/*---------------------------------------------------------------------------*\
========= |
\\ / F ield | OpenFOAM: The Open Source CFD Toolbox
\\ / O peration | Website: https://openfoam.org
\\ / A nd | Copyright (C) 2011-2024 OpenFOAM Foundation
\\/ M anipulation |
-------------------------------------------------------------------------------
License
This file is part of OpenFOAM.
OpenFOAM is free software: you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenFOAM is distributed in the hope that it will be useful, but WITHOUT
ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License
along with OpenFOAM. If not, see & points = meshMod.points();
forAll(points, pointi)
{
meshTools::writeOBJ(str1, points[pointi]);
meshTools::writeOBJ(str2, points[pointi]);
}
const DynamicList& faces = meshMod.faces();
forAll(faces, facei)
{
const face& f = faces[facei];
str1<< 'f';
forAll(f, fp)
{
str1<< ' ' << f[fp]+1;
}
str1<< nl;
str2<< 'l';
forAll(f, fp)
{
str2<< ' ' << f[fp]+1;
}
str2<< ' ' << f[0]+1 << nl;
}
}
Foam::label Foam::meshDualiser::findDualCell
(
const label celli,
const label pointi
) const
{
const labelList& dualCells = pointToDualCells_[pointi];
if (dualCells.size() == 1)
{
return dualCells[0];
}
else
{
label index = findIndex(mesh_.pointCells()[pointi], celli);
return dualCells[index];
}
}
void Foam::meshDualiser::generateDualBoundaryEdges
(
const PackedBoolList& isBoundaryEdge,
const label pointi,
polyTopoChange& meshMod
)
{
const labelList& pEdges = mesh_.pointEdges()[pointi];
forAll(pEdges, pEdgeI)
{
label edgeI = pEdges[pEdgeI];
if (edgeToDualPoint_[edgeI] == -1 && isBoundaryEdge.get(edgeI) == 1)
{
const edge& e = mesh_.edges()[edgeI];
edgeToDualPoint_[edgeI] = meshMod.addPoint
(
e.centre(mesh_.points()),
pointi, // masterPoint
true // inCell
);
}
}
}
// Return true if point on face has same dual cells on both owner and neighbour
// sides.
bool Foam::meshDualiser::sameDualCell
(
const label facei,
const label pointi
) const
{
if (!mesh_.isInternalFace(facei))
{
FatalErrorInFunction
<< "face:" << facei << " is not internal face."
<< abort(FatalError);
}
label own = mesh_.faceOwner()[facei];
label nei = mesh_.faceNeighbour()[facei];
return findDualCell(own, pointi) == findDualCell(nei, pointi);
}
Foam::label Foam::meshDualiser::addInternalFace
(
const label masterPointi,
const label masterEdgeI,
const label masterFacei,
const bool edgeOrder,
const label dualCell0,
const label dualCell1,
const DynamicList& verts,
polyTopoChange& meshMod
) const
{
face newFace(verts);
if (edgeOrder != (dualCell0 < dualCell1))
{
reverse(newFace);
}
label dualFacei;
if (dualCell0 < dualCell1)
{
dualFacei = meshMod.addFace
(
newFace,
dualCell0, // own
dualCell1, // nei
masterFacei, // masterFaceID
false, // flipFaceFlux
-1 // patchID
);
// pointField dualPoints(meshMod.points());
// vector n(newFace.normal(dualPoints));
// n /= mag(n);
// Pout<< "Generated internal dualFace:" << dualFacei
// << " verts:" << newFace
// << " points:" << UIndirectList(meshMod.points(), newFace)()
// << " n:" << n
// << " between dualowner:" << dualCell0
// << " dualneighbour:" << dualCell1
// << endl;
}
else
{
dualFacei = meshMod.addFace
(
newFace,
dualCell1, // own
dualCell0, // nei
masterFacei, // masterFaceID
false, // flipFaceFlux
-1 // patchID
);
// pointField dualPoints(meshMod.points());
// vector n(newFace.normal(dualPoints));
// n /= mag(n);
// Pout<< "Generated internal dualFace:" << dualFacei
// << " verts:" << newFace
// << " points:" << UIndirectList(meshMod.points(), newFace)()
// << " n:" << n
// << " between dualowner:" << dualCell1
// << " dualneighbour:" << dualCell0
// << endl;
}
return dualFacei;
}
Foam::label Foam::meshDualiser::addBoundaryFace
(
const label masterPointi,
const label masterEdgeI,
const label masterFacei,
const label dualCelli,
const label patchi,
const DynamicList& verts,
polyTopoChange& meshMod
) const
{
face newFace(verts);
label dualFacei = meshMod.addFace
(
newFace,
dualCelli, // own
-1, // nei
masterFacei, // masterFaceID
false, // flipFaceFlux
patchi // patchID
);
// pointField dualPoints(meshMod.points());
// vector n(newFace.normal(dualPoints));
// n /= mag(n);
// Pout<< "Generated boundary dualFace:" << dualFacei
// << " verts:" << newFace
// << " points:" << UIndirectList(meshMod.points(), newFace)()
// << " n:" << n
// << " on dualowner:" << dualCelli
// << endl;
return dualFacei;
}
// Walks around edgeI.
// splitFace=true : creates multiple faces
// splitFace=false: creates single face if same dual cells on both sides,
// multiple faces otherwise.
void Foam::meshDualiser::createFacesAroundEdge
(
const bool splitFace,
const PackedBoolList& isBoundaryEdge,
const label edgeI,
const label startFacei,
polyTopoChange& meshMod,
boolList& doneEFaces
) const
{
const edge& e = mesh_.edges()[edgeI];
const labelList& eFaces = mesh_.edgeFaces()[edgeI];
label fp = edgeFaceCirculator::getMinIndex
(
mesh_.faces()[startFacei],
e[0],
e[1]
);
edgeFaceCirculator ie
(
mesh_,
startFacei, // face
true, // ownerSide
fp, // fp
isBoundaryEdge.get(edgeI) == 1 // isBoundaryEdge
);
ie.setCanonical();
bool edgeOrder = ie.sameOrder(e[0], e[1]);
label startFaceLabel = ie.faceLabel();
// Pout<< "At edge:" << edgeI << " verts:" << e
// << " points:" << mesh_.points()[e[0]] << mesh_.points()[e[1]]
// << " started walking at face:" << ie.faceLabel()
// << " verts:" << mesh_.faces()[ie.faceLabel()]
// << " edgeOrder:" << edgeOrder
// << " in direction of cell:" << ie.cellLabel()
// << endl;
// Walk and collect face.
DynamicList verts(100);
if (edgeToDualPoint_[edgeI] != -1)
{
verts.append(edgeToDualPoint_[edgeI]);
}
if (faceToDualPoint_[ie.faceLabel()] != -1)
{
doneEFaces[findIndex(eFaces, ie.faceLabel())] = true;
verts.append(faceToDualPoint_[ie.faceLabel()]);
}
if (cellToDualPoint_[ie.cellLabel()] != -1)
{
verts.append(cellToDualPoint_[ie.cellLabel()]);
}
label currentDualCell0 = findDualCell(ie.cellLabel(), e[0]);
label currentDualCell1 = findDualCell(ie.cellLabel(), e[1]);
++ie;
while (true)
{
label facei = ie.faceLabel();
// Mark face as visited.
doneEFaces[findIndex(eFaces, facei)] = true;
if (faceToDualPoint_[facei] != -1)
{
verts.append(faceToDualPoint_[facei]);
}
label celli = ie.cellLabel();
if (celli == -1)
{
// At ending boundary face. We've stored the face point above
// so this is the whole face.
break;
}
label dualCell0 = findDualCell(celli, e[0]);
label dualCell1 = findDualCell(celli, e[1]);
// Generate face. (always if splitFace=true; only if needed to
// separate cells otherwise)
if
(
splitFace
|| (
dualCell0 != currentDualCell0
|| dualCell1 != currentDualCell1
)
)
{
// Close current face.
addInternalFace
(
-1, // masterPointi
edgeI, // masterEdgeI
-1, // masterFacei
edgeOrder,
currentDualCell0,
currentDualCell1,
verts.shrink(),
meshMod
);
// Restart
currentDualCell0 = dualCell0;
currentDualCell1 = dualCell1;
verts.clear();
if (edgeToDualPoint_[edgeI] != -1)
{
verts.append(edgeToDualPoint_[edgeI]);
}
if (faceToDualPoint_[facei] != -1)
{
verts.append(faceToDualPoint_[facei]);
}
}
if (cellToDualPoint_[celli] != -1)
{
verts.append(cellToDualPoint_[celli]);
}
++ie;
if (ie == ie.end())
{
// Back at start face (for internal edge only). See if this needs
// adding.
if (isBoundaryEdge.get(edgeI) == 0)
{
label startDual = faceToDualPoint_[startFaceLabel];
if (startDual != -1 && findIndex(verts, startDual) == -1)
{
verts.append(startDual);
}
}
break;
}
}
verts.shrink();
addInternalFace
(
-1, // masterPointi
edgeI, // masterEdgeI
-1, // masterFacei
edgeOrder,
currentDualCell0,
currentDualCell1,
verts,
meshMod
);
}
// Walks around circumference of facei. Creates single face. Gets given
// starting (feature) edge to start from. Returns ending edge. (all edges
// in form of index in faceEdges)
void Foam::meshDualiser::createFaceFromInternalFace
(
const label facei,
label& fp,
polyTopoChange& meshMod
) const
{
const face& f = mesh_.faces()[facei];
const labelList& fEdges = mesh_.faceEdges()[facei];
label own = mesh_.faceOwner()[facei];
label nei = mesh_.faceNeighbour()[facei];
// Pout<< "createFaceFromInternalFace : At face:" << facei
// << " verts:" << f
// << " points:" << UIndirectList(mesh_.points(), f)()
// << " started walking at edge:" << fEdges[fp]
// << " verts:" << mesh_.edges()[fEdges[fp]]
// << endl;
// Walk and collect face.
DynamicList verts(100);
verts.append(faceToDualPoint_[facei]);
verts.append(edgeToDualPoint_[fEdges[fp]]);
// Step to vertex after edge mid
fp = f.fcIndex(fp);
// Get cells on either side of face at that point
label currentDualCell0 = findDualCell(own, f[fp]);
label currentDualCell1 = findDualCell(nei, f[fp]);
forAll(f, i)
{
// Check vertex
if (pointToDualPoint_[f[fp]] != -1)
{
verts.append(pointToDualPoint_[f[fp]]);
}
// Edge between fp and fp+1
label edgeI = fEdges[fp];
if (edgeToDualPoint_[edgeI] != -1)
{
verts.append(edgeToDualPoint_[edgeI]);
}
// Next vertex on edge
label nextFp = f.fcIndex(fp);
// Get dual cells on nextFp to check whether face needs closing.
label dualCell0 = findDualCell(own, f[nextFp]);
label dualCell1 = findDualCell(nei, f[nextFp]);
if (dualCell0 != currentDualCell0 || dualCell1 != currentDualCell1)
{
// Check: make sure that there is a midpoint on the edge.
if (edgeToDualPoint_[edgeI] == -1)
{
FatalErrorInFunction
<< "face:" << facei << " verts:" << f
<< " points:" << UIndirectList(mesh_.points(), f)()
<< " no feature edge between " << f[fp]
<< " and " << f[nextFp] << " although have different"
<< " dual cells." << endl
<< "point " << f[fp] << " has dual cells "
<< currentDualCell0 << " and " << currentDualCell1
<< " ; point "<< f[nextFp] << " has dual cells "
<< dualCell0 << " and " << dualCell1
<< abort(FatalError);
}
// Close current face.
verts.shrink();
addInternalFace
(
-1, // masterPointi
-1, // masterEdgeI
facei, // masterFacei
true, // edgeOrder,
currentDualCell0,
currentDualCell1,
verts,
meshMod
);
break;
}
fp = nextFp;
}
}
// Given a point on a face converts the faces around the point.
// (pointFaces()). Gets starting face and marks off visited faces in donePFaces.
void Foam::meshDualiser::createFacesAroundBoundaryPoint
(
const label patchi,
const label patchPointi,
const label startFacei,
polyTopoChange& meshMod,
boolList& donePFaces // pFaces visited
) const
{
const polyBoundaryMesh& patches = mesh_.boundaryMesh();
const polyPatch& pp = patches[patchi];
const labelList& pFaces = pp.pointFaces()[patchPointi];
const labelList& own = mesh_.faceOwner();
label pointi = pp.meshPoints()[patchPointi];
if (pointToDualPoint_[pointi] == -1)
{
// Not a feature point. Loop over all connected
// pointFaces.
// Starting face
label facei = startFacei;
DynamicList verts(4);
while (true)
{
label index = findIndex(pFaces, facei-pp.start());
// Has face been visited already?
if (donePFaces[index])
{
break;
}
donePFaces[index] = true;
// Insert face centre
verts.append(faceToDualPoint_[facei]);
label dualCelli = findDualCell(own[facei], pointi);
// Get the edge before the patchPointi
const face& f = mesh_.faces()[facei];
label fp = findIndex(f, pointi);
label prevFp = f.rcIndex(fp);
label edgeI = mesh_.faceEdges()[facei][prevFp];
if (edgeToDualPoint_[edgeI] != -1)
{
verts.append(edgeToDualPoint_[edgeI]);
}
// Get next boundary face (whilst staying on edge).
edgeFaceCirculator circ
(
mesh_,
facei,
true, // ownerSide
prevFp, // index of edge in face
true // isBoundaryEdge
);
do
{
++circ;
}
while (mesh_.isInternalFace(circ.faceLabel()));
// Step to next face
facei = circ.faceLabel();
if (facei < pp.start() || facei >= pp.start()+pp.size())
{
FatalErrorInFunction
<< "Walked from face on patch:" << patchi
<< " to face:" << facei
<< " fc:" << mesh_.faceCentres()[facei]
<< " on patch:" << patches.whichPatch(facei)
<< abort(FatalError);
}
// Check if different cell.
if (dualCelli != findDualCell(own[facei], pointi))
{
FatalErrorInFunction
<< "Different dual cells but no feature edge"
<< " in between point:" << pointi
<< " coord:" << mesh_.points()[pointi]
<< abort(FatalError);
}
}
verts.shrink();
label dualCelli = findDualCell(own[facei], pointi);
// Bit dodgy: create dualface from the last face (instead of from
// the central point). This will also use the original faceZone to
// put the new face (which might span multiple original faces) in.
addBoundaryFace
(
// pointi, // masterPointi
-1, // masterPointi
-1, // masterEdgeI
facei, // masterFacei
dualCelli,
patchi,
verts,
meshMod
);
}
else
{
label facei = startFacei;
// Storage for face
DynamicList verts(mesh_.faces()[facei].size());
// Starting point.
verts.append(pointToDualPoint_[pointi]);
// Find edge between pointi and next point on face.
const labelList& fEdges = mesh_.faceEdges()[facei];
label nextEdgeI = fEdges[findIndex(mesh_.faces()[facei], pointi)];
if (edgeToDualPoint_[nextEdgeI] != -1)
{
verts.append(edgeToDualPoint_[nextEdgeI]);
}
do
{
label index = findIndex(pFaces, facei-pp.start());
// Has face been visited already?
if (donePFaces[index])
{
break;
}
donePFaces[index] = true;
// Face centre
verts.append(faceToDualPoint_[facei]);
// Find edge before pointi on facei
const labelList& fEdges = mesh_.faceEdges()[facei];
const face& f = mesh_.faces()[facei];
label prevFp = f.rcIndex(findIndex(f, pointi));
label edgeI = fEdges[prevFp];
if (edgeToDualPoint_[edgeI] != -1)
{
// Feature edge. Close any face so far. Note: uses face to
// create dualFace from. Could use pointi instead.
verts.append(edgeToDualPoint_[edgeI]);
addBoundaryFace
(
-1, // masterPointi
-1, // masterEdgeI
facei, // masterFacei
findDualCell(own[facei], pointi),
patchi,
verts.shrink(),
meshMod
);
verts.clear();
verts.append(pointToDualPoint_[pointi]);
verts.append(edgeToDualPoint_[edgeI]);
}
// Cross edgeI to next boundary face
edgeFaceCirculator circ
(
mesh_,
facei,
true, // ownerSide
prevFp, // index of edge in face
true // isBoundaryEdge
);
do
{
++circ;
}
while (mesh_.isInternalFace(circ.faceLabel()));
// Step to next face. Quit if not on same patch.
facei = circ.faceLabel();
}
while
(
facei != startFacei
&& facei >= pp.start()
&& facei < pp.start()+pp.size()
);
if (verts.size() > 2)
{
// Note: face created from face, not from pointi
addBoundaryFace
(
-1, // masterPointi
-1, // masterEdgeI
startFacei, // masterFacei
findDualCell(own[facei], pointi),
patchi,
verts.shrink(),
meshMod
);
}
}
}
// * * * * * * * * * * * * * * * * Constructors * * * * * * * * * * * * * * //
Foam::meshDualiser::meshDualiser(const polyMesh& mesh)
:
mesh_(mesh),
pointToDualCells_(mesh_.nPoints()),
pointToDualPoint_(mesh_.nPoints(), -1),
cellToDualPoint_(mesh_.nCells()),
faceToDualPoint_(mesh_.nFaces(), -1),
edgeToDualPoint_(mesh_.nEdges(), -1)
{}
// * * * * * * * * * * * * * * * Member Functions * * * * * * * * * * * * * //
void Foam::meshDualiser::setRefinement
(
const bool splitFace,
const labelList& featureFaces,
const labelList& featureEdges,
const labelList& singleCellFeaturePoints,
const labelList& multiCellFeaturePoints,
polyTopoChange& meshMod
)
{
const labelList& own = mesh_.faceOwner();
const labelList& nei = mesh_.faceNeighbour();
const vectorField& cellCentres = mesh_.cellCentres();
// Mark boundary edges and points.
// (Note: in 1.4.2 we can use the built-in mesh point ordering
// facility instead)
PackedBoolList isBoundaryEdge(mesh_.nEdges());
for (label facei = mesh_.nInternalFaces(); facei < mesh_.nFaces(); facei++)
{
const labelList& fEdges = mesh_.faceEdges()[facei];
forAll(fEdges, i)
{
isBoundaryEdge.set(fEdges[i], 1);
}
}
if (splitFace)
{
// This is a special mode where whenever we are walking around an edge
// every area through a cell becomes a separate dualface. So two
// dual cells will probably have more than one dualface between them!
// This mode implies that
// - all faces have to be feature faces since there has to be a
// dualpoint at the face centre.
// - all edges have to be feature edges ,,
boolList featureFaceSet(mesh_.nFaces(), false);
forAll(featureFaces, i)
{
featureFaceSet[featureFaces[i]] = true;
}
label facei = findIndex(featureFaceSet, false);
if (facei != -1)
{
FatalErrorInFunction
<< "In split-face-mode (splitFace=true) but not all faces"
<< " marked as feature faces." << endl
<< "First conflicting face:" << facei
<< " centre:" << mesh_.faceCentres()[facei]
<< abort(FatalError);
}
boolList featureEdgeSet(mesh_.nEdges(), false);
forAll(featureEdges, i)
{
featureEdgeSet[featureEdges[i]] = true;
}
label edgeI = findIndex(featureEdgeSet, false);
if (edgeI != -1)
{
const edge& e = mesh_.edges()[edgeI];
FatalErrorInFunction
<< "In split-face-mode (splitFace=true) but not all edges"
<< " marked as feature edges." << endl
<< "First conflicting edge:" << edgeI
<< " verts:" << e
<< " coords:" << mesh_.points()[e[0]] << mesh_.points()[e[1]]
<< abort(FatalError);
}
}
else
{
// Check that all boundary faces are feature faces.
boolList featureFaceSet(mesh_.nFaces(), false);
forAll(featureFaces, i)
{
featureFaceSet[featureFaces[i]] = true;
}
for
(
label facei = mesh_.nInternalFaces();
facei < mesh_.nFaces();
facei++
)
{
if (!featureFaceSet[facei])
{
FatalErrorInFunction
<< "Not all boundary faces marked as feature faces."
<< endl
<< "First conflicting face:" << facei
<< " centre:" << mesh_.faceCentres()[facei]
<< abort(FatalError);
}
}
}
// Start creating cells, points, and faces (in that order)
// 1. Mark which cells to create
// Mostly every point becomes one cell but sometimes (for feature points)
// all cells surrounding a feature point become cells. Also a non-manifold
// point can create two cells! So a dual cell is uniquely defined by a
// mesh point + cell (as in pointCells index)
// 2. Mark which face centres to create
// 3. Internal faces can now consist of
// - only cell centres of walk around edge
// - cell centres + face centres of walk around edge
// - same but now other side is not a single cell
// 4. Boundary faces (or internal faces between cell zones!) now consist of
// - walk around boundary point.
autoPtr dualCcStr;
if (debug)
{
dualCcStr.reset(new OFstream("dualCc.obj"));
Pout<< "Dumping centres of dual cells to " << dualCcStr().name()
<< endl;
}
// Dual cells (from points)
// ~~~~~~~~~~~~~~~~~~~~~~~~
// pointToDualCells_[pointi]
// - single entry : all cells surrounding point all become the same
// cell.
// - multiple entries: in order of pointCells.
// feature points that become single cell
forAll(singleCellFeaturePoints, i)
{
label pointi = singleCellFeaturePoints[i];
pointToDualPoint_[pointi] = meshMod.addPoint
(
mesh_.points()[pointi],
pointi, // masterPoint
true // inCell
);
// Generate single cell
pointToDualCells_[pointi].setSize(1);
pointToDualCells_[pointi][0] = meshMod.addCell
(
-1 // masterCellID,
);
if (dualCcStr.valid())
{
meshTools::writeOBJ(dualCcStr(), mesh_.points()[pointi]);
}
}
// feature points that become multiple cells
forAll(multiCellFeaturePoints, i)
{
label pointi = multiCellFeaturePoints[i];
if (pointToDualCells_[pointi].size() > 0)
{
FatalErrorInFunction
<< "Point " << pointi << " at:" << mesh_.points()[pointi]
<< " is both in singleCellFeaturePoints"
<< " and multiCellFeaturePoints."
<< abort(FatalError);
}
pointToDualPoint_[pointi] = meshMod.addPoint
(
mesh_.points()[pointi],
pointi, // masterPoint
true // inCell
);
// Create dualcell for every cell connected to dual point
const labelList& pCells = mesh_.pointCells()[pointi];
pointToDualCells_[pointi].setSize(pCells.size());
forAll(pCells, pCelli)
{
pointToDualCells_[pointi][pCelli] = meshMod.addCell
(
-1 // masterCellID
);
if (dualCcStr.valid())
{
meshTools::writeOBJ
(
dualCcStr(),
0.5*(mesh_.points()[pointi]+cellCentres[pCells[pCelli]])
);
}
}
}
// Normal points
forAll(mesh_.points(), pointi)
{
if (pointToDualCells_[pointi].empty())
{
pointToDualCells_[pointi].setSize(1);
pointToDualCells_[pointi][0] = meshMod.addCell
(
-1 // masterCellID,
);
if (dualCcStr.valid())
{
meshTools::writeOBJ(dualCcStr(), mesh_.points()[pointi]);
}
}
}
// Dual points (from cell centres, feature faces, feature edges)
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
forAll(cellToDualPoint_, celli)
{
cellToDualPoint_[celli] = meshMod.addPoint
(
cellCentres[celli],
mesh_.faces()[mesh_.cells()[celli][0]][0], // masterPoint
true // inCell
);
}
// From face to dual point
forAll(featureFaces, i)
{
label facei = featureFaces[i];
faceToDualPoint_[facei] = meshMod.addPoint
(
mesh_.faceCentres()[facei],
mesh_.faces()[facei][0], // masterPoint
true // inCell
);
}
// Detect whether different dual cells on either side of a face. This
// would necessitate having a dual face built from the face and thus a
// dual point at the face centre.
for (label facei = 0; facei < mesh_.nInternalFaces(); facei++)
{
if (faceToDualPoint_[facei] == -1)
{
const face& f = mesh_.faces()[facei];
forAll(f, fp)
{
label ownDualCell = findDualCell(own[facei], f[fp]);
label neiDualCell = findDualCell(nei[facei], f[fp]);
if (ownDualCell != neiDualCell)
{
faceToDualPoint_[facei] = meshMod.addPoint
(
mesh_.faceCentres()[facei],
f[fp], // masterPoint
true // inCell
);
break;
}
}
}
}
// From edge to dual point
forAll(featureEdges, i)
{
label edgeI = featureEdges[i];
const edge& e = mesh_.edges()[edgeI];
edgeToDualPoint_[edgeI] = meshMod.addPoint
(
e.centre(mesh_.points()),
e[0], // masterPoint
true // inCell
);
}
// Detect whether different dual cells on either side of an edge. This
// would necessitate having a dual face built perpendicular to the edge
// and thus a dual point at the mid of the edge.
// Note: not really true - the face can be built without the edge centre!
const labelListList& edgeCells = mesh_.edgeCells();
forAll(edgeCells, edgeI)
{
if (edgeToDualPoint_[edgeI] == -1)
{
const edge& e = mesh_.edges()[edgeI];
// We need a point on the edge if not all cells on both sides
// are the same.
const labelList& eCells = mesh_.edgeCells()[edgeI];
label dualE0 = findDualCell(eCells[0], e[0]);
label dualE1 = findDualCell(eCells[0], e[1]);
for (label i = 1; i < eCells.size(); i++)
{
label newDualE0 = findDualCell(eCells[i], e[0]);
if (dualE0 != newDualE0)
{
edgeToDualPoint_[edgeI] = meshMod.addPoint
(
e.centre(mesh_.points()),
e[0], // masterPoint
true // inCell
);
break;
}
label newDualE1 = findDualCell(eCells[i], e[1]);
if (dualE1 != newDualE1)
{
edgeToDualPoint_[edgeI] = meshMod.addPoint
(
e.centre(mesh_.points()),
e[1], // masterPoint
true // inCell
);
break;
}
}
}
}
// Make sure all boundary edges emanating from feature points are
// feature edges as well.
forAll(singleCellFeaturePoints, i)
{
generateDualBoundaryEdges
(
isBoundaryEdge,
singleCellFeaturePoints[i],
meshMod
);
}
forAll(multiCellFeaturePoints, i)
{
generateDualBoundaryEdges
(
isBoundaryEdge,
multiCellFeaturePoints[i],
meshMod
);
}
// Check for duplicate points
if (debug)
{
dumpPolyTopoChange(meshMod, "generatedPoints_");
}
// Now we have all points and cells
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
// - pointToDualCells_ : per point a single dualCell or multiple dualCells
// - pointToDualPoint_ : per point -1 or the dual point at the coordinate
// - edgeToDualPoint_ : per edge -1 or the edge centre
// - faceToDualPoint_ : per face -1 or the face centre
// - cellToDualPoint_ : per cell the cell centre
// Now we have to walk all edges and construct faces. Either single face
// per edge or multiple (-if nonmanifold edge -if different dualcells)
const edgeList& edges = mesh_.edges();
forAll(edges, edgeI)
{
const labelList& eFaces = mesh_.edgeFaces()[edgeI];
boolList doneEFaces(eFaces.size(), false);
forAll(eFaces, i)
{
if (!doneEFaces[i])
{
// We found a face that hasn't yet been visited. This might
// happen for non-manifold edges where a single edge can
// become multiple faces.
label startFacei = eFaces[i];
// Pout<< "Walking edge:" << edgeI
// << " points:" << mesh_.points()[e[0]]
// << mesh_.points()[e[1]]
// << " startFace:" << startFacei
// << " at:" << mesh_.faceCentres()[startFacei]
// << endl;
createFacesAroundEdge
(
splitFace,
isBoundaryEdge,
edgeI,
startFacei,
meshMod,
doneEFaces
);
}
}
}
if (debug)
{
dumpPolyTopoChange(meshMod, "generatedFacesFromEdges_");
}
// Create faces from feature faces. These can be internal or external faces.
// - feature face : centre needs to be included.
// - single cells on either side: triangulate
// - multiple cells: create single face between unique cell pair. Only
// create face where cells differ on either side.
// - non-feature face : in between cell zones.
forAll(faceToDualPoint_, facei)
{
if (faceToDualPoint_[facei] != -1 && mesh_.isInternalFace(facei))
{
const face& f = mesh_.faces()[facei];
const labelList& fEdges = mesh_.faceEdges()[facei];
// Starting edge
label fp = 0;
do
{
// Find edge that is in dual mesh and where the
// next point (fp+1) has different dual cells on either side.
bool foundStart = false;
do
{
if
(
edgeToDualPoint_[fEdges[fp]] != -1
&& !sameDualCell(facei, f.nextLabel(fp))
)
{
foundStart = true;
break;
}
fp = f.fcIndex(fp);
}
while (fp != 0);
if (!foundStart)
{
break;
}
// Walk from edge fp and generate a face.
createFaceFromInternalFace
(
facei,
fp,
meshMod
);
}
while (fp != 0);
}
}
if (debug)
{
dumpPolyTopoChange(meshMod, "generatedFacesFromFeatFaces_");
}
// Create boundary faces. Every boundary point has one or more dualcells.
// These need to be closed.
const polyBoundaryMesh& patches = mesh_.boundaryMesh();
forAll(patches, patchi)
{
const polyPatch& pp = patches[patchi];
const labelListList& pointFaces = pp.pointFaces();
forAll(pointFaces, patchPointi)
{
const labelList& pFaces = pointFaces[patchPointi];
boolList donePFaces(pFaces.size(), false);
forAll(pFaces, i)
{
if (!donePFaces[i])
{
// Starting face
label startFacei = pp.start()+pFaces[i];
// Pout<< "Walking around point:" << pointi
// << " coord:" << mesh_.points()[pointi]
// << " on patch:" << patchi
// << " startFace:" << startFacei
// << " at:" << mesh_.faceCentres()[startFacei]
// << endl;
createFacesAroundBoundaryPoint
(
patchi,
patchPointi,
startFacei,
meshMod,
donePFaces // pFaces visited
);
}
}
}
}
if (debug)
{
dumpPolyTopoChange(meshMod, "generatedFacesFromBndFaces_");
}
}
// ************************************************************************* //