MaxElementLength3D_i::GetFunctorType()
+{
+ return SMESH::FT_MaxElementLength3D;
+}
+
/*
Class : Length_i
Description : Functor for calculating length off edge
{
INFOS("Length2D_i::GetValues");
SMESH::Controls::Length2D::TValues aValues;
- myLength2DPtr->GetValues( aValues );
+ (dynamic_cast<SMESH::Controls::Length2D*>(myFunctorPtr.get()))->GetValues( aValues );
long i = 0, iEnd = aValues.size();
SMESH::Length2D::Values_var aResult = new SMESH::Length2D::Values(iEnd);
+ aResult->length(iEnd);
SMESH::Controls::Length2D::TValues::const_iterator anIter;
for ( anIter = aValues.begin() ; anIter != aValues.end(); anIter++, i++ )
return SMESH::FT_MultiConnection;
}
+/*
+ Class : BallDiameter_i
+ Description : Functor returning diameter of a ball element
+*/
+BallDiameter_i::BallDiameter_i()
+{
+ myNumericalFunctorPtr.reset( new Controls::BallDiameter() );
+ myFunctorPtr = myNumericalFunctorPtr;
+}
+
+FunctorType BallDiameter_i::GetFunctorType()
+{
+ return SMESH::FT_BallDiameter;
+}
+
/*
Class : MultiConnection2D_i
Description : Functor for calculating number of faces conneted to the edge
{
INFOS("MultiConnection2D_i::GetValues");
SMESH::Controls::MultiConnection2D::MValues aValues;
- myMulticonnection2DPtr->GetValues( aValues );
-
+ (dynamic_cast<SMESH::Controls::MultiConnection2D*>(myFunctorPtr.get()))->GetValues( aValues );
+
long i = 0, iEnd = aValues.size();
SMESH::MultiConnection2D::Values_var aResult = new SMESH::MultiConnection2D::Values(iEnd);
+ aResult->length(iEnd);
SMESH::Controls::MultiConnection2D::MValues::const_iterator anIter;
for ( anIter = aValues.begin() ; anIter != aValues.end(); anIter++, i++ )
return myPredicatePtr->IsSatisfy( theId );
}
+CORBA::Long Predicate_i::NbSatisfying( SMESH::SMESH_IDSource_ptr obj )
+{
+ SMESH::SMESH_Mesh_var meshVar = obj->GetMesh();
+ const SMDS_Mesh* meshDS = MeshPtr2SMDSMesh( meshVar );
+ if ( !meshDS )
+ return 0;
+ myPredicatePtr->SetMesh( meshDS );
+
+ SMDSAbs_ElementType elemType = SMDSAbs_ElementType( GetElementType() );
+
+ int nb = 0;
+ SMDS_ElemIteratorPtr elemIt =
+ SMESH::DownCast<SMESH_Mesh_i*>( meshVar )->GetElements( obj, GetElementType() );
+ if ( elemIt )
+ while ( elemIt->more() )
+ {
+ const SMDS_MeshElement* e = elemIt->next();
+ if ( e && e->GetType() == elemType )
+ nb += myPredicatePtr->IsSatisfy( e->GetID() );
+ }
+ return nb;
+}
+
Controls::PredicatePtr Predicate_i::GetPredicate()
{
return myPredicatePtr;
return SMESH::FT_BadOrientedVolume;
}
+/*
+ Class : BareBorderVolume_i
+ Description : Verify whether a mesh volume has a free facet without a face on it
+*/
+BareBorderVolume_i::BareBorderVolume_i()
+{
+ Controls::PredicatePtr control( new Controls::BareBorderVolume() );
+ myFunctorPtr = myPredicatePtr = control;
+};
+
+FunctorType BareBorderVolume_i::GetFunctorType()
+{
+ return SMESH::FT_BareBorderVolume;
+}
+
+/*
+ Class : BareBorderFace_i
+ Description : Verify whether a mesh face has a free border without an edge on it
+*/
+BareBorderFace_i::BareBorderFace_i()
+{
+ Controls::PredicatePtr control( new Controls::BareBorderFace() );
+ myFunctorPtr = myPredicatePtr = control;
+};
+
+FunctorType BareBorderFace_i::GetFunctorType()
+{
+ return SMESH::FT_BareBorderFace;
+}
+
+/*
+ Class : OverConstrainedVolume_i
+ Description : Verify whether a mesh volume has only one facet shared with other volumes
+*/
+OverConstrainedVolume_i::OverConstrainedVolume_i()
+{
+ Controls::PredicatePtr control( new Controls::OverConstrainedVolume() );
+ myFunctorPtr = myPredicatePtr = control;
+};
+
+FunctorType OverConstrainedVolume_i::GetFunctorType()
+{
+ return SMESH::FT_OverConstrainedVolume;
+}
+
+/*
+ Class : OverConstrainedFace_i
+ Description : Verify whether a mesh face has only one border shared with other faces
+*/
+OverConstrainedFace_i::OverConstrainedFace_i()
+{
+ Controls::PredicatePtr control( new Controls::OverConstrainedFace() );
+ myFunctorPtr = myPredicatePtr = control;
+};
+
+FunctorType OverConstrainedFace_i::GetFunctorType()
+{
+ return SMESH::FT_OverConstrainedFace;
+}
+
/*
Class : BelongToGeom_i
Description : Predicate for selection on geometrical support
else
myShapeID = 0;
- if ( myShapeID && strcmp(myShapeName, getShapeNameByID(myShapeID)) == 0 )
+ if ( myShapeID && myShapeName == getShapeNameByID(myShapeID))
myBelongToGeomPtr->SetGeom( getShapeByID(myShapeID) );
else
myBelongToGeomPtr->SetGeom( getShapeByName( myShapeName ) );
else
myShapeID = 0;
- if ( myShapeID && strcmp(myShapeName, getShapeNameByID(myShapeID)) == 0 )
+ if ( myShapeID && myShapeName == getShapeNameByID(myShapeID))
myElementsOnSurfacePtr->SetSurface( getShapeByID(myShapeID), (SMDSAbs_ElementType)theType );
else
myElementsOnSurfacePtr->SetSurface( getShapeByName( myShapeName ), (SMDSAbs_ElementType)theType );
else
myShapeID = 0;
- if ( myShapeID && strcmp(myShapeName, getShapeNameByID(myShapeID)) == 0 )
+ if ( myShapeID && myShapeName == getShapeNameByID(myShapeID))
myLyingOnGeomPtr->SetGeom( getShapeByID(myShapeID) );
else
myLyingOnGeomPtr->SetGeom( getShapeByName( myShapeName ) );
return SMESH::FT_FreeNodes;
}
+/*
+ Class : EqualNodes_i
+ Description : Predicate for Equal nodes
+*/
+EqualNodes_i::EqualNodes_i()
+{
+ myCoincidentNodesPtr.reset(new Controls::CoincidentNodes());
+ myFunctorPtr = myPredicatePtr = myCoincidentNodesPtr;
+}
+
+FunctorType EqualNodes_i::GetFunctorType()
+{
+ return SMESH::FT_EqualNodes;
+}
+
+void EqualNodes_i::SetTolerance( double tol )
+{
+ myCoincidentNodesPtr->SetTolerance( tol );
+}
+
+double EqualNodes_i::GetTolerance()
+{
+ return myCoincidentNodesPtr->GetTolerance();
+}
+
+/*
+ Class : EqualEdges_i
+ Description : Predicate for Equal Edges
+*/
+EqualEdges_i::EqualEdges_i()
+{
+ myPredicatePtr.reset(new Controls::CoincidentElements1D());
+ myFunctorPtr = myPredicatePtr;
+}
+
+FunctorType EqualEdges_i::GetFunctorType()
+{
+ return SMESH::FT_EqualEdges;
+}
+
+/*
+ Class : EqualFaces_i
+ Description : Predicate for Equal Faces
+*/
+EqualFaces_i::EqualFaces_i()
+{
+ myPredicatePtr.reset(new Controls::CoincidentElements2D());
+ myFunctorPtr = myPredicatePtr;
+}
+
+FunctorType EqualFaces_i::GetFunctorType()
+{
+ return SMESH::FT_EqualFaces;
+}
+
+/*
+ Class : EqualVolumes_i
+ Description : Predicate for Equal Volumes
+*/
+EqualVolumes_i::EqualVolumes_i()
+{
+ myPredicatePtr.reset(new Controls::CoincidentElements3D());
+ myFunctorPtr = myPredicatePtr;
+}
+
+FunctorType EqualVolumes_i::GetFunctorType()
+{
+ return SMESH::FT_EqualVolumes;
+}
+
+
/*
Class : RangeOfIds_i
Description : Predicate for Range of Ids.
GeometryType ElemGeomType_i::GetGeometryType() const
{
- return (GeometryType)myElemGeomTypePtr->GetGeomType();;
+ return (GeometryType)myElemGeomTypePtr->GetGeomType();
}
FunctorType ElemGeomType_i::GetFunctorType()
}
/*
- Class : Comparator_i
- Description : Base class for comparators
+ Class : ElemEntityType_i
+ Description : Predicate check is element has indicated entity type
*/
-Comparator_i::Comparator_i():
- myNumericalFunctor( NULL )
-{}
-
-Comparator_i::~Comparator_i()
-{
- if ( myNumericalFunctor )
- myNumericalFunctor->Destroy();
-}
-
-void Comparator_i::SetMargin( CORBA::Double theValue )
+ElemEntityType_i::ElemEntityType_i()
{
- myComparatorPtr->SetMargin( theValue );
- TPythonDump()<<this<<".SetMargin("<<theValue<<")";
+ myElemEntityTypePtr.reset(new Controls::ElemEntityType());
+ myFunctorPtr = myPredicatePtr = myElemEntityTypePtr;
}
-CORBA::Double Comparator_i::GetMargin()
+void ElemEntityType_i::SetElementType(ElementType theType)
{
- return myComparatorPtr->GetMargin();
+ myElemEntityTypePtr->SetType(SMDSAbs_ElementType(theType));
+ TPythonDump()<<this<<".SetElementType("<<theType<<")";
}
-void Comparator_i::SetNumFunctor( NumericalFunctor_ptr theFunct )
+void ElemEntityType_i::SetEntityType(EntityType theEntityType)
{
- if ( myNumericalFunctor )
- myNumericalFunctor->Destroy();
-
- myNumericalFunctor = DownCast<NumericalFunctor_i*>(theFunct);
-
- if ( myNumericalFunctor )
- {
- myComparatorPtr->SetNumFunctor( myNumericalFunctor->GetNumericalFunctor() );
- myNumericalFunctor->Register();
- TPythonDump()<<this<<".SetNumFunctor("<<myNumericalFunctor<<")";
- }
+ myElemEntityTypePtr->SetElemEntityType(SMDSAbs_EntityType (theEntityType));
+ TPythonDump()<<this<<".SetEntityType("<<theEntityType<<")";
}
-
-Controls::ComparatorPtr Comparator_i::GetComparator()
+EntityType ElemEntityType_i::GetEntityType() const
{
- return myComparatorPtr;
+ return (EntityType) myElemEntityTypePtr->GetElemEntityType();
}
-NumericalFunctor_i* Comparator_i::GetNumFunctor_i()
+FunctorType ElemEntityType_i::GetFunctorType()
{
- return myNumericalFunctor;
+ return SMESH::FT_EntityType;
}
-
/*
- Class : LessThan_i
- Description : Comparator "<"
+ Class : CoplanarFaces_i
+ Description : Returns true if a mesh face is a coplanar neighbour to a given one
*/
-LessThan_i::LessThan_i()
+CoplanarFaces_i::CoplanarFaces_i()
{
- myComparatorPtr.reset( new Controls::LessThan() );
- myFunctorPtr = myPredicatePtr = myComparatorPtr;
+ myCoplanarFacesPtr.reset(new Controls::CoplanarFaces());
+ myFunctorPtr = myPredicatePtr = myCoplanarFacesPtr;
}
-FunctorType LessThan_i::GetFunctorType()
+void CoplanarFaces_i::SetFace ( CORBA::Long theFaceID )
{
- return SMESH::FT_LessThan;
+ myCoplanarFacesPtr->SetFace(theFaceID);
+ TPythonDump()<<this<<".SetFace("<<theFaceID<<")";
}
-
-/*
- Class : MoreThan_i
- Description : Comparator ">"
-*/
-MoreThan_i::MoreThan_i()
+void CoplanarFaces_i::SetTolerance( CORBA::Double theToler )
{
- myComparatorPtr.reset( new Controls::MoreThan() );
- myFunctorPtr = myPredicatePtr = myComparatorPtr;
+ myCoplanarFacesPtr->SetTolerance(theToler);
+ TPythonDump()<<this<<".SetTolerance("<<theToler<<")";
}
-FunctorType MoreThan_i::GetFunctorType()
+CORBA::Long CoplanarFaces_i::GetFace () const
{
- return SMESH::FT_MoreThan;
+ return myCoplanarFacesPtr->GetFace();
}
+char* CoplanarFaces_i::GetFaceAsString () const
+{
+ TCollection_AsciiString str(Standard_Integer(myCoplanarFacesPtr->GetFace()));
+ return CORBA::string_dup( str.ToCString() );
+}
-/*
- Class : EqualTo_i
- Description : Comparator "="
-*/
-EqualTo_i::EqualTo_i()
-: myEqualToPtr( new Controls::EqualTo() )
+CORBA::Double CoplanarFaces_i::GetTolerance() const
{
- myFunctorPtr = myPredicatePtr = myComparatorPtr = myEqualToPtr;
+ return myCoplanarFacesPtr->GetTolerance();
}
-void EqualTo_i::SetTolerance( CORBA::Double theToler )
+FunctorType CoplanarFaces_i::GetFunctorType()
{
- myEqualToPtr->SetTolerance( theToler );
- TPythonDump()<<this<<".SetTolerance("<<theToler<<")";
+ return SMESH::FT_CoplanarFaces;
}
-CORBA::Double EqualTo_i::GetTolerance()
+/*
+ * Class : ConnectedElements_i
+ * Description : Returns true if an element is connected via other elements to the element
+ * located at a given point.
+ */
+ConnectedElements_i::ConnectedElements_i()
{
- return myEqualToPtr->GetTolerance();
+ myConnectedElementsPtr.reset(new Controls::ConnectedElements());
+ myFunctorPtr = myPredicatePtr = myConnectedElementsPtr;
}
-FunctorType EqualTo_i::GetFunctorType()
+FunctorType ConnectedElements_i::GetFunctorType()
{
- return SMESH::FT_EqualTo;
+ return FT_ConnectedElements;
}
-/*
- Class : LogicalNOT_i
- Description : Logical NOT predicate
-*/
-LogicalNOT_i::LogicalNOT_i()
-: myPredicate( NULL ),
- myLogicalNOTPtr( new Controls::LogicalNOT() )
+void ConnectedElements_i::SetElementType( ElementType theType )
{
- myFunctorPtr = myPredicatePtr = myLogicalNOTPtr;
+ myConnectedElementsPtr->SetType( SMDSAbs_ElementType( theType ));
+ TPythonDump() << this << ".SetElementType( " << theType << " )";
}
-LogicalNOT_i::~LogicalNOT_i()
+void ConnectedElements_i::SetPoint( CORBA::Double x, CORBA::Double y, CORBA::Double z )
{
- if ( myPredicate )
- myPredicate->Destroy();
+ myConnectedElementsPtr->SetPoint( x,y,z );
+ myVertexID.clear();
+ TPythonDump() << this << ".SetPoint( " << x << ", " << y << ", " << z << " )";
}
-void LogicalNOT_i::SetPredicate( Predicate_ptr thePredicate )
+void ConnectedElements_i::SetVertex( GEOM::GEOM_Object_ptr vertex )
+ throw (SALOME::SALOME_Exception)
{
- if ( myPredicate )
- myPredicate->Destroy();
+ TopoDS_Shape shape = SMESH_Gen_i::GetSMESHGen()->GeomObjectToShape( vertex );
+ if ( shape.IsNull() )
+ THROW_SALOME_CORBA_EXCEPTION( "ConnectedElements_i::SetVertex(): NULL Vertex",
+ SALOME::BAD_PARAM );
- myPredicate = SMESH::GetPredicate(thePredicate);
+ TopExp_Explorer v( shape, TopAbs_VERTEX );
+ if ( !v.More() )
+ THROW_SALOME_CORBA_EXCEPTION( "ConnectedElements_i::SetVertex(): empty vertex",
+ SALOME::BAD_PARAM );
- if ( myPredicate ){
- myLogicalNOTPtr->SetPredicate(myPredicate->GetPredicate());
- myPredicate->Register();
- TPythonDump()<<this<<".SetPredicate("<<myPredicate<<")";
- }
+ gp_Pnt p = BRep_Tool::Pnt( TopoDS::Vertex( v.Current() ));
+ myConnectedElementsPtr->SetPoint( p.X(), p.Y(), p.Z() );
+ //
+ CORBA::String_var id = vertex->GetStudyEntry();
+ myVertexID = id.in();
+
+ TPythonDump() << this << ".SetVertex( " << vertex << " )";
}
-FunctorType LogicalNOT_i::GetFunctorType()
+void ConnectedElements_i::SetNode ( CORBA::Long nodeID )
+ throw (SALOME::SALOME_Exception)
{
- return SMESH::FT_LogicalNOT;
+ if ( nodeID < 1 )
+ THROW_SALOME_CORBA_EXCEPTION( "ConnectedElements_i::SetNode(): nodeID must be > 0",
+ SALOME::BAD_PARAM );
+
+ myConnectedElementsPtr->SetNode( nodeID );
+ myVertexID.clear();
+ TPythonDump() << this << ".SetNode( " << nodeID << " )";
}
-Predicate_i* LogicalNOT_i::GetPredicate_i()
+/*!
+ * \brief This is a comfort method for Filter dialog
+ */
+void ConnectedElements_i::SetThreshold ( const char* threshold,
+ SMESH::ConnectedElements::ThresholdType type )
+ throw (SALOME::SALOME_Exception)
+{
+ if ( !threshold )
+ THROW_SALOME_CORBA_EXCEPTION( "ConnectedElements_i::SetThreshold(): NULL threshold",
+ SALOME::BAD_PARAM );
+ switch ( type )
+ {
+ case SMESH::ConnectedElements::POINT: // read 3 node coordinates ///////////////////
+ {
+ vector< double > xyz;
+ char* endptr;
+ do
+ {
+ // skip a separator
+ while ( *threshold &&
+ *threshold != '+' &&
+ *threshold != '-' &&
+ !isdigit( *threshold ))
+ ++threshold;
+ if ( !*threshold )
+ break;
+ // read a coordinate
+ xyz.push_back( strtod( threshold, &endptr ));
+ if ( threshold == endptr )
+ {
+ xyz.resize( xyz.size() - 1 );
+ break;
+ }
+ threshold = endptr;
+ }
+ while ( xyz.size() < 3 );
+
+ if ( xyz.size() < 3 )
+ THROW_SALOME_CORBA_EXCEPTION
+ ( "ConnectedElements_i::SetThreshold(): invalid point coordinates", SALOME::BAD_PARAM );
+
+ SetPoint( xyz[0], xyz[1], xyz[2] );
+ break;
+ }
+ case SMESH::ConnectedElements::VERTEX: // get a VERTEX by its entry /////////////////
+ {
+ SALOMEDS::Study_var study = SMESH_Gen_i::GetSMESHGen()->GetCurrentStudy();
+ if ( study->_is_nil() )
+ THROW_SALOME_CORBA_EXCEPTION
+ ( "ConnectedElements_i::SetThreshold(): NULL current study", SALOME::BAD_PARAM );
+ SALOMEDS::SObject_wrap sobj = study->FindObjectID( threshold );
+ if ( sobj->_is_nil() )
+ THROW_SALOME_CORBA_EXCEPTION
+ ( "ConnectedElements_i::SetThreshold(): invalid vertex study entry", SALOME::BAD_PARAM );
+ CORBA::Object_var obj = sobj->GetObject();
+ GEOM::GEOM_Object_wrap vertex = GEOM::GEOM_Object::_narrow( obj );
+ if ( vertex->_is_nil() )
+ THROW_SALOME_CORBA_EXCEPTION
+ ( "ConnectedElements_i::SetThreshold(): no GEOM_Object in SObject", SALOME::BAD_PARAM );
+ SetVertex( vertex );
+ break;
+ }
+ case SMESH::ConnectedElements::NODE: // read a node ID ////////////////////////////
+ {
+ char* endptr;
+ int id = strtol( threshold, &endptr, 10 );
+ if ( threshold == endptr )
+ THROW_SALOME_CORBA_EXCEPTION
+ ( "ConnectedElements_i::SetThreshold(): invalid node ID", SALOME::BAD_PARAM );
+ SetNode( id );
+ break;
+ }
+ default:
+ THROW_SALOME_CORBA_EXCEPTION
+ ( "ConnectedElements_i::SetThreshold(): invalid ThresholdType", SALOME::BAD_PARAM );
+ }
+}
+
+char* ConnectedElements_i::GetThreshold ( SMESH::ConnectedElements::ThresholdType& type )
+{
+ std::string threshold;
+ if ( !myVertexID.empty() )
+ {
+ threshold = myVertexID;
+ type = SMESH::ConnectedElements::VERTEX;
+ }
+ else
+ {
+ std::vector<double> xyz = myConnectedElementsPtr->GetPoint();
+ if ( xyz.size() == 3 )
+ {
+ threshold = SMESH_Comment( xyz[0] ) << "; " << xyz[1] << "; " << xyz[2];
+ type = SMESH::ConnectedElements::POINT;
+ }
+ else
+ {
+ threshold = SMESH_Comment( myConnectedElementsPtr->GetNode() );
+ type = SMESH::ConnectedElements::NODE;
+ }
+ }
+ return CORBA::string_dup( threshold.c_str() );
+}
+
+/*
+ Class : Comparator_i
+ Description : Base class for comparators
+*/
+Comparator_i::Comparator_i():
+ myNumericalFunctor( NULL )
+{}
+
+Comparator_i::~Comparator_i()
+{
+ if ( myNumericalFunctor )
+ myNumericalFunctor->UnRegister();
+}
+
+void Comparator_i::SetMargin( CORBA::Double theValue )
+{
+ myComparatorPtr->SetMargin( theValue );
+ TPythonDump()<<this<<".SetMargin("<<theValue<<")";
+}
+
+CORBA::Double Comparator_i::GetMargin()
+{
+ return myComparatorPtr->GetMargin();
+}
+
+void Comparator_i::SetNumFunctor( NumericalFunctor_ptr theFunct )
+{
+ if ( myNumericalFunctor )
+ myNumericalFunctor->UnRegister();
+
+ myNumericalFunctor = DownCast<NumericalFunctor_i*>(theFunct);
+
+ if ( myNumericalFunctor )
+ {
+ myComparatorPtr->SetNumFunctor( myNumericalFunctor->GetNumericalFunctor() );
+ myNumericalFunctor->Register();
+ TPythonDump()<<this<<".SetNumFunctor("<<myNumericalFunctor<<")";
+ }
+}
+
+Controls::ComparatorPtr Comparator_i::GetComparator()
+{
+ return myComparatorPtr;
+}
+
+NumericalFunctor_i* Comparator_i::GetNumFunctor_i()
+{
+ return myNumericalFunctor;
+}
+
+
+/*
+ Class : LessThan_i
+ Description : Comparator "<"
+*/
+LessThan_i::LessThan_i()
+{
+ myComparatorPtr.reset( new Controls::LessThan() );
+ myFunctorPtr = myPredicatePtr = myComparatorPtr;
+}
+
+FunctorType LessThan_i::GetFunctorType()
+{
+ return SMESH::FT_LessThan;
+}
+
+
+/*
+ Class : MoreThan_i
+ Description : Comparator ">"
+*/
+MoreThan_i::MoreThan_i()
+{
+ myComparatorPtr.reset( new Controls::MoreThan() );
+ myFunctorPtr = myPredicatePtr = myComparatorPtr;
+}
+
+FunctorType MoreThan_i::GetFunctorType()
+{
+ return SMESH::FT_MoreThan;
+}
+
+
+/*
+ Class : EqualTo_i
+ Description : Comparator "="
+*/
+EqualTo_i::EqualTo_i()
+: myEqualToPtr( new Controls::EqualTo() )
+{
+ myFunctorPtr = myPredicatePtr = myComparatorPtr = myEqualToPtr;
+}
+
+void EqualTo_i::SetTolerance( CORBA::Double theToler )
+{
+ myEqualToPtr->SetTolerance( theToler );
+ TPythonDump()<<this<<".SetTolerance("<<theToler<<")";
+}
+
+CORBA::Double EqualTo_i::GetTolerance()
+{
+ return myEqualToPtr->GetTolerance();
+}
+
+FunctorType EqualTo_i::GetFunctorType()
+{
+ return SMESH::FT_EqualTo;
+}
+
+/*
+ Class : LogicalNOT_i
+ Description : Logical NOT predicate
+*/
+LogicalNOT_i::LogicalNOT_i()
+: myPredicate( NULL ),
+ myLogicalNOTPtr( new Controls::LogicalNOT() )
+{
+ myFunctorPtr = myPredicatePtr = myLogicalNOTPtr;
+}
+
+LogicalNOT_i::~LogicalNOT_i()
+{
+ if ( myPredicate )
+ myPredicate->UnRegister();
+}
+
+void LogicalNOT_i::SetPredicate( Predicate_ptr thePredicate )
+{
+ if ( myPredicate )
+ myPredicate->UnRegister();
+
+ myPredicate = SMESH::GetPredicate(thePredicate);
+
+ if ( myPredicate ){
+ myLogicalNOTPtr->SetPredicate(myPredicate->GetPredicate());
+ myPredicate->Register();
+ TPythonDump()<<this<<".SetPredicate("<<myPredicate<<")";
+ }
+}
+
+FunctorType LogicalNOT_i::GetFunctorType()
+{
+ return SMESH::FT_LogicalNOT;
+}
+
+Predicate_i* LogicalNOT_i::GetPredicate_i()
{
return myPredicate;
}
LogicalBinary_i::~LogicalBinary_i()
{
if ( myPredicate1 )
- myPredicate1->Destroy();
+ myPredicate1->UnRegister();
if ( myPredicate2 )
- myPredicate2->Destroy();
+ myPredicate2->UnRegister();
}
void LogicalBinary_i::SetMesh( SMESH_Mesh_ptr theMesh )
void LogicalBinary_i::SetPredicate1( Predicate_ptr thePredicate )
{
if ( myPredicate1 )
- myPredicate1->Destroy();
+ myPredicate1->UnRegister();
myPredicate1 = SMESH::GetPredicate(thePredicate);
void LogicalBinary_i::SetPredicate2( Predicate_ptr thePredicate )
{
if ( myPredicate2 )
- myPredicate2->Destroy();
+ myPredicate2->UnRegister();
myPredicate2 = SMESH::GetPredicate(thePredicate);
FilterManager_i::~FilterManager_i()
{
- //TPythonDump()<<this<<".Destroy()";
+ //TPythonDump()<<this<<".UnRegister()";
}
}
+MaxElementLength2D_ptr FilterManager_i::CreateMaxElementLength2D()
+{
+ SMESH::MaxElementLength2D_i* aServant = new SMESH::MaxElementLength2D_i();
+ SMESH::MaxElementLength2D_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateMaxElementLength2D()";
+ return anObj._retn();
+}
+
+
+MaxElementLength3D_ptr FilterManager_i::CreateMaxElementLength3D()
+{
+ SMESH::MaxElementLength3D_i* aServant = new SMESH::MaxElementLength3D_i();
+ SMESH::MaxElementLength3D_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateMaxElementLength3D()";
+ return anObj._retn();
+}
+
+
Length_ptr FilterManager_i::CreateLength()
{
SMESH::Length_i* aServant = new SMESH::Length_i();
return anObj._retn();
}
+BallDiameter_ptr FilterManager_i::CreateBallDiameter()
+{
+ SMESH::BallDiameter_i* aServant = new SMESH::BallDiameter_i();
+ SMESH::BallDiameter_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateBallDiameter()";
+ return anObj._retn();
+}
+
BelongToGeom_ptr FilterManager_i::CreateBelongToGeom()
{
SMESH::BelongToGeom_i* aServant = new SMESH::BelongToGeom_i();
return anObj._retn();
}
+CoplanarFaces_ptr FilterManager_i::CreateCoplanarFaces()
+{
+ SMESH::CoplanarFaces_i* aServant = new SMESH::CoplanarFaces_i();
+ SMESH::CoplanarFaces_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateCoplanarFaces()";
+ return anObj._retn();
+}
+
+ConnectedElements_ptr FilterManager_i::CreateConnectedElements()
+{
+ SMESH::ConnectedElements_i* aServant = new SMESH::ConnectedElements_i();
+ SMESH::ConnectedElements_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateConnectedElements()";
+ return anObj._retn();
+}
+
FreeBorders_ptr FilterManager_i::CreateFreeBorders()
{
SMESH::FreeBorders_i* aServant = new SMESH::FreeBorders_i();
return anObj._retn();
}
+EqualNodes_ptr FilterManager_i::CreateEqualNodes()
+{
+ SMESH::EqualNodes_i* aServant = new SMESH::EqualNodes_i();
+ SMESH::EqualNodes_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateEqualNodes()";
+ return anObj._retn();
+}
+
+EqualEdges_ptr FilterManager_i::CreateEqualEdges()
+{
+ SMESH::EqualEdges_i* aServant = new SMESH::EqualEdges_i();
+ SMESH::EqualEdges_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateEqualEdges()";
+ return anObj._retn();
+}
+EqualFaces_ptr FilterManager_i::CreateEqualFaces()
+{
+ SMESH::EqualFaces_i* aServant = new SMESH::EqualFaces_i();
+ SMESH::EqualFaces_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateEqualFaces()";
+ return anObj._retn();
+}
+EqualVolumes_ptr FilterManager_i::CreateEqualVolumes()
+{
+ SMESH::EqualVolumes_i* aServant = new SMESH::EqualVolumes_i();
+ SMESH::EqualVolumes_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateEqualVolumes()";
+ return anObj._retn();
+}
+
RangeOfIds_ptr FilterManager_i::CreateRangeOfIds()
{
SMESH::RangeOfIds_i* aServant = new SMESH::RangeOfIds_i();
return anObj._retn();
}
+BareBorderVolume_ptr FilterManager_i::CreateBareBorderVolume()
+{
+ SMESH::BareBorderVolume_i* aServant = new SMESH::BareBorderVolume_i();
+ SMESH::BareBorderVolume_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateBareBorderVolume()";
+ return anObj._retn();
+}
+
+BareBorderFace_ptr FilterManager_i::CreateBareBorderFace()
+{
+ SMESH::BareBorderFace_i* aServant = new SMESH::BareBorderFace_i();
+ SMESH::BareBorderFace_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateBareBorderFace()";
+ return anObj._retn();
+}
+
+OverConstrainedVolume_ptr FilterManager_i::CreateOverConstrainedVolume()
+{
+ SMESH::OverConstrainedVolume_i* aServant = new SMESH::OverConstrainedVolume_i();
+ SMESH::OverConstrainedVolume_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateOverConstrainedVolume()";
+ return anObj._retn();
+}
+
+OverConstrainedFace_ptr FilterManager_i::CreateOverConstrainedFace()
+{
+ SMESH::OverConstrainedFace_i* aServant = new SMESH::OverConstrainedFace_i();
+ SMESH::OverConstrainedFace_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateOverConstrainedFace()";
+ return anObj._retn();
+}
+
LessThan_ptr FilterManager_i::CreateLessThan()
{
SMESH::LessThan_i* aServant = new SMESH::LessThan_i();
return anObj._retn();
}
+ElemEntityType_ptr FilterManager_i::CreateElemEntityType()
+{
+ SMESH::ElemEntityType_i* aServant = new SMESH::ElemEntityType_i();
+ SMESH::ElemEntityType_var anObj = aServant->_this();
+ TPythonDump()<<aServant<<" = "<<this<<".CreateElemEntityType()";
+ return anObj._retn();
+}
+
Filter_ptr FilterManager_i::CreateFilter()
{
SMESH::Filter_i* aServant = new SMESH::Filter_i();
{
SMESH::FilterLibrary_i* aServant = new SMESH::FilterLibrary_i( aFileName );
SMESH::FilterLibrary_var anObj = aServant->_this();
- TPythonDump()<<aServant<<" = "<<this<<".LoadLibrary("<<aFileName<<")";
+ TPythonDump()<<aServant<<" = "<<this<<".LoadLibrary('"<<aFileName<<"')";
return anObj._retn();
}
Filter_i::~Filter_i()
{
if ( myPredicate )
- myPredicate->Destroy();
+ myPredicate->UnRegister();
if(!CORBA::is_nil(myMesh))
- myMesh->Destroy();
+ myMesh->UnRegister();
- //TPythonDump()<<this<<".Destroy()";
+ //TPythonDump()<<this<<".UnRegister()";
}
//=======================================================================
void Filter_i::SetPredicate( Predicate_ptr thePredicate )
{
if ( myPredicate )
- myPredicate->Destroy();
+ myPredicate->UnRegister();
myPredicate = SMESH::GetPredicate(thePredicate);
{
myFilter.SetPredicate( myPredicate->GetPredicate() );
myPredicate->Register();
+ if ( const SMDS_Mesh* aMesh = MeshPtr2SMDSMesh(myMesh))
+ myPredicate->GetPredicate()->SetMesh( aMesh );
TPythonDump()<<this<<".SetPredicate("<<myPredicate<<")";
}
+ std::list<TPredicateChangeWaiter*>::iterator i = myWaiters.begin();
+ for ( ; i != myWaiters.end(); ++i )
+ (*i)->PredicateChanged();
}
//=======================================================================
theMesh->Register();
if(!CORBA::is_nil(myMesh))
- myMesh->Destroy();
+ myMesh->UnRegister();
- myMesh = theMesh;
+ myMesh = SMESH_Mesh::_duplicate( theMesh );
TPythonDump()<<this<<".SetMesh("<<theMesh<<")";
+
+ if ( myPredicate )
+ if ( const SMDS_Mesh* aMesh = MeshPtr2SMDSMesh(theMesh))
+ myPredicate->GetPredicate()->SetMesh( aMesh );
}
SMESH::long_array*
return anArray._retn();
}
+//=============================================================================
+/*!
+ * \brief Returns number of mesh elements per each \a EntityType
+ */
+//=============================================================================
+
+SMESH::long_array* ::Filter_i::GetMeshInfo()
+{
+ SMESH::long_array_var aRes = new SMESH::long_array();
+ aRes->length(SMESH::Entity_Last);
+ for (int i = 0; i < SMESH::Entity_Last; i++)
+ aRes[i] = 0;
+
+ if ( !CORBA::is_nil(myMesh) && myPredicate )
+ {
+ const SMDS_Mesh* aMesh = MeshPtr2SMDSMesh(myMesh);
+ SMDS_ElemIteratorPtr it = aMesh->elementsIterator( SMDSAbs_ElementType( GetElementType() ));
+ while ( it->more() )
+ {
+ const SMDS_MeshElement* anElem = it->next();
+ if ( myPredicate->IsSatisfy( anElem->GetID() ) )
+ aRes[ anElem->GetEntityType() ]++;
+ }
+ }
+
+ return aRes._retn();
+}
+
+//=============================================================================
+/*!
+ * \brief Returns number of mesh elements of each \a ElementType
+ */
+//=============================================================================
+
+SMESH::long_array* ::Filter_i::GetNbElementsByType()
+{
+ SMESH::long_array_var aRes = new SMESH::long_array();
+ aRes->length(SMESH::NB_ELEMENT_TYPES);
+ for (int i = 0; i < SMESH::NB_ELEMENT_TYPES; i++)
+ aRes[i] = 0;
+
+ if ( !CORBA::is_nil(myMesh) && myPredicate ) {
+ const SMDS_Mesh* aMesh = MeshPtr2SMDSMesh(myMesh);
+ SMDS_ElemIteratorPtr it = aMesh->elementsIterator( SMDSAbs_ElementType( GetElementType() ));
+ CORBA::Long& nbElems = aRes[ GetElementType() ];
+ while ( it->more() )
+ {
+ const SMDS_MeshElement* anElem = it->next();
+ if ( myPredicate->IsSatisfy( anElem->GetID() ) )
+ nbElems++;
+ }
+ }
+
+ return aRes._retn();
+}
+
+
+//================================================================================
+/*!
+ * \brief Return GetElementType() within an array
+ * Implement SMESH_IDSource interface
+ */
+//================================================================================
+
+SMESH::array_of_ElementType* Filter_i::GetTypes()
+{
+ SMESH::array_of_ElementType_var types = new SMESH::array_of_ElementType;
+
+ // check if any element passes through the filter
+ if ( !CORBA::is_nil(myMesh) && myPredicate )
+ {
+ const SMDS_Mesh* aMesh = MeshPtr2SMDSMesh(myMesh);
+ SMDS_ElemIteratorPtr it = aMesh->elementsIterator( SMDSAbs_ElementType( GetElementType() ));
+ bool satisfies = false;
+ while ( !satisfies && it->more() )
+ satisfies = myPredicate->IsSatisfy( it->next()->GetID() );
+ if ( satisfies ) {
+ types->length( 1 );
+ types[0] = GetElementType();
+ }
+ }
+ return types._retn();
+}
+
+//=======================================================================
+//function : GetMesh
+//purpose : Returns mesh
+//=======================================================================
+
+SMESH::SMESH_Mesh_ptr Filter_i::GetMesh()
+{
+ return SMESH_Mesh::_duplicate( myMesh );
+}
+
+//================================================================================
+/*!
+ * \brief Stores an object to be notified on change of predicate
+ */
+//================================================================================
+
+void Filter_i::AddWaiter( TPredicateChangeWaiter* waiter )
+{
+ if ( waiter )
+ myWaiters.push_back( waiter );
+}
+
+//================================================================================
+/*!
+ * \brief Removes an object to be notified on change of predicate
+ */
+//================================================================================
+
+void Filter_i::RemoveWaiter( TPredicateChangeWaiter* waiter )
+{
+ myWaiters.remove( waiter );
+}
+
//=======================================================================
// name : getCriteria
// Purpose : Retrieve criterions from predicate
{
int aFType = thePred->GetFunctorType();
+ switch ( aFType )
+ {
+ case FT_LogicalNOT:
+ {
+ Predicate_i* aPred = ( dynamic_cast<LogicalNOT_i*>( thePred ) )->GetPredicate_i();
+ getCriteria( aPred, theCriteria );
+ theCriteria[ theCriteria->length() - 1 ].UnaryOp = FT_LogicalNOT;
+ }
+ return true;
+
+ case FT_LogicalAND:
+ case FT_LogicalOR:
+ {
+ Predicate_i* aPred1 = ( dynamic_cast<LogicalBinary_i*>( thePred ) )->GetPredicate1_i();
+ Predicate_i* aPred2 = ( dynamic_cast<LogicalBinary_i*>( thePred ) )->GetPredicate2_i();
+ if ( !getCriteria( aPred1, theCriteria ) )
+ return false;
+ theCriteria[ theCriteria->length() - 1 ].BinaryOp = aFType;
+ return getCriteria( aPred2, theCriteria );
+ }
+ case FT_Undefined:
+ return false;
+ }
+
+ // resize theCriteria
+ CORBA::ULong i = theCriteria->length();
+ theCriteria->length( i + 1 );
+ theCriteria[ i ] = createCriterion();
+
+ // set members of the added Criterion
+
+ theCriteria[ i ].Type = aFType;
+ theCriteria[ i ].TypeOfElement = thePred->GetElementType();
+
switch ( aFType )
{
case FT_FreeBorders:
case FT_FreeFaces:
case FT_LinearOrQuadratic:
case FT_FreeNodes:
+ case FT_EqualEdges:
+ case FT_EqualFaces:
+ case FT_EqualVolumes:
+ case FT_BadOrientedVolume:
+ case FT_BareBorderVolume:
+ case FT_BareBorderFace:
+ case FT_OverConstrainedVolume:
+ case FT_OverConstrainedFace:
{
- CORBA::ULong i = theCriteria->length();
- theCriteria->length( i + 1 );
-
- theCriteria[ i ] = createCriterion();
-
- theCriteria[ i ].Type = aFType;
- theCriteria[ i ].TypeOfElement = thePred->GetElementType();
return true;
}
case FT_BelongToGeom:
{
BelongToGeom_i* aPred = dynamic_cast<BelongToGeom_i*>( thePred );
-
- CORBA::ULong i = theCriteria->length();
- theCriteria->length( i + 1 );
-
- theCriteria[ i ] = createCriterion();
-
- theCriteria[ i ].Type = FT_BelongToGeom;
theCriteria[ i ].ThresholdStr = aPred->GetShapeName();
theCriteria[ i ].ThresholdID = aPred->GetShapeID();
- theCriteria[ i ].TypeOfElement = aPred->GetElementType();
-
+ theCriteria[ i ].Tolerance = aPred->GetTolerance();
return true;
}
case FT_BelongToPlane:
case FT_BelongToGenSurface:
{
BelongToSurface_i* aPred = dynamic_cast<BelongToSurface_i*>( thePred );
-
- CORBA::ULong i = theCriteria->length();
- theCriteria->length( i + 1 );
-
- theCriteria[ i ] = createCriterion();
-
- theCriteria[ i ].Type = aFType;
theCriteria[ i ].ThresholdStr = aPred->GetShapeName();
theCriteria[ i ].ThresholdID = aPred->GetShapeID();
- theCriteria[ i ].TypeOfElement = aPred->GetElementType();
theCriteria[ i ].Tolerance = aPred->GetTolerance();
-
return true;
}
- case FT_LyingOnGeom:
+ case FT_LyingOnGeom:
{
LyingOnGeom_i* aPred = dynamic_cast<LyingOnGeom_i*>( thePred );
-
- CORBA::ULong i = theCriteria->length();
- theCriteria->length( i + 1 );
-
- theCriteria[ i ] = createCriterion();
-
- theCriteria[ i ].Type = FT_LyingOnGeom;
theCriteria[ i ].ThresholdStr = aPred->GetShapeName();
theCriteria[ i ].ThresholdID = aPred->GetShapeID();
- theCriteria[ i ].TypeOfElement = aPred->GetElementType();
-
+ theCriteria[ i ].Tolerance = aPred->GetTolerance();
return true;
}
- case FT_RangeOfIds:
+ case FT_CoplanarFaces:
{
- RangeOfIds_i* aPred = dynamic_cast<RangeOfIds_i*>( thePred );
-
- CORBA::ULong i = theCriteria->length();
- theCriteria->length( i + 1 );
-
- theCriteria[ i ] = createCriterion();
-
- theCriteria[ i ].Type = FT_RangeOfIds;
- theCriteria[ i ].ThresholdStr = aPred->GetRangeStr();
- theCriteria[ i ].TypeOfElement = aPred->GetElementType();
-
+ CoplanarFaces_i* aPred = dynamic_cast<CoplanarFaces_i*>( thePred );
+ theCriteria[ i ].ThresholdID = aPred->GetFaceAsString();
+ theCriteria[ i ].Tolerance = aPred->GetTolerance();
return true;
}
- case FT_BadOrientedVolume:
+ case FT_ConnectedElements:
{
- BadOrientedVolume_i* aPred = dynamic_cast<BadOrientedVolume_i*>( thePred );
-
- CORBA::ULong i = theCriteria->length();
- theCriteria->length( i + 1 );
-
- theCriteria[ i ] = createCriterion();
-
- theCriteria[ i ].Type = FT_BadOrientedVolume;
- theCriteria[ i ].TypeOfElement = aPred->GetElementType();
-
+ ConnectedElements_i* aPred = dynamic_cast<ConnectedElements_i*>( thePred );
+ SMESH::ConnectedElements::ThresholdType type;
+ CORBA::String_var threshold = aPred->GetThreshold( type );
+ switch ( type ) {
+ case SMESH::ConnectedElements::POINT:
+ theCriteria[ i ].ThresholdStr = threshold; break;
+ case SMESH::ConnectedElements::VERTEX:
+ theCriteria[ i ].ThresholdID = threshold; break;
+ case SMESH::ConnectedElements::NODE:
+ theCriteria[ i ].Threshold = atof( threshold.in() ); break;
+ default:;
+ }
+ return true;
+ }
+ case FT_EqualNodes:
+ {
+ EqualNodes_i* aPred = dynamic_cast<EqualNodes_i*>( thePred );
+ theCriteria[ i ].Tolerance = aPred->GetTolerance();
+ return true;
+ }
+ case FT_RangeOfIds:
+ {
+ RangeOfIds_i* aPred = dynamic_cast<RangeOfIds_i*>( thePred );
+ theCriteria[ i ].ThresholdStr = aPred->GetRangeStr();
return true;
}
case FT_LessThan:
case FT_EqualTo:
{
Comparator_i* aCompar = dynamic_cast<Comparator_i*>( thePred );
-
- CORBA::ULong i = theCriteria->length();
- theCriteria->length( i + 1 );
-
- theCriteria[ i ] = createCriterion();
-
theCriteria[ i ].Type = aCompar->GetNumFunctor_i()->GetFunctorType();
theCriteria[ i ].Compare = aFType;
theCriteria[ i ].Threshold = aCompar->GetMargin();
- theCriteria[ i ].TypeOfElement = aCompar->GetElementType();
-
if ( aFType == FT_EqualTo )
{
EqualTo_i* aCompar = dynamic_cast<EqualTo_i*>( thePred );
theCriteria[ i ].Tolerance = aCompar->GetTolerance();
}
- }
- return true;
-
- case FT_LogicalNOT:
- {
- Predicate_i* aPred = ( dynamic_cast<LogicalNOT_i*>( thePred ) )->GetPredicate_i();
- getCriteria( aPred, theCriteria );
- theCriteria[ theCriteria->length() - 1 ].UnaryOp = FT_LogicalNOT;
- }
- return true;
-
- case FT_LogicalAND:
- case FT_LogicalOR:
- {
- Predicate_i* aPred1 = ( dynamic_cast<LogicalBinary_i*>( thePred ) )->GetPredicate1_i();
- Predicate_i* aPred2 = ( dynamic_cast<LogicalBinary_i*>( thePred ) )->GetPredicate2_i();
- if ( !getCriteria( aPred1, theCriteria ) )
- return false;
- theCriteria[ theCriteria->length() - 1 ].BinaryOp = aFType;
- return getCriteria( aPred2, theCriteria );
+ return true;
}
case FT_GroupColor:
{
- CORBA::ULong i = theCriteria->length();
- theCriteria->length( i + 1 );
-
- theCriteria[ i ] = createCriterion();
-
GroupColor_i* aPred = dynamic_cast<GroupColor_i*>( thePred );
- theCriteria[ i ].Type = aFType;
- theCriteria[ i ].TypeOfElement = aPred->GetElementType();
- theCriteria[ i ].ThresholdStr = aPred->GetColorStr();
-
+ theCriteria[ i ].ThresholdStr = aPred->GetColorStr();
return true;
}
case FT_ElemGeomType:
{
- CORBA::ULong i = theCriteria->length();
- theCriteria->length( i + 1 );
-
- theCriteria[ i ] = createCriterion();
-
ElemGeomType_i* aPred = dynamic_cast<ElemGeomType_i*>( thePred );
- theCriteria[ i ].Type = aFType;
- theCriteria[ i ].TypeOfElement = aPred->GetElementType();
- theCriteria[ i ].Threshold = (double)aPred->GetGeometryType();
+ theCriteria[ i ].Threshold = (double)aPred->GetGeometryType();
+ return true;
+ }
+ case FT_EntityType:
+ {
+ ElemEntityType_i* aPred = dynamic_cast<ElemEntityType_i*>( thePred );
+ theCriteria[ i ].Threshold = (double)aPred->GetEntityType();
return true;
}
-
- case FT_Undefined:
- return false;
default:
return false;
}
CORBA::Boolean Filter_i::SetCriteria( const SMESH::Filter::Criteria& theCriteria )
{
if ( myPredicate != 0 )
- myPredicate->Destroy();
+ myPredicate->UnRegister();
SMESH::FilterManager_i* aFilter = new SMESH::FilterManager_i();
FilterManager_ptr aFilterMgr = aFilter->_this();
{
TPythonDump pd;
- pd << "aCriterion = SMESH.Filter.Criterion(" << aCriterion << "," << aCompare
- << "," << aThreshold << ",'" << aThresholdStr;
- if (aThresholdID)
- pd << "',salome.ObjectToID(" << aThresholdID
- << ")," << aUnary << "," << aBinary << "," << aTolerance
- << "," << aTypeOfElem << "," << aPrecision << ")";
- else
- pd << "',''," << aUnary << "," << aBinary << "," << aTolerance
- << "," << aTypeOfElem << "," << aPrecision << ")";
+ pd << "aCriterion = SMESH.Filter.Criterion("
+ << aCriterion << ", "
+ << aCompare << ", "
+ << aThreshold << ", '"
+ << aThresholdStr << "', '"
+ << aThresholdID << "', "
+ << aUnary << ", "
+ << aBinary << ", "
+ << aTolerance << ", "
+ << aTypeOfElem << ", "
+ << aPrecision << ")";
}
+ TPythonDump pd;
SMESH::Predicate_ptr aPredicate = SMESH::Predicate::_nil();
SMESH::NumericalFunctor_ptr aFunctor = SMESH::NumericalFunctor::_nil();
case SMESH::FT_Volume3D:
aFunctor = aFilterMgr->CreateVolume3D();
break;
+ case SMESH::FT_MaxElementLength2D:
+ aFunctor = aFilterMgr->CreateMaxElementLength2D();
+ break;
+ case SMESH::FT_MaxElementLength3D:
+ aFunctor = aFilterMgr->CreateMaxElementLength3D();
+ break;
+ case SMESH::FT_BallDiameter:
+ aFunctor = aFilterMgr->CreateBallDiameter();
+ break;
// Predicates
case SMESH::FT_FreeNodes:
aPredicate = aFilterMgr->CreateFreeNodes();
break;
+ case SMESH::FT_EqualNodes:
+ {
+ SMESH::EqualNodes_ptr pred = aFilterMgr->CreateEqualNodes();
+ pred->SetTolerance( aTolerance );
+ aPredicate = pred;
+ break;
+ }
+ case SMESH::FT_EqualEdges:
+ aPredicate = aFilterMgr->CreateEqualEdges();
+ break;
+ case SMESH::FT_EqualFaces:
+ aPredicate = aFilterMgr->CreateEqualFaces();
+ break;
+ case SMESH::FT_EqualVolumes:
+ aPredicate = aFilterMgr->CreateEqualVolumes();
+ break;
case SMESH::FT_BelongToGeom:
{
SMESH::BelongToGeom_ptr tmpPred = aFilterMgr->CreateBelongToGeom();
tmpPred->SetElementType( aTypeOfElem );
tmpPred->SetShape( aThresholdID, aThresholdStr );
+ tmpPred->SetTolerance( aTolerance );
aPredicate = tmpPred;
}
break;
{
SMESH::LyingOnGeom_ptr tmpPred = aFilterMgr->CreateLyingOnGeom();
tmpPred->SetElementType( aTypeOfElem );
- tmpPred->SetShape( aThresholdID, aThresholdStr );
+ tmpPred->SetShape( aThresholdID, aThresholdStr );
+ tmpPred->SetTolerance( aTolerance );
aPredicate = tmpPred;
}
break;
aPredicate = aFilterMgr->CreateBadOrientedVolume();
}
break;
+ case SMESH::FT_BareBorderVolume:
+ {
+ aPredicate = aFilterMgr->CreateBareBorderVolume();
+ }
+ break;
+ case SMESH::FT_BareBorderFace:
+ {
+ aPredicate = aFilterMgr->CreateBareBorderFace();
+ }
+ break;
+ case SMESH::FT_OverConstrainedVolume:
+ {
+ aPredicate = aFilterMgr->CreateOverConstrainedVolume();
+ }
+ break;
+ case SMESH::FT_OverConstrainedFace:
+ {
+ aPredicate = aFilterMgr->CreateOverConstrainedFace();
+ }
+ break;
case SMESH::FT_LinearOrQuadratic:
{
SMESH::LinearOrQuadratic_ptr tmpPred = aFilterMgr->CreateLinearOrQuadratic();
{
SMESH::ElemGeomType_ptr tmpPred = aFilterMgr->CreateElemGeomType();
tmpPred->SetElementType( aTypeOfElem );
- tmpPred->SetGeometryType( (GeometryType)(aThreshold + 0.5) );
+ tmpPred->SetGeometryType( (GeometryType)(int)(aThreshold + 0.5) );
+ aPredicate = tmpPred;
+ break;
+ }
+ case SMESH::FT_EntityType:
+ {
+ SMESH::ElemEntityType_ptr tmpPred = aFilterMgr->CreateElemEntityType();
+ tmpPred->SetElementType( aTypeOfElem );
+ tmpPred->SetEntityType( EntityType( (int (aThreshold + 0.5))));
+ aPredicate = tmpPred;
+ break;
+ }
+ case SMESH::FT_CoplanarFaces:
+ {
+ SMESH::CoplanarFaces_ptr tmpPred = aFilterMgr->CreateCoplanarFaces();
+ tmpPred->SetFace( atol (aThresholdID ));
+ tmpPred->SetTolerance( aTolerance );
+ aPredicate = tmpPred;
+ break;
+ }
+ case SMESH::FT_ConnectedElements:
+ {
+ SMESH::ConnectedElements_ptr tmpPred = aFilterMgr->CreateConnectedElements();
+ if ( strlen( aThresholdID ) > 0 ) // shape ID
+ tmpPred->SetThreshold( aThresholdID, SMESH::ConnectedElements::VERTEX );
+ else if ( strlen( aThresholdStr ) > 0 ) // point coords
+ tmpPred->SetThreshold( aThresholdStr, SMESH::ConnectedElements::POINT );
+ else if ( aThreshold >= 1 )
+ tmpPred->SetNode( (CORBA::Long) aThreshold ); // node ID
+ tmpPred->SetElementType( aTypeOfElem );
aPredicate = tmpPred;
break;
}
// logical op
aPredicates.push_back( aPredicate );
aBinaries.push_back( aBinary );
- TPythonDump()<<"aCriteria.append(aCriterion)";
+ pd <<"aCriteria.append(aCriterion)";
} // end of for
- TPythonDump()<<this<<".SetCriteria(aCriteria)";
+ TPythonDump pd; pd<<this<<".SetCriteria(aCriteria)";
// CREATE ONE PREDICATE FROM PREVIOUSLY CREATED MAP
else
{
SMESH::Predicate_var anObj = myPredicate->_this();
+ // if ( SMESH::Functor_i* fun = SMESH::DownCast<SMESH::Functor_i*>( anObj ))
+ // TPythonDump() << fun << " = " << this << ".GetPredicate()";
return anObj._retn();
}
}
case FT_Skew : return "Skew";
case FT_Area : return "Area";
case FT_Volume3D : return "Volume3D";
+ case FT_MaxElementLength2D: return "Max element length 2D";
+ case FT_MaxElementLength3D: return "Max element length 3D";
case FT_BelongToGeom : return "Belong to Geom";
case FT_BelongToPlane : return "Belong to Plane";
case FT_BelongToCylinder: return "Belong to Cylinder";
case FT_BelongToGenSurface: return "Belong to Generic Surface";
case FT_LyingOnGeom : return "Lying on Geom";
- case FT_BadOrientedVolume: return "Bad Oriented Volume";
+ case FT_BadOrientedVolume:return "Bad Oriented Volume";
+ case FT_BareBorderVolume: return "Volumes with bare border";
+ case FT_BareBorderFace : return "Faces with bare border";
+ case FT_OverConstrainedVolume: return "Over-constrained Volumes";
+ case FT_OverConstrainedFace : return "Over-constrained Faces";
case FT_RangeOfIds : return "Range of IDs";
case FT_FreeBorders : return "Free borders";
case FT_FreeEdges : return "Free edges";
case FT_FreeFaces : return "Free faces";
case FT_FreeNodes : return "Free nodes";
+ case FT_EqualNodes : return "Equal nodes";
+ case FT_EqualEdges : return "Equal edges";
+ case FT_EqualFaces : return "Equal faces";
+ case FT_EqualVolumes : return "Equal volumes";
case FT_MultiConnection : return "Borders at multi-connections";
- case FT_MultiConnection2D: return "Borders at multi-connections 2D";
+ case FT_MultiConnection2D:return "Borders at multi-connections 2D";
case FT_Length : return "Length";
case FT_Length2D : return "Length 2D";
case FT_LessThan : return "Less than";
case FT_GroupColor : return "Color of Group";
case FT_LinearOrQuadratic : return "Linear or Quadratic";
case FT_ElemGeomType : return "Element geomtry type";
+ case FT_EntityType : return "Entity type";
case FT_Undefined : return "";
default : return "";
}
else if ( theStr.equals( "Skew" ) ) return FT_Skew;
else if ( theStr.equals( "Area" ) ) return FT_Area;
else if ( theStr.equals( "Volume3D" ) ) return FT_Volume3D;
+ else if ( theStr.equals( "Max element length 2D" ) ) return FT_MaxElementLength2D;
+ else if ( theStr.equals( "Max element length 3D" ) ) return FT_MaxElementLength3D;
else if ( theStr.equals( "Belong to Geom" ) ) return FT_BelongToGeom;
else if ( theStr.equals( "Belong to Plane" ) ) return FT_BelongToPlane;
else if ( theStr.equals( "Belong to Cylinder" ) ) return FT_BelongToCylinder;
else if ( theStr.equals( "Free edges" ) ) return FT_FreeEdges;
else if ( theStr.equals( "Free faces" ) ) return FT_FreeFaces;
else if ( theStr.equals( "Free nodes" ) ) return FT_FreeNodes;
+ else if ( theStr.equals( "Equal nodes" ) ) return FT_EqualNodes;
+ else if ( theStr.equals( "Equal edges" ) ) return FT_EqualEdges;
+ else if ( theStr.equals( "Equal faces" ) ) return FT_EqualFaces;
+ else if ( theStr.equals( "Equal volumes" ) ) return FT_EqualVolumes;
else if ( theStr.equals( "Borders at multi-connections" ) ) return FT_MultiConnection;
// else if ( theStr.equals( "Borders at multi-connections 2D" ) ) return FT_MultiConnection2D;
else if ( theStr.equals( "Length" ) ) return FT_Length;
// else if ( theStr.equals( "Length2D" ) ) return FT_Length2D;
else if ( theStr.equals( "Range of IDs" ) ) return FT_RangeOfIds;
else if ( theStr.equals( "Bad Oriented Volume" ) ) return FT_BadOrientedVolume;
+ else if ( theStr.equals( "Volumes with bare border" ) ) return FT_BareBorderVolume;
+ else if ( theStr.equals( "Faces with bare border" ) ) return FT_BareBorderFace;
+ else if ( theStr.equals( "Over-constrained Volumes" ) ) return FT_OverConstrainedVolume;
+ else if ( theStr.equals( "Over-constrained Faces" ) ) return FT_OverConstrainedFace;
else if ( theStr.equals( "Less than" ) ) return FT_LessThan;
else if ( theStr.equals( "More than" ) ) return FT_MoreThan;
else if ( theStr.equals( "Equal to" ) ) return FT_EqualTo;
else if ( theStr.equals( "Color of Group" ) ) return FT_GroupColor;
else if ( theStr.equals( "Linear or Quadratic" ) ) return FT_LinearOrQuadratic;
else if ( theStr.equals( "Element geomtry type" ) ) return FT_ElemGeomType;
+ else if ( theStr.equals( "Entity type" ) ) return FT_EntityType;
else if ( theStr.equals( "" ) ) return FT_Undefined;
else return FT_Undefined;
}
FilterLibrary_i::~FilterLibrary_i()
{
delete myFileName;
- //TPythonDump()<<this<<".Destroy()";
+ //TPythonDump()<<this<<".UnRegister()";
}
//=======================================================================
{
aFilterItem.ReplaceElement( aNewItem );
if(Filter_i* aFilter = DownCast<Filter_i*>(theFilter))
- TPythonDump()<<this<<".Replace('"<<theFilterName<<"',"<<theNewName<<"',"<<aFilter<<")";
+ TPythonDump()<<this<<".Replace('"<<theFilterName<<"','"<<theNewName<<"',"<<aFilter<<")";
return true;
}
}
return aResArray._retn();
}
+
+//================================================================================
+/*!
+ * \brief Return an array of strings corresponding to items of enum FunctorType
+ */
+//================================================================================
+
+static const char** getFunctNames()
+{
+ static const char* functName[ SMESH::FT_Undefined + 1 ] = {
+ // IT's necessary to update this array according to enum FunctorType (SMESH_Filter.idl)
+ // The order is IMPORTANT !!!
+ "FT_AspectRatio",
+ "FT_AspectRatio3D",
+ "FT_Warping",
+ "FT_MinimumAngle",
+ "FT_Taper",
+ "FT_Skew",
+ "FT_Area",
+ "FT_Volume3D",
+ "FT_MaxElementLength2D",
+ "FT_MaxElementLength3D",
+ "FT_FreeBorders",
+ "FT_FreeEdges",
+ "FT_FreeNodes",
+ "FT_FreeFaces",
+ "FT_EqualNodes",
+ "FT_EqualEdges",
+ "FT_EqualFaces",
+ "FT_EqualVolumes",
+ "FT_MultiConnection",
+ "FT_MultiConnection2D",
+ "FT_Length",
+ "FT_Length2D",
+ "FT_BelongToGeom",
+ "FT_BelongToPlane",
+ "FT_BelongToCylinder",
+ "FT_BelongToGenSurface",
+ "FT_LyingOnGeom",
+ "FT_RangeOfIds",
+ "FT_BadOrientedVolume",
+ "FT_BareBorderVolume",
+ "FT_BareBorderFace",
+ "FT_OverConstrainedVolume",
+ "FT_OverConstrainedFace",
+ "FT_LinearOrQuadratic",
+ "FT_GroupColor",
+ "FT_ElemGeomType",
+ "FT_EntityType",
+ "FT_CoplanarFaces",
+ "FT_BallDiameter",
+ "FT_ConnectedElements",
+ "FT_LessThan",
+ "FT_MoreThan",
+ "FT_EqualTo",
+ "FT_LogicalNOT",
+ "FT_LogicalAND",
+ "FT_LogicalOR",
+ "FT_Undefined"};
+ return functName;
+}
+
+//================================================================================
+/*!
+ * \brief Return a string corresponding to an item of enum FunctorType
+ */
+//================================================================================
+
+const char* SMESH::FunctorTypeToString(SMESH::FunctorType ft)
+{
+ if ( ft < 0 || ft > SMESH::FT_Undefined )
+ return "FT_Undefined";
+ return getFunctNames()[ ft ];
+}
+
+//================================================================================
+/*!
+ * \brief Converts a string to FunctorType. This is reverse of FunctorTypeToString()
+ */
+//================================================================================
+
+SMESH::FunctorType SMESH::StringToFunctorType(const char* str)
+{
+ std::string name( str + 3 ); // skip "FT_"
+ const char** functNames = getFunctNames();
+ int ft = 0;
+ for ( ; ft < SMESH::FT_Undefined; ++ft )
+ if ( name == ( functNames[ft] + 3 ))
+ break;
+
+ //ASSERT( strcmp( str, FunctorTypeToString( SMESH::FunctorType( ft ))) == 0 );
+
+ return SMESH::FunctorType( ft );
+}