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openfoam/applications/utilities/postProcessing/dataConversion/foamToEnsightParts/foamToEnsightParts.C
Mark Olesen faaa93fdb5 ENH: add IOobjectList::findObject() method 
- naming similar to objectRegistry, with unambiguous resolution.
  The lookup() methods have different return types depending on the
  calling parameter.

STYLE: use IOobjectListTemplates.C for implementations

- previously included as local definition within IOobjectList.C,
  but will be adding more templated methods soon.

- adjust parameters (eg, matchName instead of matcher) to show their
  function

ENH: handle objectRegistry::names<void>(...)

- this is equivalent to no Type restriction, and can be used when
  filtering names. Eg,

     obr.names<void>(wordRe..);
2018-11-09 21:57:55 +01:00

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/*---------------------------------------------------------------------------*\
========= |
\\ / F ield | OpenFOAM: The Open Source CFD Toolbox
\\ / O peration |
\\ / A nd | Copyright (C) 2011-2016 OpenFOAM Foundation
\\/ M anipulation | Copyright (C) 2016-2018 OpenCFD Ltd.
-------------------------------------------------------------------------------
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
foamToEnsightParts
Group
grpPostProcessingUtilities
Description
Translates OpenFOAM data to Ensight format.
An Ensight part is created for each cellZone and patch.
Usage
\b foamToEnsightParts [OPTION]
Options:
- \par -ascii
Write Ensight data in ASCII format instead of "C Binary"
- \par -name \<subdir\>
Define sub-directory name to use for Ensight data (default: "Ensight")
- \par -noZero
Exclude the often incomplete initial conditions.
- \par -index \<start\>
Ignore the time index contained in the time file and use a
simple indexing when creating the \c Ensight/data/######## files.
- \par -noLagrangian
Suppress writing lagrangian positions and fields.
- \par -noMesh
Suppress writing the geometry. Can be useful for converting partial
results for a static geometry.
- \par -width \<n\>
Width of Ensight data subdir
Note
- no parallel data.
- writes to \a Ensight directory to avoid collisions with foamToEnsight.
\*---------------------------------------------------------------------------*/
#include "argList.H"
#include "timeSelector.H"
#include "volFields.H"
#include "OFstream.H"
#include "IOmanip.H"
#include "IOobjectList.H"
#include "scalarIOField.H"
#include "tensorIOField.H"
// file-format/conversion
#include "ensightCase.H"
#include "ensightGeoFile.H"
#include "ensightParts.H"
#include "ensightSerialOutput.H"
// local files
#include "ensightOutputSerialCloud.H"
#include "memInfo.H"
using namespace Foam;
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
int main(int argc, char *argv[])
{
// Enable -constant
// Probably don't need -withZero though, since the fields are vetted
// afterwards anyhow
timeSelector::addOptions(true, false);
argList::noParallel();
argList::addBoolOption
(
"ascii",
"Write in ASCII format instead of 'C Binary'"
);
argList::addOption
(
"index",
"start",
"Ignore the time index contained in the uniform/time file "
"and use simple indexing when creating the files"
);
argList::addBoolOption
(
"noLagrangian",
"Suppress writing lagrangian positions and fields"
);
argList::addBoolOption
(
"noMesh",
"Suppress writing the geometry. "
"Can be useful for converting partial results for a static geometry"
);
argList::addOption
(
"name",
"subdir",
"Sub-directory name for ensight output (default: 'Ensight')"
);
argList::addOption
(
"width",
"n",
"Width of Ensight data subdir"
);
// The volume field types that we handle
const wordHashSet volFieldTypes
{
volScalarField::typeName,
volVectorField::typeName,
volSphericalTensorField::typeName,
volSymmTensorField::typeName,
volTensorField::typeName
};
// The lagrangian field types that we handle
const wordHashSet cloudFieldTypes
{
scalarIOField::typeName,
vectorIOField::typeName,
tensorIOField::typeName
};
#include "setRootCase.H"
// Default to binary output, unless otherwise specified
const IOstream::streamFormat format =
(
args.found("ascii")
? IOstream::ASCII
: IOstream::BINARY
);
cpuTime timer;
memInfo mem;
Info<< "Initial memory " << mem.update().size() << " kB" << endl;
#include "createTime.H"
instantList timeDirs = timeSelector::select0(runTime, args);
#include "createNamedMesh.H"
fileName regionPrefix; // Mesh instance (region0 gets filtered out)
if (regionName != polyMesh::defaultRegion)
{
regionPrefix = regionName;
}
//
// general (case) output options
//
ensightCase::options caseOpts(format);
caseOpts.width(args.lookupOrDefault<label>("width", 8));
caseOpts.overwrite(false); // leave existing output directory
// Can also have separate directory for lagrangian
// caseOpts.separateCloud(true);
// Define sub-directory name to use for EnSight data.
// The path to the ensight directory is at case level only
// - For parallel cases, data only written from master
fileName ensightDir = args.lookupOrDefault<word>("name", "Ensight");
if (!ensightDir.isAbsolute())
{
ensightDir = args.globalPath()/ensightDir;
}
//
// Open new ensight case file, initialize header etc.
//
ensightCase ensCase
(
ensightDir,
"Ensight", // args.globalCaseName(),
caseOpts
);
//
// Miscellaneous output configuration
//
// Control for renumbering iterations
label indexingNumber = 0;
const bool optIndex = args.readIfPresent("index", indexingNumber);
const bool noLagrangian = args.found("noLagrangian");
// Always write the geometry, unless the -noMesh option is specified
bool optNoMesh = args.found("noMesh");
// Construct the list of ensight parts for the entire mesh
ensightParts partsList(mesh);
// Write summary information
if (Pstream::master())
{
Info<< "Converting " << timeDirs.size() << " time steps" << endl;
OFstream info(ensCase.path()/"partsInfo");
info
<< "// summary of ensight parts" << nl << nl;
partsList.writeSummary(info);
}
#include "checkMeshMoving.H"
#include "findFields.H"
if (meshMoving && optNoMesh)
{
Info<< "mesh is moving: ignoring '-noMesh' option" << endl;
optNoMesh = false;
}
Info<< "Startup in "
<< timer.cpuTimeIncrement() << " s, "
<< mem.update().size() << " kB" << nl << endl;
forAll(timeDirs, timeI)
{
runTime.setTime(timeDirs[timeI], timeI);
#include "getTimeIndex.H"
#include "moveMesh.H"
ensCase.setTime(timeDirs[timeI], timeIndex);
if (timeI == 0 || mesh.moving())
{
if (mesh.moving())
{
partsList.recalculate(mesh);
}
if (!optNoMesh)
{
autoPtr<ensightGeoFile> os = ensCase.newGeometry(meshMoving);
partsList.write(os.ref());
}
}
Info<< "Write volume field (" << flush;
forAllConstIters(volumeFields, fieldIter)
{
const word& fieldName = fieldIter.key();
const word& fieldType = fieldIter.object();
IOobject fieldObject
(
fieldName,
mesh.time().timeName(),
mesh,
IOobject::MUST_READ,
IOobject::NO_WRITE
);
bool wrote = false;
if (fieldType == volScalarField::typeName)
{
autoPtr<ensightFile> os = ensCase.newData<scalar>
(
fieldName
);
volScalarField vf(fieldObject, mesh);
wrote = ensightSerialOutput::writeField<scalar>
(
vf, partsList, os
);
}
else if (fieldType == volVectorField::typeName)
{
autoPtr<ensightFile> os = ensCase.newData<vector>
(
fieldName
);
volVectorField vf(fieldObject, mesh);
wrote = ensightSerialOutput::writeField<vector>
(
vf, partsList, os
);
}
else if (fieldType == volSphericalTensorField::typeName)
{
autoPtr<ensightFile> os = ensCase.newData<sphericalTensor>
(
fieldName
);
volSphericalTensorField vf(fieldObject, mesh);
wrote = ensightSerialOutput::writeField<sphericalTensor>
(
vf, partsList, os
);
}
else if (fieldType == volSymmTensorField::typeName)
{
autoPtr<ensightFile> os = ensCase.newData<symmTensor>
(
fieldName
);
volSymmTensorField vf(fieldObject, mesh);
wrote = ensightSerialOutput::writeField<symmTensor>
(
vf, partsList, os
);
}
else if (fieldType == volTensorField::typeName)
{
autoPtr<ensightFile> os = ensCase.newData<tensor>
(
fieldName
);
volTensorField vf(fieldObject, mesh);
wrote = ensightSerialOutput::writeField<tensor>
(
vf, partsList, os
);
}
if (wrote)
{
Info<< " " << fieldObject.name() << flush;
}
}
Info<< " )" << endl;
// Check for clouds
forAllConstIters(cloudFields, cloudIter)
{
const word& cloudName = cloudIter.key();
const HashTable<word>& theseCloudFields = cloudIter.object();
const fileName cloudPrefix(regionPrefix/cloud::prefix);
if (!isDir(runTime.timePath()/cloudPrefix/cloudName))
{
continue;
}
IOobjectList cloudObjs
(
mesh,
runTime.timeName(),
cloudPrefix/cloudName
);
// Clouds require "coordinates".
// The "positions" are for v1706 and lower.
const bool cloudExists =
(
cloudObjs.found("coordinates")
|| cloudObjs.found("positions")
);
if (!cloudExists)
{
continue;
}
Info<< "Write " << cloudName << " (" << flush;
ensightSerialCloud::writePositions
(
mesh,
cloudName,
ensCase.newCloud(cloudName)
);
Info<< " positions";
forAllConstIters(theseCloudFields, fieldIter)
{
const word& fieldName = fieldIter.key();
const word& fieldType = fieldIter.object();
IOobject *fieldObject = cloudObjs.findObject(fieldName);
if (!fieldObject)
{
Info<< "missing "
<< runTime.timeName()/cloudPrefix/cloudName/fieldName
<< endl;
continue;
}
bool wrote = false;
if (fieldType == scalarIOField::typeName)
{
wrote = ensightSerialCloud::writeCloudField<scalar>
(
*fieldObject,
ensCase.newCloudData<scalar>(cloudName, fieldName)
);
}
else if (fieldType == vectorIOField::typeName)
{
wrote = ensightSerialCloud::writeCloudField<vector>
(
*fieldObject,
ensCase.newCloudData<vector>(cloudName, fieldName)
);
}
else if (fieldType == tensorIOField::typeName)
{
wrote = ensightSerialCloud::writeCloudField<tensor>
(
*fieldObject,
ensCase.newCloudData<tensor>(cloudName, fieldName)
);
}
if (wrote)
{
Info<< " " << fieldObject->name();
}
}
Info<< " )" << endl;
}
Info<< "Wrote in "
<< timer.cpuTimeIncrement() << " s, "
<< mem.update().size() << " kB" << endl;
}
ensCase.write();
Info<< "\nEnd: "
<< timer.elapsedCpuTime() << " s, "
<< mem.update().peak() << " kB (peak)\n" << endl;
return 0;
}
// ************************************************************************* //
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