void Foam::decompositionMethod::calcCellCells
(
const polyMesh& mesh,
const labelList& agglom,
const label nLocalCoarse,
const bool parallel,
CompactListList<label>& cellCells
)
{
const labelList& faceOwner = mesh.faceOwner();
const labelList& faceNeighbour = mesh.faceNeighbour();
const polyBoundaryMesh& patches = mesh.boundaryMesh();
// Create global cell numbers
// ~~~~~~~~~~~~~~~~~~~~~~~~~~
globalIndex globalAgglom
(
nLocalCoarse,
Pstream::msgType(),
Pstream::worldComm,
parallel
);
// Get agglomerate owner on other side of coupled faces
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
labelList globalNeighbour(mesh.nFaces()-mesh.nInternalFaces());
forAll(patches, patchI)
{
const polyPatch& pp = patches[patchI];
if (pp.coupled() && (parallel || !isA<processorPolyPatch>(pp)))
{
label faceI = pp.start();
label bFaceI = pp.start() - mesh.nInternalFaces();
forAll(pp, i)
{
globalNeighbour[bFaceI] = globalAgglom.toGlobal
(
agglom[faceOwner[faceI]]
);
bFaceI++;
faceI++;
}
}
Foam::Cloud<ParticleType>::Cloud
(
const polyMesh& pMesh,
const IDLList<ParticleType>& particles
)
:
cloud(pMesh),
IDLList<ParticleType>(particles),
polyMesh_(pMesh),
allFaces_(pMesh.faces()),
points_(pMesh.points()),
cellFaces_(pMesh.cells()),
allFaceCentres_(pMesh.faceCentres()),
owner_(pMesh.faceOwner()),
neighbour_(pMesh.faceNeighbour()),
meshInfo_(polyMesh_)
{}
Foam::Cloud<ParticleType>::Cloud
(
const polyMesh& pMesh,
const bool checkClass
)
:
cloud(pMesh),
polyMesh_(pMesh),
allFaces_(pMesh.faces()),
points_(pMesh.points()),
cellFaces_(pMesh.cells()),
allFaceCentres_(pMesh.faceCentres()),
owner_(pMesh.faceOwner()),
neighbour_(pMesh.faceNeighbour()),
meshInfo_(polyMesh_)
{
initCloud(checkClass);
}
Foam::label Foam::polyMeshTetDecomposition::findSharedBasePoint
(
const polyMesh& mesh,
label fI,
const point& nCc,
scalar tol,
bool report
)
{
const faceList& pFaces = mesh.faces();
const pointField& pPts = mesh.points();
const vectorField& pC = mesh.cellCentres();
const labelList& pOwner = mesh.faceOwner();
const face& f = pFaces[fI];
label oCI = pOwner[fI];
const point& oCc = pC[oCI];
List<scalar> tetQualities(2, 0.0);
forAll(f, faceBasePtI)
{
scalar thisBaseMinTetQuality = VGREAT;
const point& tetBasePt = pPts[f[faceBasePtI]];
for (label tetPtI = 1; tetPtI < f.size() - 1; tetPtI++)
{
label facePtI = (tetPtI + faceBasePtI) % f.size();
label otherFacePtI = f.fcIndex(facePtI);
{
// owner cell tet
label ptAI = f[facePtI];
label ptBI = f[otherFacePtI];
const point& pA = pPts[ptAI];
const point& pB = pPts[ptBI];
tetPointRef tet(oCc, tetBasePt, pA, pB);
tetQualities[0] = tet.quality();
}
{
// neighbour cell tet
label ptAI = f[otherFacePtI];
label ptBI = f[facePtI];
const point& pA = pPts[ptAI];
const point& pB = pPts[ptBI];
tetPointRef tet(nCc, tetBasePt, pA, pB);
tetQualities[1] = tet.quality();
}
if (min(tetQualities) < thisBaseMinTetQuality)
{
thisBaseMinTetQuality = min(tetQualities);
}
}
if (thisBaseMinTetQuality > tol)
{
return faceBasePtI;
}
}
Foam::vtkTopo::vtkTopo(const polyMesh& mesh)
:
mesh_(mesh),
vertLabels_(),
cellTypes_(),
addPointCellLabels_(),
superCells_()
{
const cellModel& tet = *(cellModeller::lookup("tet"));
const cellModel& pyr = *(cellModeller::lookup("pyr"));
const cellModel& prism = *(cellModeller::lookup("prism"));
const cellModel& tetWedge = *(cellModeller::lookup("tetWedge"));
const cellModel& hex = *(cellModeller::lookup("hex"));
const cellShapeList& cellShapes = mesh_.cellShapes();
// Number of additional points needed by the decomposition of polyhedra
label nAddPoints = 0;
// Number of additional cells generated by the decomposition of polyhedra
label nAddCells = 0;
// face owner is needed to determine the face orientation
const labelList& owner = mesh.faceOwner();
// Scan for cells which need to be decomposed and count additional points
// and cells
if (decomposePoly)
{
forAll(cellShapes, cellI)
{
const cellModel& model = cellShapes[cellI].model();
if
(
model != hex
// && model != wedge // See above.
&& model != prism
&& model != pyr
&& model != tet
&& model != tetWedge
)
{
const cell& cFaces = mesh_.cells()[cellI];
forAll(cFaces, cFaceI)
{
const face& f = mesh_.faces()[cFaces[cFaceI]];
label nQuads = 0;
label nTris = 0;
f.nTrianglesQuads(mesh_.points(), nTris, nQuads);
nAddCells += nQuads + nTris;
}
nAddCells--;
nAddPoints++;
}
}
}
// Set size of additional point addressing array
// (from added point to original cell)
addPointCellLabels_.setSize(nAddPoints);
// Set size of additional cells mapping array
// (from added cell to original cell)
superCells_.setSize(nAddCells);
// List of vertex labels in VTK ordering
vertLabels_.setSize(cellShapes.size() + nAddCells);
// Label of vtk type
cellTypes_.setSize(cellShapes.size() + nAddCells);
// Set counters for additional points and additional cells
label addPointI = 0, addCellI = 0;
forAll(cellShapes, cellI)
{
const cellShape& cellShape = cellShapes[cellI];
const cellModel& cellModel = cellShape.model();
labelList& vtkVerts = vertLabels_[cellI];
if (cellModel == tet)
{
vtkVerts = cellShape;
cellTypes_[cellI] = VTK_TETRA;
}
else if (cellModel == pyr)
{
vtkVerts = cellShape;
cellTypes_[cellI] = VTK_PYRAMID;
}
else if (cellModel == prism)
{
// VTK has a different node order for VTK_WEDGE
// their triangles point outwards!
vtkVerts = cellShape;
Foam::Swap(vtkVerts[1], vtkVerts[2]);
Foam::Swap(vtkVerts[4], vtkVerts[5]);
cellTypes_[cellI] = VTK_WEDGE;
}
else if (cellModel == tetWedge)
{
// Treat as squeezed prism
vtkVerts.setSize(6);
vtkVerts[0] = cellShape[0];
vtkVerts[1] = cellShape[2];
vtkVerts[2] = cellShape[1];
vtkVerts[3] = cellShape[3];
vtkVerts[4] = cellShape[4];
vtkVerts[5] = cellShape[4];
cellTypes_[cellI] = VTK_WEDGE;
}
// else if (cellModel == wedge)
// {
// // Treat as squeezed hex
// vtkVerts.setSize(8);
// vtkVerts[0] = cellShape[0];
// vtkVerts[1] = cellShape[1];
// vtkVerts[2] = cellShape[2];
// vtkVerts[3] = cellShape[0];
// vtkVerts[4] = cellShape[3];
// vtkVerts[5] = cellShape[4];
// vtkVerts[6] = cellShape[5];
// vtkVerts[7] = cellShape[6];
//
// cellTypes_[cellI] = VTK_HEXAHEDRON;
// }
else if (cellModel == hex)
{
vtkVerts = cellShape;
cellTypes_[cellI] = VTK_HEXAHEDRON;
}
else if (decomposePoly)
{
// Polyhedral cell. Decompose into tets + pyramids.
// Mapping from additional point to cell
addPointCellLabels_[addPointI] = cellI;
// The new vertex from the cell-centre
const label newVertexLabel = mesh_.nPoints() + addPointI;
// Whether to insert cell in place of original or not.
bool substituteCell = true;
const labelList& cFaces = mesh_.cells()[cellI];
forAll(cFaces, cFaceI)
{
const face& f = mesh_.faces()[cFaces[cFaceI]];
const bool isOwner = (owner[cFaces[cFaceI]] == cellI);
// Number of triangles and quads in decomposition
label nTris = 0;
label nQuads = 0;
f.nTrianglesQuads(mesh_.points(), nTris, nQuads);
// Do actual decomposition into triFcs and quadFcs.
faceList triFcs(nTris);
faceList quadFcs(nQuads);
label trii = 0;
label quadi = 0;
f.trianglesQuads(mesh_.points(), trii, quadi, triFcs, quadFcs);
forAll(quadFcs, quadI)
{
label thisCellI;
if (substituteCell)
{
thisCellI = cellI;
substituteCell = false;
}
else
{
thisCellI = mesh_.nCells() + addCellI;
superCells_[addCellI++] = cellI;
}
labelList& addVtkVerts = vertLabels_[thisCellI];
addVtkVerts.setSize(5);
const face& quad = quadFcs[quadI];
// Ensure we have the correct orientation for the
// base of the primitive cell shape.
// If the cell is face owner, the orientation needs to be
// flipped.
// At the moment, VTK doesn't actually seem to care if
// negative cells are defined, but we'll do it anyhow
// (for safety).
if (isOwner)
{
addVtkVerts[0] = quad[3];
addVtkVerts[1] = quad[2];
addVtkVerts[2] = quad[1];
addVtkVerts[3] = quad[0];
}
else
{
addVtkVerts[0] = quad[0];
addVtkVerts[1] = quad[1];
addVtkVerts[2] = quad[2];
addVtkVerts[3] = quad[3];
}
addVtkVerts[4] = newVertexLabel;
cellTypes_[thisCellI] = VTK_PYRAMID;
}
forAll(triFcs, triI)
{
label thisCellI;
if (substituteCell)
{
thisCellI = cellI;
substituteCell = false;
}
else
{
thisCellI = mesh_.nCells() + addCellI;
superCells_[addCellI++] = cellI;
}
labelList& addVtkVerts = vertLabels_[thisCellI];
const face& tri = triFcs[triI];
addVtkVerts.setSize(4);
// See note above about the orientation.
if (isOwner)
{
addVtkVerts[0] = tri[2];
addVtkVerts[1] = tri[1];
addVtkVerts[2] = tri[0];
}
else
{
addVtkVerts[0] = tri[0];
addVtkVerts[1] = tri[1];
addVtkVerts[2] = tri[2];
}
addVtkVerts[3] = newVertexLabel;
cellTypes_[thisCellI] = VTK_TETRA;
}
}
addPointI++;
}
void Foam::cellPointWeight::findTriangle
(
const polyMesh& mesh,
const vector& position,
const label facei
)
{
if (debug)
{
Pout<< "\nbool Foam::cellPointWeight::findTriangle" << nl
<< "position = " << position << nl
<< "facei = " << facei << endl;
}
List<tetIndices> faceTets = polyMeshTetDecomposition::faceTetIndices
(
mesh,
facei,
mesh.faceOwner()[facei]
);
const scalar faceAreaSqr = magSqr(mesh.faceAreas()[facei]);
forAll(faceTets, tetI)
{
const tetIndices& tetIs = faceTets[tetI];
// Barycentric coordinates of the position
barycentric2D triWeights;
const scalar det =
tetIs.faceTri(mesh).pointToBarycentric(position, triWeights);
if (0.25*mag(det)/faceAreaSqr > tol)
{
const scalar& u = triWeights[0];
const scalar& v = triWeights[1];
if
(
(u + tol > 0)
&& (v + tol > 0)
&& (u + v < 1 + tol)
)
{
// Weight[0] is for the cell centre.
weights_[0] = 0;
weights_[1] = triWeights[0];
weights_[2] = triWeights[1];
weights_[3] = triWeights[2];
faceVertices_ = tetIs.faceTriIs(mesh);
return;
}
}
}
// A suitable point in a triangle was not found, find the nearest.
scalar minNearDist = vGreat;
label nearestTetI = -1;
forAll(faceTets, tetI)
{
const tetIndices& tetIs = faceTets[tetI];
scalar nearDist = tetIs.faceTri(mesh).nearestPoint(position).distance();
if (nearDist < minNearDist)
{
minNearDist = nearDist;
nearestTetI = tetI;
}
}
if (debug)
{
Pout<< "cellPointWeight::findTriangle" << nl
<< " Triangle search failed; using closest tri to point "
<< position << nl
<< " face: "
<< facei << nl
<< endl;
}
const tetIndices& tetIs = faceTets[nearestTetI];
// Barycentric coordinates of the position, ignoring if the
// determinant is suitable. If not, the return from barycentric
// to triWeights is safe.
const barycentric2D triWeights =
tetIs.faceTri(mesh).pointToBarycentric(position);
// Weight[0] is for the cell centre.
weights_[0] = 0;
weights_[1] = triWeights[0];
weights_[2] = triWeights[1];
weights_[3] = triWeights[2];
faceVertices_ = tetIs.faceTriIs(mesh);
}
void insertDuplicateMerge
(
const polyMesh& mesh,
const labelList& duplicates,
polyTopoChange& meshMod
)
{
const faceList& faces = mesh.faces();
const labelList& faceOwner = mesh.faceOwner();
const faceZoneMesh& faceZones = mesh.faceZones();
forAll(duplicates, bFacei)
{
label otherFacei = duplicates[bFacei];
if (otherFacei != -1 && otherFacei > bFacei)
{
// Two duplicate faces. Merge.
label face0 = mesh.nInternalFaces() + bFacei;
label face1 = mesh.nInternalFaces() + otherFacei;
label own0 = faceOwner[face0];
label own1 = faceOwner[face1];
if (own0 < own1)
{
// Use face0 as the new internal face.
label zoneID = faceZones.whichZone(face0);
bool zoneFlip = false;
if (zoneID >= 0)
{
const faceZone& fZone = faceZones[zoneID];
zoneFlip = fZone.flipMap()[fZone.whichFace(face0)];
}
meshMod.setAction(polyRemoveFace(face1));
meshMod.setAction
(
polyModifyFace
(
faces[face0], // modified face
face0, // label of face being modified
own0, // owner
own1, // neighbour
false, // face flip
-1, // patch for face
false, // remove from zone
zoneID, // zone for face
zoneFlip // face flip in zone
)
);
}
else
{
// Use face1 as the new internal face.
label zoneID = faceZones.whichZone(face1);
bool zoneFlip = false;
if (zoneID >= 0)
{
const faceZone& fZone = faceZones[zoneID];
zoneFlip = fZone.flipMap()[fZone.whichFace(face1)];
}
meshMod.setAction(polyRemoveFace(face0));
meshMod.setAction
(
polyModifyFace
(
faces[face1], // modified face
face1, // label of face being modified
own1, // owner
own0, // neighbour
false, // face flip
-1, // patch for face
false, // remove from zone
zoneID, // zone for face
zoneFlip // face flip in zone
)
);
}
}
}
