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foam-extend4.1-coherent-io/applications/utilities/preProcessing/fluentDataToFoam/fluentDataToFoam.L

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/*---------------------------------------------------------------------------*\
========= |
\\ / 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
Application
fluentDataToFoam
Description
Converts Fluent data to OpenFOAM format
\*---------------------------------------------------------------------------*/
%{
#undef yyFlexLexer
/* ------------------------------------------------------------------------- *\
------ local definitions
\* ------------------------------------------------------------------------- */
#include "fvCFD.H"
#include <fstream>
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
using namespace Foam;
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
label dimensionOfGrid = 0;
// Machine config
label mc1 = 0;
label mc2 = 0;
label mc3 = 0;
label mc4 = 0;
label mc5 = 0;
label mc6 = 0;
label mc7 = 0;
label mc8 = 0;
label mc9 = 0;
label mc10 = 0;
label mc11 = 0;
label nPoints = 0;
label nFaces = 0;
label nCells = 0;
SLList<label> fieldID;
SLList<label> zoneID;
SLList<label> nEntriesPerObject;
SLList<label> firstID;
SLList<label> lastID;
SLPtrList<FieldField<Field, scalar> > zoneData;
// 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 <<EOF>>
#if YY_FLEX_SUBMINOR_VERSION < 34
extern "C" int yywrap()
#else
int yyFlexLexer::yywrap()
#endif
{
return 1;
}
%}
one_space [ \t\f]
space {one_space}*
some_space {one_space}+
cspace ","{space}
spaceNl ({space}|\n|\r)*
alpha [_[:alpha:]]
digit [[:digit:]]
decDigit [[:digit:]]
octalDigit [0-7]
hexDigit [[:xdigit:]]
lbrac "("
rbrac ")"
quote \"
dash "-"
comma ","
dotColonDash [.:-]
schemeSpecialInitial [!$%&*/:<=>?~_^#.]
schemeSpecialSubsequent [.+-]
schemeSymbol (({some_space}|{alpha}|{quote}|{schemeSpecialInitial})({alpha}|{quote}|{digit}|{schemeSpecialInitial}|{schemeSpecialSubsequent})*)
identifier {alpha}({alpha}|{digit})*
integer {decDigit}+
label [1-9]{decDigit}*
hexLabel {hexDigit}+
zeroLabel {digit}*
word ({alpha}|{digit}|{dotColonDash})*
exponent_part [eE][-+]?{digit}+
fractional_constant [-+]?(({digit}*"."{digit}+)|({digit}+".")|({digit}))
double ((({fractional_constant}{exponent_part}?)|({digit}+{exponent_part}))|0)
x {double}
y {double}
z {double}
scalar {double}
labelListElement {space}{zeroLabel}
hexLabelListElement {space}{hexLabel}
scalarListElement {space}{double}
schemeSymbolListElement {space}{schemeSymbol}
labelList ({labelListElement}+{space})
hexLabelList ({hexLabelListElement}+{space})
scalarList ({scalarListElement}+{space})
schemeSymbolList ({schemeSymbolListElement}+{space})
starStar ("**")
text ({space}({comma}*{word}*{space})*)
dateDDMMYYYY ({digit}{digit}"/"{digit}{digit}"/"{digit}{digit}{digit}{digit})
dateDDMonYYYY ((({digit}{digit}{space})|({digit}{space})){alpha}*{space}{digit}{digit}{digit}{digit})
time ({digit}{digit}":"{digit}{digit}":"{digit}{digit})
versionNumber ({digit}|".")*
comment {spaceNl}"(0"{space}
header {spaceNl}"(1"{space}
dimension {spaceNl}"(2"{space}
machineConfig {spaceNl}"(4"{space}
gridSize {spaceNl}"(33"{space}
variables {spaceNl}"(37"{space}
fieldData {spaceNl}"(300"{space}
endOfSection {space}")"{space}
/* ------------------------------------------------------------------------- *\
----- Exclusive start states -----
\* ------------------------------------------------------------------------- */
%option stack
%x readComment
%x embeddedCommentState
%x readHeader
%x readDimension
%x readMachineConfigHeader
%x readMachineConfig
%x readGridSizeHeader
%x readGridSize
%x readFieldData
%x readFieldDataHeader
%x readFieldSize
%x readField
%x unknownBlock
%x embeddedUnknownBlock
%%
%{
// Data index
label curNEntriesPerObject = 0;
// Dummy, not used
label nTimeLevels;
label nPhases;
label curFirstID = 0;
label curLastID = 0;
label objI = 0;
FieldField<Field, scalar>* curZdPtr = NULL;
%}
/* ------------------------------------------------------------------------ *\
------ Start Lexing ------
\* ------------------------------------------------------------------------ */
/* ------ Reading control header ------ */
{comment} {
yy_push_state(readComment);
}
<readComment>{quote}{text}{quote} {
}
<readComment>{spaceNl}{endOfSection} {
yy_pop_state();
}
{header} {
BEGIN(readHeader);
}
<readHeader>{quote}{text}{quote} {
Info<< "Reading header: " << YYText() << endl;
}
{dimension} {
BEGIN(readDimension);
}
<readDimension>{space}{label}{space} {
IStringStream dimOfGridStream(YYText());
dimensionOfGrid = readLabel(dimOfGridStream);
Info<< "Dimension of grid: " << dimensionOfGrid << endl;
}
{machineConfig} {
yy_push_state(readMachineConfigHeader);
}
<readMachineConfigHeader>{spaceNl}{lbrac} {
yy_push_state(readMachineConfig);
}
<readMachineConfig>{space}{labelList} {
IStringStream machineConfigStream(YYText());
mc1 = readLabel(machineConfigStream);
mc2 = readLabel(machineConfigStream);
mc3 = readLabel(machineConfigStream);
mc4 = readLabel(machineConfigStream);
mc5 = readLabel(machineConfigStream);
mc6 = readLabel(machineConfigStream);
mc7 = readLabel(machineConfigStream);
mc8 = readLabel(machineConfigStream);
mc9 = readLabel(machineConfigStream);
mc10 = readLabel(machineConfigStream);
mc11 = readLabel(machineConfigStream);
Info<< "Machine config: "
<< mc1 << mc2 << mc3 << mc4 << mc5 << mc6
<< mc7 << mc8 << mc9 << mc10 << mc11
<< endl;
}
{gridSize} {
yy_push_state(readGridSizeHeader);
}
<readGridSizeHeader>{spaceNl}{lbrac} {
yy_push_state(readGridSize);
}
<readGridSize>{space}{labelList} {
IStringStream gridSizeStream(YYText());
nCells = readLabel(gridSizeStream);
nFaces = readLabel(gridSizeStream);
nPoints = readLabel(gridSizeStream);
Info<< "Grid size: nCells = " << nCells << " nFaces = " << nFaces
<< " nPoints = " << nPoints << endl;
}
{variables} {
yy_push_state(readComment);
}
{fieldData} {
yy_push_state(readFieldDataHeader);
}
<readFieldDataHeader>{spaceNl}{lbrac} {
BEGIN(readFieldSize);
}
<readFieldSize>{space}{labelList} {
IStringStream fieldDataStream(YYText());
// Field and zone ID
fieldID.append(readLabel(fieldDataStream));
zoneID.append(readLabel(fieldDataStream));
// Number of entries per object (cell/face)
curNEntriesPerObject = readLabel(fieldDataStream);
nEntriesPerObject.append(curNEntriesPerObject);
// Dummy, not used
nTimeLevels = readLabel(fieldDataStream);
nPhases = readLabel(fieldDataStream);
// Start and end of list
curFirstID = readLabel(fieldDataStream);
firstID.append(curFirstID);
curLastID = readLabel(fieldDataStream);
lastID.append(curLastID);
// Create field for data
// Info << "Create : " << curNEntriesPerObject << endl;
curZdPtr = new FieldField<Field, scalar>(curNEntriesPerObject);
// Info<< "Setting field with " << curNEntriesPerObject
// << " components of length " << curLastID - curFirstID +1 << endl;
for (label cmptI = 0; cmptI < curNEntriesPerObject; cmptI++)
{
curZdPtr->set(cmptI, new scalarField(curLastID - curFirstID + 1));
}
zoneData.append(curZdPtr);
}
<readFieldSize>{endOfSection} {
BEGIN(readFieldData);
}
<readFieldData>{spaceNl}{lbrac} {
// Info<< "Reading field. nEntries = " << curNEntriesPerObject
// << " firstID = " << curFirstID << " lastID = " << curLastID << endl;
// Reset the counter
objI = 0;
yy_push_state(readField);
}
<readField>{spaceNl}{scalarList} {
IStringStream fieldStream(YYText());
FieldField<Field, scalar>& zd = *curZdPtr;
// Reading field
for (label entryI = 0; entryI < curNEntriesPerObject; entryI++)
{
zd[entryI][objI] = readScalar(fieldStream);
}
objI++;
}
<readMachineConfig,readMachineConfigHeader,readGridSize,readGridSizeHeader,readFieldData,readField>{spaceNl}{endOfSection} {
yy_pop_state();
}
/* ------ Reading end of section and others ------ */
<readHeader,readDimension>{spaceNl}{endOfSection} {
BEGIN(INITIAL);
}
/* ------ Reading unknown type or non-standard comment ------ */
{lbrac}{label} {
// Info<< "Found unknown block:" << YYText() << endl;
yy_push_state(unknownBlock);
}
<readComment,unknownBlock,embeddedUnknownBlock>{spaceNl}{schemeSymbol} {
}
<readComment,unknownBlock,embeddedUnknownBlock>{spaceNl}{lbrac} {
// Info<< "Embedded blocks in comment or unknown:" << YYText() << endl;
yy_push_state(embeddedUnknownBlock);
}
<readComment,unknownBlock,embeddedUnknownBlock>{spaceNl}{endOfSection} {
// Info<< "Found end of section in unknown:" << YYText() << endl;
yy_pop_state();
}
<unknownBlock,embeddedUnknownBlock>{spaceNl}{labelList} {
}
<unknownBlock,embeddedUnknownBlock>{spaceNl}{hexLabelList} {
}
<unknownBlock,embeddedUnknownBlock>{spaceNl}{scalarList} {
}
<unknownBlock,embeddedUnknownBlock>{spaceNl}{schemeSymbolList} {
}
<unknownBlock,embeddedUnknownBlock>{spaceNl}{text} {
}
/* ------ Ignore remaining space and \n s. Any other characters are errors. */
/* ------ On EOF return to previous file, if none exists terminate. ------ */
<<EOF>> {
yyterminate();
}
%%
#include "fileName.H"
#include "fluentDataConverter.H"
int main(int argc, char *argv[])
{
argList::noParallel();
argList::validArgs.append("Fluent data file");
argList args(argc, argv);
if (!args.check())
{
FatalError.exit();
}
# include "createTime.H"
fileName fluentFile(args.additionalArgs()[0]);
std::ifstream fluentStream(fluentFile.c_str());
if (!fluentStream)
{
FatalErrorIn("fluentToFoam::main(int argc, char *argv[])")
<< args.executable()
<< ": file " << fluentFile << " not found"
<< exit(FatalError);
}
yyFlexLexer lexer(&fluentStream);
while(lexer.yylex() != 0)
{}
Info<< "\n\nFINISHED LEXING\n\n\n";
// Re-package the fields into OpenFOAM data
// Warning: syncronous iterators, check size
// HJ, 25/May/2009
const label iterSize = fieldID.size();
Info << "Number of entries read: " << iterSize << nl << endl;
if
(
zoneID.size() != iterSize
|| nEntriesPerObject.size() != iterSize
|| firstID.size() != iterSize
|| lastID.size() != iterSize
|| zoneData.size() != iterSize
)
{
FatalErrorIn(args.executable())
<< "Problem in reading: incorrect iterator size: " << iterSize
<< abort(FatalError);
}
labelHashSet fields;
for
(
SLList<label>::const_iterator fieldIDIter = fieldID.begin();
fieldIDIter != fieldID.end();
++fieldIDIter
)
{
fields.insert(fieldIDIter());
}
// Info: Available units
{
labelList u = fields.toc();
sort(u);
Info<< "Available units: " << u << endl;
}
// Create a mesh
# include "createMesh.H"
// Create a converter
fluentDataConverter fdc
(
mesh,
fieldID,
zoneID,
firstID,
lastID,
zoneData
);
if (fields.found(1))
{
Info << "Converting pressure field" << endl;
fdc.convertField
(
"p", // field name
1, // fluent Unit number
dimensionedScalar("zero", dimPressure, 0)
)().write();
}
if (fields.found(2))
{
Info << "Converting momentum field" << endl;
fdc.convertField
(
"momentum", // field name
2, // fluent Unit number
dimensionedScalar("zero", dimDensity*dimVelocity, 0)
)().write();
}
if (fields.found(3))
{
Info << "Converting temperature field" << endl;
fdc.convertField
(
"T", // field name
3, // fluent Unit number
dimensionedScalar("zero", dimTemperature, 273.15)
)().write();
}
if (fields.found(4))
{
Info << "Converting enthalpy field" << endl;
fdc.convertField
(
"h", // field name
4, // fluent Unit number
dimensionedScalar("zero", dimensionSet(0, 2, -2, 0, 0, 0, 0), 0)
)().write();
}
if (fields.found(5))
{
Info << "Converting turbulence kinetic energy field" << endl;
fdc.convertField
(
"k", // field name
5, // fluent Unit number
dimensionedScalar("zero", sqr(dimVelocity), 0)
)().write();
}
// Species not done yet. HJ, 29/May/2009
if (fields.found(8))
{
Info << "Converting G field" << endl;
fdc.convertField
(
"G", // field name
8, // fluent Unit number
dimensionedScalar("zero", dimless, 0)
)().write();
}
if (fields.found(15))
{
Info << "Converting body force field" << endl;
fdc.convertField
(
"bodyForce", // field name
15, // fluent Unit number
dimensionedScalar("zero", dimAcceleration, 0)
)().write();
}
if (fields.found(101))
{
Info << "Converting density field" << endl;
fdc.convertField
(
"rho", // field name
101, // fluent Unit number
dimensionedScalar("zero", dimDensity, 0)
)().write();
}
if (fields.found(102))
{
Info << "Converting laminar viscosity field" << endl;
fdc.convertField
(
"muLam", // field name
102, // fluent Unit number
dimensionedScalar("zero", dimPressure*dimTime, 0)
)().write();
}
if (fields.found(103))
{
Info << "Converting turbulent field" << endl;
fdc.convertField
(
"muT", // field name
103, // fluent Unit number
dimensionedScalar("zero", dimPressure*dimTime, 0)
)().write();
}
if (fields.found(104))
{
Info << "Converting field" << endl;
fdc.convertField
(
"Cp", // field name
104, // fluent Unit number
dimensionedScalar("zero", dimSpecificHeatCapacity, 0)
)().write();
}
// Velocity field
if (fields.found(111) || fields.found(112) || fields.found(113))
{
Info << "Converting velocity field" << endl;
volVectorField U
(
IOobject
(
"U",
mesh.time().timeName(),
mesh,
IOobject::NO_READ,
IOobject::NO_WRITE
),
mesh,
dimensionedVector("zero", dimVelocity, vector::zero)
);
if (fields.found(111))
{
U.replace
(
vector::X,
fdc.convertField
(
"Ux", // field name
111, // fluent Unit number
dimensionedScalar("zero", dimVelocity, 0)
)
);
}
if (fields.found(112))
{
U.replace
(
vector::Y,
fdc.convertField
(
"Uy", // field name
112, // fluent Unit number
dimensionedScalar("zero", dimVelocity, 0)
)
);
}
if (fields.found(113))
{
U.replace
(
vector::Z,
fdc.convertField
(
"Uz", // field name
113, // fluent Unit number
dimensionedScalar("zero", dimVelocity, 0)
)
);
}
U.write();
}
Info<< nl << "End" << endl;
return 0;
}
/* ------------------------------------------------------------------------- *\
------ End of fluentDataToFoam.L
\* ------------------------------------------------------------------------- */