// Copyright (C) 2003 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
+// 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 distributed in the hope that it will be useful,
+// 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
+// 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.opencascade.org/SALOME/ or email : webmaster.salome@opencascade.org
#include "SMESH_ControlsDef.hxx"
#include "SMDS_Iterator.hxx"
#include "SMDS_MeshElement.hxx"
#include "SMDS_MeshNode.hxx"
+#include "SMDS_VolumeTool.hxx"
/*
- AUXILIARY METHODS
+ AUXILIARY METHODS
*/
namespace{
inline double getAngle( const gp_XYZ& P1, const gp_XYZ& P2, const gp_XYZ& P3 )
{
gp_Vec v1( P1 - P2 ), v2( P3 - P2 );
-
+
return v1.Magnitude() < gp::Resolution() ||
v2.Magnitude() < gp::Resolution() ? 0 : v1.Angle( v2 );
}
return aDist;
}
- int getNbMultiConnection( SMDS_Mesh* theMesh, const int theId )
+ int getNbMultiConnection( const SMDS_Mesh* theMesh, const int theId )
{
if ( theMesh == 0 )
return 0;
-
+
const SMDS_MeshElement* anEdge = theMesh->FindElement( theId );
if ( anEdge == 0 || anEdge->GetType() != SMDSAbs_Edge || anEdge->NbNodes() != 2 )
return 0;
-
+
TColStd_MapOfInteger aMap;
-
+
int aResult = 0;
SMDS_ElemIteratorPtr anIter = anEdge->nodesIterator();
if ( anIter != 0 ) {
const SMDS_MeshElement* anElem = anElemIter->next();
if ( anElem != 0 && anElem->GetType() != SMDSAbs_Edge ) {
int anId = anElem->GetID();
-
+
if ( anIter->more() ) // i.e. first node
aMap.Add( anId );
else if ( aMap.Contains( anId ) )
}
}
}
-
+
return aResult;
}
myPrecision = -1;
}
-void NumericalFunctor::SetMesh( SMDS_Mesh* theMesh )
+void NumericalFunctor::SetMesh( const SMDS_Mesh* theMesh )
{
myMesh = theMesh;
}
return 0.;
}
+//=======================================================================
+//function : GetValue
+//purpose :
+//=======================================================================
+
+double Volume::GetValue( long theElementId )
+{
+ if ( theElementId && myMesh ) {
+ SMDS_VolumeTool aVolumeTool;
+ if ( aVolumeTool.Set( myMesh->FindElement( theElementId )))
+ return aVolumeTool.GetSize();
+ }
+ return 0;
+}
+
+//=======================================================================
+//function : GetBadRate
+//purpose : meaningless as it is not quality control functor
+//=======================================================================
+
+double Volume::GetBadRate( double Value, int /*nbNodes*/ ) const
+{
+ return Value;
+}
+
+//=======================================================================
+//function : GetType
+//purpose :
+//=======================================================================
+
+SMDSAbs_ElementType Volume::GetType() const
+{
+ return SMDSAbs_Volume;
+}
+
+
/*
Class : MinimumAngle
Description : Functor for calculation of minimum angle
{
double aMin;
- if ( P.size() == 3 )
- {
- double A0 = getAngle( P( 3 ), P( 1 ), P( 2 ) );
- double A1 = getAngle( P( 1 ), P( 2 ), P( 3 ) );
- double A2 = getAngle( P( 2 ), P( 3 ), P( 1 ) );
+ if (P.size() <3)
+ return 0.;
- aMin = Min( A0, Min( A1, A2 ) );
- }
- else if ( P.size() == 4 )
- {
- double A0 = getAngle( P( 4 ), P( 1 ), P( 2 ) );
- double A1 = getAngle( P( 1 ), P( 2 ), P( 3 ) );
- double A2 = getAngle( P( 2 ), P( 3 ), P( 4 ) );
- double A3 = getAngle( P( 3 ), P( 4 ), P( 1 ) );
-
- aMin = Min( Min( A0, A1 ), Min( A2, A3 ) );
+ aMin = getAngle(P( P.size() ), P( 1 ), P( 2 ));
+ aMin = Min(aMin,getAngle(P( P.size()-1 ), P( P.size() ), P( 1 )));
+
+ for (int i=2; i<P.size();i++){
+ double A0 = getAngle( P( i-1 ), P( i ), P( i+1 ) );
+ aMin = Min(aMin,A0);
}
- else
- return 0.;
-
- return aMin * 180 / PI;
+
+ return aMin * 180.0 / PI;
}
double MinimumAngle::GetBadRate( double Value, int nbNodes ) const
{
- const double aBestAngle = PI / nbNodes;
+ //const double aBestAngle = PI / nbNodes;
+ const double aBestAngle = 180.0 - ( 360.0 / double(nbNodes) );
return ( fabs( aBestAngle - Value ));
}
{
int nbNodes = P.size();
- if ( nbNodes != 3 && nbNodes != 4 )
+ if ( nbNodes < 3 )
return 0;
// Compute lengths of the sides
- double aLen[ nbNodes ];
+ //double aLen[ nbNodes ];
+#ifndef WNT
+ double aLen [nbNodes];
+#else
+ double* aLen = (double *)new double[nbNodes];
+#endif
+
for ( int i = 0; i < nbNodes - 1; i++ )
aLen[ i ] = getDistance( P( i + 1 ), P( i + 2 ) );
aLen[ nbNodes - 1 ] = getDistance( P( 1 ), P( nbNodes ) );
// Compute aspect ratio
- if ( nbNodes == 3 )
+ if ( nbNodes == 3 )
{
double anArea = getArea( P( 1 ), P( 2 ), P( 3 ) );
if ( anArea <= Precision::Confusion() )
}
else
{
- double aMinLen = Min( Min( aLen[ 0 ], aLen[ 1 ] ), Min( aLen[ 2 ], aLen[ 3 ] ) );
+ double aMinLen = aLen[ 0 ];
+ double aMaxLen = aLen[ 0 ];
+
+ for(int i = 1; i < nbNodes ; i++ ){
+ aMinLen = Min( aMinLen, aLen[ i ] );
+ aMaxLen = Max( aMaxLen, aLen[ i ] );
+ }
+#ifdef WNT
+ delete [] aLen;
+#endif
if ( aMinLen <= Precision::Confusion() )
return 0.;
- double aMaxLen = Max( Max( aLen[ 0 ], aLen[ 1 ] ), Max( aLen[ 2 ], aLen[ 3 ] ) );
-
+
return aMaxLen / aMinLen;
}
}
double Q = b2*f2*(a2+c2+d2+e2-b2-f2);
double R = c2*d2*(a2+b2+e2+f2-c2-d2);
double S = a2*b2*d2+b2*c2*e2+a2*c2*f2+d2*e2*f2;
-
+
return sqrt(P+Q+R-S)/12.0;
}
gp_Vec aVec2( P( 3 ) - P( 1 ) );
gp_Vec aVec3( P( 4 ) - P( 1 ) );
gp_Vec anAreaVec( aVec1 ^ aVec2 );
- return abs(aVec3 * anAreaVec) / 6.0;
+ return fabs(aVec3 * anAreaVec) / 6.0;
}
inline double getMaxHeight(double theLen[6])
if ( L < Precision::Confusion())
return 0.;
- gp_XYZ GI = ( thePnt2 - thePnt1 ) / 2. - theG;
- gp_XYZ GJ = ( thePnt3 - thePnt2 ) / 2. - theG;
+ gp_XYZ GI = ( thePnt2 + thePnt1 ) / 2. - theG;
+ gp_XYZ GJ = ( thePnt3 + thePnt2 ) / 2. - theG;
gp_XYZ N = GI.Crossed( GJ );
if ( N.Modulus() < gp::Resolution() )
return Max( A0, Max( A1, A2 ) ) * 180 / PI;
}
- else
+ else
{
gp_XYZ p12 = ( P( 1 ) + P( 2 ) ) / 2;
gp_XYZ p23 = ( P( 2 ) + P( 3 ) ) / 2;
*/
double Area::GetValue( const TSequenceOfXYZ& P )
{
+ double aArea = 0;
if ( P.size() == 3 )
return getArea( P( 1 ), P( 2 ), P( 3 ) );
- else if ( P.size() == 4 )
- return getArea( P( 1 ), P( 2 ), P( 3 ) ) + getArea( P( 1 ), P( 3 ), P( 4 ) );
+ else if (P.size() > 3)
+ aArea = getArea( P( 1 ), P( 2 ), P( 3 ) );
else
return 0;
+
+ for (int i=4; i<=P.size(); i++)
+ aArea += getArea(P(1),P(i-1),P(i));
+ return aArea;
}
double Area::GetBadRate( double Value, int /*nbNodes*/ ) const
{
+ // meaningless as it is not quality control functor
return Value;
}
double Length::GetBadRate( double Value, int /*nbNodes*/ ) const
{
+ // meaningless as it is not quality control functor
return Value;
}
TSequenceOfXYZ P;
if (GetPoints(theElementId,P)){
-
+
double aVal;// = GetValue( P );
const SMDS_MeshElement* aElem = myMesh->FindElement( theElementId );
SMDSAbs_ElementType aType = aElem->GetType();
-
+
int len = P.size();
-
+
switch (aType){
case SMDSAbs_All:
- case SMDSAbs_Node:
+ case SMDSAbs_Node:
case SMDSAbs_Edge:
if (len == 2){
aVal = getDistance( P( 1 ), P( 2 ) );
double L6 = getDistance(P( 3 ),P( 4 ));
aVal = Max(Max(Max(L1,L2),Max(L3,L4)),Max(L5,L6));
break;
- }
+ }
else if (len == 5){ // piramids
double L1 = getDistance(P( 1 ),P( 2 ));
double L2 = getDistance(P( 2 ),P( 3 ));
double L6 = getDistance(P( 2 ),P( 5 ));
double L7 = getDistance(P( 3 ),P( 5 ));
double L8 = getDistance(P( 4 ),P( 5 ));
-
+
aVal = Max(Max(Max(L1,L2),Max(L3,L4)),Max(L5,L6));
aVal = Max(aVal,Max(L7,L8));
break;
double L7 = getDistance(P( 1 ),P( 4 ));
double L8 = getDistance(P( 2 ),P( 5 ));
double L9 = getDistance(P( 3 ),P( 6 ));
-
+
aVal = Max(Max(Max(L1,L2),Max(L3,L4)),Max(L5,L6));
aVal = Max(aVal,Max(Max(L7,L8),L9));
break;
double L10= getDistance(P( 2 ),P( 6 ));
double L11= getDistance(P( 3 ),P( 7 ));
double L12= getDistance(P( 4 ),P( 8 ));
-
+
aVal = Max(Max(Max(L1,L2),Max(L3,L4)),Max(L5,L6));
aVal = Max(aVal,Max(Max(L7,L8),Max(L9,L10)));
aVal = Max(aVal,Max(L11,L12));
break;
-
+
}
-
- default: aVal=-1;
+
+ default: aVal=-1;
}
-
+
if (aVal <0){
return 0.;
}
double prec = pow( 10., (double)( myPrecision ) );
aVal = floor( aVal * prec + 0.5 ) / prec;
}
-
+
return aVal;
}
double Length2D::GetBadRate( double Value, int /*nbNodes*/ ) const
{
+ // meaningless as it is not quality control functor
return Value;
}
SMDS_ElemIteratorPtr aNodesIter = anElem->nodesIterator();
long aNodeId[2];
gp_Pnt P[3];
-
+
double aLength;
const SMDS_MeshElement* aNode;
if(aNodesIter->more()){
P[0] = P[1] = gp_Pnt(aNodes->X(),aNodes->Y(),aNodes->Z());
aNodeId[0] = aNodeId[1] = aNode->GetID();
aLength = 0;
- }
+ }
for(; aNodesIter->more(); ){
aNode = aNodesIter->next();
const SMDS_MeshNode* aNodes = (SMDS_MeshNode*) aNode;
long anId = aNode->GetID();
-
+
P[2] = gp_Pnt(aNodes->X(),aNodes->Y(),aNodes->Z());
aLength = P[1].Distance(P[2]);
-
+
Value aValue(aLength,aNodeId[1],anId);
aNodeId[1] = anId;
P[1] = P[2];
theValues.insert(aValue);
}
-
+
aLength = P[0].Distance(P[1]);
-
+
Value aValue(aLength,aNodeId[0],aNodeId[1]);
theValues.insert(aValue);
}
double MultiConnection::GetBadRate( double Value, int /*nbNodes*/ ) const
{
+ // meaningless as it is not quality control functor
return Value;
}
{
TSequenceOfXYZ P;
int aResult = 0;
-
+
if (GetPoints(theElementId,P)){
- double aVal;
const SMDS_MeshElement* anFaceElem = myMesh->FindElement( theElementId );
SMDSAbs_ElementType aType = anFaceElem->GetType();
-
+
int len = P.size();
-
+
TColStd_MapOfInteger aMap;
int aResult = 0;
-
+
switch (aType){
case SMDSAbs_All:
- case SMDSAbs_Node:
+ case SMDSAbs_Node:
case SMDSAbs_Edge:
case SMDSAbs_Face:
if (len == 3){ // triangles
}
}
}
-
+
aResult = Max(Max(Nb[0],Nb[1]),Nb[2]);
}
break;
case SMDSAbs_Volume:
default: aResult=0;
}
-
+
}
return aResult;//getNbMultiConnection( myMesh, theId );
}
double MultiConnection2D::GetBadRate( double Value, int /*nbNodes*/ ) const
{
+ // meaningless as it is not quality control functor
return Value;
}
SMDS_FaceIteratorPtr anIter = myMesh->facesIterator();
for(; anIter->more(); ){
const SMDS_MeshFace* anElem = anIter->next();
- long anElemId = anElem->GetID();
SMDS_ElemIteratorPtr aNodesIter = anElem->nodesIterator();
long aNodeId[3];
aNode2 = (SMDS_MeshNode*) aNodesIter->next();
long anId = aNode2->GetID();
aNodeId[2] = anId;
-
+
Value aValue(aNodeId[1],aNodeId[2]);
MValues::iterator aItr = theValues.find(aValue);
if (aItr != theValues.end()){
PREDICATES
*/
+/*
+ Class : BadOrientedVolume
+ Description : Predicate bad oriented volumes
+*/
+
+BadOrientedVolume::BadOrientedVolume()
+{
+ myMesh = 0;
+}
+
+void BadOrientedVolume::SetMesh( const SMDS_Mesh* theMesh )
+{
+ myMesh = theMesh;
+}
+
+bool BadOrientedVolume::IsSatisfy( long theId )
+{
+ if ( myMesh == 0 )
+ return false;
+
+ SMDS_VolumeTool vTool( myMesh->FindElement( theId ));
+ return !vTool.IsForward();
+}
+
+SMDSAbs_ElementType BadOrientedVolume::GetType() const
+{
+ return SMDSAbs_Volume;
+}
+
+
+
/*
Class : FreeBorders
Description : Predicate for free borders
myMesh = 0;
}
-void FreeBorders::SetMesh( SMDS_Mesh* theMesh )
+void FreeBorders::SetMesh( const SMDS_Mesh* theMesh )
{
myMesh = theMesh;
}
myMesh = 0;
}
-void FreeEdges::SetMesh( SMDS_Mesh* theMesh )
+void FreeEdges::SetMesh( const SMDS_Mesh* theMesh )
{
myMesh = theMesh;
}
{
int anId = anElem->GetID();
- if ( i == 0 )
+ if ( i == 0 )
aMap.Add( anId );
else if ( aMap.Contains( anId ) && anId != theFaceId )
return false;
return false;
int nbNodes = aFace->NbNodes();
- const SMDS_MeshNode* aNodes[ nbNodes ];
+ //const SMDS_MeshNode* aNodes[ nbNodes ];
+#ifndef WNT
+ const SMDS_MeshNode* aNodes [nbNodes];
+#else
+ const SMDS_MeshNode** aNodes = (const SMDS_MeshNode **)new SMDS_MeshNode*[nbNodes];
+#endif
int i = 0;
SMDS_ElemIteratorPtr anIter = aFace->nodesIterator();
if ( anIter != 0 )
}
for ( int i = 0; i < nbNodes - 1; i++ )
- if ( IsFreeEdge( &aNodes[ i ], theId ) )
+ if ( IsFreeEdge( &aNodes[ i ], theId ) ) {
+#ifdef WNT
+ delete [] aNodes;
+#endif
return true;
+ }
aNodes[ 1 ] = aNodes[ nbNodes - 1 ];
-
- return IsFreeEdge( &aNodes[ 0 ], theId );
-
+ const Standard_Boolean isFree = IsFreeEdge( &aNodes[ 0 ], theId );
+#ifdef WNT
+ delete [] aNodes;
+#endif
+// return
+ return isFree;
}
SMDSAbs_ElementType FreeEdges::GetType() const
}
inline void UpdateBorders(const FreeEdges::Border& theBorder,
- FreeEdges::TBorders& theRegistry,
+ FreeEdges::TBorders& theRegistry,
FreeEdges::TBorders& theContainer)
{
if(theRegistry.find(theBorder) == theRegistry.end()){
if(aNodesIter->more()){
aNode = aNodesIter->next();
aNodeId[0] = aNodeId[1] = aNode->GetID();
- }
+ }
for(; aNodesIter->more(); ){
aNode = aNodesIter->next();
long anId = aNode->GetID();
//=======================================================================
// name : SetMesh
-// Purpose : Set mesh
+// Purpose : Set mesh
//=======================================================================
-void RangeOfIds::SetMesh( SMDS_Mesh* theMesh )
+void RangeOfIds::SetMesh( const SMDS_Mesh* theMesh )
{
myMesh = theMesh;
}
TCollection_AsciiString aStr;
if ( aMinId != IntegerFirst() )
aStr += aMinId;
-
+
aStr += "-";
-
+
if ( aMaxId != IntegerLast() )
aStr += aMaxId;
{
tmpStr = aStr.Token( ",", i++ );
int aPos = tmpStr.Search( '-' );
-
+
if ( aPos == -1 )
{
if ( tmpStr.IsIntegerValue() )
{
TCollection_AsciiString aMaxStr = tmpStr.Split( aPos );
TCollection_AsciiString aMinStr = tmpStr;
-
+
while ( aMinStr.Search( "-" ) != -1 ) aMinStr.RemoveAll( '-' );
while ( aMaxStr.Search( "-" ) != -1 ) aMaxStr.RemoveAll( '-' );
if ( !aMinStr.IsEmpty() && !aMinStr.IsIntegerValue() ||
!aMaxStr.IsEmpty() && !aMaxStr.IsIntegerValue() )
return false;
-
+
myMin.Append( aMinStr.IsEmpty() ? IntegerFirst() : aMinStr.IntegerValue() );
myMax.Append( aMaxStr.IsEmpty() ? IntegerLast() : aMaxStr.IntegerValue() );
}
if ( anElem == 0 || myType != anElem->GetType() && myType != SMDSAbs_All )
return false;
}
-
+
if ( myIds.Contains( theId ) )
return true;
Comparator::~Comparator()
{}
-void Comparator::SetMesh( SMDS_Mesh* theMesh )
+void Comparator::SetMesh( const SMDS_Mesh* theMesh )
{
if ( myFunctor )
myFunctor->SetMesh( theMesh );
return myPredicate && !myPredicate->IsSatisfy( theId );
}
-void LogicalNOT::SetMesh( SMDS_Mesh* theMesh )
+void LogicalNOT::SetMesh( const SMDS_Mesh* theMesh )
{
if ( myPredicate )
myPredicate->SetMesh( theMesh );
LogicalBinary::~LogicalBinary()
{}
-void LogicalBinary::SetMesh( SMDS_Mesh* theMesh )
+void LogicalBinary::SetMesh( const SMDS_Mesh* theMesh )
{
if ( myPredicate1 )
myPredicate1->SetMesh( theMesh );
*/
bool LogicalAND::IsSatisfy( long theId )
{
- return
- myPredicate1 &&
- myPredicate2 &&
- myPredicate1->IsSatisfy( theId ) &&
+ return
+ myPredicate1 &&
+ myPredicate2 &&
+ myPredicate1->IsSatisfy( theId ) &&
myPredicate2->IsSatisfy( theId );
}
*/
bool LogicalOR::IsSatisfy( long theId )
{
- return
- myPredicate1 &&
- myPredicate2 &&
- myPredicate1->IsSatisfy( theId ) ||
+ return
+ myPredicate1 &&
+ myPredicate2 &&
+ myPredicate1->IsSatisfy( theId ) ||
myPredicate2->IsSatisfy( theId );
}
myPredicate = thePredicate;
}
-
-template<class TElement, class TIterator, class TPredicate>
-void FillSequence(const TIterator& theIterator,
- TPredicate& thePredicate,
- Filter::TIdSequence& theSequence)
+template<class TElement, class TIterator, class TPredicate>
+inline void FillSequence(const TIterator& theIterator,
+ TPredicate& thePredicate,
+ Filter::TIdSequence& theSequence)
{
if ( theIterator ) {
while( theIterator->more() ) {
}
}
-Filter::TIdSequence
-Filter::GetElementsId( SMDS_Mesh* theMesh )
+void
+Filter::
+GetElementsId( const SMDS_Mesh* theMesh,
+ PredicatePtr thePredicate,
+ TIdSequence& theSequence )
{
- TIdSequence aSequence;
- if ( !theMesh || !myPredicate ) return aSequence;
+ theSequence.clear();
+
+ if ( !theMesh || !thePredicate )
+ return;
- myPredicate->SetMesh( theMesh );
+ thePredicate->SetMesh( theMesh );
- SMDSAbs_ElementType aType = myPredicate->GetType();
+ SMDSAbs_ElementType aType = thePredicate->GetType();
switch(aType){
- case SMDSAbs_Node:{
- FillSequence<const SMDS_MeshNode*>(theMesh->nodesIterator(),myPredicate,aSequence);
+ case SMDSAbs_Node:
+ FillSequence<const SMDS_MeshNode*>(theMesh->nodesIterator(),thePredicate,theSequence);
break;
- }
- case SMDSAbs_Edge:{
- FillSequence<const SMDS_MeshElement*>(theMesh->edgesIterator(),myPredicate,aSequence);
+ case SMDSAbs_Edge:
+ FillSequence<const SMDS_MeshElement*>(theMesh->edgesIterator(),thePredicate,theSequence);
break;
- }
- case SMDSAbs_Face:{
- FillSequence<const SMDS_MeshElement*>(theMesh->facesIterator(),myPredicate,aSequence);
+ case SMDSAbs_Face:
+ FillSequence<const SMDS_MeshElement*>(theMesh->facesIterator(),thePredicate,theSequence);
break;
- }
- case SMDSAbs_Volume:{
- FillSequence<const SMDS_MeshElement*>(theMesh->volumesIterator(),myPredicate,aSequence);
+ case SMDSAbs_Volume:
+ FillSequence<const SMDS_MeshElement*>(theMesh->volumesIterator(),thePredicate,theSequence);
break;
- }
- case SMDSAbs_All:{
- FillSequence<const SMDS_MeshElement*>(theMesh->edgesIterator(),myPredicate,aSequence);
- FillSequence<const SMDS_MeshElement*>(theMesh->facesIterator(),myPredicate,aSequence);
- FillSequence<const SMDS_MeshElement*>(theMesh->volumesIterator(),myPredicate,aSequence);
+ case SMDSAbs_All:
+ FillSequence<const SMDS_MeshElement*>(theMesh->edgesIterator(),thePredicate,theSequence);
+ FillSequence<const SMDS_MeshElement*>(theMesh->facesIterator(),thePredicate,theSequence);
+ FillSequence<const SMDS_MeshElement*>(theMesh->volumesIterator(),thePredicate,theSequence);
break;
}
- }
- return aSequence;
+}
+
+void
+Filter::GetElementsId( const SMDS_Mesh* theMesh,
+ Filter::TIdSequence& theSequence )
+{
+ GetElementsId(theMesh,myPredicate,theSequence);
}
/*
typedef std::set<SMDS_MeshFace*> TMapOfFacePtr;
-/*
+/*
Internal class Link
-*/
+*/
ManifoldPart::Link::Link( SMDS_MeshNode* theNode1,
SMDS_MeshNode* theNode2 )
bool ManifoldPart::IsEqual( const ManifoldPart::Link& theLink1,
const ManifoldPart::Link& theLink2 )
-{
+{
return theLink1.IsEqual( theLink2 );
}
myMesh = 0;
}
-void ManifoldPart::SetMesh( SMDS_Mesh* theMesh )
+void ManifoldPart::SetMesh( const SMDS_Mesh* theMesh )
{
myMesh = theMesh;
process();
{
myMapIds.Clear();
myMapBadGeomIds.Clear();
-
+
myAllFacePtr.clear();
myAllFacePtrIntDMap.clear();
if ( !myMesh )
if ( fi == aStartIndx )
isStartTreat = true;
// as result next time when fi will be equal to aStartIndx
-
+
SMDS_MeshFace* aFacePtr = myAllFacePtr[ fi ];
if ( aMapOfTreated.Contains( aFacePtr->GetID() ) )
continue;
SMDS_MeshNode* aNode = 0;
for ( ; aNodeItr->more() && i <= aNbNode; )
{
-
+
SMDS_MeshNode* aN1 = (SMDS_MeshNode*)aNodeItr->next();
if ( i == 1 )
aNode = aN1;
SMDS_MeshNode* aNode = (SMDS_MeshNode*)aNodeItr->next();
anArrOfXYZ.SetValue(i, gp_XYZ( aNode->X(), aNode->Y(), aNode->Z() ) );
}
-
+
gp_XYZ q1 = anArrOfXYZ.Value(2) - anArrOfXYZ.Value(1);
gp_XYZ q2 = anArrOfXYZ.Value(3) - anArrOfXYZ.Value(1);
n = q1 ^ q2;
theResFaces.Clear();
if ( !theAllFacePtrInt.size() )
return false;
-
+
if ( getNormale( theStartFace ).SquareModulus() <= gp::Resolution() )
{
myMapBadGeomIds.Add( theStartFace->GetID() );
theResFaces.Add( theStartFace->GetID() );
ManifoldPart::TDataMapOfLinkFacePtr aDMapLinkFace;
- expandBoundary( aMapOfBoundary, aSeqOfBoundary,
+ expandBoundary( aMapOfBoundary, aSeqOfBoundary,
aDMapLinkFace, theNonManifold, theStartFace );
bool isDone = false;
ManifoldPart::TVectorOfFacePtr aFaces;
// find next
- if ( myIsOnlyManifold &&
+ if ( myIsOnlyManifold &&
(theNonManifold.find( aLink ) != theNonManifold.end()) )
continue;
else
continue;
}
}
-
+
// compare normal with normals of neighbor element
SMDS_MeshFace* aPrevFace = aDMapLinkFace[ aLink ];
ManifoldPart::TVectorOfFacePtr::iterator pFace = aFaces.begin();
continue;
// add new element to connected and extend the boundaries.
theResFaces.Add( anNextFaceID );
- expandBoundary( aMapOfBoundary, aSeqOfBoundary,
+ expandBoundary( aMapOfBoundary, aSeqOfBoundary,
aDMapLinkFace, theNonManifold, aNextFace );
isToReset = true;
}
{
ManifoldPart::TVectorOfLink aLinks;
getLinks( theNextFace, aLinks );
- int aNbLink = aLinks.size();
+ int aNbLink = (int)aLinks.size();
for ( int i = 0; i < aNbLink; i++ )
{
ManifoldPart::Link aLink = aLinks[ i ];
myMesh = 0;
}
-void ElementsOnSurface::SetMesh( SMDS_Mesh* theMesh )
-{
+void ElementsOnSurface::SetMesh( const SMDS_Mesh* theMesh )
+{
if ( myMesh == theMesh )
return;
myMesh = theMesh;