-// Copyright (C) 2007-2015 CEA/DEN, EDF R&D, OPEN CASCADE
+// Copyright (C) 2007-2016 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
/*!
* \brief Constructor
*/
- SMESH_NodeSearcherImpl( const SMDS_Mesh* theMesh )
+ SMESH_NodeSearcherImpl( const SMDS_Mesh* theMesh = 0,
+ SMDS_ElemIteratorPtr theElemIt = SMDS_ElemIteratorPtr() )
{
myMesh = ( SMDS_Mesh* ) theMesh;
while ( nIt->more() )
nodes.insert( nodes.end(), nIt->next() );
}
+ else if ( theElemIt )
+ {
+ while ( theElemIt->more() )
+ {
+ const SMDS_MeshElement* e = theElemIt->next();
+ nodes.insert( e->begin_nodes(), e->end_nodes() );
+ }
+ }
myOctreeNode = new SMESH_OctreeNode(nodes) ;
// get max size of a leaf box
ElementBndBoxTree::~ElementBndBoxTree()
{
- for ( int i = 0; i < _elements.size(); ++i )
+ for ( size_t i = 0; i < _elements.size(); ++i )
if ( --_elements[i]->_refCount <= 0 )
delete _elements[i];
}
Bnd_B3d* ElementBndBoxTree::buildRootBox()
{
Bnd_B3d* box = new Bnd_B3d;
- for ( int i = 0; i < _elements.size(); ++i )
+ for ( size_t i = 0; i < _elements.size(); ++i )
box->Add( *_elements[i] );
return box;
}
void ElementBndBoxTree::buildChildrenData()
{
- for ( int i = 0; i < _elements.size(); ++i )
+ for ( size_t i = 0; i < _elements.size(); ++i )
{
for (int j = 0; j < 8; j++)
{
for (int j = 0; j < 8; j++)
{
ElementBndBoxTree* child = static_cast<ElementBndBoxTree*>( myChildren[j]);
- if ( child->_elements.size() <= MaxNbElemsInLeaf )
+ if ((int) child->_elements.size() <= MaxNbElemsInLeaf )
child->myIsLeaf = true;
if ( child->_elements.capacity() - child->_elements.size() > 1000 )
if ( isLeaf() )
{
- for ( int i = 0; i < _elements.size(); ++i )
+ for ( size_t i = 0; i < _elements.size(); ++i )
if ( !_elements[i]->IsOut( point.XYZ() ))
foundElems.insert( _elements[i]->_element );
}
if ( isLeaf() )
{
- for ( int i = 0; i < _elements.size(); ++i )
+ for ( size_t i = 0; i < _elements.size(); ++i )
if ( !_elements[i]->IsOut( line ))
foundElems.insert( _elements[i]->_element );
}
if ( isLeaf() )
{
- for ( int i = 0; i < _elements.size(); ++i )
+ for ( size_t i = 0; i < _elements.size(); ++i )
if ( !_elements[i]->IsOut( center, radius ))
foundElems.insert( _elements[i]->_element );
}
void GetElementsNearLine( const gp_Ax1& line,
SMDSAbs_ElementType type,
vector< const SMDS_MeshElement* >& foundElems);
+ void GetElementsInSphere( const gp_XYZ& center,
+ const double radius,
+ SMDSAbs_ElementType type,
+ vector< const SMDS_MeshElement* >& foundElems);
double getTolerance();
bool getIntersParamOnLine(const gp_Lin& line, const SMDS_MeshElement* face,
const double tolerance, double & param);
{
return _outerFaces.empty() || _outerFaces.count(face);
}
+
struct TInters //!< data of intersection of the line and the mesh face (used in GetPointState())
{
const SMDS_MeshElement* _face;
{
GC_MakeSegment edge( SMESH_TNodeXYZ( face->GetNode( i )),
SMESH_TNodeXYZ( face->GetNode( (i+1)%nbNodes) ));
- anExtCC.Init( lineCurve, edge);
+ anExtCC.Init( lineCurve, edge.Value() );
if ( anExtCC.NbExtrema() > 0 && anExtCC.LowerDistance() <= tol)
{
Quantity_Parameter pl, pe;
set< const SMDS_MeshElement*, TIDCompare >::const_iterator face = faces.begin();
for ( ; face != faces.end(); ++face )
{
+ if ( *face == outerFace ) continue;
if ( !SMESH_MeshAlgos::FaceNormal( *face, fNorm, /*normalized=*/false ))
continue;
gp_Vec dirInF = gp_Vec( fNorm ) ^ n1n2;
// store the found outer face and add its links to continue seaching from
if ( outerFace2 )
{
- _outerFaces.insert( outerFace );
- int nbNodes = outerFace2->NbNodes()/( outerFace2->IsQuadratic() ? 2 : 1 );
+ _outerFaces.insert( outerFace2 );
+ int nbNodes = outerFace2->NbCornerNodes();
for ( int i = 0; i < nbNodes; ++i )
{
SMESH_TLink link2( outerFace2->GetNode(i), outerFace2->GetNode((i+1)%nbNodes));
if ( type == SMDSAbs_Node || type == SMDSAbs_0DElement || type == SMDSAbs_Ball)
{
if ( !_nodeSearcher )
- _nodeSearcher = new SMESH_NodeSearcherImpl( _mesh );
-
+ {
+ if ( _meshPartIt )
+ _nodeSearcher = new SMESH_NodeSearcherImpl( 0, _meshPartIt );
+ else
+ _nodeSearcher = new SMESH_NodeSearcherImpl( _mesh );
+ }
std::vector< const SMDS_MeshNode* > foundNodes;
_nodeSearcher->FindNearPoint( point, tolerance, foundNodes );
}
else if ( ! intersection.IsParallel() && intersection.NbPoints() > 0 )
{
+ double tol = 1e-4 * Sqrt( fNorm.Modulus() );
gp_Pnt intersectionPoint = intersection.Point(1);
- if ( !SMESH_MeshAlgos::IsOut( *face, intersectionPoint, tolerance ))
+ if ( !SMESH_MeshAlgos::IsOut( *face, intersectionPoint, tol ))
u2inters.insert(make_pair( intersection.ParamOnConic(1), TInters( *face, fNorm )));
}
}
foundElems.assign( suspectFaces.begin(), suspectFaces.end());
}
+//=======================================================================
+/*
+ * Return elements whose bounding box intersects a sphere
+ */
+//=======================================================================
+
+void SMESH_ElementSearcherImpl::GetElementsInSphere( const gp_XYZ& center,
+ const double radius,
+ SMDSAbs_ElementType type,
+ vector< const SMDS_MeshElement* >& foundElems)
+{
+ if ( !_ebbTree || _elementType != type )
+ {
+ if ( _ebbTree ) delete _ebbTree;
+ _ebbTree = new ElementBndBoxTree( *_mesh, _elementType = type, _meshPartIt );
+ }
+ TIDSortedElemSet suspectFaces; // elements possibly intersecting the line
+ _ebbTree->getElementsInSphere( center, radius, suspectFaces );
+ foundElems.assign( suspectFaces.begin(), suspectFaces.end() );
+}
+
//=======================================================================
/*!
* \brief Return true if the point is IN or ON of the element
// get ordered nodes
- vector< SMESH_TNodeXYZ > xyz;
+ vector< SMESH_TNodeXYZ > xyz; xyz.reserve( element->NbNodes()+1 );
SMDS_ElemIteratorPtr nodeIt = element->interlacedNodesElemIterator();
- while ( nodeIt->more() )
- {
- SMESH_TNodeXYZ node = nodeIt->next();
- xyz.push_back( node );
- }
+ for ( int i = 0; nodeIt->more(); ++i )
+ xyz.push_back( SMESH_TNodeXYZ( nodeIt->next() ));
int i, nbNodes = (int) xyz.size(); // central node of biquadratic is missing
// check if the point lays on face plane
gp_Vec n2p( xyz[0], point );
- if ( fabs( n2p * faceNorm ) > tol )
- return true; // not on face plane
+ double dot = n2p * faceNorm;
+ if ( Abs( dot ) > tol ) // not on face plane
+ {
+ bool isOut = true;
+ if ( nbNodes > 3 ) // maybe the face is not planar
+ {
+ double elemThick = 0;
+ for ( i = 1; i < nbNodes; ++i )
+ {
+ gp_Vec n2n( xyz[0], xyz[i] );
+ elemThick = Max( elemThick, Abs( n2n * faceNorm ));
+ }
+ isOut = Abs( dot ) > elemThick + tol;
+ }
+ if ( isOut )
+ return isOut;
+ }
// check if point is out of face boundary:
// define it by closest transition of a ray point->infinity through face boundary
normSize = plnNorm.Magnitude();
if ( normSize <= tol ) return false; // point coincides with the first node
plnNorm /= normSize;
- // for each node of the face, compute its signed distance to the plane
+ // for each node of the face, compute its signed distance to the cutting plane
vector<double> dist( nbNodes + 1);
for ( i = 0; i < nbNodes; ++i )
{
dist.back() = dist.front();
// find the closest intersection
int iClosest = -1;
- double rClosest, distClosest = 1e100;;
+ double rClosest = 0, distClosest = 1e100;
gp_Pnt pClosest;
for ( i = 0; i < nbNodes; ++i )
{
double r;
- if ( fabs( dist[i]) < tol )
+ if ( fabs( dist[i] ) < tol )
r = 0.;
else if ( fabs( dist[i+1]) < tol )
r = 1.;
else
continue; // no intersection
gp_Pnt pInt = xyz[i] * (1.-r) + xyz[i+1] * r;
- gp_Vec p2int ( point, pInt);
- if ( p2int * ray > -tol ) // right half-space
+ gp_Vec p2int( point, pInt);
+ double intDist = p2int.SquareMagnitude();
+ if ( intDist < distClosest )
{
- double intDist = p2int.SquareMagnitude();
- if ( intDist < distClosest )
- {
- iClosest = i;
- rClosest = r;
- pClosest = pInt;
- distClosest = intDist;
- }
+ iClosest = i;
+ rClosest = r;
+ pClosest = pInt;
+ distClosest = intDist;
}
}
if ( iClosest < 0 )
bool covexCorner = ( edgeNorm * edgeAdjacent * (rClosest==1. ? 1. : -1.)) < 0;
return covexCorner ? (out || out2) : (out && out2);
}
+
if ( element->GetType() == SMDSAbs_Edge ) // --------------------------------------------------
{
// point is out of edge if it is NOT ON any straight part of edge
}
return true;
}
+
// Node or 0D element -------------------------------------------------------------------------
{
gp_Vec n2p ( xyz[0], point );
- return n2p.SquareMagnitude() <= tol * tol;
+ return n2p.SquareMagnitude() > tol * tol;
}
return true;
}
return GetDistance( dynamic_cast<const SMDS_MeshEdge*>( elem ), point);
case SMDSAbs_Node:
return point.Distance( SMESH_TNodeXYZ( elem ));
+ default:;
}
return -1;
}
// cout << distVec.Magnitude() << " VERTEX " << face->GetNode(pos._index)->GetID() << endl;
return distVec.Magnitude();
}
+ default:;
}
return badDistance;
}
*/
//=======================================================================
-double SMESH_MeshAlgos::GetDistance( const SMDS_MeshEdge* edge, const gp_Pnt& point )
+double SMESH_MeshAlgos::GetDistance( const SMDS_MeshEdge* seg, const gp_Pnt& point )
{
- throw SALOME_Exception(LOCALIZED("not implemented so far"));
+ double dist = Precision::Infinite();
+ if ( !seg ) return dist;
+
+ int i = 0, nbNodes = seg->NbNodes();
+
+ vector< SMESH_TNodeXYZ > xyz( nbNodes );
+ SMDS_ElemIteratorPtr nodeIt = seg->interlacedNodesElemIterator();
+ while ( nodeIt->more() )
+ xyz[ i++ ].Set( nodeIt->next() );
+
+ for ( i = 1; i < nbNodes; ++i )
+ {
+ gp_Vec edge( xyz[i-1], xyz[i] );
+ gp_Vec n1p ( xyz[i-1], point );
+ double u = ( edge * n1p ) / edge.SquareMagnitude(); // param [0,1] on the edge
+ if ( u <= 0. ) {
+ dist = Min( dist, n1p.SquareMagnitude() );
+ }
+ else if ( u >= 1. ) {
+ dist = Min( dist, point.SquareDistance( xyz[i] ));
+ }
+ else {
+ gp_XYZ proj = ( 1. - u ) * xyz[i-1] + u * xyz[i]; // projection of the point on the edge
+ dist = Min( dist, point.SquareDistance( proj ));
+ }
+ }
+ return Sqrt( dist );
}
//=======================================================================
int* n2ind)
{
- int i1, i2;
+ int i1 = 0, i2 = 0;
const SMDS_MeshElement* face = 0;
SMDS_ElemIteratorPtr invElemIt = n1->GetInverseElementIterator(SMDSAbs_Face);
- //MESSAGE("n1->GetInverseElementIterator(SMDSAbs_Face) " << invElemIt);
while ( invElemIt->more() && !face ) // loop on inverse faces of n1
{
- //MESSAGE("in while ( invElemIt->more() && !face )");
const SMDS_MeshElement* elem = invElemIt->next();
if (avoidSet.count( elem ))
continue;
if ( !face && elem->IsQuadratic())
{
// analysis for quadratic elements using all nodes
- // const SMDS_VtkFace* F = dynamic_cast<const SMDS_VtkFace*>(elem);
- // if (!F) throw SALOME_Exception(LOCALIZED("not an SMDS_VtkFace"));
- // use special nodes iterator
SMDS_ElemIteratorPtr anIter = elem->interlacedNodesElemIterator();
const SMDS_MeshNode* prevN = static_cast<const SMDS_MeshNode*>( anIter->next() );
for ( i1 = -1, i2 = 0; anIter->more() && !face; i1++, i2++ )
return new SMESH_NodeSearcherImpl( &mesh );
}
+//=======================================================================
+/*!
+ * \brief Return SMESH_NodeSearcher
+ */
+//=======================================================================
+
+SMESH_NodeSearcher* SMESH_MeshAlgos::GetNodeSearcher(SMDS_ElemIteratorPtr elemIt)
+{
+ return new SMESH_NodeSearcherImpl( 0, elemIt );
+}
+
//=======================================================================
/*!
* \brief Return SMESH_ElementSearcher