/*---------------------------------------------------------------------------*\ ========= | \\ / 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 Extrude mesh from existing patch (by default outwards facing normals; optional flips faces) or from patch read from file. Note: Merges close points so be careful. Type of extrusion prescribed by run-time selectable model. \*---------------------------------------------------------------------------*/ #include "argList.H" #include "Time.H" #include "dimensionedTypes.H" #include "IFstream.H" #include "faceMesh.H" #include "mapPolyMesh.H" #include "directTopoChange.H" #include "polyTopoChange.H" #include "polyTopoChanger.H" #include "edgeCollapser.H" #include "mathematicalConstants.H" #include "globalMeshData.H" #include "perfectInterface.H" #include "extrudedMesh.H" #include "extrudeModel.H" using namespace Foam; // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // // Main program: int main(int argc, char *argv[]) { # include "setRootCase.H" # include "createTimeExtruded.H" autoPtr meshPtr(NULL); IOdictionary dict ( IOobject ( "extrudeProperties", runTimeExtruded.constant(), runTimeExtruded, IOobject::MUST_READ ) ); autoPtr model(extrudeModel::New(dict)); const word sourceType(dict.lookup("constructFrom")); autoPtr fMesh; if (sourceType == "patch") { fileName sourceCasePath(dict.lookup("sourceCase")); sourceCasePath.expand(); fileName sourceRootDir = sourceCasePath.path(); fileName sourceCaseDir = sourceCasePath.name(); word patchName(dict.lookup("sourcePatch")); Info<< "Extruding patch " << patchName << " on mesh " << sourceCasePath << nl << endl; Time runTime ( Time::controlDictName, sourceRootDir, sourceCaseDir ); #include "createPolyMesh.H" label patchID = mesh.boundaryMesh().findPatchID(patchName); if (patchID == -1) { FatalErrorIn(args.executable()) << "Cannot find patch " << patchName << " in the source mesh.\n" << "Valid patch names are " << mesh.boundaryMesh().names() << exit(FatalError); } const polyPatch& pp = mesh.boundaryMesh()[patchID]; fMesh.reset(new faceMesh(pp.localFaces(), pp.localPoints())); { fileName surfName(runTime.path()/patchName + ".sMesh"); Info<< "Writing patch as surfaceMesh to " << surfName << nl << endl; OFstream os(surfName); os << fMesh() << nl; } } else if (sourceType == "surface") { // Read from surface fileName surfName(dict.lookup("surface")); Info<< "Extruding surfaceMesh read from file " << surfName << nl << endl; IFstream is(surfName); fMesh.reset(new faceMesh(is)); Info<< "Read patch from file " << surfName << nl << endl; } else { FatalErrorIn(args.executable()) << "Illegal 'constructFrom' specification. Should either be " << "patch or surface." << exit(FatalError); } Switch flipNormals(dict.lookup("flipNormals")); if (flipNormals) { Info<< "Flipping faces." << nl << endl; faceList faces(fMesh().size()); forAll(faces, i) { faces[i] = fMesh()[i].reverseFace(); } fMesh.reset(new faceMesh(faces, fMesh().localPoints())); } Info<< "Extruding patch with :" << nl << " points : " << fMesh().points().size() << nl << " faces : " << fMesh().size() << nl << " normals[0] : " << fMesh().faceNormals()[0] << nl << endl; extrudedMesh mesh ( IOobject ( extrudedMesh::defaultRegion, runTimeExtruded.constant(), runTimeExtruded ), fMesh(), model() ); const boundBox& bb = mesh.globalData().bb(); const vector span = bb.span(); const scalar mergeDim = 1e-4 * bb.minDim(); Info<< "Mesh bounding box : " << bb << nl << " with span : " << span << nl << "Merge distance : " << mergeDim << nl << endl; const polyBoundaryMesh& patches = mesh.boundaryMesh(); const label origPatchID = patches.findPatchID("originalPatch"); const label otherPatchID = patches.findPatchID("otherSide"); if (origPatchID == -1 || otherPatchID == -1) { FatalErrorIn(args.executable()) << "Cannot find patch originalPatch or otherSide." << nl << "Valid patches are " << patches.names() << exit(FatalError); } // Collapse edges // ~~~~~~~~~~~~~~ { Info<< "Collapsing edges < " << mergeDim << " ..." << nl << endl; // Edge collapsing engine edgeCollapser collapser(mesh); const edgeList& edges = mesh.edges(); const pointField& points = mesh.points(); forAll(edges, edgeI) { const edge& e = edges[edgeI]; scalar d = e.mag(points); if (d < mergeDim) { Info<< "Merging edge " << e << " since length " << d << " << " << mergeDim << nl; // Collapse edge to e[0] collapser.collapseEdge(edgeI, e[0]); } } // Topo change container directTopoChange meshMod(mesh); // Put all modifications into meshMod bool anyChange = collapser.setRefinement(meshMod); if (anyChange) { // Construct new mesh from directTopoChange. autoPtr map = meshMod.changeMesh(mesh, false); // Update fields mesh.updateMesh(map); // Move mesh (if inflation used) if (map().hasMotionPoints()) { mesh.movePoints(map().preMotionPoints()); } } } // Merging front and back patch faces // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Switch mergeFaces(dict.lookup("mergeFaces")); if (mergeFaces) { Info<< "Assuming full 360 degree axisymmetric case;" << " stitching faces on patches " << patches[origPatchID].name() << " and " << patches[otherPatchID].name() << " together ..." << nl << endl; polyTopoChanger stitcher(mesh); stitcher.setSize(1); // Make list of masterPatch faces labelList isf(patches[origPatchID].size()); forAll (isf, i) { isf[i] = patches[origPatchID].start() + i; } const word cutZoneName("originalCutFaceZone"); List fz ( 1, new faceZone ( cutZoneName, isf, boolList(isf.size(), false), 0, mesh.faceZones() ) ); mesh.addZones(List(0), fz, List(0)); // Add the perfect interface mesh modifier stitcher.set ( 0, new perfectInterface ( "couple", 0, stitcher, cutZoneName, patches[origPatchID].name(), patches[otherPatchID].name() ) ); // Execute all polyMeshModifiers autoPtr morphMap = stitcher.changeMesh(); mesh.movePoints(morphMap->preMotionPoints()); } if (!mesh.write()) { FatalErrorIn(args.executable()) << "Failed writing mesh" << exit(FatalError); } Info << "End\n" << endl; return 0; } // ************************************************************************* //