981 lines
25 KiB
C
981 lines
25 KiB
C
/*---------------------------------------------------------------------------*\
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========= |
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\\ / F ield | foam-extend: Open Source CFD
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\\ / O peration | Version: 3.2
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\\ / A nd | Web: http://www.foam-extend.org
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\\/ M anipulation | For copyright notice see file Copyright
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-------------------------------------------------------------------------------
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License
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This file is part of foam-extend.
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foam-extend is free software: you can redistribute it and/or modify it
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under the terms of the GNU General Public License as published by the
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Free Software Foundation, either version 3 of the License, or (at your
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option) any later version.
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foam-extend is distributed in the hope that it will be useful, but
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WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with foam-extend. If not, see <http://www.gnu.org/licenses/>.
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Description
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Takes multiply connected surface and tries to split surface at
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multiply connected edges by duplicating points. Introduces concept of
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- borderEdge. Edge with 4 faces connected to it.
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- borderPoint. Point connected to exactly 2 borderEdges.
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- borderLine. Connected list of borderEdges.
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By duplicating borderPoints this will split 'borderLines'. As a
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preprocessing step it can detect borderEdges without any borderPoints
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and explicitly split these triangles.
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The problems in this algorithm are:
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- determining which two (of the four) faces form a surface. Done by walking
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face-edge-face while keeping and edge or point on the borderEdge
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borderPoint.
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- determining the outwards pointing normal to be used to slightly offset the
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duplicated point.
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Uses sortedEdgeFaces quite a bit.
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Is tested on simple borderLines resulting from extracting a surface
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from a hex mesh. Will quite possibly go wrong on more complicated border
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lines (i.e. ones forming a loop).
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Dumps surface every so often since might take a long time to complete.
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\*---------------------------------------------------------------------------*/
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#include "argList.H"
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#include "triSurface.H"
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#include "OFstream.H"
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#include "ListOps.H"
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#include "triSurfaceTools.H"
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using namespace Foam;
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// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
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void writeOBJ(Ostream& os, const pointField& pts)
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{
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forAll(pts, i)
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{
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const point& pt = pts[i];
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os << "v " << pt.x() << ' ' << pt.y() << ' ' << pt.z() << endl;
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}
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}
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void dumpPoints(const triSurface& surf, const labelList& borderPoint)
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{
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fileName fName("borderPoints.obj");
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Info<< "Dumping borderPoints as Lightwave .obj file to " << fName
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<< "\nThis can be visualized with e.g. javaview (www.javaview.de)\n\n";
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OFstream os(fName);
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forAll(borderPoint, pointI)
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{
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if (borderPoint[pointI] != -1)
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{
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const point& pt = surf.localPoints()[pointI];
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os << "v " << pt.x() << ' ' << pt.y() << ' ' << pt.z() << endl;
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}
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}
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}
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void dumpEdges(const triSurface& surf, const boolList& borderEdge)
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{
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fileName fName("borderEdges.obj");
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Info<< "Dumping borderEdges as Lightwave .obj file to " << fName
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<< "\nThis can be visualized with e.g. javaview (www.javaview.de)\n\n";
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OFstream os(fName);
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writeOBJ(os, surf.localPoints());
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forAll(borderEdge, edgeI)
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{
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if (borderEdge[edgeI])
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{
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const edge& e = surf.edges()[edgeI];
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os << "l " << e.start()+1 << ' ' << e.end()+1 << endl;
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}
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}
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}
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void dumpFaces
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(
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const fileName& fName,
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const triSurface& surf,
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const Map<label>& connectedFaces
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)
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{
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Info<< "Dumping connectedFaces as Lightwave .obj file to " << fName
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<< "\nThis can be visualized with e.g. javaview (www.javaview.de)\n\n";
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OFstream os(fName);
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for
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(
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Map<label>::const_iterator iter = connectedFaces.begin();
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iter != connectedFaces.end();
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++iter
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)
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{
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const labelledTri& f = surf.localFaces()[iter.key()];
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point ctr(f.centre(surf.localPoints()));
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os << "v " << ctr.x() << ' ' << ctr.y() << ' ' << ctr.z() << endl;
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}
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}
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void testSortedEdgeFaces(const triSurface& surf)
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{
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const labelListList& edgeFaces = surf.edgeFaces();
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const labelListList& sortedEdgeFaces = surf.sortedEdgeFaces();
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forAll(edgeFaces, edgeI)
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{
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const labelList& myFaces = edgeFaces[edgeI];
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const labelList& sortMyFaces = sortedEdgeFaces[edgeI];
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forAll(myFaces, i)
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{
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if (findIndex(sortMyFaces, myFaces[i]) == -1)
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{
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FatalErrorIn("testSortedEdgeFaces(..)") << abort(FatalError);
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}
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}
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forAll(sortMyFaces, i)
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{
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if (findIndex(myFaces, sortMyFaces[i]) == -1)
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{
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FatalErrorIn("testSortedEdgeFaces(..)") << abort(FatalError);
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}
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}
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}
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}
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// Mark off all border edges. Return number of border edges.
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label markBorderEdges
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(
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const bool debug,
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const triSurface& surf,
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boolList& borderEdge
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)
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{
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label nBorderEdges = 0;
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const labelListList& edgeFaces = surf.edgeFaces();
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forAll(edgeFaces, edgeI)
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{
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if (edgeFaces[edgeI].size() == 4)
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{
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borderEdge[edgeI] = true;
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nBorderEdges++;
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}
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}
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if (debug)
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{
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dumpEdges(surf, borderEdge);
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}
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return nBorderEdges;
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}
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// Mark off all border points. Return number of border points. Border points
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// marked by setting value to newly introduced point.
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label markBorderPoints
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(
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const bool debug,
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const triSurface& surf,
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const boolList& borderEdge,
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labelList& borderPoint
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)
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{
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label nPoints = surf.nPoints();
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const labelListList& pointEdges = surf.pointEdges();
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forAll(pointEdges, pointI)
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{
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const labelList& pEdges = pointEdges[pointI];
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label nBorderEdges = 0;
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forAll(pEdges, i)
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{
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if (borderEdge[pEdges[i]])
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{
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nBorderEdges++;
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}
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}
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if (nBorderEdges == 2 && borderPoint[pointI] == -1)
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{
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borderPoint[pointI] = nPoints++;
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}
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}
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label nBorderPoints = nPoints - surf.nPoints();
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if (debug)
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{
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dumpPoints(surf, borderPoint);
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}
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return nBorderPoints;
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}
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// Get minumum length of edges connected to pointI
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// Serves to get some local length scale.
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scalar minEdgeLen(const triSurface& surf, const label pointI)
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{
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const pointField& points = surf.localPoints();
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const labelList& pEdges = surf.pointEdges()[pointI];
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scalar minLen = GREAT;
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forAll(pEdges, i)
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{
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label edgeI = pEdges[i];
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scalar len = surf.edges()[edgeI].mag(points);
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if (len < minLen)
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{
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minLen = len;
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}
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}
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return minLen;
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}
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// Find edge among edgeLabels with endpoints v0,v1
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label findEdge
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(
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const triSurface& surf,
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const labelList& edgeLabels,
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const label v0,
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const label v1
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)
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{
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forAll(edgeLabels, i)
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{
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label edgeI = edgeLabels[i];
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const edge& e = surf.edges()[edgeI];
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if
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(
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(
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e.start() == v0
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&& e.end() == v1
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)
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|| (
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e.start() == v1
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&& e.end() == v0
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)
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)
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{
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return edgeI;
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}
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}
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FatalErrorIn("findEdge(..)") << "Cannot find edge with labels " << v0
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<< ' ' << v1 << " in candidates " << edgeLabels
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<< " with vertices:" << UIndirectList<edge>(surf.edges(), edgeLabels)()
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<< abort(FatalError);
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return -1;
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}
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// Get the other edge connected to pointI on faceI.
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label otherEdge
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(
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const triSurface& surf,
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const label faceI,
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const label otherEdgeI,
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const label pointI
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)
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{
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const labelList& fEdges = surf.faceEdges()[faceI];
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forAll(fEdges, i)
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{
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label edgeI = fEdges[i];
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const edge& e = surf.edges()[edgeI];
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if
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(
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edgeI != otherEdgeI
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&& (
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e.start() == pointI
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|| e.end() == pointI
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)
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)
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{
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return edgeI;
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}
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}
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FatalErrorIn("otherEdge(..)") << "Cannot find other edge on face " << faceI
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<< " verts:" << surf.localPoints()[faceI]
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<< " connected to point " << pointI
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<< " faceEdges:" << UIndirectList<edge>(surf.edges(), fEdges)()
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<< abort(FatalError);
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return -1;
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}
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// Starting from startPoint on startEdge on startFace walk along border
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// and insert faces along the way. Walk keeps always one point or one edge
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// on the border line.
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void walkSplitLine
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(
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const triSurface& surf,
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const boolList& borderEdge,
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const labelList& borderPoint,
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const label startFaceI,
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const label startEdgeI, // is border edge
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const label startPointI, // is border point
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Map<label>& faceToEdge,
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Map<label>& faceToPoint
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)
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{
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label faceI = startFaceI;
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label edgeI = startEdgeI;
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label pointI = startPointI;
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do
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{
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//
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// Stick to pointI and walk face-edge-face until back on border edge.
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//
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do
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{
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// Cross face to next edge.
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edgeI = otherEdge(surf, faceI, edgeI, pointI);
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if (borderEdge[edgeI])
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{
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if (!faceToEdge.insert(faceI, edgeI))
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{
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// Was already visited.
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return;
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}
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else
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{
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// First visit to this borderEdge. We're back on borderline.
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break;
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}
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}
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else if (!faceToPoint.insert(faceI, pointI))
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{
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// Was already visited.
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return;
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}
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// Cross edge to other face
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const labelList& eFaces = surf.edgeFaces()[edgeI];
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if (eFaces.size() != 2)
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{
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FatalErrorIn("walkSplitPoint(..)")
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<< "Can only handle edges with 2 or 4 edges for now."
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<< abort(FatalError);
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}
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if (eFaces[0] == faceI)
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{
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faceI = eFaces[1];
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}
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else if (eFaces[1] == faceI)
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{
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faceI = eFaces[0];
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}
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else
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{
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FatalErrorIn("walkSplitPoint(..)") << abort(FatalError);
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}
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}
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while (true);
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//
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// Back on border edge. Cross to other point on edge.
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//
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pointI = surf.edges()[edgeI].otherVertex(pointI);
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if (borderPoint[pointI] == -1)
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{
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return;
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}
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}
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while (true);
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}
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// Find second face which is from same surface i.e. has points on the
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// shared edge in reverse order.
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label sharedFace
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(
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const triSurface& surf,
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const label firstFaceI,
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const label sharedEdgeI
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)
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{
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// Find ordering of face points in edge.
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const edge& e = surf.edges()[sharedEdgeI];
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const labelledTri& f = surf.localFaces()[firstFaceI];
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label startIndex = findIndex(f, e.start());
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// points in face in same order as edge
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bool edgeOrder = (f[f.fcIndex(startIndex)] == e.end());
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// Get faces using edge in sorted order. (sorted such that walking
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// around them in anti-clockwise order corresponds to edge vector
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// acc. to right-hand rule)
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const labelList& eFaces = surf.sortedEdgeFaces()[sharedEdgeI];
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// Get position of face in sorted edge faces
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label faceIndex = findIndex(eFaces, firstFaceI);
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if (edgeOrder)
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{
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// Get face before firstFaceI
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return eFaces[eFaces.rcIndex(faceIndex)];
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}
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else
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{
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// Get face after firstFaceI
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return eFaces[eFaces.fcIndex(faceIndex)];
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}
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}
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// Calculate (inward pointing) normals on edges shared by faces in faceToEdge and
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// averages them to pointNormals.
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void calcPointVecs
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(
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const triSurface& surf,
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const Map<label>& faceToEdge,
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const Map<label>& faceToPoint,
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vectorField& borderPointVec
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)
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{
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const labelListList& sortedEdgeFaces = surf.sortedEdgeFaces();
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const edgeList& edges = surf.edges();
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const pointField& points = surf.localPoints();
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boolList edgeDone(surf.nEdges(), false);
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for
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(
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Map<label>::const_iterator iter = faceToEdge.begin();
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iter != faceToEdge.end();
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++iter
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)
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{
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label edgeI = iter();
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if (!edgeDone[edgeI])
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{
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edgeDone[edgeI] = true;
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// Get the two connected faces in sorted order
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// Note: should have stored this when walking ...
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label face0I = -1;
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label face1I = -1;
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const labelList& eFaces = sortedEdgeFaces[edgeI];
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forAll(eFaces, i)
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{
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label faceI = eFaces[i];
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if (faceToEdge.found(faceI))
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{
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if (face0I == -1)
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{
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face0I = faceI;
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}
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else if (face1I == -1)
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{
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face1I = faceI;
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break;
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}
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}
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}
|
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if (face0I == -1 && face1I == -1)
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{
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Info<< "Writing surface to errorSurf.ftr" << endl;
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surf.write("errorSurf.ftr");
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FatalErrorIn("calcPointVecs(..)")
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<< "Cannot find two faces using border edge " << edgeI
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<< " verts:" << edges[edgeI]
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<< " eFaces:" << eFaces << endl
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<< "face0I:" << face0I
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<< " face1I:" << face1I << nl
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<< "faceToEdge:" << faceToEdge << nl
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<< "faceToPoint:" << faceToPoint
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<< "Written surface to errorSurf.ftr"
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<< abort(FatalError);
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}
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// Now we have edge and the two faces in counter-clockwise order
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// as seen from edge vector. Calculate normal.
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const edge& e = edges[edgeI];
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vector eVec = e.vec(points);
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// Determine vector as average of the vectors in the two faces.
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// If there is only one face available use only one vector.
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vector midVec(vector::zero);
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if (face0I != -1)
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{
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label v0 = triSurfaceTools::oppositeVertex(surf, face0I, edgeI);
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vector e0 = (points[v0] - points[e.start()]) ^ eVec;
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e0 /= mag(e0);
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midVec = e0;
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}
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if (face1I != -1)
|
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{
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label v1 = triSurfaceTools::oppositeVertex(surf, face1I, edgeI);
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vector e1 = (points[e.start()] - points[v1]) ^ eVec;
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e1 /= mag(e1);
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midVec += e1;
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}
|
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scalar magMidVec = mag(midVec);
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if (magMidVec > SMALL)
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{
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midVec /= magMidVec;
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|
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// Average to pointVec
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borderPointVec[e.start()] += midVec;
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borderPointVec[e.end()] += midVec;
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}
|
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}
|
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}
|
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}
|
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|
|
|
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// Renumbers vertices (of triangles in faceToEdge) of which the pointMap is
|
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// not -1.
|
|
void renumberFaces
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(
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const triSurface& surf,
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const labelList& pointMap,
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const Map<label>& faceToEdge,
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List<labelledTri>& newTris
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)
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{
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for
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(
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Map<label>::const_iterator iter = faceToEdge.begin();
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iter != faceToEdge.end();
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++iter
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)
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{
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label faceI = iter.key();
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const labelledTri& f = surf.localFaces()[faceI];
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forAll(f, fp)
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{
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if (pointMap[f[fp]] != -1)
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{
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newTris[faceI][fp] = pointMap[f[fp]];
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}
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}
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}
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}
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// Split all borderEdges that don't have borderPoint. Return true if split
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// anything.
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bool splitBorderEdges
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(
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triSurface& surf,
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const boolList& borderEdge,
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const labelList& borderPoint
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)
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{
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labelList edgesToBeSplit(surf.nEdges());
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label nSplit = 0;
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forAll(borderEdge, edgeI)
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{
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if (borderEdge[edgeI])
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{
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const edge& e = surf.edges()[edgeI];
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if (borderPoint[e.start()] == -1 && borderPoint[e.end()] == -1)
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{
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// None of the points of the edge is borderPoint. Split edge
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// to introduce border point.
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edgesToBeSplit[nSplit++] = edgeI;
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}
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}
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}
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edgesToBeSplit.setSize(nSplit);
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if (nSplit > 0)
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{
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Info<< "Splitting surface along " << nSplit << " borderEdges that don't"
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<< " neighbour other borderEdges" << nl << endl;
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surf = triSurfaceTools::greenRefine(surf, edgesToBeSplit);
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return true;
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}
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else
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{
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Info<< "No edges to be split" <<nl << endl;
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return false;
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}
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}
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// Main program:
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int main(int argc, char *argv[])
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{
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argList::noParallel();
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argList::validArgs.clear();
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argList::validArgs.append("surface file");
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argList::validArgs.append("output surface file");
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argList::validOptions.insert("debug", "");
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argList args(argc, argv);
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fileName inSurfName(args.additionalArgs()[0]);
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fileName outSurfName(args.additionalArgs()[1]);
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bool debug = args.optionFound("debug");
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Info<< "Reading surface from " << inSurfName << endl;
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triSurface surf(inSurfName);
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// Make sure sortedEdgeFaces is calculated correctly
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testSortedEdgeFaces(surf);
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// Get all quad connected edges. These are seen as borders when walking.
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boolList borderEdge(surf.nEdges(), false);
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markBorderEdges(debug, surf, borderEdge);
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// Points on two sides connected to borderEdges are called borderPoints and
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// will be duplicated. borderPoint contains label of newly introduced vertex.
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labelList borderPoint(surf.nPoints(), -1);
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markBorderPoints(debug, surf, borderEdge, borderPoint);
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// Split edges where there would be no borderPoint to duplicate.
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splitBorderEdges(surf, borderEdge, borderPoint);
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|
|
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Info<< "Writing split surface to " << outSurfName << nl << endl;
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surf.write(outSurfName);
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Info<< "Finished writing surface to " << outSurfName << nl << endl;
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|
|
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// Last iteration values.
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label nOldBorderEdges = -1;
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label nOldBorderPoints = -1;
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label iteration = 0;
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do
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{
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// Redo borderEdge/borderPoint calculation.
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boolList borderEdge(surf.nEdges(), false);
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label nBorderEdges = markBorderEdges(debug, surf, borderEdge);
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if (nBorderEdges == 0)
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{
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Info<< "Found no border edges. Exiting." << nl << nl;
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break;
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}
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// Label of newly introduced duplicate.
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labelList borderPoint(surf.nPoints(), -1);
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label nBorderPoints =
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markBorderPoints
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(
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debug,
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surf,
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borderEdge,
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borderPoint
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);
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if (nBorderPoints == 0)
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{
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Info<< "Found no border points. Exiting." << nl << nl;
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break;
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}
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Info<< "Found:\n"
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<< " border edges :" << nBorderEdges << nl
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<< " border points:" << nBorderPoints << nl
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<< endl;
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if
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(
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nBorderPoints == nOldBorderPoints
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&& nBorderEdges == nOldBorderEdges
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)
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{
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Info<< "Stopping since number of border edges and point is same"
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<< " as in previous iteration" << nl << endl;
|
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break;
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}
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//
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// Define splitLine as a series of connected borderEdges. Find start
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// of one (as edge and point on edge)
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//
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label startEdgeI = -1;
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label startPointI = -1;
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forAll(borderEdge, edgeI)
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{
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if (borderEdge[edgeI])
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{
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const edge& e = surf.edges()[edgeI];
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if ((borderPoint[e[0]] != -1) && (borderPoint[e[1]] == -1))
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{
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startEdgeI = edgeI;
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startPointI = e[0];
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break;
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}
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else if ((borderPoint[e[0]] == -1) && (borderPoint[e[1]] != -1))
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{
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startEdgeI = edgeI;
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startPointI = e[1];
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break;
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}
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}
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}
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if (startEdgeI == -1)
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{
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Info<< "Cannot find starting point of splitLine\n" << endl;
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break;
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}
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// Pick any face using edge to start from.
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const labelList& eFaces = surf.edgeFaces()[startEdgeI];
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label firstFaceI = eFaces[0];
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// Find second face which is from same surface i.e. has outwards
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// pointing normal as well (actually bit more complex than this)
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label secondFaceI = sharedFace(surf, firstFaceI, startEdgeI);
|
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Info<< "Starting local walk from:" << endl
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<< " edge :" << startEdgeI << endl
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<< " point:" << startPointI << endl
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<< " face0:" << firstFaceI << endl
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<< " face1:" << secondFaceI << endl
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<< endl;
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// From face on border edge to edge.
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Map<label> faceToEdge(2*nBorderEdges);
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// From face connected to border point (but not border edge) to point.
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Map<label> faceToPoint(2*nBorderPoints);
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faceToEdge.insert(firstFaceI, startEdgeI);
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walkSplitLine
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(
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surf,
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borderEdge,
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borderPoint,
|
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firstFaceI,
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startEdgeI,
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startPointI,
|
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faceToEdge,
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faceToPoint
|
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);
|
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faceToEdge.insert(secondFaceI, startEdgeI);
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walkSplitLine
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(
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surf,
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borderEdge,
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borderPoint,
|
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|
secondFaceI,
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startEdgeI,
|
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startPointI,
|
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faceToEdge,
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faceToPoint
|
|
);
|
|
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|
Info<< "Finished local walk and visited" << nl
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<< " border edges :" << faceToEdge.size() << nl
|
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<< " border points(but not edges):" << faceToPoint.size() << nl
|
|
<< endl;
|
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|
|
if (debug)
|
|
{
|
|
dumpFaces("faceToEdge.obj", surf, faceToEdge);
|
|
dumpFaces("faceToPoint.obj", surf, faceToPoint);
|
|
}
|
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|
|
//
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// Create coordinates for borderPoints by duplicating the existing
|
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// point and then slightly shifting it inwards. To determine the
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// inwards direction get the average normal of both connectedFaces on
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// the edge and then interpolate this to the (border)point.
|
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//
|
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vectorField borderPointVec(surf.nPoints(), vector(GREAT, GREAT, GREAT));
|
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|
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calcPointVecs(surf, faceToEdge, faceToPoint, borderPointVec);
|
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|
|
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// New position. Start off from copy of old points.
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pointField newPoints(surf.localPoints());
|
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newPoints.setSize(newPoints.size() + nBorderPoints);
|
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forAll(borderPoint, pointI)
|
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{
|
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label newPointI = borderPoint[pointI];
|
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|
if (newPointI != -1)
|
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{
|
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scalar minLen = minEdgeLen(surf, pointI);
|
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|
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vector n = borderPointVec[pointI];
|
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n /= mag(n);
|
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|
|
newPoints[newPointI] = newPoints[pointI] + 0.1 * minLen * n;
|
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}
|
|
}
|
|
|
|
|
|
//
|
|
// Renumber all faces in connectedFaces
|
|
//
|
|
|
|
// Start off from copy of faces.
|
|
List<labelledTri> newTris(surf.size());
|
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|
|
forAll(surf, faceI)
|
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{
|
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newTris[faceI] = surf.localFaces()[faceI];
|
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|
|
newTris[faceI].region() = surf[faceI].region();
|
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}
|
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|
|
// Renumber all faces in faceToEdge
|
|
renumberFaces(surf, borderPoint, faceToEdge, newTris);
|
|
// Renumber all faces in faceToPoint
|
|
renumberFaces(surf, borderPoint, faceToPoint, newTris);
|
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|
|
|
|
// Check if faces use unmoved points.
|
|
forAll(newTris, faceI)
|
|
{
|
|
const labelledTri& f = newTris[faceI];
|
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|
|
forAll(f, fp)
|
|
{
|
|
const point& pt = newPoints[f[fp]];
|
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|
|
if (mag(pt) >= GREAT/2)
|
|
{
|
|
Info<< "newTri:" << faceI << " verts:" << f
|
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<< " vert:" << f[fp] << " point:" << pt << endl;
|
|
}
|
|
}
|
|
}
|
|
|
|
|
|
surf = triSurface(newTris, surf.patches(), newPoints);
|
|
|
|
if (debug || (iteration != 0 && (iteration % 20) == 0))
|
|
{
|
|
Info<< "Writing surface to " << outSurfName << nl << endl;
|
|
|
|
surf.write(outSurfName);
|
|
|
|
Info<< "Finished writing surface to " << outSurfName << nl << endl;
|
|
}
|
|
|
|
// Save prev iteration values.
|
|
nOldBorderEdges = nBorderEdges;
|
|
nOldBorderPoints = nBorderPoints;
|
|
|
|
iteration++;
|
|
}
|
|
while (true);
|
|
|
|
Info<< "Writing final surface to " << outSurfName << nl << endl;
|
|
|
|
surf.write(outSurfName);
|
|
|
|
Info << "End\n" << endl;
|
|
|
|
return 0;
|
|
}
|
|
|
|
|
|
// ************************************************************************* //
|