#include <GeomLib_IsPlanarSurface.hxx>
#include <Geom_Curve.hxx>
#include <Standard_ErrorHandler.hxx>
-#include <TColStd_DataMapOfIntegerInteger.hxx>
#include <TopExp.hxx>
#include <TopExp_Explorer.hxx>
#include <TopTools_ListIteratorOfListOfShape.hxx>
algo->myProxyMesh.reset( new SMESH_ProxyMesh( *helper->GetMesh() ));
algo->myQuadList.clear();
+ algo->myHelper = 0;
if ( helper )
algo->_quadraticMesh = helper->GetIsQuadratic();
{
// use transformation (issue 0020680, IPAL0052499) or a "straight line" approach
StdMeshers_Sweeper sweeper;
+ sweeper.myHelper = myHelper;
+ sweeper.myBotFace = thePrism.myBottom;
+ sweeper.myTopFace = thePrism.myTop;
// load boundary nodes into sweeper
bool dummy;
- const SMDS_MeshNode* prevN0 = 0, *prevN1 = 0;
+ std::set< const SMDS_MeshNode* > usedEndNodes;
list< TopoDS_Edge >::const_iterator edge = thePrism.myBottomEdges.begin();
for ( ; edge != thePrism.myBottomEdges.end(); ++edge )
{
TParam2ColumnMap::iterator u2colIt = u2col->begin(), u2colEnd = u2col->end();
const SMDS_MeshNode* n0 = u2colIt->second[0];
const SMDS_MeshNode* n1 = u2col->rbegin()->second[0];
- if ( n0 == prevN0 || n0 == prevN1 ) ++u2colIt;
- if ( n1 == prevN0 || n1 == prevN1 ) --u2colEnd;
- prevN0 = n0; prevN1 = n1;
+ if ( !usedEndNodes.insert ( n0 ).second ) ++u2colIt;
+ if ( !usedEndNodes.insert ( n1 ).second ) --u2colEnd;
for ( ; u2colIt != u2colEnd; ++u2colIt )
sweeper.myBndColumns.push_back( & u2colIt->second );
}
// load node columns inside the bottom FACE
- TNode2ColumnMap::iterator bot_column = myBotToColumnMap.begin();
sweeper.myIntColumns.reserve( myBotToColumnMap.size() );
+ TNode2ColumnMap::iterator bot_column = myBotToColumnMap.begin();
for ( ; bot_column != myBotToColumnMap.end(); ++bot_column )
sweeper.myIntColumns.push_back( & bot_column->second );
{
double tol = getSweepTolerance( thePrism );
bool allowHighBndError = !isSimpleBottom( thePrism );
- myUseBlock = !sweeper.ComputeNodes( *myHelper, tol, allowHighBndError );
+ myUseBlock = !sweeper.ComputeNodesByTrsf( tol, allowHighBndError );
}
else if ( sweeper.CheckSameZ() )
{
- myUseBlock = !sweeper.ComputeNodesOnStraightSameZ( *myHelper );
+ myUseBlock = !sweeper.ComputeNodesOnStraightSameZ();
}
else
{
- myUseBlock = !sweeper.ComputeNodesOnStraight( *myHelper, thePrism.myBottom, thePrism.myTop );
+ myUseBlock = !sweeper.ComputeNodesOnStraight();
}
myHelper->SetElementsOnShape( false );
}
// column nodes; middle part of the column are zero pointers
TNodeColumn& column = bot_column->second;
+ // check if a column is already computed using non-block approach
+ size_t i;
+ for ( i = 0; i < column.size(); ++i )
+ if ( !column[ i ])
+ break;
+ if ( i == column.size() )
+ continue; // all nodes created
+
gp_XYZ botParams, topParams;
if ( !tBotNode.HasParams() )
{
TopoDS_Vertex v = myHelper->IthVertex( is2ndV, E );
mesh->GetSubMesh( v )->ComputeStateEngine( SMESH_subMesh::COMPUTE );
const SMDS_MeshNode* n = SMESH_Algo::VertexNode( v, meshDS );
- newNodes[ is2ndV ? 0 : newNodes.size()-1 ] = (SMDS_MeshNode*) n;
+ newNodes[ is2ndV ? newNodes.size()-1 : 0 ] = (SMDS_MeshNode*) n;
}
// compute nodes on target EDGEs
TNode2ColumnMap::iterator bN_col =
myBotToColumnMap.insert( make_pair ( bN, TNodeColumn() )).first;
TNodeColumn & column = bN_col->second;
- column.resize( zSize );
+ column.resize( zSize, 0 );
column.front() = botNode;
column.back() = topNode;
}
//=======================================================================
//function : isSimpleQuad
-//purpose : check if the bottom FACE is meshable with nice qudrangles,
+//purpose : check if the bottom FACE is meshable with nice quadrangles,
// if so the block aproach can work rather fast.
// This is a temporary mean caused by problems in StdMeshers_Sweeper
//=======================================================================
if ( !myHelper->LoadNodeColumns( faceColumns, (*quad)->face, quadBot, meshDS ))
return error(COMPERR_BAD_INPUT_MESH, TCom("Can't find regular quadrangle mesh ")
<< "on a side face #" << MeshDS()->ShapeToIndex( (*quad)->face ));
-
- if ( !faceColumns.empty() && (int)faceColumns.begin()->second.size() != VerticalSize() )
- return error(COMPERR_BAD_INPUT_MESH, "Different 'vertical' discretization");
}
+ if ( !faceColumns.empty() && (int)faceColumns.begin()->second.size() != VerticalSize() )
+ return error(COMPERR_BAD_INPUT_MESH, "Different 'vertical' discretization");
+
// edge columns
int id = MeshDS()->ShapeToIndex( *edgeIt );
bool isForward = true; // meaningless for intenal wires
const vector< gp_XYZ >& toBndPoints,
const vector< gp_XYZ >& fromIntPoints,
vector< gp_XYZ >& toIntPoints,
+ const double r,
NSProjUtils::TrsfFinder3D& trsf,
vector< gp_XYZ > * bndError)
{
(*bndError)[ iP ] = toBndPoints[ iP ] - fromTrsf;
}
}
- return true;
-}
-//================================================================================
-/*!
- * \brief Add boundary error to ineternal points
- */
-//================================================================================
-
-void StdMeshers_Sweeper::applyBoundaryError(const vector< gp_XYZ >& bndPoints,
- const vector< gp_XYZ >& bndError1,
- const vector< gp_XYZ >& bndError2,
- const double r,
- vector< gp_XYZ >& intPoints,
- vector< double >& int2BndDist)
-{
- // fix each internal point
- const double eps = 1e-100;
- for ( size_t iP = 0; iP < intPoints.size(); ++iP )
+ // apply boundary error
+ if ( bndError && toIntPoints.size() == myTopBotTriangles.size() )
{
- gp_XYZ & intPnt = intPoints[ iP ];
-
- // compute distance from intPnt to each boundary node
- double int2BndDistSum = 0;
- for ( size_t iBnd = 0; iBnd < bndPoints.size(); ++iBnd )
+ for ( size_t iP = 0; iP < toIntPoints.size(); ++iP )
{
- int2BndDist[ iBnd ] = 1 / (( intPnt - bndPoints[ iBnd ]).SquareModulus() + eps );
- int2BndDistSum += int2BndDist[ iBnd ];
- }
-
- // apply bndError
- for ( size_t iBnd = 0; iBnd < bndPoints.size(); ++iBnd )
- {
- intPnt += bndError1[ iBnd ] * ( 1 - r ) * int2BndDist[ iBnd ] / int2BndDistSum;
- intPnt += bndError2[ iBnd ] * r * int2BndDist[ iBnd ] / int2BndDistSum;
+ const TopBotTriangles& tbTrias = myTopBotTriangles[ iP ];
+ for ( int i = 0; i < 3; ++i ) // boundary errors at 3 triangle nodes
+ {
+ toIntPoints[ iP ] +=
+ ( (*bndError)[ tbTrias.myBotTriaNodes[i] ] * tbTrias.myBotBC[i] * ( 1 - r ) +
+ (*bndError)[ tbTrias.myTopTriaNodes[i] ] * tbTrias.myTopBC[i] * ( r ));
+ }
}
}
+
+ return true;
}
//================================================================================
/*!
- * \brief Create internal nodes of the prism
+ * \brief Create internal nodes of the prism by computing an affine transformation
+ * from layer to layer
*/
//================================================================================
-bool StdMeshers_Sweeper::ComputeNodes( SMESH_MesherHelper& helper,
- const double tol,
- const bool allowHighBndError)
+bool StdMeshers_Sweeper::ComputeNodesByTrsf( const double tol,
+ const bool allowHighBndError)
{
const size_t zSize = myBndColumns[0]->size();
const size_t zSrc = 0, zTgt = zSize-1;
intPntsOfLayer[ zTgt ][ iP ] = intPoint( iP, zTgt );
}
+ // for each internal column find boundary nodes whose error to use for correction
+ prepareTopBotDelaunay();
+ bool isErrorCorrectable = findDelaunayTriangles();
+
// compute coordinates of internal nodes by projecting (transfroming) src and tgt
// nodes towards the central layer
}
if (! projectIntPoints( fromSrcBndPnts, toSrcBndPnts,
intPntsOfLayer[ zS-1 ], intPntsOfLayer[ zS ],
+ zS / ( zSize - 1.),
trsfOfLayer [ zS-1 ], & bndError[ zS-1 ]))
return false;
if (! projectIntPoints( fromTgtBndPnts, toTgtBndPnts,
intPntsOfLayer[ zT+1 ], intPntsOfLayer[ zT ],
+ zT / ( zSize - 1.),
trsfOfLayer [ zT+1 ], & bndError[ zT+1 ]))
return false;
fromSrcBndPnts.swap( toSrcBndPnts );
}
+ // Evaluate an error of boundary points
+
+ if ( !isErrorCorrectable && !allowHighBndError )
+ {
+ for ( size_t iP = 0; iP < myBndColumns.size(); ++iP )
+ {
+ double sumError = 0;
+ for ( size_t z = 1; z < zS; ++z ) // loop on layers
+ sumError += ( bndError[ z-1 ][ iP ].Modulus() +
+ bndError[ zSize-z ][ iP ].Modulus() );
+
+ if ( sumError > tol )
+ return false;
+ }
+ }
+
// Compute two projections of internal points to the central layer
// in order to evaluate an error of internal points
}
if (! projectIntPoints( fromSrcBndPnts, toSrcBndPnts,
intPntsOfLayer[ zS-1 ], centerSrcIntPnts,
+ zS / ( zSize - 1.),
trsfOfLayer [ zS-1 ], & bndError[ zS-1 ]))
return false;
if (! projectIntPoints( fromTgtBndPnts, toTgtBndPnts,
intPntsOfLayer[ zT+1 ], centerTgtIntPnts,
+ zT / ( zSize - 1.),
trsfOfLayer [ zT+1 ], & bndError[ zT+1 ]))
return false;
(intPntsOfLayer[ zS-1 ][ iP ] - centerTgtIntPnts[ iP ]).SquareModulus() < tol*tol;
}
- // Evaluate an error of boundary points
-
- bool bndErrorIsSmall = true;
- for ( size_t iP = 0; ( iP < myBndColumns.size() && bndErrorIsSmall ); ++iP )
- {
- double sumError = 0;
- for ( size_t z = 1; z < zS; ++z ) // loop on layers
- sumError += ( bndError[ z-1 ][ iP ].Modulus() +
- bndError[ zSize-z ][ iP ].Modulus() );
-
- bndErrorIsSmall = ( sumError < tol );
- }
-
- if ( !bndErrorIsSmall && !allowHighBndError )
- return false;
-
// compute final points on the central layer
- std::vector< double > int2BndDist( myBndColumns.size() ); // work array of applyBoundaryError()
double r = zS / ( zSize - 1.);
if ( zS == zT )
{
intPntsOfLayer[ zS ][ iP ] =
( 1 - r ) * centerSrcIntPnts[ iP ] + r * centerTgtIntPnts[ iP ];
}
- if ( !bndErrorIsSmall )
- {
- applyBoundaryError( toSrcBndPnts, bndError[ zS-1 ], bndError[ zS+1 ], r,
- intPntsOfLayer[ zS ], int2BndDist );
- }
}
else
{
intPntsOfLayer[ zT ][ iP ] =
r * intPntsOfLayer[ zT ][ iP ] + ( 1 - r ) * centerTgtIntPnts[ iP ];
}
- if ( !bndErrorIsSmall )
- {
- applyBoundaryError( toSrcBndPnts, bndError[ zS-1 ], bndError[ zS+1 ], r,
- intPntsOfLayer[ zS ], int2BndDist );
- applyBoundaryError( toTgtBndPnts, bndError[ zT+1 ], bndError[ zT-1 ], r,
- intPntsOfLayer[ zT ], int2BndDist );
- }
}
- centerIntErrorIsSmall = true; // 3D_mesh_Extrusion_00/A3
- bndErrorIsSmall = true;
if ( !centerIntErrorIsSmall )
{
// Compensate the central error; continue adding projection
}
projectIntPoints( fromSrcBndPnts, toSrcBndPnts,
fromSrcIntPnts, toSrcIntPnts,
+ zS / ( zSize - 1.),
trsfOfLayer[ zS+1 ], & srcBndError );
projectIntPoints( fromTgtBndPnts, toTgtBndPnts,
fromTgtIntPnts, toTgtIntPnts,
+ zT / ( zSize - 1.),
trsfOfLayer[ zT-1 ], & tgtBndError );
// if ( zS == zTgt - 1 )
zTIntPnts[ iP ] = r * zTIntPnts[ iP ] + ( 1 - r ) * toTgtIntPnts[ iP ];
}
- // compensate bnd error
- if ( !bndErrorIsSmall )
- {
- applyBoundaryError( toSrcBndPnts, srcBndError, bndError[ zS+1 ], r,
- intPntsOfLayer[ zS ], int2BndDist );
- applyBoundaryError( toTgtBndPnts, tgtBndError, bndError[ zT-1 ], r,
- intPntsOfLayer[ zT ], int2BndDist );
- }
-
fromSrcBndPnts.swap( toSrcBndPnts );
fromSrcIntPnts.swap( toSrcIntPnts );
fromTgtBndPnts.swap( toTgtBndPnts );
}
} // if ( !centerIntErrorIsSmall )
- else if ( !bndErrorIsSmall )
- {
- zS = zSrc + 1;
- zT = zTgt - 1;
- for ( ; zS < zT; ++zS, --zT ) // vertical loop on layers
- {
- for ( size_t iP = 0; iP < myBndColumns.size(); ++iP )
- {
- toSrcBndPnts[ iP ] = bndPoint( iP, zS );
- toTgtBndPnts[ iP ] = bndPoint( iP, zT );
- }
- // compensate bnd error
- applyBoundaryError( toSrcBndPnts, bndError[ zS-1 ], bndError[ zS-1 ], 0.5,
- intPntsOfLayer[ zS ], int2BndDist );
- applyBoundaryError( toTgtBndPnts, bndError[ zT+1 ], bndError[ zT+1 ], 0.5,
- intPntsOfLayer[ zT ], int2BndDist );
- }
- }
- // cout << "centerIntErrorIsSmall = " << centerIntErrorIsSmall<< endl;
- // cout << "bndErrorIsSmall = " << bndErrorIsSmall<< endl;
+ //cout << "centerIntErrorIsSmall = " << centerIntErrorIsSmall<< endl;
// Create nodes
for ( size_t iP = 0; iP < myIntColumns.size(); ++iP )
for ( size_t z = zSrc + 1; z < zTgt; ++z ) // vertical loop on layers
{
const gp_XYZ & xyz = intPntsOfLayer[ z ][ iP ];
- if ( !( nodeCol[ z ] = helper.AddNode( xyz.X(), xyz.Y(), xyz.Z() )))
+ if ( !( nodeCol[ z ] = myHelper->AddNode( xyz.X(), xyz.Y(), xyz.Z() )))
return false;
}
}
*/
//================================================================================
-bool StdMeshers_Sweeper::ComputeNodesOnStraightSameZ( SMESH_MesherHelper& helper )
+bool StdMeshers_Sweeper::ComputeNodesOnStraightSameZ()
{
TZColumn& z = myZColumns[0];
for ( size_t iZ = 0; iZ < z.size(); ++iZ )
{
gp_XYZ p = n0 * ( 1 - z[iZ] ) + n1 * z[iZ];
- nodes[ iZ+1 ] = helper.AddNode( p.X(), p.Y(), p.Z() );
+ nodes[ iZ+1 ] = myHelper->AddNode( p.X(), p.Y(), p.Z() );
}
}
*/
//================================================================================
-bool StdMeshers_Sweeper::ComputeNodesOnStraight( SMESH_MesherHelper& helper,
- const TopoDS_Face& botFace,
- const TopoDS_Face& topFace )
+bool StdMeshers_Sweeper::ComputeNodesOnStraight()
{
- // get data to create a Morph
- UVPtStructVec botUV( myBndColumns.size() + 1 );
- UVPtStructVec topUV( myBndColumns.size() + 1 );
+ prepareTopBotDelaunay();
+
+ const SMDS_MeshNode *botNode, *topNode;
+ const BRepMesh_Triangle *topTria;
+ double botBC[3], topBC[3]; // barycentric coordinates
+ int botTriaNodes[3], topTriaNodes[3];
+ bool checkUV = true;
+
+ int nbInternalNodes = myIntColumns.size();
+ myBotDelaunay->InitTraversal( nbInternalNodes );
+
+ while (( botNode = myBotDelaunay->NextNode( botBC, botTriaNodes )))
+ {
+ TNodeColumn* column = myIntColumns[ myNodeID2ColID( botNode->GetID() )];
+
+ // find a Delaunay triangle containing the topNode
+ topNode = column->back();
+ gp_XY topUV = myHelper->GetNodeUV( myTopFace, topNode, NULL, &checkUV );
+ // get a starting triangle basing on that top and bot boundary nodes have same index
+ topTria = myTopDelaunay->GetTriangleNear( botTriaNodes[0] );
+ topTria = myTopDelaunay->FindTriangle( topUV, topTria, topBC, topTriaNodes );
+ if ( !topTria )
+ return false;
+
+ // create nodes along a line
+ SMESH_NodeXYZ botP( botNode ), topP( topNode );
+ for ( size_t iZ = 0; iZ < myZColumns[0].size(); ++iZ )
+ {
+ // use barycentric coordinates as weight of Z of boundary columns
+ double botZ = 0, topZ = 0;
+ for ( int i = 0; i < 3; ++i )
+ {
+ botZ += botBC[i] * myZColumns[ botTriaNodes[i] ][ iZ ];
+ topZ += topBC[i] * myZColumns[ topTriaNodes[i] ][ iZ ];
+ }
+ double rZ = double( iZ + 1 ) / ( myZColumns[0].size() + 1 );
+ double z = botZ * ( 1 - rZ ) + topZ * rZ;
+ gp_XYZ p = botP * ( 1 - z ) + topP * z;
+ (*column)[ iZ+1 ] = myHelper->AddNode( p.X(), p.Y(), p.Z() );
+ }
+ }
+
+ return myBotDelaunay->NbVisitedNodes() == nbInternalNodes;
+}
+
+//================================================================================
+/*!
+ * \brief Compute Z of nodes of a straight column
+ */
+//================================================================================
+
+void StdMeshers_Sweeper::fillZColumn( TZColumn& zColumn,
+ TNodeColumn& nodes )
+{
+ if ( zColumn.size() == nodes.size() - 2 )
+ return;
+
+ gp_Pnt p0 = SMESH_NodeXYZ( nodes[0] );
+ gp_Vec line( p0, SMESH_NodeXYZ( nodes.back() ));
+ double len2 = line.SquareMagnitude();
+
+ zColumn.resize( nodes.size() - 2 );
+ for ( size_t i = 0; i < zColumn.size(); ++i )
+ {
+ gp_Vec vec( p0, SMESH_NodeXYZ( nodes[ i+1] ));
+ zColumn[i] = ( line * vec ) / len2; // param [0,1] on the line
+ }
+}
+
+//================================================================================
+/*!
+ * \brief Initialize *Delaunay members
+ */
+//================================================================================
+
+void StdMeshers_Sweeper::prepareTopBotDelaunay()
+{
+ UVPtStructVec botUV( myBndColumns.size() );
+ UVPtStructVec topUV( myBndColumns.size() );
for ( size_t i = 0; i < myBndColumns.size(); ++i )
{
TNodeColumn& nodes = *myBndColumns[i];
botUV[i].node = nodes[0];
- botUV[i].SetUV( helper.GetNodeUV( botFace, nodes[0] ));
+ botUV[i].SetUV( myHelper->GetNodeUV( myBotFace, nodes[0] ));
topUV[i].node = nodes.back();
- topUV[i].SetUV( helper.GetNodeUV( topFace, nodes.back() ));
+ topUV[i].SetUV( myHelper->GetNodeUV( myTopFace, nodes.back() ));
botUV[i].node->setIsMarked( true );
}
- botUV.back() = botUV[0];
- topUV.back() = topUV[0];
-
TopoDS_Edge dummyE;
- TSideVector botWires( 1, StdMeshers_FaceSide::New( botUV, botFace, dummyE, helper.GetMesh() ));
- TSideVector topWires( 1, StdMeshers_FaceSide::New( topUV, topFace, dummyE, helper.GetMesh() ));
+ SMESH_Mesh* mesh = myHelper->GetMesh();
+ TSideVector botWires( 1, StdMeshers_FaceSide::New( botUV, myBotFace, dummyE, mesh ));
+ TSideVector topWires( 1, StdMeshers_FaceSide::New( topUV, myTopFace, dummyE, mesh ));
- // use Morph to make delauney mesh on the FACEs. Locating of a node within a
- // delauney triangle will be used to get a weighted Z.
- NSProjUtils::Morph botDelauney( botWires );
- NSProjUtils::Morph topDelauney( topWires );
+ // Delaunay mesh on the FACEs.
+ bool checkUV = false;
+ myBotDelaunay.reset( new NSProjUtils::Delaunay( botWires, checkUV ));
+ myTopDelaunay.reset( new NSProjUtils::Delaunay( topWires, checkUV ));
- if ( helper.GetIsQuadratic() )
+ if ( myHelper->GetIsQuadratic() )
{
// mark all medium nodes of faces on botFace to avoid their treating
- SMESHDS_SubMesh* smDS = helper.GetMeshDS()->MeshElements( botFace );
+ SMESHDS_SubMesh* smDS = myHelper->GetMeshDS()->MeshElements( myBotFace );
SMDS_ElemIteratorPtr eIt = smDS->GetElements();
while ( eIt->more() )
{
}
// map to get a node column by a bottom node
- TColStd_DataMapOfIntegerInteger iNode2iCol( myIntColumns.size() );
+ myNodeID2ColID.Clear(/*doReleaseMemory=*/false);
+ myNodeID2ColID.ReSize( myIntColumns.size() );
- // un-mark nodes to treat (internal bottom nodes); later we will mark treated nodes
+ // un-mark nodes to treat (internal bottom nodes) to be returned by myBotDelaunay
for ( size_t i = 0; i < myIntColumns.size(); ++i )
{
const SMDS_MeshNode* botNode = myIntColumns[i]->front();
botNode->setIsMarked( false );
- iNode2iCol.Bind( botNode->GetID(), i );
+ myNodeID2ColID.Bind( botNode->GetID(), i );
}
+}
- const int botFaceID = helper.GetMesh()->GetSubMesh( botFace )->GetId();
- const SMDS_MeshNode *botNode, *topNode;
- const BRepMesh_Triangle *botTria, *topTria;
- double botBC[3], topBC[3]; // barycentric coordinates
- int botTriaNodes[3], topTriaNodes[3];
- bool checkUV = true;
-
- // a queue of bottom nodes with starting delauney triangles
- NSProjUtils::Morph::TNodeTriaList botNoTriQueue;
+//================================================================================
+/*!
+ * \brief For each internal node column, find Delaunay triangles including it
+ * and Barycentric Coordinates within the triangles. Fill in myTopBotTriangles
+ */
+//================================================================================
- size_t iBndN = 1; // index of a bottom boundary node
- int nbNodesToProcess = myIntColumns.size();
- while ( nbNodesToProcess > 0 )
- {
- while ( !botNoTriQueue.empty() ) // treat all nodes in the queue
- {
- botNode = botNoTriQueue.front().first;
- botTria = botNoTriQueue.front().second;
- botNoTriQueue.pop_front();
- if ( botNode->isMarked() )
- continue;
- --nbNodesToProcess;
- botNode->setIsMarked( true );
+bool StdMeshers_Sweeper::findDelaunayTriangles()
+{
+ const SMDS_MeshNode *botNode, *topNode;
+ const BRepMesh_Triangle *topTria;
+ TopBotTriangles tbTrias;
+ bool checkUV = true;
- TNodeColumn* column = myIntColumns[ iNode2iCol( botNode->GetID() )];
+ int nbInternalNodes = myIntColumns.size();
+ myTopBotTriangles.resize( nbInternalNodes );
- // find a delauney triangle containing the botNode
- gp_XY botUV = helper.GetNodeUV( botFace, botNode, NULL, &checkUV );
- botUV *= botDelauney.GetScale();
- botTria = botDelauney.FindTriangle( botUV, botTria, botBC, botTriaNodes );
- if ( !botTria )
- return false;
+ myBotDelaunay->InitTraversal( nbInternalNodes );
- // find a delauney triangle containing the topNode
- topNode = column->back();
- gp_XY topUV = helper.GetNodeUV( topFace, topNode, NULL, &checkUV );
- topUV *= topDelauney.GetScale();
- // get a starting triangle basing on that top and bot boundary nodes have same index
- topTria = topDelauney.GetTriangleNear( botTriaNodes[0] );
- topTria = topDelauney.FindTriangle( topUV, topTria, topBC, topTriaNodes );
- if ( !topTria )
- return false;
+ while (( botNode = myBotDelaunay->NextNode( tbTrias.myBotBC, tbTrias.myBotTriaNodes )))
+ {
+ int colID = myNodeID2ColID( botNode->GetID() );
+ TNodeColumn* column = myIntColumns[ colID ];
- // create nodes along a line
- SMESH_NodeXYZ botP( botNode ), topP( topNode);
- for ( size_t iZ = 0; iZ < myZColumns[0].size(); ++iZ )
- {
- // use barycentric coordinates as weight of Z of boundary columns
- double botZ = 0, topZ = 0;
- for ( int i = 0; i < 3; ++i )
- {
- botZ += botBC[i] * myZColumns[ botTriaNodes[i]-1 ][ iZ ];
- topZ += topBC[i] * myZColumns[ topTriaNodes[i]-1 ][ iZ ];
- }
- double rZ = double( iZ + 1 ) / ( myZColumns[0].size() + 1 );
- double z = botZ * ( 1 - rZ ) + topZ * rZ;
- gp_XYZ p = botP * ( 1 - z ) + topP * z;
- (*column)[ iZ+1 ] = helper.AddNode( p.X(), p.Y(), p.Z() );
- }
+ // find a Delaunay triangle containing the topNode
+ topNode = column->back();
+ gp_XY topUV = myHelper->GetNodeUV( myTopFace, topNode, NULL, &checkUV );
+ // get a starting triangle basing on that top and bot boundary nodes have same index
+ topTria = myTopDelaunay->GetTriangleNear( tbTrias.myBotTriaNodes[0] );
+ topTria = myTopDelaunay->FindTriangle( topUV, topTria,
+ tbTrias.myTopBC, tbTrias.myTopTriaNodes );
+ if ( !topTria )
+ tbTrias.SetTopByBottom();
- // add neighbor nodes to the queue
- botDelauney.AddCloseNodes( botNode, botTria, botFaceID, botNoTriQueue );
- }
+ myTopBotTriangles[ colID ] = tbTrias;
+ }
- if ( nbNodesToProcess > 0 ) // fill the queue
- {
- // assure that all bot nodes are visited
- for ( ; iBndN-1 < myBndColumns.size() && botNoTriQueue.empty(); ++iBndN )
- {
- botTria = botDelauney.GetTriangleNear( iBndN );
- const SMDS_MeshNode* bndNode = botDelauney.GetBndNodes()[ iBndN ];
- botDelauney.AddCloseNodes( bndNode, botTria, botFaceID, botNoTriQueue );
- }
- if ( botNoTriQueue.empty() )
- {
- for ( size_t i = 0; i < myIntColumns.size(); ++i )
- {
- botNode = myIntColumns[i]->front();
- if ( !botNode->isMarked() )
- botNoTriQueue.push_back( make_pair( botNode, botTria ));
- }
- }
- }
+ if ( myBotDelaunay->NbVisitedNodes() < nbInternalNodes )
+ {
+ myTopBotTriangles.clear();
+ return false;
}
+ myBotDelaunay.reset();
+ myTopDelaunay.reset();
+ myNodeID2ColID.Clear();
+
return true;
}
//================================================================================
/*!
- * \brief Compute Z of nodes of a straight column
+ * \brief Initialize fields
*/
//================================================================================
-void StdMeshers_Sweeper::fillZColumn( TZColumn& zColumn,
- TNodeColumn& nodes )
+StdMeshers_Sweeper::TopBotTriangles::TopBotTriangles()
{
- if ( zColumn.size() == nodes.size() - 2 )
- return;
+ myBotBC[0] = myBotBC[1] = myBotBC[2] = myTopBC[0] = myTopBC[1] = myTopBC[2] = 0.;
+ myBotTriaNodes[0] = myBotTriaNodes[1] = myBotTriaNodes[2] = 0;
+ myTopTriaNodes[0] = myTopTriaNodes[1] = myTopTriaNodes[2] = 0;
+}
- gp_Pnt p0 = SMESH_NodeXYZ( nodes[0] );
- gp_Vec line( p0, SMESH_NodeXYZ( nodes.back() ));
- double len2 = line.SquareMagnitude();
+//================================================================================
+/*!
+ * \brief Set top data equal to bottom data
+ */
+//================================================================================
- zColumn.resize( nodes.size() - 2 );
- for ( size_t i = 0; i < zColumn.size(); ++i )
+void StdMeshers_Sweeper::TopBotTriangles::SetTopByBottom()
+{
+ for ( int i = 0; i < 3; ++i )
{
- gp_Vec vec( p0, SMESH_NodeXYZ( nodes[ i+1] ));
- zColumn[i] = ( line * vec ) / len2; // param [0,1] on the line
+ myTopBC[i] = myBotBC[i];
+ myTopTriaNodes[i] = myBotTriaNodes[0];
}
}