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foam-extend4.1-coherent-io/applications/utilities/mesh/manipulation/checkMesh/checkGeometry.C

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#include "checkGeometry.H"
#include "polyMesh.H"
#include "globalMeshData.H"
#include "cellSet.H"
#include "faceSet.H"
#include "pointSet.H"
#include "EdgeMap.H"
Foam::label Foam::checkGeometry(const polyMesh& mesh, const bool allGeometry)
{
label noFailedChecks = 0;
Info<< "\nChecking geometry..." << endl;
// Check directions
{
Vector<label> dirs = mesh.directions();
label nValidDirs = 0;
for (direction cmpt = 0; cmpt < Vector<label>::nComponents; cmpt++)
{
if (dirs[cmpt] > 0)
{
nValidDirs++;
}
}
if (nValidDirs == 0)
{
Info<< " This mesh has no valid solving directions. dirs = "
<< dirs << ". Please check mesh definition for empty patches."
<< endl;
noFailedChecks++;
}
Info << " This is a " << nValidDirs << "-D mesh" << endl;
}
// Get a small relative length from the bounding box
const boundBox& globalBb = mesh.bounds();
Info<< " Overall domain bounding box "
<< globalBb.min() << " " << globalBb.max() << endl;
// Min length
scalar minDistSqr = magSqr(1e-6 * globalBb.span());
// Non-empty directions
const Vector<label> validDirs = (mesh.geometricD() + Vector<label>::one)/2;
Info<< " Mesh (non-empty, non-wedge) directions " << validDirs << endl;
const Vector<label> solDirs = (mesh.solutionD() + Vector<label>::one)/2;
Info<< " Mesh (non-empty) directions " << solDirs << endl;
scalar nGeomDims = mesh.nGeometricD();
Info<< " Mesh (non-empty, non-wedge) dimensions "
<< nGeomDims << endl;
if (nGeomDims < 3)
{
pointSet nonAlignedPoints(mesh, "nonAlignedEdges", mesh.nPoints()/100);
if (mesh.checkEdgeAlignment(true, validDirs, &nonAlignedPoints))
{
noFailedChecks++;
label nNonAligned = returnReduce
(
nonAlignedPoints.size(),
sumOp<label>()
);
if (nNonAligned > 0)
{
Info<< " Writing " << nNonAligned
<< " points on non-aligned edges to set "
<< nonAlignedPoints.name() << endl;
nonAlignedPoints.write();
}
}
}
if (mesh.checkClosedBoundary(true)) noFailedChecks++;
{
cellSet cells(mesh, "nonClosedCells", mesh.nCells()/100 + 1);
cellSet aspectCells(mesh, "highAspectRatioCells", mesh.nCells()/100 + 1);
if (mesh.checkClosedCells(true, &cells, &aspectCells))
{
noFailedChecks++;
label nNonClosed = returnReduce(cells.size(), sumOp<label>());
if (nNonClosed > 0)
{
Info<< " Writing " << nNonClosed
<< " non closed cells to set " << cells.name() << endl;
cells.write();
}
}
label nHighAspect = returnReduce(aspectCells.size(), sumOp<label>());
if (nHighAspect > 0)
{
Info<< " Writing " << nHighAspect
<< " cells with high aspect ratio to set "
<< aspectCells.name() << endl;
aspectCells.write();
}
}
{
faceSet faces(mesh, "zeroAreaFaces", mesh.nFaces()/100 + 1);
if (mesh.checkFaceAreas(true, &faces))
{
noFailedChecks++;
label nFaces = returnReduce(faces.size(), sumOp<label>());
if (nFaces > 0)
{
Info<< " Writing " << nFaces
<< " zero area faces to set " << faces.name() << endl;
faces.write();
}
}
}
{
cellSet cells(mesh, "zeroVolumeCells", mesh.nCells()/100 + 1);
if (mesh.checkCellVolumes(true, &cells))
{
noFailedChecks++;
label nCells = returnReduce(cells.size(), sumOp<label>());
if (nCells > 0)
{
Info<< " Writing " << nCells
<< " zero volume cells to set " << cells.name() << endl;
cells.write();
}
}
}
{
faceSet faces(mesh, "nonOrthoFaces", mesh.nFaces()/100 + 1);
if (mesh.checkFaceOrthogonality(true, &faces))
{
noFailedChecks++;
}
label nFaces = returnReduce(faces.size(), sumOp<label>());
if (nFaces > 0)
{
Info<< " Writing " << nFaces
<< " non-orthogonal faces to set " << faces.name() << endl;
faces.write();
}
}
{
faceSet faces(mesh, "wrongOrientedFaces", mesh.nFaces()/100 + 1);
if (mesh.checkFacePyramids(true, -SMALL, &faces))
{
noFailedChecks++;
label nFaces = returnReduce(faces.size(), sumOp<label>());
if (nFaces > 0)
{
Info<< " Writing " << nFaces
<< " faces with incorrect orientation to set "
<< faces.name() << endl;
faces.write();
}
}
}
{
faceSet faces(mesh, "skewFaces", mesh.nFaces()/100 + 1);
if (mesh.checkFaceSkewness(true, &faces))
{
noFailedChecks++;
label nFaces = returnReduce(faces.size(), sumOp<label>());
if (nFaces > 0)
{
Info<< " Writing " << nFaces
<< " skew faces to set " << faces.name() << endl;
faces.write();
}
}
}
if (allGeometry)
{
// Note use of nPoints since don't want edge construction.
pointSet points(mesh, "shortEdges", mesh.nPoints()/1000 + 1);
if (mesh.checkEdgeLength(true, minDistSqr, &points))
{
//noFailedChecks++;
label nPoints = returnReduce(points.size(), sumOp<label>());
if (nPoints > 0)
{
Info<< " Writing " << nPoints
<< " points on short edges to set " << points.name()
<< endl;
points.write();
}
}
label nEdgeClose = returnReduce(points.size(), sumOp<label>());
if (mesh.checkPointNearness(false, minDistSqr, &points))
{
//noFailedChecks++;
label nPoints = returnReduce(points.size(), sumOp<label>());
if (nPoints > nEdgeClose)
{
pointSet nearPoints(mesh, "nearPoints", points);
Info<< " Writing " << nPoints
<< " near (closer than " << Foam::sqrt(minDistSqr)
<< " apart) points to set " << nearPoints.name() << endl;
nearPoints.write();
}
}
}
if (allGeometry)
{
faceSet faces(mesh, "concaveFaces", mesh.nFaces()/100 + 1);
if (mesh.checkFaceAngles(true, 10, &faces))
{
//noFailedChecks++;
label nFaces = returnReduce(faces.size(), sumOp<label>());
if (nFaces > 0)
{
Info<< " Writing " << nFaces
<< " faces with concave angles to set " << faces.name()
<< endl;
faces.write();
}
}
}
if (allGeometry)
{
faceSet faces(mesh, "warpedFaces", mesh.nFaces()/100 + 1);
if (mesh.checkFaceFlatness(true, 0.8, &faces))
{
//noFailedChecks++;
label nFaces = returnReduce(faces.size(), sumOp<label>());
if (nFaces > 0)
{
Info<< " Writing " << nFaces
<< " warped faces to set " << faces.name() << endl;
faces.write();
}
}
}
if (allGeometry)
{
cellSet cells(mesh, "underdeterminedCells", mesh.nCells()/100);
if (mesh.checkCellDeterminant(true, &cells))
{
noFailedChecks++;
label nCells = returnReduce(cells.size(), sumOp<label>());
Info<< " Writing " << nCells
<< " under-determined cells to set " << cells.name() << endl;
cells.write();
}
}
return noFailedChecks;
}