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openfoam/applications/utilities/postProcessing/dataConversion/foamToEnsight/foamToEnsight.C

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/*---------------------------------------------------------------------------*\
========= |
\\ / F ield | OpenFOAM: The Open Source CFD Toolbox
\\ / O peration |
\\ / A nd | Copyright (C) 2011-2016 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 <http://www.gnu.org/licenses/>.
Application
foamToEnsight
Group
grpPostProcessingUtilitie
Description
Translates OpenFOAM data to EnSight format.
An Ensight part is created for the internalMesh and for each patch.
Usage
\b foamToEnsight [OPTION]
Options:
- \par -ascii
Write Ensight data in ASCII format instead of "C Binary"
- \par -patches patchList
Specify particular patches to write.
Specifying an empty list suppresses writing the internalMesh.
- \par -noPatches
Suppress writing any patches.
- \par -faceZones zoneList
Specify faceZones to write, with wildcards
- \par -cellZone zoneName
Specify single cellZone to write (not lagrangian)
Note
Parallel support for cloud data is not supported
- writes to \a EnSight directory to avoid collisions with foamToEnsightParts
\*---------------------------------------------------------------------------*/
#include "argList.H"
#include "timeSelector.H"
#include "IOobjectList.H"
#include "IOmanip.H"
#include "OFstream.H"
#include "volFields.H"
#include "labelIOField.H"
#include "scalarIOField.H"
#include "tensorIOField.H"
#include "ensightMesh.H"
#include "ensightField.H"
#include "ensightParticlePositions.H"
#include "ensightCloudField.H"
#include "fvc.H"
#include "cellSet.H"
#include "fvMeshSubset.H"
#include "memInfo.H"
using namespace Foam;
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
bool inFileNameList
(
const fileNameList& nameList,
const word& name
)
{
forAll(nameList, i)
{
if (nameList[i] == name)
{
return true;
}
}
return false;
}
int main(int argc, char *argv[])
{
timeSelector::addOptions();
#include "addRegionOption.H"
argList::addBoolOption
(
"ascii",
"write in ASCII format instead of 'C Binary'"
);
argList::addBoolOption
(
"nodeValues",
"write values in nodes"
);
argList::addBoolOption
(
"noPatches",
"suppress writing any patches"
);
argList::addOption
(
"patches",
"wordReList",
"specify particular patches to write - eg '(outlet \"inlet.*\")'. "
"An empty list suppresses writing the internalMesh."
);
argList::addOption
(
"faceZones",
"wordReList",
"specify faceZones to write - eg '( slice \"mfp-.*\" )'."
);
argList::addOption
(
"fields",
"wordReList",
"specify fields to export (all by default) - eg '( \"U.*\" )'."
);
argList::addOption
(
"cellZone",
"word",
"specify cellZone to write"
);
#include "setRootCase.H"
// Check options
const bool binary = !args.optionFound("ascii");
const bool nodeValues = args.optionFound("nodeValues");
cpuTime timer;
memInfo mem;
Info<< "Initial memory "
<< mem.update().size() << " kB" << endl;
#include "createTime.H"
instantList Times = timeSelector::select0(runTime, args);
#include "createNamedMesh.H"
// Mesh instance (region0 gets filtered out)
fileName regionPrefix = "";
if (regionName != polyMesh::defaultRegion)
{
regionPrefix = regionName;
}
const label nVolFieldTypes = 10;
const word volFieldTypes[] =
{
volScalarField::typeName,
volVectorField::typeName,
volSphericalTensorField::typeName,
volSymmTensorField::typeName,
volTensorField::typeName,
volScalarField::Internal::typeName,
volVectorField::Internal::typeName,
volSphericalTensorField::Internal::typeName,
volSymmTensorField::Internal::typeName,
volTensorField::Internal::typeName
};
// Path to EnSight directory at case level only
// - For parallel cases, data only written from master
fileName ensightDir = args.rootPath()/args.globalCaseName()/"EnSight";
if (Pstream::master())
{
if (isDir(ensightDir))
{
rmDir(ensightDir);
}
mkDir(ensightDir);
}
// Start of case file header output
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
const word prepend = args.globalCaseName() + '.';
OFstream *ensightCaseFilePtr = nullptr;
if (Pstream::master())
{
fileName caseFileName = prepend + "case";
Info<< nl << "write case: " << caseFileName.c_str() << endl;
// the case file is always ASCII
ensightCaseFilePtr = new OFstream
(
ensightDir/caseFileName,
IOstream::ASCII
);
*ensightCaseFilePtr
<< "FORMAT" << nl
<< "type: ensight gold" << nl << nl;
}
OFstream& ensightCaseFile = *ensightCaseFilePtr;
// Construct the EnSight mesh
const bool selectedPatches = args.optionFound("patches");
wordReList patchPatterns;
if (selectedPatches)
{
patchPatterns = wordReList(args.optionLookup("patches")());
}
const bool selectedZones = args.optionFound("faceZones");
wordReList zonePatterns;
if (selectedZones)
{
zonePatterns = wordReList(args.optionLookup("faceZones")());
}
const bool selectedFields = args.optionFound("fields");
wordReList fieldPatterns;
if (selectedFields)
{
fieldPatterns = wordReList(args.optionLookup("fields")());
}
word cellZoneName;
const bool doCellZone = args.optionReadIfPresent("cellZone", cellZoneName);
fvMeshSubset meshSubsetter(mesh);
if (doCellZone)
{
Info<< "Converting cellZone " << cellZoneName
<< " only (puts outside faces into patch "
<< mesh.boundaryMesh()[0].name()
<< ")" << endl;
const cellZone& cz = mesh.cellZones()[cellZoneName];
cellSet c0(mesh, "c0", labelHashSet(cz));
meshSubsetter.setLargeCellSubset(c0, 0);
}
ensightMesh eMesh
(
(
meshSubsetter.hasSubMesh()
? meshSubsetter.subMesh()
: meshSubsetter.baseMesh()
),
args.optionFound("noPatches"),
selectedPatches,
patchPatterns,
selectedZones,
zonePatterns,
binary
);
// Set Time to the last time before looking for the lagrangian objects
runTime.setTime(Times.last(), Times.size()-1);
IOobjectList objects(mesh, runTime.timeName());
#include "checkMeshMoving.H"
if (meshMoving)
{
Info<< "Detected a moving mesh (multiple polyMesh/points files)."
<< " Writing meshes for every timestep." << endl;
}
wordHashSet allCloudNames;
if (Pstream::master())
{
word geomFileName = prepend + "0000";
// test pre check variable if there is a moving mesh
if (meshMoving)
{
geomFileName = prepend + "****";
}
ensightCaseFile
<< "GEOMETRY" << nl
<< "model: 1 "
<< (geomFileName + ".mesh").c_str() << nl;
}
// Identify if lagrangian data exists at each time, and add clouds
// to the 'allCloudNames' hash set
forAll(Times, timeI)
{
runTime.setTime(Times[timeI], timeI);
fileNameList cloudDirs = readDir
(
runTime.timePath()/regionPrefix/cloud::prefix,
fileName::DIRECTORY
);
forAll(cloudDirs, cloudI)
{
IOobjectList cloudObjs
(
mesh,
runTime.timeName(),
cloud::prefix/cloudDirs[cloudI]
);
IOobject* positionsPtr = cloudObjs.lookup(word("positions"));
if (positionsPtr)
{
allCloudNames.insert(cloudDirs[cloudI]);
}
}
}
HashTable<HashTable<word>> allCloudFields;
forAllConstIter(wordHashSet, allCloudNames, cloudIter)
{
// Add the name of the cloud(s) to the case file header
if (Pstream::master())
{
ensightCaseFile
<< (
"measured: 1 "
+ prepend
+ "****."
+ cloudIter.key()
).c_str()
<< nl;
}
// Create a new hash table for each cloud
allCloudFields.insert(cloudIter.key(), HashTable<word>());
// Identify the new cloud in the hash table
HashTable<HashTable<word>>::iterator newCloudIter =
allCloudFields.find(cloudIter.key());
// Loop over all times to build list of fields and field types
// for each cloud
forAll(Times, timeI)
{
runTime.setTime(Times[timeI], timeI);
IOobjectList cloudObjs
(
mesh,
runTime.timeName(),
cloud::prefix/cloudIter.key()
);
forAllConstIter(IOobjectList, cloudObjs, fieldIter)
{
const IOobject obj = *fieldIter();
if (obj.name() != "positions")
{
// Add field and field type
newCloudIter().insert
(
obj.name(),
obj.headerClassName()
);
}
}
}
}
label nTimeSteps = 0;
forAll(Times, timeIndex)
{
nTimeSteps++;
runTime.setTime(Times[timeIndex], timeIndex);
word timeName = itoa(timeIndex);
word timeFile = prepend + timeName;
Info<< "Translating time = " << runTime.timeName() << nl;
polyMesh::readUpdateState meshState = mesh.readUpdate();
if (timeIndex != 0 && meshSubsetter.hasSubMesh())
{
Info<< "Converting cellZone " << cellZoneName
<< " only (puts outside faces into patch "
<< mesh.boundaryMesh()[0].name()
<< ")" << endl;
const cellZone& cz = mesh.cellZones()[cellZoneName];
cellSet c0(mesh, "c0", labelHashSet(cz));
meshSubsetter.setLargeCellSubset(c0, 0);
}
if (meshState != polyMesh::UNCHANGED)
{
eMesh.correct();
}
if (timeIndex == 0 || meshMoving)
{
eMesh.write
(
ensightDir,
prepend,
timeIndex,
meshMoving,
ensightCaseFile
);
}
// Start of field data output
// ~~~~~~~~~~~~~~~~~~~~~~~~~~
if (timeIndex == 0 && Pstream::master())
{
ensightCaseFile<< nl << "VARIABLE" << nl;
}
// Cell field data output
// ~~~~~~~~~~~~~~~~~~~~~~
for (label i=0; i<nVolFieldTypes; i++)
{
wordList fieldNames = objects.names(volFieldTypes[i]);
forAll(fieldNames, j)
{
const word& fieldName = fieldNames[j];
// Check if the field has to be exported
if (selectedFields)
{
if (!findStrings(fieldPatterns, fieldName))
{
continue;
}
}
#include "checkData.H"
if (!variableGood)
{
continue;
}
IOobject fieldObject
(
fieldName,
mesh.time().timeName(),
mesh,
IOobject::MUST_READ,
IOobject::NO_WRITE
);
if (volFieldTypes[i] == volScalarField::typeName)
{
volScalarField vf(fieldObject, mesh);
ensightField<scalar>
(
volField(meshSubsetter, vf),
eMesh,
ensightDir,
prepend,
timeIndex,
binary,
nodeValues,
ensightCaseFile
);
}
else if (volFieldTypes[i] == volVectorField::typeName)
{
volVectorField vf(fieldObject, mesh);
ensightField<vector>
(
volField(meshSubsetter, vf),
eMesh,
ensightDir,
prepend,
timeIndex,
binary,
nodeValues,
ensightCaseFile
);
}
else if (volFieldTypes[i] == volSphericalTensorField::typeName)
{
volSphericalTensorField vf(fieldObject, mesh);
ensightField<sphericalTensor>
(
volField(meshSubsetter, vf),
eMesh,
ensightDir,
prepend,
timeIndex,
binary,
nodeValues,
ensightCaseFile
);
}
else if (volFieldTypes[i] == volSymmTensorField::typeName)
{
volSymmTensorField vf(fieldObject, mesh);
ensightField<symmTensor>
(
volField(meshSubsetter, vf),
eMesh,
ensightDir,
prepend,
timeIndex,
binary,
nodeValues,
ensightCaseFile
);
}
else if (volFieldTypes[i] == volTensorField::typeName)
{
volTensorField vf(fieldObject, mesh);
ensightField<tensor>
(
volField(meshSubsetter, vf),
eMesh,
ensightDir,
prepend,
timeIndex,
binary,
nodeValues,
ensightCaseFile
);
}
// DimensionedFields
else if
(
volFieldTypes[i] == volScalarField::Internal::typeName
)
{
volScalarField::Internal df(fieldObject, mesh);
ensightField<scalar>
(
volField<scalar>(meshSubsetter, df),
eMesh,
ensightDir,
prepend,
timeIndex,
binary,
nodeValues,
ensightCaseFile
);
}
else if
(
volFieldTypes[i] == volVectorField::Internal::typeName
)
{
volVectorField::Internal df(fieldObject, mesh);
ensightField<vector>
(
volField<vector>(meshSubsetter, df),
eMesh,
ensightDir,
prepend,
timeIndex,
binary,
nodeValues,
ensightCaseFile
);
}
else if
(
volFieldTypes[i]
== volSphericalTensorField::Internal::typeName
)
{
volSphericalTensorField::Internal df(fieldObject, mesh);
ensightField<sphericalTensor>
(
volField<sphericalTensor>(meshSubsetter, df),
eMesh,
ensightDir,
prepend,
timeIndex,
binary,
nodeValues,
ensightCaseFile
);
}
else if
(
volFieldTypes[i] == volSymmTensorField::Internal::typeName
)
{
volSymmTensorField::Internal df(fieldObject, mesh);
ensightField<symmTensor>
(
volField<symmTensor>(meshSubsetter, df),
eMesh,
ensightDir,
prepend,
timeIndex,
binary,
nodeValues,
ensightCaseFile
);
}
else if
(
volFieldTypes[i] == volTensorField::Internal::typeName
)
{
volTensorField::Internal df(fieldObject, mesh);
ensightField<tensor>
(
volField<tensor>(meshSubsetter, df),
eMesh,
ensightDir,
prepend,
timeIndex,
binary,
nodeValues,
ensightCaseFile
);
}
}
}
// Cloud field data output
// ~~~~~~~~~~~~~~~~~~~~~~~
forAllConstIter(HashTable<HashTable<word>>, allCloudFields, cloudIter)
{
const word& cloudName = cloudIter.key();
fileNameList currentCloudDirs = readDir
(
runTime.timePath()/regionPrefix/cloud::prefix,
fileName::DIRECTORY
);
bool cloudExists = inFileNameList(currentCloudDirs, cloudName);
ensightParticlePositions
(
mesh,
ensightDir,
timeFile,
cloudName,
cloudExists
);
forAllConstIter(HashTable<word>, cloudIter(), fieldIter)
{
const word& fieldName = fieldIter.key();
const word& fieldType = fieldIter();
IOobject fieldObject
(
fieldName,
mesh.time().timeName(),
cloud::prefix/cloudName,
mesh,
IOobject::MUST_READ
);
bool fieldExists = fieldObject.typeHeaderOk<IOField<scalar>>
(
false
);
if (fieldType == scalarIOField::typeName)
{
ensightCloudField<scalar>
(
fieldObject,
ensightDir,
prepend,
timeIndex,
cloudName,
ensightCaseFile,
fieldExists
);
}
else if (fieldType == vectorIOField::typeName)
{
ensightCloudField<vector>
(
fieldObject,
ensightDir,
prepend,
timeIndex,
cloudName,
ensightCaseFile,
fieldExists
);
}
else
{
Info<< "Unable to convert field type " << fieldType
<< " for field " << fieldName << endl;
}
}
}
Info<< "Wrote in "
<< timer.cpuTimeIncrement() << " s, "
<< mem.update().size() << " kB" << endl;
}
#include "ensightCaseTail.H"
if (Pstream::master())
{
delete ensightCaseFilePtr;
}
Info<< "\nEnd: "
<< timer.elapsedCpuTime() << " s, "
<< mem.update().peak() << " kB (peak)\n" << endl;
return 0;
}
// ************************************************************************* //
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