/*--------------------------------*- C++ -*----------------------------------*\
========= |
\\ / F ield | foam-extend: Open Source CFD
\\ / O peration |
\\ / A nd | For copyright notice see file Copyright
\\/ M anipulation |
-------------------------------------------------------------------------------
License
This file is part of foam-extend.
foam-extend 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.
foam-extend 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 foam-extend. If not, see .
Application
ansysToFoam
Description
Converts an ANSYS input mesh file, exported from I-DEAS, to FOAM format.
\*---------------------------------------------------------------------------*/
%{
#undef yyFlexLexer
/* ------------------------------------------------------------------------- *\
------ local definitions
\* ------------------------------------------------------------------------- */
#include
// For EOF only
#include
#include "scalar.H"
#include "IStringStream.H"
using namespace Foam;
#include "argList.H"
#include "objectRegistry.H"
#include "Time.H"
#include "polyMesh.H"
#include "emptyPolyPatch.H"
#include "preservePatchTypes.H"
#include "cellShape.H"
#include "cellModeller.H"
#include "SLList.H"
#include "SLPtrList.H"
SLList slPoints;
SLList slPointMap;
label maxNodei = 0;
SLPtrList slCellLabels;
SLList slCellMap;
SLList slCellType;
label maxCelli = 0;
PtrList > slPatchCells;
PtrList > slPatchCellFaces;
// Cell types
Map cellTypes;
label currentTypei = -1;
// Dummy yywrap to keep yylex happy at compile time.
// It is called by yylex but is not used as the mechanism to change file.
// See <>
#if YY_FLEX_SUBMINOR_VERSION < 34
extern "C" int yywrap()
#else
int yyFlexLexer::yywrap()
#endif
{
return 1;
}
%}
one_space [ \t\f\r]
space {one_space}*
some_space {one_space}+
cspace ","{space}
alpha [_A-Za-z]
digit [0-9]
identifier {alpha}({alpha}|{digit})*
integer {digit}+
label [1-9]{digit}*
exponent_part [eE][-+]?{digit}+
fractional_constant [-+]?(({digit}*"."{digit}+)|({digit}+"."?))
floatNum (({fractional_constant}{exponent_part}?)|({digit}+{exponent_part}))
x {floatNum}
y {floatNum}
z {floatNum}
value {floatNum}
node ^{space}"N"{cspace}
element ^{space}"EN"{cspace}
bface ^{space}"SFE"{cspace}
elementTypeName ^{space}"ET"{cspace}
elementType ^{space}"TYPE"{cspace}
%%
%{
labelList labels(8);
%}
/* ------------------------------------------------------------------------- *\
------ Start Lexing ------
\* ------------------------------------------------------------------------- */
{node}{label}{cspace}{x}{cspace}{y}{cspace}{z}{space}\n {
IStringStream nodeStream(YYText());
char tag, c;
label nodei;
point node;
nodeStream
>> tag
>> c >> nodei
>> c >> node.x()
>> c >> node.y()
>> c >> node.z();
if (nodei > maxNodei) maxNodei = nodei;
slPointMap.append(nodei);
slPoints.append(node);
}
{element}{label}{cspace}{label}{cspace}{label}{cspace}{label}{cspace}{label}{cspace}{label}{cspace}{label}{cspace}{label}{cspace}{label}{space}\n {
IStringStream elementStream(YYText());
char tag, c;
label celli;
elementStream
>> tag >> tag
>> c >> celli
>> c >> labels[0]
>> c >> labels[1]
>> c >> labels[2]
>> c >> labels[3]
>> c >> labels[4]
>> c >> labels[5]
>> c >> labels[6]
>> c >> labels[7];
if (celli > maxCelli) maxCelli = celli;
slCellMap.append(celli);
slCellLabels.append(new labelList(labels));
slCellType.append(currentTypei);
}
{bface}{label}{cspace}{label}{cspace}{identifier}{cspace}{integer}{cspace}{value}{space}\n {
IStringStream bfaceStream(YYText());
char tag, c;
label elementi;
label facei;
scalar indexValue, unknown;
bfaceStream
>> tag >> tag >> tag
>> c >> elementi
>> c >> facei
>> c >> tag >> tag >> tag >> tag
>> c >> unknown
>> c >> indexValue;
label patchi = label(indexValue);
if (patchi > slPatchCells.size())
{
slPatchCells.setSize(patchi);
forAll(slPatchCells, i)
{
if (!slPatchCells(i))
{
slPatchCells.set(i, new SLList);
}
}
}
if (patchi > slPatchCellFaces.size())
{
slPatchCellFaces.setSize(patchi);
forAll(slPatchCells, i)
{
if (!slPatchCellFaces(i))
{
slPatchCellFaces.set(i, new SLList);
}
}
}
slPatchCells[patchi-1].append(elementi);
slPatchCellFaces[patchi-1].append(facei);
}
{elementTypeName}{label}{cspace}{identifier}{space}\n {
IStringStream elementStream(YYText());
char tag,c;
label cellTypei;
word cellTypeName;
elementStream
>> tag >> tag // skip 'ET'
>> c >> cellTypei
>> c >> cellTypeName;
Info<< "Read typeName " << cellTypeName
<< " for type " << cellTypei << endl;
cellTypes.insert(cellTypei, cellTypeName);
}
{elementType}{label}{space}\n {
IStringStream elementStream(YYText());
char tag,c;
label cellTypei;
elementStream
>> tag >> tag >> tag >> tag // skip 'TYPE'
>> c >> cellTypei;
currentTypei = cellTypei;
}
/* ------------------------------------------------------------------------- *\
------ Ignore remaining space and \n s. Any other characters are errors.
\* ------------------------------------------------------------------------- */
.|\n {}
/* ------------------------------------------------------------------------- *\
------ On EOF return to previous file, if none exists terminate.
\* ------------------------------------------------------------------------- */
<> {
yyterminate();
}
%%
#include "fileName.H"
#include
using std::ifstream;
label findFace(const polyMesh& mesh, const face& f)
{
const labelList& pFaces = mesh.pointFaces()[f[0]];
forAll(pFaces, i)
{
label faceI = pFaces[i];
if (mesh.faces()[faceI] == f)
{
return faceI;
}
}
FatalErrorIn("findFace(const polyMesh&, const face&)")
<< "Cannot find a face matching " << f
<< exit(FatalError);
return -1;
}
int main(int argc, char *argv[])
{
argList::noParallel();
argList::validArgs.append("ANSYS input file");
argList::validOptions.insert("scale", "scale factor");
argList args(argc, argv);
if (!args.check())
{
FatalError.exit();
}
scalar scaleFactor = 1.0;
args.optionReadIfPresent("scale", scaleFactor);
# include "createTime.H"
fileName ansysFile(args.additionalArgs()[0]);
ifstream ansysStream(ansysFile.c_str());
if (!ansysStream)
{
FatalErrorIn("ansysToFoam::main(int argc, char *argv[])")
<< args.executable()
<< ": file " << ansysFile << " not found"
<< exit(FatalError);
}
yyFlexLexer lexer(&ansysStream);
while (lexer.yylex() != 0)
{}
Info<< "Creating points" << endl;
pointField points(slPoints.size());
label i = 0;
forAllConstIter(SLList, slPoints, pointIter)
{
// Scale points for the given scale factor
points[i++] = scaleFactor * pointIter();
}
labelList pointMap(maxNodei+1);
i = 0;
forAllConstIter(SLList, slPointMap, pointMapIter)
{
pointMap[pointMapIter()] = i++;
}
Info<< "Creating cells" << endl;
labelList cellMap(maxCelli+1);
i = 0;
forAllConstIter(SLList, slCellMap, cellMapIter)
{
cellMap[cellMapIter()] = i++;
}
const cellModel& hex = *(cellModeller::lookup("hex"));
const cellModel& prism = *(cellModeller::lookup("prism"));
const cellModel& pyr = *(cellModeller::lookup("pyr"));
const cellModel& tet = *(cellModeller::lookup("tet"));
labelList labelsHex(8);
labelList labelsPrism(6);
labelList labelsPyramid(5);
labelList labelsTet(4);
cellShapeList cellShapes(slCellLabels.size());
label nCells = 0;
forAllConstIter(SLPtrList, slCellLabels, cellIter)
{
if // Tetrahedron
(
cellIter()[2] == cellIter()[3]
&& cellIter()[4] == cellIter()[5]
&& cellIter()[5] == cellIter()[6]
&& cellIter()[6] == cellIter()[7]
)
{
labelsTet[0] = pointMap[cellIter()[0] ];
labelsTet[1] = pointMap[cellIter()[1] ];
labelsTet[2] = pointMap[cellIter()[2] ];
labelsTet[3] = pointMap[cellIter()[4] ];
cellShapes[nCells++] = cellShape(tet, labelsTet);
}
else if // Square-based pyramid
(
cellIter()[4] == cellIter()[5]
&& cellIter()[5] == cellIter()[6]
&& cellIter()[6] == cellIter()[7]
)
{
labelsPyramid[0] = pointMap[cellIter()[0] ];
labelsPyramid[1] = pointMap[cellIter()[1] ];
labelsPyramid[2] = pointMap[cellIter()[2] ];
labelsPyramid[3] = pointMap[cellIter()[3] ];
labelsPyramid[4] = pointMap[cellIter()[4] ];
cellShapes[nCells++] = cellShape(pyr, labelsPyramid);
}
else if // Triangular prism
(
cellIter()[2] == cellIter()[3]
&& cellIter()[6] == cellIter()[7]
)
{
labelsPrism[0] = pointMap[cellIter()[0] ];
labelsPrism[1] = pointMap[cellIter()[1] ];
labelsPrism[2] = pointMap[cellIter()[2] ];
labelsPrism[3] = pointMap[cellIter()[4] ];
labelsPrism[4] = pointMap[cellIter()[5] ];
labelsPrism[5] = pointMap[cellIter()[6] ];
cellShapes[nCells++] = cellShape(prism, labelsPrism);
}
else // Hex
{
labelsHex[0] = pointMap[cellIter()[0] ];
labelsHex[1] = pointMap[cellIter()[1] ];
labelsHex[2] = pointMap[cellIter()[2] ];
labelsHex[3] = pointMap[cellIter()[3] ];
labelsHex[4] = pointMap[cellIter()[4] ];
labelsHex[5] = pointMap[cellIter()[5] ];
labelsHex[6] = pointMap[cellIter()[6] ];
labelsHex[7] = pointMap[cellIter()[7] ];
cellShapes[nCells++] = cellShape(hex, labelsHex);
}
}
const word defaultFacesName = "defaultFaces";
word defaultFacesType = emptyPolyPatch::typeName;
// Create dummy mesh just to find out what are internal/external
// faces
autoPtr dummyMesh
(
new polyMesh
(
IOobject
(
"dummyMesh",
runTime.constant(),
runTime
),
xferCopy(points),
cellShapes,
faceListList(0),
wordList(0),
wordList(0),
defaultFacesName,
defaultFacesType,
wordList(0)
)
);
// Warning: tet face order has changed between version 1.9.6 and 2.0
//
label faceIndex[7][6] =
{
{-1, -1, -1, -1, -1, -1}, // 0
{-1, -1, -1, -1, -1, -1}, // 1
{-1, -1, -1, -1, -1, -1}, // 2
{-1, -1, -1, -1, -1, -1}, // 3
{ 3, 2, 0, -1, 1, -1}, // tet (version 2.0)
{ 0, 4, 3, -1, 2, 1}, // prism
{ 4, 2, 1, 3, 0, 5}, // hex
};
Info<< "Creating boundary patches" << endl;
faceListList boundary(slPatchCells.size());
wordList patchNames(slPatchCells.size());
forAll(slPatchCells, patchI)
{
SLList patchFaces;
SLList::iterator cellIter(slPatchCells[patchI].begin());
SLList::iterator faceIter(slPatchCellFaces[patchI].begin());
for
(
;
cellIter != slPatchCells[patchI].end()
&& faceIter != slPatchCellFaces[patchI].end();
++cellIter, ++faceIter
)
{
const cellShape& shape = cellShapes[cellMap[cellIter()]];
patchFaces.append
(
shape.faces()
[
faceIndex
[shape.nFaces()]
[faceIter()-1]
]
);
}
boundary[patchI] = patchFaces;
patchNames[patchI] = word("patch") + name(patchI + 1);
}
//
// Lookup the face labels for all the boundary faces
//
labelListList boundaryFaceLabels(boundary.size());
forAll(boundary, patchI)
{
const faceList& bFaces = boundary[patchI];
labelList& bFaceLabels = boundaryFaceLabels[patchI];
bFaceLabels.setSize(bFaces.size());
forAll(bFaces, i)
{
bFaceLabels[i] = findFace(dummyMesh(), bFaces[i]);
}
}
// Now split the boundary faces into external and internal faces. All
// faces go into faceZones and external faces go into patches.
List patchFaces(slPatchCells.size());
labelList patchNFaces(slPatchCells.size(), 0);
forAll(boundary, patchI)
{
const faceList& bFaces = boundary[patchI];
const labelList& bFaceLabels = boundaryFaceLabels[patchI];
patchFaces[patchI].setSize(bFaces.size());
forAll(bFaces, i)
{
if (!dummyMesh().isInternalFace(bFaceLabels[i]))
{
patchFaces[patchI][patchNFaces[patchI]++] = bFaces[i];
}
}
patchFaces[patchI].setSize(patchNFaces[patchI]);
Info<< "Patch " << patchI << " named " << patchNames[patchI]
<< ": " << boundary[patchI].size() << " faces" << endl;
}
// We no longer need the dummyMesh
dummyMesh.clear();
Info<< "ansysToFoam: " << endl
<< "Ansys file format does not provide information about the type of "
<< "the patch (eg. wall, symmetry plane, cyclic etc)." << endl
<< "All the patches have been created "
<< "as type patch. Please reset after mesh conversion as necessary."
<< endl;
PtrList patchDicts;
preservePatchTypes
(
runTime,
runTime.constant(),
polyMesh::meshSubDir,
patchNames,
patchDicts,
defaultFacesName,
defaultFacesType
);
// Add information to dictionary
forAll(patchNames, patchI)
{
if (!patchDicts.set(patchI))
{
patchDicts.set(patchI, new dictionary());
}
// Add but not overwrite
patchDicts[patchI].add("type", polyPatch::typeName, false);
}
polyMesh pShapeMesh
(
IOobject
(
polyMesh::defaultRegion,
runTime.constant(),
runTime
),
xferMove(points),
cellShapes,
patchFaces,
patchNames,
patchDicts,
defaultFacesName,
defaultFacesType
);
if (cellTypes.size() > 0 || patchNames.size() > 0)
{
DynamicList pz;
DynamicList fz;
DynamicList cz;
// FaceZones
forAll(boundaryFaceLabels, patchI)
{
if (boundaryFaceLabels[patchI].size())
{
// Re-do the boundaryFaceLabels since the boundary face
// labels will be different on the pShapeMesh.
const faceList& bFaces = boundary[patchI];
labelList& bFaceLabels = boundaryFaceLabels[patchI];
forAll(bFaceLabels, i)
{
bFaceLabels[i] = findFace(pShapeMesh, bFaces[i]);
}
Info<< "Creating faceZone " << patchNames[patchI]
<< " with " << bFaceLabels.size() << " faces" << endl;
fz.append
(
new faceZone
(
patchNames[patchI],
bFaceLabels,
boolList(bFaceLabels.size(), false),
fz.size(),
pShapeMesh.faceZones()
)
);
}
}
// CellZones
labelList types = cellTypes.toc();
forAll(types, j)
{
label cellType = types[j];
// Pick up cells in zone
DynamicList addr;
SLList::iterator cellMapIter = slCellMap.begin();
SLList::iterator typeIter = slCellType.begin();
for
(
;
typeIter != slCellType.end();
++typeIter, ++cellMapIter
)
{
if (typeIter() == cellType)
{
addr.append(cellMap[cellMapIter()]);
}
}
Info<< "Creating cellZone " << cellTypes[cellType]
<< " with " << addr.size() << " cells" << endl;
cz.append
(
new cellZone
(
cellTypes[cellType],
addr,
j,
pShapeMesh.cellZones()
)
);
}
pShapeMesh.addZones(pz, fz, cz);
}
// Set the precision of the points data to 10
IOstream::defaultPrecision(max(10u, IOstream::defaultPrecision()));
Info<< "Writing polyMesh" << endl;
pShapeMesh.write();
Info<< nl << "end" << endl;
return 0;
}
/* ------------------------------------------------------------------------- *\
------ End of ansysToFoam.L
\* ------------------------------------------------------------------------- */