}
for ( int variant = 0; variant < nbVariants && method._nbSplits == 0; ++variant )
{
- // check method compliancy with adjacent tetras,
+ // check method compliance with adjacent tetras,
// all found splits must be among facets of tetras described by this method
method = TSplitMethod( nbTet, connVariants[variant] );
if ( hasAdjacentSplits && method._nbSplits > 0 )
// there are adjacent prism
for ( int variant = 0; variant < nbVariants; ++variant )
{
- // check method compliancy with adjacent prisms,
+ // check method compliance with adjacent prisms,
// the found prism facets must be among facets of prisms described by current method
method._nbSplits = nbSplits;
method._nbCorners = 6;
}
else {
if ( isUPeriodic )
- newUV.SetX( ElCLib::InPeriod( newUV.X(), u1, u2 )); // todo: u may be used unitialized
+ newUV.SetX( ElCLib::InPeriod( newUV.X(), u1, u2 ));
if ( isVPeriodic )
- newUV.SetY( ElCLib::InPeriod( newUV.Y(), v1, v2 )); // todo: v may be used unitialized
+ newUV.SetY( ElCLib::InPeriod( newUV.Y(), v1, v2 ));
// check new UV
// if ( posType != SMDS_TOP_3DSPACE )
// dist2 = pNode.SquareDistance( surface->Value( newUV.X(), newUV.Y() ));