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foam-extend4.1-coherent-io/applications/utilities/mesh/conversion/polyDualMesh/polyDualMeshApp.C

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/*---------------------------------------------------------------------------*\
========= |
\\ / F ield | OpenFOAM: The Open Source CFD Toolbox
\\ / O peration |
\\ / A nd | Copyright held by original author
\\/ 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 2 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, write to the Free Software Foundation,
Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
Description
Calculate the dual of a polyMesh. Adheres to all the feature and patch
edges.
Usage
- polyDualMesh featureAngle
Detects any boundary edge > angle and creates multiple boundary faces
for it. Normal behaviour is to have each point become a cell
(1.5 behaviour)
@param -concaveMultiCells
Creates multiple cells for each point on a concave edge. Might limit
the amount of distortion on some meshes.
@param -splitAllFaces
Normally only constructs a single face between two cells. This single face
might be too distorted. splitAllFaces will create a single face for every
original cell the face passes through. The mesh will thus have
multiple faces inbetween two cells! (so is not strictly upper-triangular
anymore - checkMesh will complain)
@param -doNotPreserveFaceZones:
By default all faceZones are preserved by marking all faces, edges and
points on them as features. The -doNotPreserveFaceZones disables this
behaviour.
Note: is just a driver for meshDualiser. Substitute your own
simpleMarkFeatures to have different behaviour.
\*---------------------------------------------------------------------------*/
#include "argList.H"
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#include "objectRegistry.H"
#include "Time.H"
#include "timeSelector.H"
#include "fvMesh.H"
#include "mathematicalConstants.H"
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#include "directTopoChange.H"
#include "mapPolyMesh.H"
#include "PackedBoolList.H"
#include "meshTools.H"
#include "OFstream.H"
#include "meshDualiser.H"
#include "ReadFields.H"
#include "volFields.H"
#include "surfaceFields.H"
using namespace Foam;
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
// Naive feature detection. All boundary edges with angle > featureAngle become
// feature edges. All points on feature edges become feature points. All
// boundary faces become feature faces.
void simpleMarkFeatures
(
const polyMesh& mesh,
const PackedBoolList& isBoundaryEdge,
const scalar featureAngle,
const bool concaveMultiCells,
const bool doNotPreserveFaceZones,
labelList& featureFaces,
labelList& featureEdges,
labelList& singleCellFeaturePoints,
labelList& multiCellFeaturePoints
)
{
scalar minCos = Foam::cos(featureAngle * mathematicalConstant::pi/180.0);
const polyBoundaryMesh& patches = mesh.boundaryMesh();
// Working sets
labelHashSet featureEdgeSet;
labelHashSet singleCellFeaturePointSet;
labelHashSet multiCellFeaturePointSet;
// 1. Mark all edges between patches
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
forAll(patches, patchI)
{
const polyPatch& pp = patches[patchI];
const labelList& meshEdges = pp.meshEdges();
// All patch corner edges. These need to be feature points & edges!
for (label edgeI = pp.nInternalEdges(); edgeI < pp.nEdges(); edgeI++)
{
label meshEdgeI = meshEdges[edgeI];
featureEdgeSet.insert(meshEdgeI);
singleCellFeaturePointSet.insert(mesh.edges()[meshEdgeI][0]);
singleCellFeaturePointSet.insert(mesh.edges()[meshEdgeI][1]);
}
}
// 2. Mark all geometric feature edges
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
// Make distinction between convex features where the boundary point becomes
// a single cell and concave features where the boundary point becomes
// multiple 'half' cells.
// Addressing for all outside faces
primitivePatch allBoundary
(
SubList<face>
(
mesh.faces(),
mesh.nFaces()-mesh.nInternalFaces(),
mesh.nInternalFaces()
),
mesh.points()
);
// Check for non-manifold points (surface pinched at point)
allBoundary.checkPointManifold(false, &singleCellFeaturePointSet);
// Check for non-manifold edges (surface pinched at edge)
const labelListList& edgeFaces = allBoundary.edgeFaces();
const labelList& meshPoints = allBoundary.meshPoints();
forAll(edgeFaces, edgeI)
{
const labelList& eFaces = edgeFaces[edgeI];
if (eFaces.size() > 2)
{
const edge& e = allBoundary.edges()[edgeI];
//Info<< "Detected non-manifold boundary edge:" << edgeI
// << " coords:"
// << allBoundary.points()[meshPoints[e[0]]]
// << allBoundary.points()[meshPoints[e[1]]] << endl;
singleCellFeaturePointSet.insert(meshPoints[e[0]]);
singleCellFeaturePointSet.insert(meshPoints[e[1]]);
}
}
// Check for features.
forAll(edgeFaces, edgeI)
{
const labelList& eFaces = edgeFaces[edgeI];
if (eFaces.size() == 2)
{
label f0 = eFaces[0];
label f1 = eFaces[1];
// check angle
const vector& n0 = allBoundary.faceNormals()[f0];
const vector& n1 = allBoundary.faceNormals()[f1];
if ((n0 & n1) < minCos)
{
const edge& e = allBoundary.edges()[edgeI];
label v0 = meshPoints[e[0]];
label v1 = meshPoints[e[1]];
label meshEdgeI = meshTools::findEdge(mesh, v0, v1);
featureEdgeSet.insert(meshEdgeI);
// Check if convex or concave by looking at angle
// between face centres and normal
vector c1c0
(
allBoundary[f1].centre(allBoundary.points())
- allBoundary[f0].centre(allBoundary.points())
);
if (concaveMultiCells && (c1c0 & n0) > SMALL)
{
// Found concave edge. Make into multiCell features
Info<< "Detected concave feature edge:" << edgeI
<< " cos:" << (c1c0 & n0)
<< " coords:"
<< allBoundary.points()[v0]
<< allBoundary.points()[v1]
<< endl;
singleCellFeaturePointSet.erase(v0);
multiCellFeaturePointSet.insert(v0);
singleCellFeaturePointSet.erase(v1);
multiCellFeaturePointSet.insert(v1);
}
else
{
// Convex. singleCell feature.
if (!multiCellFeaturePointSet.found(v0))
{
singleCellFeaturePointSet.insert(v0);
}
if (!multiCellFeaturePointSet.found(v1))
{
singleCellFeaturePointSet.insert(v1);
}
}
}
}
}
// 3. Mark all feature faces
// ~~~~~~~~~~~~~~~~~~~~~~~~~
// Face centres that need inclusion in the dual mesh
labelHashSet featureFaceSet(mesh.nFaces()-mesh.nInternalFaces());
// A. boundary faces.
for (label faceI = mesh.nInternalFaces(); faceI < mesh.nFaces(); faceI++)
{
featureFaceSet.insert(faceI);
}
// B. face zones.
const faceZoneMesh& faceZones = mesh.faceZones();
if (doNotPreserveFaceZones)
{
if (faceZones.size() > 0)
{
WarningIn("simpleMarkFeatures(..)")
<< "Detected " << faceZones.size()
<< " faceZones. These will not be preserved."
<< endl;
}
}
else
{
if (faceZones.size() > 0)
{
Info<< "Detected " << faceZones.size()
<< " faceZones. Preserving these by marking their"
<< " points, edges and faces as features." << endl;
}
forAll(faceZones, zoneI)
{
const faceZone& fz = faceZones[zoneI];
Info<< "Inserting all faces in faceZone " << fz.name()
<< " as features." << endl;
forAll(fz, i)
{
label faceI = fz[i];
const face& f = mesh.faces()[faceI];
const labelList& fEdges = mesh.faceEdges()[faceI];
featureFaceSet.insert(faceI);
forAll(f, fp)
{
// Mark point as multi cell point (since both sides of
// face should have different cells)
singleCellFeaturePointSet.erase(f[fp]);
multiCellFeaturePointSet.insert(f[fp]);
// Make sure there are points on the edges.
featureEdgeSet.insert(fEdges[fp]);
}
}
}
}
// Transfer to arguments
featureFaces = featureFaceSet.toc();
featureEdges = featureEdgeSet.toc();
singleCellFeaturePoints = singleCellFeaturePointSet.toc();
multiCellFeaturePoints = multiCellFeaturePointSet.toc();
}
// Dump features to .obj files
void dumpFeatures
(
const polyMesh& mesh,
const labelList& featureFaces,
const labelList& featureEdges,
const labelList& singleCellFeaturePoints,
const labelList& multiCellFeaturePoints
)
{
{
OFstream str("featureFaces.obj");
Info<< "Dumping centres of featureFaces to obj file " << str.name()
<< endl;
forAll(featureFaces, i)
{
meshTools::writeOBJ(str, mesh.faceCentres()[featureFaces[i]]);
}
}
{
OFstream str("featureEdges.obj");
Info<< "Dumping featureEdges to obj file " << str.name() << endl;
label vertI = 0;
forAll(featureEdges, i)
{
const edge& e = mesh.edges()[featureEdges[i]];
meshTools::writeOBJ(str, mesh.points()[e[0]]);
vertI++;
meshTools::writeOBJ(str, mesh.points()[e[1]]);
vertI++;
str<< "l " << vertI-1 << ' ' << vertI << nl;
}
}
{
OFstream str("singleCellFeaturePoints.obj");
Info<< "Dumping featurePoints that become a single cell to obj file "
<< str.name() << endl;
forAll(singleCellFeaturePoints, i)
{
meshTools::writeOBJ(str, mesh.points()[singleCellFeaturePoints[i]]);
}
}
{
OFstream str("multiCellFeaturePoints.obj");
Info<< "Dumping featurePoints that become multiple cells to obj file "
<< str.name() << endl;
forAll(multiCellFeaturePoints, i)
{
meshTools::writeOBJ(str, mesh.points()[multiCellFeaturePoints[i]]);
}
}
}
int main(int argc, char *argv[])
{
argList::noParallel();
timeSelector::addOptions(true, false);
argList::validArgs.append("feature angle[0-180]");
argList::validOptions.insert("splitAllFaces", "");
argList::validOptions.insert("concaveMultiCells", "");
argList::validOptions.insert("doNotPreserveFaceZones", "");
argList::validOptions.insert("overwrite", "");
# include "setRootCase.H"
# include "createTime.H"
instantList timeDirs = timeSelector::select0(runTime, args);
# include "createMesh.H"
const word oldInstance = mesh.pointsInstance();
// 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);
}
}
scalar featureAngle(readScalar(IStringStream(args.additionalArgs()[0])()));
scalar minCos = Foam::cos(featureAngle * mathematicalConstant::pi/180.0);
Info<< "Feature:" << featureAngle << endl
<< "minCos :" << minCos << endl
<< endl;
const bool splitAllFaces = args.optionFound("splitAllFaces");
if (splitAllFaces)
{
Info<< "Splitting all internal faces to create multiple faces"
<< " between two cells." << nl
<< endl;
}
const bool overwrite = args.optionFound("overwrite");
const bool doNotPreserveFaceZones = args.optionFound
(
"doNotPreserveFaceZones"
);
const bool concaveMultiCells = args.optionFound("concaveMultiCells");
if (concaveMultiCells)
{
Info<< "Generating multiple cells for points on concave feature edges."
<< nl << endl;
}
// Face(centre)s that need inclusion in the dual mesh
labelList featureFaces;
// Edge(centre)s ,,
labelList featureEdges;
// Points (that become a single cell) that need inclusion in the dual mesh
labelList singleCellFeaturePoints;
// Points (that become a multiple cells) ,,
labelList multiCellFeaturePoints;
// Sample implementation of feature detection.
simpleMarkFeatures
(
mesh,
isBoundaryEdge,
featureAngle,
concaveMultiCells,
doNotPreserveFaceZones,
featureFaces,
featureEdges,
singleCellFeaturePoints,
multiCellFeaturePoints
);
// If we want to split all polyMesh faces into one dualface per cell
// we are passing through we also need a point
// at the polyMesh facecentre and edgemid of the faces we want to
// split.
if (splitAllFaces)
{
featureEdges = identity(mesh.nEdges());
featureFaces = identity(mesh.nFaces());
}
// Write obj files for debugging
dumpFeatures
(
mesh,
featureFaces,
featureEdges,
singleCellFeaturePoints,
multiCellFeaturePoints
);
// Read objects in time directory
IOobjectList objects(mesh, runTime.timeName());
// Read vol fields.
PtrList<volScalarField> vsFlds;
ReadFields(mesh, objects, vsFlds);
PtrList<volVectorField> vvFlds;
ReadFields(mesh, objects, vvFlds);
PtrList<volSphericalTensorField> vstFlds;
ReadFields(mesh, objects, vstFlds);
PtrList<volSymmTensorField> vsymtFlds;
ReadFields(mesh, objects, vsymtFlds);
PtrList<volTensorField> vtFlds;
ReadFields(mesh, objects, vtFlds);
// Read surface fields.
PtrList<surfaceScalarField> ssFlds;
ReadFields(mesh, objects, ssFlds);
PtrList<surfaceVectorField> svFlds;
ReadFields(mesh, objects, svFlds);
PtrList<surfaceSphericalTensorField> sstFlds;
ReadFields(mesh, objects, sstFlds);
PtrList<surfaceSymmTensorField> ssymtFlds;
ReadFields(mesh, objects, ssymtFlds);
PtrList<surfaceTensorField> stFlds;
ReadFields(mesh, objects, stFlds);
// Topo change container
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directTopoChange meshMod(mesh.boundaryMesh().size());
// Mesh dualiser engine
meshDualiser dualMaker(mesh);
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// Insert all commands into directTopoChange to create dual of mesh.
// This does all the hard work.
dualMaker.setRefinement
(
splitAllFaces,
featureFaces,
featureEdges,
singleCellFeaturePoints,
multiCellFeaturePoints,
meshMod
);
// Create mesh, return map from old to new mesh.
autoPtr<mapPolyMesh> map = meshMod.changeMesh(mesh, false);
// Update fields
mesh.updateMesh(map);
// Optionally inflate mesh
if (map().hasMotionPoints())
{
mesh.movePoints(map().preMotionPoints());
}
if (!overwrite)
{
runTime++;
}
else
{
mesh.setInstance(oldInstance);
}
Info<< "Writing dual mesh to " << runTime.timeName() << endl;
mesh.write();
Info<< "End\n" << endl;
return 0;
}
// ************************************************************************* //