if ( myHelper->GetIsQuadratic() )
{
// fill myHelper with medium nodes built by quadAlgo
- SMDS_ElemIteratorPtr fIt = fSM->GetSubMeshDS()->GetElements();
- while ( fIt->more() )
- myHelper->AddTLinks( dynamic_cast<const SMDS_MeshFace*>( fIt->next() ));
+ for ( SMDS_ElemIteratorPtr fIt = fSM->GetSubMeshDS()->GetElements(); fIt->more(); )
+ myHelper->AddTLinks( SMDS_Mesh::DownCast<SMDS_MeshFace>( fIt->next() ));
}
}
}
if ( side._topEdge.IsNull() )
{
- // find vertical EDGEs --- EGDEs shared with neighbor side FACEs
+ // find vertical EDGEs --- EDGEs shared with neighbor side FACEs
for ( int is2nd = 0; is2nd < 2 && isOK; ++is2nd ) // 2 adjacent neighbors
{
int di = is2nd ? 1 : -1;
if ( !botSM ) // find a proper bottom
{
bool savedSetErrorToSM = mySetErrorToSM;
- mySetErrorToSM = false; // ingore errors in initPrism()
+ mySetErrorToSM = false; // ignore errors in initPrism()
// search among meshed FACEs
list< SMESH_subMesh* >::iterator sm = meshedSubMesh.begin();
}
if ( !C2d.IsNull() )
{
- double u = static_cast< const SMDS_EdgePosition* >( n->GetPosition() )->GetUParameter();
+ double u = SMDS_EdgePositionPtr( n->GetPosition() )->GetUParameter();
if ( f <= u && u <= l )
{
uv = C2d->Value( u ).XY();
const size_t zSrc = 0, zTgt = zSize-1;
if ( zSize < 3 ) return true;
- vector< vector< gp_XYZ > > intPntsOfLayer( zSize ); // node coodinates to compute
+ vector< vector< gp_XYZ > > intPntsOfLayer( zSize ); // node coordinates to compute
// set coordinates of src and tgt nodes
for ( size_t z = 0; z < intPntsOfLayer.size(); ++z )
intPntsOfLayer[ z ].resize( myIntColumns.size() );
prepareTopBotDelaunay();
bool isErrorCorrectable = findDelaunayTriangles();
- // compute coordinates of internal nodes by projecting (transfroming) src and tgt
+ // compute coordinates of internal nodes by projecting (transforming) src and tgt
// nodes towards the central layer
vector< NSProjUtils::TrsfFinder3D > trsfOfLayer( zSize );