/*---------------------------------------------------------------------------*\
========= |
\\ / F ield | OpenFOAM: The Open Source CFD Toolbox
\\ / O peration |
\\ / A nd | Copyright (C) 2011-2012 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 .
Description
A surface analysis tool which sub-sets the triSurface
to choose only a part of interest. Based on subsetMesh.
\*---------------------------------------------------------------------------*/
#include "triSurface.H"
#include "argList.H"
#include "OFstream.H"
#include "IFstream.H"
#include "Switch.H"
#include "IOdictionary.H"
#include "boundBox.H"
#include "indexedOctree.H"
#include "treeDataTriSurface.H"
#include "Random.H"
using namespace Foam;
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
// Main program:
int main(int argc, char *argv[])
{
argList::noParallel();
argList::validArgs.append("surfaceSubsetDict");
argList::validArgs.append("surfaceFile");
argList::validArgs.append("output surfaceFile");
argList args(argc, argv);
Info<< "Reading dictionary " << args[1] << " ..." << endl;
IFstream dictFile(args[1]);
dictionary meshSubsetDict(dictFile);
Info<< "Reading surface " << args[2] << " ..." << endl;
triSurface surf1(args[2]);
const fileName outFileName(args[3]);
Info<< "Original:" << endl;
surf1.writeStats(Info);
Info<< endl;
labelList markedPoints
(
meshSubsetDict.lookup("localPoints")
);
labelList markedEdges
(
meshSubsetDict.lookup("edges")
);
labelList markedFaces
(
meshSubsetDict.lookup("faces")
);
pointField markedZone
(
meshSubsetDict.lookup("zone")
);
if (markedZone.size() && markedZone.size() != 2)
{
FatalErrorIn(args.executable())
<< "zone specification should be two points, min and max of "
<< "the boundingbox" << endl
<< "zone:" << markedZone
<< exit(FatalError);
}
Switch addFaceNeighbours
(
meshSubsetDict.lookup("addFaceNeighbours")
);
const bool invertSelection =
meshSubsetDict.lookupOrDefault("invertSelection", false);
// Mark the cells for the subset
// Faces to subset
boolList facesToSubset(surf1.size(), false);
//
// pick up faces connected to "localPoints"
//
if (markedPoints.size())
{
Info<< "Found " << markedPoints.size() << " marked point(s)." << endl;
// pick up cells sharing the point
forAll(markedPoints, pointI)
{
if
(
markedPoints[pointI] < 0
|| markedPoints[pointI] >= surf1.nPoints()
)
{
FatalErrorIn(args.executable())
<< "localPoint label " << markedPoints[pointI]
<< "out of range."
<< " The mesh has got "
<< surf1.nPoints() << " localPoints."
<< exit(FatalError);
}
const labelList& curFaces =
surf1.pointFaces()[markedPoints[pointI]];
forAll(curFaces, i)
{
facesToSubset[curFaces[i]] = true;
}
}
}
//
// pick up faces connected to "edges"
//
if (markedEdges.size())
{
Info<< "Found " << markedEdges.size() << " marked edge(s)." << endl;
// pick up cells sharing the edge
forAll(markedEdges, edgeI)
{
if
(
markedEdges[edgeI] < 0
|| markedEdges[edgeI] >= surf1.nEdges()
)
{
FatalErrorIn(args.executable())
<< "edge label " << markedEdges[edgeI]
<< "out of range."
<< " The mesh has got "
<< surf1.nEdges() << " edges."
<< exit(FatalError);
}
const labelList& curFaces = surf1.edgeFaces()[markedEdges[edgeI]];
forAll(curFaces, i)
{
facesToSubset[curFaces[i]] = true;
}
}
}
//
// pick up faces with centre inside "zone"
//
if (markedZone.size() == 2)
{
const point& min = markedZone[0];
const point& max = markedZone[1];
Info<< "Using zone min:" << min << " max:" << max << endl;
forAll(surf1, faceI)
{
const point centre = surf1[faceI].centre(surf1.points());
if
(
(centre.x() >= min.x())
&& (centre.y() >= min.y())
&& (centre.z() >= min.z())
&& (centre.x() <= max.x())
&& (centre.y() <= max.y())
&& (centre.z() <= max.z())
)
{
facesToSubset[faceI] = true;
}
}
}
//
// pick up faces on certain side of surface
//
if (meshSubsetDict.found("surface"))
{
const dictionary& surfDict = meshSubsetDict.subDict("surface");
fileName surfName(surfDict.lookup("name"));
Switch outside(surfDict.lookup("outside"));
if (outside)
{
Info<< "Selecting all triangles with centre outside surface "
<< surfName << endl;
}
else
{
Info<< "Selecting all triangles with centre inside surface "
<< surfName << endl;
}
// Read surface to select on
triSurface selectSurf(surfName);
// bb of surface
treeBoundBox bb(selectSurf.localPoints());
// Random number generator
Random rndGen(354543);
// search engine
indexedOctree selectTree
(
treeDataTriSurface
(
selectSurf,
indexedOctree::perturbTol()
),
bb.extend(rndGen, 1e-4), // slightly randomize bb
8, // maxLevel
10, // leafsize
3.0 // duplicity
);
// Check if face (centre) is in outside or inside.
forAll(facesToSubset, faceI)
{
if (!facesToSubset[faceI])
{
const point fc(surf1[faceI].centre(surf1.points()));
indexedOctree::volumeType t =
selectTree.getVolumeType(fc);
if
(
outside
? (t == indexedOctree::OUTSIDE)
: (t == indexedOctree::INSIDE)
)
{
facesToSubset[faceI] = true;
}
}
}
}
//
// pick up specified "faces"
//
// Number of additional faces picked up because of addFaceNeighbours
label nFaceNeighbours = 0;
if (markedFaces.size())
{
Info<< "Found " << markedFaces.size() << " marked face(s)." << endl;
// Check and mark faces to pick up
forAll(markedFaces, faceI)
{
if
(
markedFaces[faceI] < 0
|| markedFaces[faceI] >= surf1.size()
)
{
FatalErrorIn(args.executable())
<< "Face label " << markedFaces[faceI] << "out of range."
<< " The mesh has got "
<< surf1.size() << " faces."
<< exit(FatalError);
}
// Mark the face
facesToSubset[markedFaces[faceI]] = true;
// mark its neighbours if requested
if (addFaceNeighbours)
{
const labelList& curFaces =
surf1.faceFaces()[markedFaces[faceI]];
forAll(curFaces, i)
{
label faceI = curFaces[i];
if (!facesToSubset[faceI])
{
facesToSubset[faceI] = true;
nFaceNeighbours++;
}
}
}
}
}
if (addFaceNeighbours)
{
Info<< "Added " << nFaceNeighbours
<< " faces because of addFaceNeighbours" << endl;
}
if (invertSelection)
{
Info<< "Inverting selection." << endl;
forAll(facesToSubset, i)
{
facesToSubset[i] = facesToSubset[i] ? false : true;
}
}
// Create subsetted surface
labelList pointMap;
labelList faceMap;
triSurface surf2
(
surf1.subsetMesh(facesToSubset, pointMap, faceMap)
);
Info<< "Subset:" << endl;
surf2.writeStats(Info);
Info<< endl;
Info<< "Writing surface to " << outFileName << endl;
surf2.write(outFileName);
return 0;
}
// ************************************************************************* //