bool _hasInternalFaces;
public:
virtual ~Solid() {}
- virtual bool Contains( TGeomID subID ) const { return true; }
- virtual bool ContainsAny( const vector< TGeomID>& subIDs ) const { return true; }
+ virtual bool Contains( TGeomID /*subID*/ ) const { return true; }
+ virtual bool ContainsAny( const vector< TGeomID>& /*subIDs*/ ) const { return true; }
virtual TopAbs_Orientation Orientation( const TopoDS_Shape& s ) const { return s.Orientation(); }
- virtual bool IsOutsideOriented( TGeomID faceID ) const { return true; }
+ virtual bool IsOutsideOriented( TGeomID /*faceID*/ ) const { return true; }
void SetID( TGeomID id ) { _id = id; }
TGeomID ID() const { return _id; }
void SetHasInternalFaces( bool has ) { _hasInternalFaces = has; }
gp_XYZ _origin;
gp_Mat _invB; // inverted basis of _axes
+ // index shift within _nodes of nodes of a cell from the 1st node
+ int _nodeShift[8];
+
vector< const SMDS_MeshNode* > _nodes; // mesh nodes at grid nodes
vector< const F_IntersectPoint* > _gridIntP; // grid node intersection with geometry
ObjectPool< E_IntersectPoint > _edgeIntPool; // intersections with EDGEs
bool IsBoundaryFace( TGeomID face ) const { return _geometry._boundaryFaces.Contains( face ); }
void SetOnShape( const SMDS_MeshNode* n, const F_IntersectPoint& ip, bool unset=false );
bool IsToCheckNodePos() const { return !_toAddEdges && _toCreateFaces; }
+ bool IsToRemoveExcessEntities() const { return !_toAddEdges; }
void SetCoordinates(const vector<double>& xCoords,
const vector<double>& yCoords,
*/
struct CellsAroundLink
{
+ int _iDir;
int _dInd[4][3];
size_t _nbCells[3];
int _i,_j,_k;
Grid* _grid;
CellsAroundLink( Grid* grid, int iDir ):
+ _iDir( iDir ),
_dInd{ {0,0,0}, {0,0,0}, {0,0,0}, {0,0,0} },
_nbCells{ grid->_coords[0].size() - 1,
grid->_coords[1].size() - 1,
_j = j - _dInd[iL][1];
_k = k - _dInd[iL][2];
}
- bool GetCell( int iL, int& i, int& j, int& k, int& cellIndex )
+ bool GetCell( int iL, int& i, int& j, int& k, int& cellIndex, int& linkIndex )
{
i = _i + _dInd[iL][0];
j = _j + _dInd[iL][1];
k < 0 || k >= (int)_nbCells[2] )
return false;
cellIndex = _grid->CellIndex( i,j,k );
+ linkIndex = iL + _iDir * 4;
return true;
}
};
{
struct _Split // data of a link split
{
- int _linkID; // hex link ID
+ int _linkID; // hex link ID
_Node* _nodes[2];
int _iCheckIteration; // iteration where split is tried as Hexahedron split
_Link* _checkedSplit; // split set to hex links
- bool _isUsed; // used in a volume
+ bool _isUsed; // used in a volume
_Split( _Link & split, int iLink ):
_linkID( iLink ), _nodes{ split._nodes[0], split._nodes[1] },
// --------------------------------------------------------------------------------
struct _Face
{
+ SMESH_Block::TShapeID _name;
vector< _OrientedLink > _links; // links on GridLine's
vector< _Link > _polyLinks; // links added to close a polygonal face
vector< _Node* > _eIntNodes; // nodes at intersection with EDGEs
+
+ _Face():_name( SMESH_Block::ID_NONE )
+ {}
bool IsPolyLink( const _OrientedLink& ol )
{
return _polyLinks.empty() ? false :
// --------------------------------------------------------------------------------
struct _volumeDef // holder of nodes of a volume mesh element
{
+ typedef void* _ptr;
+
struct _nodeDef
{
const SMDS_MeshNode* _node; // mesh node at hexahedron corner
const B_IntersectPoint* _intPoint;
+ _nodeDef(): _node(0), _intPoint(0) {}
_nodeDef( _Node* n ): _node( n->_node), _intPoint( n->_intPoint ) {}
const SMDS_MeshNode* Node() const
{ return ( _intPoint && _intPoint->_node ) ? _intPoint->_node : _node; }
const E_IntersectPoint* EdgeIntPnt() const
{ return static_cast< const E_IntersectPoint* >( _intPoint ); }
+ _ptr Ptr() const { return Node() ? (_ptr) Node() : (_ptr) EdgeIntPnt(); }
+ bool operator==(const _nodeDef& other ) const { return Ptr() == other.Ptr(); }
};
+
vector< _nodeDef > _nodes;
vector< int > _quantities;
_volumeDef* _next; // to store several _volumeDefs in a chain
TGeomID _solidID;
const SMDS_MeshElement* _volume; // new volume
+ vector< SMESH_Block::TShapeID > _names; // name of side a polygon originates from
+
_volumeDef(): _next(0), _solidID(0), _volume(0) {}
~_volumeDef() { delete _next; }
_volumeDef( _volumeDef& other ):
_next(0), _solidID( other._solidID ), _volume( other._volume )
- { _nodes.swap( other._nodes ); _quantities.swap( other._quantities ); other._volume = 0; }
+ { _nodes.swap( other._nodes ); _quantities.swap( other._quantities ); other._volume = 0;
+ _names.swap( other._names ); }
- void Set( const vector< _Node* >& nodes, const vector< int >& quant = vector< int >() )
- { _nodes.assign( nodes.begin(), nodes.end() ); _quantities = quant; }
+ size_t size() const { return 1 + ( _next ? _next->size() : 0 ); }
+ _volumeDef* at(int index)
+ { return index == 0 ? this : ( _next ? _next->at(index-1) : _next ); }
void Set( _Node** nodes, int nb )
{ _nodes.assign( nodes, nodes + nb ); }
void SetNext( _volumeDef* vd )
{ if ( _next ) { _next->SetNext( vd ); } else { _next = vd; }}
+
+ bool IsEmpty() const { return (( _nodes.empty() ) &&
+ ( !_next || _next->IsEmpty() )); }
+ bool IsPolyhedron() const { return ( !_quantities.empty() ||
+ ( _next && !_next->_quantities.empty() )); }
+
+
+ struct _linkDef: public std::pair<_ptr,_ptr> // to join polygons in removeExcessSideDivision()
+ {
+ _nodeDef _node1;//, _node2;
+ mutable /*const */_linkDef *_prev, *_next;
+ size_t _loopIndex;
+
+ _linkDef():_prev(0), _next(0) {}
+
+ void init( const _nodeDef& n1, const _nodeDef& n2, size_t iLoop )
+ {
+ _node1 = n1; //_node2 = n2;
+ _loopIndex = iLoop;
+ first = n1.Ptr();
+ second = n2.Ptr();
+ if ( first > second ) std::swap( first, second );
+ }
+ void setNext( _linkDef* next )
+ {
+ _next = next;
+ next->_prev = this;
+ }
+ };
};
// topology of a hexahedron
- int _nodeShift[8];
_Node _hexNodes [8];
_Link _hexLinks [12];
_Face _hexQuads [6];
// additional nodes created at intersection points
vector< _Node > _intNodes;
- // nodes inside the hexahedron (at VERTEXes)
+ // nodes inside the hexahedron (at VERTEXes) refer to _intNodes
vector< _Node* > _vIntNodes;
// computed volume elements
Hexahedron(Grid* grid);
int MakeElements(SMESH_MesherHelper& helper,
const map< TGeomID, vector< TGeomID > >& edge2faceIDsMap);
- void ComputeElements( const Solid* solid = 0, int solidIndex = -1 );
+ void computeElements( const Solid* solid = 0, int solidIndex = -1 );
private:
Hexahedron(const Hexahedron& other, size_t i, size_t j, size_t k, int cellID );
const map< TGeomID, vector< TGeomID > >& edge2faceIDsMap );
void getVolumes( vector< const SMDS_MeshElement* > & volumes );
void getBoundaryElems( vector< const SMDS_MeshElement* > & boundaryVolumes );
+ void removeExcessSideDivision(const vector< Hexahedron* >& allHexa);
+ void removeExcessNodes(vector< Hexahedron* >& allHexa);
+ void preventVolumesOverlapping();
TGeomID getAnyFace() const;
void cutByExtendedInternal( std::vector< Hexahedron* >& hexes,
const TColStd_MapOfInteger& intEdgeIDs );
TID2Nb::iterator id2nb = id2nbMap.insert( s0 ).first;
id2nb->second++;
}
- };
+ }; // class Hexahedron
#ifdef WITH_TBB
// --------------------------------------------------------------------------
{
for ( size_t i = r.begin(); i != r.end(); ++i )
if ( Hexahedron* hex = _hexVec[ i ] )
- hex->ComputeElements();
+ hex->computeElements();
}
};
// --------------------------------------------------------------------------
size_t i101 = i100 + dz;
size_t i011 = i010 + dz;
size_t i111 = i110 + dz;
- _nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V000 )] = i000;
- _nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V100 )] = i100;
- _nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V010 )] = i010;
- _nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V110 )] = i110;
- _nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V001 )] = i001;
- _nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V101 )] = i101;
- _nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V011 )] = i011;
- _nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V111 )] = i111;
+ grid->_nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V000 )] = i000;
+ grid->_nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V100 )] = i100;
+ grid->_nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V010 )] = i010;
+ grid->_nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V110 )] = i110;
+ grid->_nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V001 )] = i001;
+ grid->_nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V101 )] = i101;
+ grid->_nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V011 )] = i011;
+ grid->_nodeShift[ SMESH_Block::ShapeIndex( SMESH_Block::ID_V111 )] = i111;
vector< int > idVec;
// set nodes to links
int interlace[4] = { 0, 3, 1, 2 }; // to walk by links around a face: { u0, 1v, u1, 0v }
for ( int faceID = SMESH_Block::ID_Fxy0; faceID <= SMESH_Block::ID_F1yz; ++faceID )
{
- SMESH_Block::GetFaceEdgesIDs( faceID, idVec );
_Face& quad = _hexQuads[ SMESH_Block::ShapeIndex( faceID )];
+ quad._name = (SMESH_Block::TShapeID) faceID;
+
+ SMESH_Block::GetFaceEdgesIDs( faceID, idVec );
bool revFace = ( faceID == SMESH_Block::ID_Fxy0 ||
faceID == SMESH_Block::ID_Fx1z ||
faceID == SMESH_Block::ID_F0yz );
_polygons.reserve(100); // to avoid reallocation;
// copy topology
- for ( int i = 0; i < 8; ++i )
- _nodeShift[i] = other._nodeShift[i];
-
for ( int i = 0; i < 12; ++i )
{
const _Link& srcLink = other._hexLinks[ i ];
{
const _Face& srcQuad = other._hexQuads[ i ];
_Face& tgtQuad = this->_hexQuads[ i ];
+ tgtQuad._name = srcQuad._name;
tgtQuad._links.resize(4);
for ( int j = 0; j < 4; ++j )
{
}
#ifdef _DEBUG_
_cellID = cellID;
+#else
+ (void)cellID; // unused in release mode
#endif
}
_origNodeInd = _grid->NodeIndex( _i,_j,_k );
for ( int iN = 0; iN < 8; ++iN )
{
- _hexNodes[iN]._node = _grid->_nodes [ _origNodeInd + _nodeShift[iN] ];
- _hexNodes[iN]._intPoint = _grid->_gridIntP[ _origNodeInd + _nodeShift[iN] ];
+ _hexNodes[iN]._node = _grid->_nodes [ _origNodeInd + _grid->_nodeShift[iN] ];
+ _hexNodes[iN]._intPoint = _grid->_gridIntP[ _origNodeInd + _grid->_nodeShift[iN] ];
if ( _hexNodes[iN]._intPoint ) // intersection with a FACE
{
{
_i = i; _j = j; _k = k;
+ bool isCompute = solid;
if ( !solid )
solid = _grid->GetSolid();
{
_hexNodes[iN]._isInternalFlags = 0;
- _hexNodes[iN]._node = _grid->_nodes [ _origNodeInd + _nodeShift[iN] ];
- _hexNodes[iN]._intPoint = _grid->_gridIntP[ _origNodeInd + _nodeShift[iN] ];
+ _hexNodes[iN]._node = _grid->_nodes [ _origNodeInd + _grid->_nodeShift[iN] ];
+ _hexNodes[iN]._intPoint = _grid->_gridIntP[ _origNodeInd + _grid->_nodeShift[iN] ];
if ( _hexNodes[iN]._node && !solid->Contains( _hexNodes[iN]._node->GetShapeID() ))
_hexNodes[iN]._node = 0;
_intNodes.clear();
_vIntNodes.clear();
+ if ( !isCompute )
+ return;
+
if ( _nbFaceIntNodes + _eIntPoints.size() > 0 &&
_nbFaceIntNodes + _eIntPoints.size() + _nbCornerNodes > 3)
{
case 3: // at a corner
{
_Node& node = _hexNodes[ subEntity - SMESH_Block::ID_FirstV ];
- if ( node.Node() > 0 )
+ if ( node.Node() )
{
if ( node._intPoint )
node._intPoint->Add( _eIntPoints[ iP ]->_faceIDs, _eIntPoints[ iP ]->_node );
} // loop on _eIntPoints
}
- else if ( 3 < _nbCornerNodes && _nbCornerNodes < 8 ) // _nbFaceIntNodes == 0
+ else if (( 3 < _nbCornerNodes && _nbCornerNodes < 8 ) || // _nbFaceIntNodes == 0
+ ( !_grid->_geometry.IsOneSolid() ))
{
_Link split;
// create sub-links (_splits) of whole links
/*!
* \brief Compute mesh volumes resulted from intersection of the Hexahedron
*/
- void Hexahedron::ComputeElements( const Solid* solid, int solidIndex )
+ void Hexahedron::computeElements( const Solid* solid, int solidIndex )
{
if ( !solid )
{
for ( size_t i = 0; i < nbSolids; ++i )
{
solid = _grid->GetSolid( solidIDs[i] );
- ComputeElements( solid, i );
+ computeElements( solid, i );
if ( !_volumeDefs._nodes.empty() && i < nbSolids - 1 )
_volumeDefs.SetNext( new _volumeDef( _volumeDefs ));
}
for ( int iN = 0; iN < 8; ++iN )
_hexNodes[iN]._usedInFace = 0;
+ if ( intFlag & IS_CUT_BY_INTERNAL_FACE && !_grid->_toAddEdges ) // Issue #19913
+ preventVolumesOverlapping();
+
// Create polygons from quadrangles
// --------------------------------
vector<_Node*> chainNodes;
_Face* coplanarPolyg;
- bool hasEdgeIntersections = !_eIntPoints.empty();
+ const bool hasEdgeIntersections = !_eIntPoints.empty();
+ const bool toCheckSideDivision = isImplementEdges() || intFlag & IS_CUT_BY_INTERNAL_FACE;
for ( int iF = 0; iF < 6; ++iF ) // loop on 6 sides of a hexahedron
{
_polygons.resize( _polygons.size() + 1 );
_Face* polygon = &_polygons.back();
polygon->_polyLinks.reserve( 20 );
+ polygon->_name = quad._name;
splits.clear();
for ( int iE = 0; iE < 4; ++iE ) // loop on 4 sides of a quadrangle
_polygons.resize( _polygons.size() + 1 );
polygon = &_polygons.back();
polygon->_polyLinks.reserve( 20 );
+ polygon->_name = quad._name;
}
polygon->_links.push_back( splits[ iS ] );
splits[ iS++ ]._link = 0;
n1 = split.FirstNode();
if ( n1 == n2 &&
n1->_intPoint &&
- (( n1->_intPoint->_faceIDs.size() > 1 && isImplementEdges() ) ||
+ (( n1->_intPoint->_faceIDs.size() > 1 && toCheckSideDivision ) ||
( n1->_isInternalFlags )))
{
// n1 is at intersection with EDGE
if ( _hasTooSmall )
return false; // too small volume
+
+ // Try to find out names of no-name polygons (issue # 19887)
+ if ( _grid->IsToRemoveExcessEntities() && _polygons.back()._name == SMESH_Block::ID_NONE )
+ {
+ gp_XYZ uvwCenter =
+ 0.5 * ( _grid->_coords[0][_i] + _grid->_coords[0][_i+1] ) * _grid->_axes[0] +
+ 0.5 * ( _grid->_coords[1][_j] + _grid->_coords[1][_j+1] ) * _grid->_axes[1] +
+ 0.5 * ( _grid->_coords[2][_k] + _grid->_coords[2][_k+1] ) * _grid->_axes[2];
+ for ( size_t i = _polygons.size() - 1; _polygons[i]._name == SMESH_Block::ID_NONE; --i )
+ {
+ _Face& face = _polygons[ i ];
+ Bnd_Box bb;
+ gp_Pnt uvw;
+ for ( size_t iL = 0; iL < face._links.size(); ++iL )
+ {
+ _Node* n = face._links[ iL ].FirstNode();
+ gp_XYZ p = SMESH_NodeXYZ( n->Node() );
+ _grid->ComputeUVW( p, uvw.ChangeCoord().ChangeData() );
+ bb.Add( uvw );
+ }
+ gp_Pnt pMin = bb.CornerMin();
+ if ( bb.IsXThin( _grid->_tol ))
+ face._name = pMin.X() < uvwCenter.X() ? SMESH_Block::ID_F0yz : SMESH_Block::ID_F1yz;
+ else if ( bb.IsYThin( _grid->_tol ))
+ face._name = pMin.Y() < uvwCenter.Y() ? SMESH_Block::ID_Fx0z : SMESH_Block::ID_Fx1z;
+ else if ( bb.IsZThin( _grid->_tol ))
+ face._name = pMin.Z() < uvwCenter.Z() ? SMESH_Block::ID_Fxy0 : SMESH_Block::ID_Fxy1;
+ }
+ }
+
+ _volumeDefs._nodes.clear();
+ _volumeDefs._quantities.clear();
+ _volumeDefs._names.clear();
+
// create a classic cell if possible
int nbPolygons = 0;
else if ( nbNodes == 5 && nbPolygons == 5 ) isClassicElem = addPyra ();
if ( !isClassicElem )
{
- _volumeDefs._nodes.clear();
- _volumeDefs._quantities.clear();
-
for ( size_t iF = 0; iF < _polygons.size(); ++iF )
{
const size_t nbLinks = _polygons[ iF ]._links.size();
if ( nbLinks == 0 ) continue;
_volumeDefs._quantities.push_back( nbLinks );
+ _volumeDefs._names.push_back( _polygons[ iF ]._name );
for ( size_t iL = 0; iL < nbLinks; ++iL )
_volumeDefs._nodes.push_back( _polygons[ iF ]._links[ iL ].FirstNode() );
}
int nbIntHex = 0;
// set intersection nodes from GridLine's to links of allHexa
- int i,j,k, cellIndex;
+ int i,j,k, cellIndex, iLink;
for ( int iDir = 0; iDir < 3; ++iDir )
{
// loop on GridLine's parallel to iDir
fourCells.Init( lineInd.I(), lineInd.J(), lineInd.K() );
for ( int iL = 0; iL < 4; ++iL ) // loop on 4 cells sharing a link
{
- if ( !fourCells.GetCell( iL, i,j,k, cellIndex ))
+ if ( !fourCells.GetCell( iL, i,j,k, cellIndex, iLink ))
continue;
Hexahedron *& hex = allHexa[ cellIndex ];
if ( !hex)
hex = new Hexahedron( *this, i, j, k, cellIndex );
++nbIntHex;
}
- const int iLink = iL + iDir * 4;
hex->_hexLinks[iLink]._fIntPoints.push_back( &(*ip) );
hex->_nbFaceIntNodes += bool( ip->_node );
}
if ( hex ) // split hexahedron
{
intHexa.push_back( hex );
- if ( hex->_nbFaceIntNodes > 0 || hex->_eIntPoints.size() > 0 )
+ if ( hex->_nbFaceIntNodes > 0 ||
+ hex->_eIntPoints.size() > 0 ||
+ hex->getSolids( solidIDs ) > 1 )
continue; // treat intersected hex later in parallel
this->init( hex->_i, hex->_j, hex->_k );
}
}
}
- // add elements resulted from hexadron intersection
+ // compute definitions of volumes resulted from hexadron intersection
#ifdef WITH_TBB
tbb::parallel_for ( tbb::blocked_range<size_t>( 0, intHexa.size() ),
ParallelHexahedron( intHexa ),
- tbb::simple_partitioner()); // ComputeElements() is called here
+ tbb::simple_partitioner()); // computeElements() is called here
+#else
for ( size_t i = 0; i < intHexa.size(); ++i )
if ( Hexahedron * hex = intHexa[ i ] )
- nbAdded += hex->addVolumes( helper );
-#else
+ hex->computeElements();
+#endif
+
+ // simplify polyhedrons
+ if ( _grid->IsToRemoveExcessEntities() )
+ {
+ for ( size_t i = 0; i < intHexa.size(); ++i )
+ if ( Hexahedron * hex = intHexa[ i ] )
+ hex->removeExcessSideDivision( allHexa );
+
+ for ( size_t i = 0; i < intHexa.size(); ++i )
+ if ( Hexahedron * hex = intHexa[ i ] )
+ hex->removeExcessNodes( allHexa );
+ }
+
+ // add volumes
for ( size_t i = 0; i < intHexa.size(); ++i )
if ( Hexahedron * hex = intHexa[ i ] )
- {
- hex->ComputeElements();
nbAdded += hex->addVolumes( helper );
- }
-#endif
// fill boundaryVolumes with volumes neighboring too small skipped volumes
if ( _grid->_toCreateFaces )
continue;
// perform intersection
- E_IntersectPoint* eip, *vip;
+ E_IntersectPoint* eip, *vip = 0;
for ( int iDirZ = 0; iDirZ < 3; ++iDirZ )
{
GridPlanes& planes = pln[ iDirZ ];
int i = ! ( u < _grid->_tol ); // [0,1]
int iN = link._nodes[ i ] - hex->_hexNodes; // [0-7]
- const F_IntersectPoint * & ip = _grid->_gridIntP[ hex->_origNodeInd + _nodeShift[iN] ];
+ const F_IntersectPoint * & ip = _grid->_gridIntP[ hex->_origNodeInd +
+ _grid->_nodeShift[iN] ];
if ( !ip )
{
ip = _grid->_extIntPool.getNew();
int i,j,k, cellIndex;
for ( int iC = 0; iC < 4; ++iC ) // loop on 4 cells sharing the link
{
- if ( !fourCells.GetCell( iC, i,j,k, cellIndex ))
+ if ( !fourCells.GetCell( iC, i,j,k, cellIndex, iLink ))
continue;
Hexahedron * h = hexes[ cellIndex ];
if ( !h )
h = hexes[ cellIndex ] = new Hexahedron( *this, i, j, k, cellIndex );
- const int iL = iC + iDir * 4;
- h->_hexLinks[iL]._fIntPoints.push_back( ip );
+ h->_hexLinks[iLink]._fIntPoints.push_back( ip );
h->_nbFaceIntNodes++;
//isCut = true;
}
for ( size_t iN = 0; iN < 8; ++iN ) // check corners
{
- _hexNodes[iN]._node = _grid->_nodes [ _origNodeInd + _nodeShift[iN] ];
- _hexNodes[iN]._intPoint = _grid->_gridIntP[ _origNodeInd + _nodeShift[iN] ];
+ _hexNodes[iN]._node = _grid->_nodes [ _origNodeInd + _grid->_nodeShift[iN] ];
+ _hexNodes[iN]._intPoint = _grid->_gridIntP[ _origNodeInd + _grid->_nodeShift[iN] ];
if ( _hexNodes[iN]._intPoint )
for ( size_t iF = 0; iF < _hexNodes[iN]._intPoint->_faceIDs.size(); ++iF )
{
{
curIntPnt._paramOnLine = coords[ ijk[ iDir ]] - coords[0] + _grid->_tol;
const GridLine& line = _grid->_lines[ iDir ][ lineIndex[ iL ]];
- multiset< F_IntersectPoint >::const_iterator ip =
- line._intPoints.upper_bound( curIntPnt );
- --ip;
- firstIntPnt = &(*ip);
+ if ( !line._intPoints.empty() )
+ {
+ multiset< F_IntersectPoint >::const_iterator ip =
+ line._intPoints.upper_bound( curIntPnt );
+ --ip;
+ firstIntPnt = &(*ip);
+ }
}
else if ( !link._fIntPoints.empty() )
{
cout << "BUG: not shared link. IKJ = ( "<< _i << " " << _j << " " << _k << " )" << endl
<< "n1 (" << p1.X() << ", "<< p1.Y() << ", "<< p1.Z() << " )" << endl
<< "n2 (" << p2.X() << ", "<< p2.Y() << ", "<< p2.Z() << " )" << endl;
+#else
+ (void)link; // unused in release mode
#endif
return false;
}
if ( !faceID )
break;
if ( _grid->IsInternal( faceID ) ||
- _grid->IsShared( faceID ) /*||
- _grid->IsBoundaryFace( faceID )*/)
+ _grid->IsShared( faceID ) //||
+ //_grid->IsBoundaryFace( faceID ) -- commented for #19887
+ )
break; // create only if a new face will be used by other 3D algo
}
}
}
+ //================================================================================
+ /*!
+ * \brief Remove edges and nodes dividing a hexa side in the case if an adjacent
+ * volume also sharing the dividing edge is missing due to its small side.
+ * Issue #19887.
+ */
+ //================================================================================
+
+ void Hexahedron::removeExcessSideDivision(const vector< Hexahedron* >& allHexa)
+ {
+ if ( ! _volumeDefs.IsPolyhedron() )
+ return; // not a polyhedron
+
+ // look for a divided side adjacent to a small hexahedron
+
+ int di[6] = { 0, 0, 0, 0,-1, 1 };
+ int dj[6] = { 0, 0,-1, 1, 0, 0 };
+ int dk[6] = {-1, 1, 0, 0, 0, 0 };
+
+ for ( int iF = 0; iF < 6; ++iF ) // loop on 6 sides of a hexahedron
+ {
+ size_t neighborIndex = _grid->CellIndex( _i + di[iF],
+ _j + dj[iF],
+ _k + dk[iF] );
+ if ( neighborIndex >= allHexa.size() ||
+ !allHexa[ neighborIndex ] ||
+ !allHexa[ neighborIndex ]->_hasTooSmall )
+ continue;
+
+ // check if a side is divided into several polygons
+ for ( _volumeDef* volDef = &_volumeDefs; volDef; volDef = volDef->_next )
+ {
+ int nbPolygons = 0, nbNodes = 0;
+ for ( size_t i = 0; i < volDef->_names.size(); ++i )
+ if ( volDef->_names[ i ] == _hexQuads[ iF ]._name )
+ {
+ ++nbPolygons;
+ nbNodes += volDef->_quantities[ i ];
+ }
+ if ( nbPolygons < 2 )
+ continue;
+
+ // construct loops from polygons
+ typedef _volumeDef::_linkDef TLinkDef;
+ std::vector< TLinkDef* > loops;
+ std::vector< TLinkDef > links( nbNodes );
+ for ( size_t i = 0, iN = 0, iLoop = 0; iLoop < volDef->_quantities.size(); ++iLoop )
+ {
+ size_t nbLinks = volDef->_quantities[ iLoop ];
+ if ( volDef->_names[ iLoop ] != _hexQuads[ iF ]._name )
+ {
+ iN += nbLinks;
+ continue;
+ }
+ loops.push_back( & links[i] );
+ for ( size_t n = 0; n < nbLinks-1; ++n, ++i, ++iN )
+ {
+ links[i].init( volDef->_nodes[iN], volDef->_nodes[iN+1], iLoop );
+ links[i].setNext( &links[i+1] );
+ }
+ links[i].init( volDef->_nodes[iN], volDef->_nodes[iN-nbLinks+1], iLoop );
+ links[i].setNext( &links[i-nbLinks+1] );
+ ++i; ++iN;
+ }
+
+ // look for equal links in different loops and join such loops
+ bool loopsJoined = false;
+ std::set< TLinkDef > linkSet;
+ for ( size_t iLoop = 0; iLoop < loops.size(); ++iLoop )
+ {
+ TLinkDef* beg = 0;
+ for ( TLinkDef* l = loops[ iLoop ]; l != beg; l = l->_next ) // walk around the iLoop
+ {
+ std::pair< std::set< TLinkDef >::iterator, bool > it2new = linkSet.insert( *l );
+ if ( !it2new.second ) // equal found, join loops
+ {
+ const TLinkDef* equal = &(*it2new.first);
+ if ( equal->_loopIndex == l->_loopIndex )
+ continue; // error?
+
+ loopsJoined = true;
+
+ for ( size_t i = iLoop - 1; i < loops.size(); --i )
+ if ( loops[ i ] && loops[ i ]->_loopIndex == equal->_loopIndex )
+ loops[ i ] = 0;
+
+ // exclude l and equal and join two loops
+ if ( l->_prev != equal )
+ l->_prev->setNext( equal->_next );
+ if ( equal->_prev != l )
+ equal->_prev->setNext( l->_next );
+
+ if ( volDef->_quantities[ l->_loopIndex ] > 0 )
+ volDef->_quantities[ l->_loopIndex ] *= -1;
+ if ( volDef->_quantities[ equal->_loopIndex ] > 0 )
+ volDef->_quantities[ equal->_loopIndex ] *= -1;
+
+ if ( loops[ iLoop ] == l )
+ loops[ iLoop ] = l->_prev->_next;
+ }
+ beg = loops[ iLoop ];
+ }
+ }
+ // update volDef
+ if ( loopsJoined )
+ {
+ // set unchanged polygons
+ std::vector< int > newQuantities;
+ std::vector< _volumeDef::_nodeDef > newNodes;
+ vector< SMESH_Block::TShapeID > newNames;
+ newQuantities.reserve( volDef->_quantities.size() );
+ newNodes.reserve ( volDef->_nodes.size() );
+ newNames.reserve ( volDef->_names.size() );
+ for ( size_t i = 0, iLoop = 0; iLoop < volDef->_quantities.size(); ++iLoop )
+ {
+ if ( volDef->_quantities[ iLoop ] < 0 )
+ {
+ i -= volDef->_quantities[ iLoop ];
+ continue;
+ }
+ newQuantities.push_back( volDef->_quantities[ iLoop ]);
+ newNodes.insert( newNodes.end(),
+ volDef->_nodes.begin() + i,
+ volDef->_nodes.begin() + i + newQuantities.back() );
+ newNames.push_back( volDef->_names[ iLoop ]);
+ i += volDef->_quantities[ iLoop ];
+ }
+
+ // set joined loops
+ for ( size_t iLoop = 0; iLoop < loops.size(); ++iLoop )
+ {
+ if ( !loops[ iLoop ] )
+ continue;
+ newQuantities.push_back( 0 );
+ TLinkDef* beg = 0;
+ for ( TLinkDef* l = loops[ iLoop ]; l != beg; l = l->_next, ++newQuantities.back() )
+ {
+ newNodes.push_back( l->_node1 );
+ beg = loops[ iLoop ];
+ }
+ newNames.push_back( _hexQuads[ iF ]._name );
+ }
+ volDef->_quantities.swap( newQuantities );
+ volDef->_nodes.swap( newNodes );
+ volDef->_names.swap( newNames );
+ }
+ } // loop on volDef's
+ } // loop on hex sides
+
+ return;
+ } // removeExcessSideDivision()
+
+
+ //================================================================================
+ /*!
+ * \brief Remove nodes splitting Cartesian cell edges in the case if a node
+ * is used in every cells only by two polygons sharing the edge
+ * Issue #19887.
+ */
+ //================================================================================
+
+ void Hexahedron::removeExcessNodes(vector< Hexahedron* >& allHexa)
+ {
+ if ( ! _volumeDefs.IsPolyhedron() )
+ return; // not a polyhedron
+
+ typedef vector< _volumeDef::_nodeDef >::iterator TNodeIt;
+ vector< int > nodesInPoly[ 4 ]; // node index in _volumeDefs._nodes
+ vector< int > volDefInd [ 4 ]; // index of a _volumeDefs
+ Hexahedron* hexa [ 4 ];
+ int i,j,k, cellIndex, iLink = 0, iCellLink;
+ for ( int iDir = 0; iDir < 3; ++iDir )
+ {
+ CellsAroundLink fourCells( _grid, iDir );
+ for ( int iL = 0; iL < 4; ++iL, ++iLink ) // 4 links in a direction
+ {
+ _Link& link = _hexLinks[ iLink ];
+ fourCells.Init( _i, _j, _k, iLink );
+
+ for ( size_t iP = 0; iP < link._fIntPoints.size(); ++iP ) // loop on nodes on the link
+ {
+ bool nodeRemoved = true;
+ _volumeDef::_nodeDef node; node._intPoint = link._fIntPoints[iP];
+
+ for ( size_t i = 0, nb = _volumeDefs.size(); i < nb && nodeRemoved; ++i )
+ if ( _volumeDef* vol = _volumeDefs.at( i ))
+ nodeRemoved =
+ ( std::find( vol->_nodes.begin(), vol->_nodes.end(), node ) == vol->_nodes.end() );
+ if ( nodeRemoved )
+ continue; // node already removed
+
+ // check if a node encounters zero or two times in 4 cells sharing iLink
+ // if so, the node can be removed from the cells
+ bool nodeIsOnEdge = true;
+ int nbPolyhedraWithNode = 0;
+ for ( int iC = 0; iC < 4; ++iC ) // loop on 4 cells sharing a link
+ {
+ nodesInPoly[ iC ].clear();
+ volDefInd [ iC ].clear();
+ hexa [ iC ] = 0;
+ if ( !fourCells.GetCell( iC, i,j,k, cellIndex, iCellLink ))
+ continue;
+ hexa[ iC ] = allHexa[ cellIndex ];
+ if ( !hexa[ iC ])
+ continue;
+ for ( size_t i = 0, nb = hexa[ iC ]->_volumeDefs.size(); i < nb; ++i )
+ if ( _volumeDef* vol = hexa[ iC ]->_volumeDefs.at( i ))
+ {
+ for ( TNodeIt nIt = vol->_nodes.begin(); nIt != vol->_nodes.end(); ++nIt )
+ {
+ nIt = std::find( nIt, vol->_nodes.end(), node );
+ if ( nIt != vol->_nodes.end() )
+ {
+ nodesInPoly[ iC ].push_back( std::distance( vol->_nodes.begin(), nIt ));
+ volDefInd [ iC ].push_back( i );
+ }
+ else
+ break;
+ }
+ nbPolyhedraWithNode += ( !nodesInPoly[ iC ].empty() );
+ }
+ if ( nodesInPoly[ iC ].size() != 0 &&
+ nodesInPoly[ iC ].size() != 2 )
+ {
+ nodeIsOnEdge = false;
+ break;
+ }
+ } // loop on 4 cells
+
+ // remove nodes from polyhedra
+ if ( nbPolyhedraWithNode > 0 && nodeIsOnEdge )
+ {
+ for ( int iC = 0; iC < 4; ++iC ) // loop on 4 cells sharing the link
+ {
+ if ( nodesInPoly[ iC ].empty() )
+ continue;
+ for ( int i = volDefInd[ iC ].size() - 1; i >= 0; --i )
+ {
+ _volumeDef* vol = hexa[ iC ]->_volumeDefs.at( volDefInd[ iC ][ i ]);
+ int nIndex = nodesInPoly[ iC ][ i ];
+ // decrement _quantities
+ for ( size_t iQ = 0; iQ < vol->_quantities.size(); ++iQ )
+ if ( nIndex < vol->_quantities[ iQ ])
+ {
+ vol->_quantities[ iQ ]--;
+ break;
+ }
+ else
+ {
+ nIndex -= vol->_quantities[ iQ ];
+ }
+ vol->_nodes.erase( vol->_nodes.begin() + nodesInPoly[ iC ][ i ]);
+
+ if ( i == 0 &&
+ vol->_nodes.size() == 6 * 4 &&
+ vol->_quantities.size() == 6 ) // polyhedron becomes hexahedron?
+ {
+ bool allQuads = true;
+ for ( size_t iQ = 0; iQ < vol->_quantities.size() && allQuads; ++iQ )
+ allQuads = ( vol->_quantities[ iQ ] == 4 );
+ if ( allQuads )
+ {
+ // set side nodes as this: bottom, top, top, ...
+ int iTop = 0, iBot = 0; // side indices
+ for ( int iS = 0; iS < 6; ++iS )
+ {
+ if ( vol->_names[ iS ] == SMESH_Block::ID_Fxy0 )
+ iBot = iS;
+ if ( vol->_names[ iS ] == SMESH_Block::ID_Fxy1 )
+ iTop = iS;
+ }
+ if ( iBot != 0 )
+ {
+ if ( iTop == 0 )
+ {
+ std::copy( vol->_nodes.begin(),
+ vol->_nodes.begin() + 4,
+ vol->_nodes.begin() + 4 );
+ iTop = 1;
+ }
+ std::copy( vol->_nodes.begin() + 4 * iBot,
+ vol->_nodes.begin() + 4 * ( iBot + 1),
+ vol->_nodes.begin() );
+ }
+ if ( iTop != 1 )
+ std::copy( vol->_nodes.begin() + 4 * iTop,
+ vol->_nodes.begin() + 4 * ( iTop + 1),
+ vol->_nodes.begin() + 4 );
+
+ std::copy( vol->_nodes.begin() + 4,
+ vol->_nodes.begin() + 8,
+ vol->_nodes.begin() + 8 );
+ // set up top facet nodes by comparing their uvw with bottom nodes
+ E_IntersectPoint ip[8];
+ for ( int iN = 0; iN < 8; ++iN )
+ {
+ SMESH_NodeXYZ p = vol->_nodes[ iN ].Node();
+ _grid->ComputeUVW( p, ip[ iN ]._uvw );
+ }
+ const double tol2 = _grid->_tol * _grid->_tol;
+ for ( int iN = 0; iN < 4; ++iN )
+ {
+ gp_Pnt2d pBot( ip[ iN ]._uvw[0], ip[ iN ]._uvw[1] );
+ for ( int iT = 4; iT < 8; ++iT )
+ {
+ gp_Pnt2d pTop( ip[ iT ]._uvw[0], ip[ iT ]._uvw[1] );
+ if ( pBot.SquareDistance( pTop ) < tol2 )
+ {
+ // vol->_nodes[ iN + 4 ]._node = ip[ iT ]._node;
+ // vol->_nodes[ iN + 4 ]._intPoint = 0;
+ vol->_nodes[ iN + 4 ] = vol->_nodes[ iT + 4 ];
+ break;
+ }
+ }
+ }
+ vol->_nodes.resize( 8 );
+ vol->_quantities.clear();
+ //vol->_names.clear();
+ }
+ }
+ } // loop on _volumeDefs
+ } // loop on 4 cell abound a link
+ } // if ( nodeIsOnEdge )
+ } // loop on intersection points of a link
+ } // loop on 4 links of a direction
+ } // loop on 3 directions
+
+ return;
+
+ } // removeExcessNodes()
+
+ //================================================================================
+ /*!
+ * \brief [Issue #19913] Modify _hexLinks._splits to prevent creating overlapping volumes
+ */
+ //================================================================================
+
+ void Hexahedron::preventVolumesOverlapping()
+ {
+ // Cut off a quadrangle corner if two links sharing the corner
+ // are shared by same two solids, in this case each of solids gets
+ // a triangle for it-self.
+ std::vector< TGeomID > soIDs[4];
+ for ( int iF = 0; iF < 6; ++iF ) // loop on 6 sides of a hexahedron
+ {
+ _Face& quad = _hexQuads[ iF ] ;
+
+ int iFOpposite = iF + ( iF % 2 ? -1 : 1 );
+ _Face& quadOpp = _hexQuads[ iFOpposite ] ;
+
+ int nbSides = 0, nbSidesOpp = 0;
+ for ( int iE = 0; iE < 4; ++iE ) // loop on 4 sides of a quadrangle
+ {
+ nbSides += ( quad._links [ iE ].NbResultLinks() > 0 );
+ nbSidesOpp += ( quadOpp._links[ iE ].NbResultLinks() > 0 );
+ }
+ if ( nbSides < 4 || nbSidesOpp != 2 )
+ continue;
+
+ for ( int iE = 0; iE < 4; ++iE )
+ {
+ soIDs[ iE ].clear();
+ _Node* n = quad._links[ iE ].FirstNode();
+ if ( n->_intPoint && n->_intPoint->_faceIDs.size() )
+ soIDs[ iE ] = _grid->GetSolidIDs( n->_intPoint->_faceIDs[0] );
+ }
+ if ((( soIDs[0].size() >= 2 ) +
+ ( soIDs[1].size() >= 2 ) +
+ ( soIDs[2].size() >= 2 ) +
+ ( soIDs[3].size() >= 2 ) ) < 3 )
+ continue;
+
+ bool done = false;
+ for ( int i = 0; i < 4; ++i )
+ {
+ int i1 = _grid->_helper->WrapIndex( i + 1, 4 );
+ int i2 = _grid->_helper->WrapIndex( i + 2, 4 );
+ int i3 = _grid->_helper->WrapIndex( i + 3, 4 );
+ if ( soIDs[i1].size() == 2 && soIDs[i ] != soIDs[i1] &&
+ soIDs[i2].size() == 2 && soIDs[i1] == soIDs[i2] &&
+ soIDs[i3].size() == 2 && soIDs[i2] == soIDs[i3] )
+ {
+ quad._links[ i1 ]._link->_splits.clear();
+ quad._links[ i2 ]._link->_splits.clear();
+ done = true;
+ break;
+ }
+ }
+ if ( done )
+ break;
+ }
+ return;
+ } // preventVolumesOverlapping()
+
//================================================================================
/*!
* \brief Set to _hexLinks a next portion of splits located on one side of INTERNAL FACEs
*/
//=============================================================================
-bool StdMeshers_Cartesian_3D::Evaluate(SMESH_Mesh & theMesh,
- const TopoDS_Shape & theShape,
- MapShapeNbElems& theResMap)
+bool StdMeshers_Cartesian_3D::Evaluate(SMESH_Mesh & /*theMesh*/,
+ const TopoDS_Shape & /*theShape*/,
+ MapShapeNbElems& /*theResMap*/)
{
// TODO
// std::vector<int> aResVec(SMDSEntity_Last);
// --------------------------------------------------------------------------------
// unsetting _alwaysComputed flag if "Cartesian_3D" was removed
//
- virtual void ProcessEvent(const int event,
+ virtual void ProcessEvent(const int /*event*/,
const int eventType,
SMESH_subMesh* subMeshOfSolid,
- SMESH_subMeshEventListenerData* data,
- const SMESH_Hypothesis* hyp = 0)
+ SMESH_subMeshEventListenerData* /*data*/,
+ const SMESH_Hypothesis* /*hyp*/ = 0)
{
if ( eventType == SMESH_subMesh::COMPUTE_EVENT )
{