def __init__(self):
InitialDatasetSearchPath = covise.getCoConfigEntry("vr-prepare.InitialDatasetSearchPath")
if not InitialDatasetSearchPath:
InitialDatasetSearchPath = os.getcwd()
self.currentFilePath = InitialDatasetSearchPath
self.ReadCfx_1 = 'None'
self.scale=1.0
self.mirror=0 # 0=none, 1=X, 2=Y, 3=Z
self.rotAxisX=1.0
self.rotAxisY=1.0
self.rotAxisZ=1.0
self.rotAngle=0.0
self.composedGrid = False
self.noGrid = False
self.processBoundaries = True
self.numVariables = 0
self.fixdomain = "None"
self.calculatePDYNFlag = False
self.domains=[]
self.coCaseFile = "None"
self.reduce = False
self.reductionFactor = 40.0
#
# init base class
#
Cfx2CoviseGuiBase.__init__(self, None)
#
# remove unused menubar items
#
self.fileNewAction.setVisible(False)
#
# disable all buttons
#
self.gridFrame.setEnabled(False)
self.reduceFrame.setEnabled(False)
self.variableFrame.setEnabled(False)
self.settingsFrame.setEnabled(False)
self.startConversionFrame.setEnabled(False)
self.outputDirFrame.setEnabled(False)
#
# register error log action
#
self.aErrorLogAction = ErrorLogAction()
CoviseMsgLoop().register(self.aErrorLogAction)
self.aErrorLogAction.register(self)
#
# register action to read message and boundaries
self.aBoundaryCollectorAction = BoundariesCollectorAction()
CoviseMsgLoop().register(self.aBoundaryCollectorAction)
#
# register choice action
#
self.domainsGetterAction = ChoiceGetterAction()
self.RegionsSelectionGetterAction = ChoiceGetterAction()
self.BoundarySelectionGetterAction = ChoiceGetterAction()
self.scalar_dataGetterAction = ChoiceGetterAction()
self.vector_dataGetterAction = ChoiceGetterAction()
self.timestepsGetterAction = IntGetterAction()
#self.first_timestepGetterAction = ChoiceGetterAction()
#self.readGridGetterAction = ChoiceGetterAction()
#self.readRegionsGetterAction = ChoiceGetterAction()
#self.readBoundariesGetterAction = ChoiceGetterAction()
self.boundary_scalar_dataGetterAction = ChoiceGetterAction()
self.boundary_vector_dataGetterAction = ChoiceGetterAction()
#self.grid_is_time_dependentGetterAction = ChoiceGetterAction()
#self.zone_with_time_dependent_gridGetterAction = ChoiceGetterAction()
#self.rotAxisGetterAction = ChoiceGetterAction()
#self.point_on_rotAxisGetterAction = ChoiceGetterAction()
#self.rot_Angle_pre_timestepGetterAction = ChoiceGetterAction()
#self.transform_velocityGetterAction = ChoiceGetterAction()
#self.transform_directionGetterAction = ChoiceGetterAction()
#self.rotation_axisGetterAction = ChoiceGetterAction()
#self.zone_to_transform_velocityGetterAction = ChoiceGetterAction()
#self.angular_velocityGetterAction = ChoiceGetterAction()
#self.rotate_velocityGetterAction = ChoiceGetterAction()
self.domainsGetterAction.register(self)
self.RegionsSelectionGetterAction.register(self)
self.BoundarySelectionGetterAction.register(self)
self.scalar_dataGetterAction.register(self)
self.vector_dataGetterAction.register(self)
#self.timestepsGetterAction.register(self)
#self.first_timestepGetterAction.register(self)
#self.readGridGetterAction.register(self)
#self.readRegionsGetterAction.register(self)
#self.readBoundariesGetterAction.register(self)
self.boundary_scalar_dataGetterAction.register(self)
self.boundary_vector_dataGetterAction.register(self)
#self.grid_is_time_dependentGetterAction.register(self)
#self.zone_with_time_dependent_gridGetterAction.register(self)
#self.rotAxisGetterAction.register(self)
#self.point_on_rotAxisGetterAction.register(self)
#self.rot_Angle_pre_timestepGetterAction.register(self)
#self.transform_velocityGetterAction.register(self)
#self.transform_directionGetterAction.register(self)
#self.rotation_axisGetterAction.register(self)
#self.zone_to_transform_velocityGetterAction.register(self)
#self.angular_velocityGetterAction.register(self)
#self.rotate_velocityGetterAction.register(self)
global theNet
theNet = net()
#
# MODULE: ReadCfx
#
self.ReadCfx_1 = ReadCFX()
theNet.add( self.ReadCfx_1 )
#
# hang in variable-getters
#
self.ReadCfx_1.addNotifier('domains',self.domainsGetterAction)
self.ReadCfx_1.addNotifier('RegionsSelection',self.RegionsSelectionGetterAction)
self.ReadCfx_1.addNotifier('BoundarySelection',self.BoundarySelectionGetterAction)
self.ReadCfx_1.addNotifier('scalar_data',self.scalar_dataGetterAction)
self.ReadCfx_1.addNotifier('vector_data',self.vector_dataGetterAction)
self.ReadCfx_1.addNotifier('timesteps',self.timestepsGetterAction)
#self.ReadCfx_1.addNotifier('first_timestep',self.first_timestepGetterAction)
#self.ReadCfx_1.addNotifier('readGrid',self.readGridGetterAction)
#self.ReadCfx_1.addNotifier('readRegions',self.readRegionsGetterAction)
#self.ReadCfx_1.addNotifier('readBoundaries',self.readBoundariesGetterAction)
self.ReadCfx_1.addNotifier('boundary_scalar_data',self.boundary_scalar_dataGetterAction)
self.ReadCfx_1.addNotifier('boundary_vector_data',self.boundary_vector_dataGetterAction)
#self.ReadCfx_1.addNotifier('grid_is_time_dependent',self.grid_is_time_dependentGetterAction)
#self.ReadCfx_1.addNotifier('zone_with_time_dependent_grid',self.zone_with_time_dependent_gridGetterAction)
#self.ReadCfx_1.addNotifier('rotAxis',self.rotAxisGetterAction)
#self.ReadCfx_1.addNotifier('point_on_rotAxis',self.point_on_rotAxisGetterAction)
#self.ReadCfx_1.addNotifier('rot_Angle_pre_timestep',self.rot_Angle_pre_timestepGetterAction)
#self.ReadCfx_1.addNotifier('transform_velocity',self.transform_velocityGetterAction)
#self.ReadCfx_1.addNotifier('transform_direction',self.transform_directionGetterAction)
#self.ReadCfx_1.addNotifier('rotation_axis',self.rotation_axisGetterAction)
#self.ReadCfx_1.addNotifier('zone_to_transform_velocity',self.zone_to_transform_velocityGetterAction)
#self.ReadCfx_1.addNotifier('angular_velocity',self.angular_velocityGetterAction)
#self.ReadCfx_1.addNotifier('rotate_velocity',self.rotate_velocityGetterAction)
#
# connect buttons
#
self.cbNoGrid.stateChanged.connect(self.setNoGrid)
self.cbNoGrid.stateChanged.connect(self.setComposedGrid)
self.cbNoGrid.stateChanged.connect(self.setTransientGrid)
self.cbNoGrid.currentIndexChanged.connect(self.setNumVar)
self.cbNoGrid.stateChanged.connect(self.setPdyn)
self.cbNoGrid.stateChanged.connect(self.setNoBound)
self.cbNoGrid.currentIndexChanged.connect(self.setDomain)
self.cbNoGrid.returnPressed.connect(self.setOutputDir)
self.cbNoGrid.clicked.connect(self.addToCoCase)
self.cbNoGrid.clicked.connect(self.startConversion)
#import time
logFile.write("\nConverting File:\n")
logFile.write("fullCfxCaseName = %s\n"%(fullCfxCaseName,))
logFile.flush()
print("")
print("Converting Case:")
print("fullCfxCaseName ", fullCfxCaseName)
domainsGetterAction = ChoiceGetterAction()
regionsGetterAction = ChoiceGetterAction()
boundariesGetterAction = ChoiceGetterAction()
scalarVariablesGetterAction = ChoiceGetterAction()
vectorVariablesGetterAction = ChoiceGetterAction()
timestepsGetterAction = IntGetterAction()
#
# MODULE: ReadCfx
#
ReadCFX_1 = ReadCFX()
theNet.add( ReadCFX_1 )
#
# hang in variable-getters
#
ReadCFX_1.addNotifier('domains', domainsGetterAction)
ReadCFX_1.addNotifier('regions', regionsGetterAction)
ReadCFX_1.addNotifier('boundaries', boundariesGetterAction)
ReadCFX_1.addNotifier('scalar_variables', scalarVariablesGetterAction)
ReadCFX_1.addNotifier('vector_variables', vectorVariablesGetterAction)
ReadCFX_1.addNotifier('timesteps', timestepsGetterAction)
class Cfx2CoviseGui(Cfx2CoviseGuiBase):
def __init__(self):
InitialDatasetSearchPath = covise.getCoConfigEntry("vr-prepare.InitialDatasetSearchPath")
if not InitialDatasetSearchPath:
InitialDatasetSearchPath = os.getcwd()
self.currentFilePath = InitialDatasetSearchPath
self.ReadCfx_1 = 'None'
self.scale=1.0
self.mirror=0 # 0=none, 1=X, 2=Y, 3=Z
self.rotAxisX=1.0
self.rotAxisY=1.0
self.rotAxisZ=1.0
self.rotAngle=0.0
self.composedGrid = False
self.noGrid = False
self.processBoundaries = True
self.numVariables = 0
self.fixdomain = "None"
self.calculatePDYNFlag = False
self.domains=[]
self.coCaseFile = "None"
self.reduce = False
self.reductionFactor = 40.0
#
# init base class
#
Cfx2CoviseGuiBase.__init__(self, None)
#
# remove unused menubar items
#
self.fileNewAction.setVisible(False)
#
# disable all buttons
#
self.gridFrame.setEnabled(False)
self.reduceFrame.setEnabled(False)
self.variableFrame.setEnabled(False)
self.settingsFrame.setEnabled(False)
self.startConversionFrame.setEnabled(False)
self.outputDirFrame.setEnabled(False)
#
# register error log action
#
self.aErrorLogAction = ErrorLogAction()
CoviseMsgLoop().register(self.aErrorLogAction)
self.aErrorLogAction.register(self)
#
# register action to read message and boundaries
self.aBoundaryCollectorAction = BoundariesCollectorAction()
CoviseMsgLoop().register(self.aBoundaryCollectorAction)
#
# register choice action
#
self.domainsGetterAction = ChoiceGetterAction()
self.RegionsSelectionGetterAction = ChoiceGetterAction()
self.BoundarySelectionGetterAction = ChoiceGetterAction()
self.scalar_dataGetterAction = ChoiceGetterAction()
self.vector_dataGetterAction = ChoiceGetterAction()
self.timestepsGetterAction = IntGetterAction()
#self.first_timestepGetterAction = ChoiceGetterAction()
#self.readGridGetterAction = ChoiceGetterAction()
#self.readRegionsGetterAction = ChoiceGetterAction()
#self.readBoundariesGetterAction = ChoiceGetterAction()
self.boundary_scalar_dataGetterAction = ChoiceGetterAction()
self.boundary_vector_dataGetterAction = ChoiceGetterAction()
#self.grid_is_time_dependentGetterAction = ChoiceGetterAction()
#self.zone_with_time_dependent_gridGetterAction = ChoiceGetterAction()
#self.rotAxisGetterAction = ChoiceGetterAction()
#self.point_on_rotAxisGetterAction = ChoiceGetterAction()
#self.rot_Angle_pre_timestepGetterAction = ChoiceGetterAction()
#self.transform_velocityGetterAction = ChoiceGetterAction()
#self.transform_directionGetterAction = ChoiceGetterAction()
#self.rotation_axisGetterAction = ChoiceGetterAction()
#self.zone_to_transform_velocityGetterAction = ChoiceGetterAction()
#self.angular_velocityGetterAction = ChoiceGetterAction()
#self.rotate_velocityGetterAction = ChoiceGetterAction()
self.domainsGetterAction.register(self)
self.RegionsSelectionGetterAction.register(self)
self.BoundarySelectionGetterAction.register(self)
self.scalar_dataGetterAction.register(self)
self.vector_dataGetterAction.register(self)
#self.timestepsGetterAction.register(self)
#self.first_timestepGetterAction.register(self)
#self.readGridGetterAction.register(self)
#self.readRegionsGetterAction.register(self)
#self.readBoundariesGetterAction.register(self)
self.boundary_scalar_dataGetterAction.register(self)
self.boundary_vector_dataGetterAction.register(self)
#self.grid_is_time_dependentGetterAction.register(self)
#self.zone_with_time_dependent_gridGetterAction.register(self)
#self.rotAxisGetterAction.register(self)
#self.point_on_rotAxisGetterAction.register(self)
#self.rot_Angle_pre_timestepGetterAction.register(self)
#self.transform_velocityGetterAction.register(self)
#self.transform_directionGetterAction.register(self)
#self.rotation_axisGetterAction.register(self)
#self.zone_to_transform_velocityGetterAction.register(self)
#self.angular_velocityGetterAction.register(self)
#self.rotate_velocityGetterAction.register(self)
global theNet
theNet = net()
#
# MODULE: ReadCfx
#
self.ReadCfx_1 = ReadCFX()
theNet.add( self.ReadCfx_1 )
#
# hang in variable-getters
#
self.ReadCfx_1.addNotifier('domains',self.domainsGetterAction)
self.ReadCfx_1.addNotifier('RegionsSelection',self.RegionsSelectionGetterAction)
self.ReadCfx_1.addNotifier('BoundarySelection',self.BoundarySelectionGetterAction)
self.ReadCfx_1.addNotifier('scalar_data',self.scalar_dataGetterAction)
self.ReadCfx_1.addNotifier('vector_data',self.vector_dataGetterAction)
self.ReadCfx_1.addNotifier('timesteps',self.timestepsGetterAction)
#self.ReadCfx_1.addNotifier('first_timestep',self.first_timestepGetterAction)
#self.ReadCfx_1.addNotifier('readGrid',self.readGridGetterAction)
#self.ReadCfx_1.addNotifier('readRegions',self.readRegionsGetterAction)
#self.ReadCfx_1.addNotifier('readBoundaries',self.readBoundariesGetterAction)
self.ReadCfx_1.addNotifier('boundary_scalar_data',self.boundary_scalar_dataGetterAction)
self.ReadCfx_1.addNotifier('boundary_vector_data',self.boundary_vector_dataGetterAction)
#self.ReadCfx_1.addNotifier('grid_is_time_dependent',self.grid_is_time_dependentGetterAction)
#self.ReadCfx_1.addNotifier('zone_with_time_dependent_grid',self.zone_with_time_dependent_gridGetterAction)
#self.ReadCfx_1.addNotifier('rotAxis',self.rotAxisGetterAction)
#self.ReadCfx_1.addNotifier('point_on_rotAxis',self.point_on_rotAxisGetterAction)
#self.ReadCfx_1.addNotifier('rot_Angle_pre_timestep',self.rot_Angle_pre_timestepGetterAction)
#self.ReadCfx_1.addNotifier('transform_velocity',self.transform_velocityGetterAction)
#self.ReadCfx_1.addNotifier('transform_direction',self.transform_directionGetterAction)
#self.ReadCfx_1.addNotifier('rotation_axis',self.rotation_axisGetterAction)
#self.ReadCfx_1.addNotifier('zone_to_transform_velocity',self.zone_to_transform_velocityGetterAction)
#self.ReadCfx_1.addNotifier('angular_velocity',self.angular_velocityGetterAction)
#self.ReadCfx_1.addNotifier('rotate_velocity',self.rotate_velocityGetterAction)
#
# connect buttons
#
self.cbNoGrid.stateChanged.connect(self.setNoGrid)
self.cbNoGrid.stateChanged.connect(self.setComposedGrid)
self.cbNoGrid.stateChanged.connect(self.setTransientGrid)
self.cbNoGrid.currentIndexChanged.connect(self.setNumVar)
self.cbNoGrid.stateChanged.connect(self.setPdyn)
self.cbNoGrid.stateChanged.connect(self.setNoBound)
self.cbNoGrid.currentIndexChanged.connect(self.setDomain)
self.cbNoGrid.returnPressed.connect(self.setOutputDir)
self.cbNoGrid.clicked.connect(self.addToCoCase)
self.cbNoGrid.clicked.connect(self.startConversion)
def closeEvent(self, event):
covise.clean()
covise.quit()
def addToCoCase(self ):
fd = QtWidgets.QFileDialog(self)#, 'Open Cfx File',self.currentFilePath,'cfx file (*.plt *.dat)')
fd.setMinimumWidth(1050)
fd.setMinimumHeight(700)
fd.setNameFilter('cocase file (*.cocase)')
fd.setWindowTitle('Open coCase File')
fd.setDirectory(self.currentFilePath)
acceptedOrRejected = fd.exec_()
if acceptedOrRejected != QtWidgets.QDialog.Accepted :
return
filenamesQt = fd.selectedFiles()
if filenamesQt.isEmpty():
return
self.coCaseFile = str(filenamesQt[0])
self.coCaseLabel.setText(self.coCaseFile)
def setNoGrid(self, i):
self.noGrid = self.cbNoGrid.isChecked()
def setComposedGrid(self, i):
self.composedGrid = self.cbComposedGrid.isChecked()
def setTransientGrid(self, i):
if self.cbTransientGrid.isChecked():
self.ReadCfx_1.set_grid_is_time_dependent("True")
else:
self.ReadCfx_1.set_grid_is_time_dependent("False")
def setNumVar(self, i):
self.numVariables = i+1
def setPdyn(self, i):
self.calculatePDYNFlag = self.cbPdyn.isChecked()
def setNoBound(self, i):
# set the boundaries to all
# choice param is "None", "All", "Affenfelsen",....
self.processBoundaries = not self.cbNoBound.isChecked()
def setDomain(self, i):
if i!=0:
self.fixdomain = str(self.comboDomain.currentText ())
self.domains=self.domainsGetterAction.getChoices()
def setOutputDir(self):
self.outputFilePath=str(self.outputDirLineEdit.text())
def customEvent(self,e):
if e.type() == NOTIFIER_EVENT:
self.variables=e.value[1:]
if e.param == "domains":
self.comboDomain.clear()
for v in self.variables:
self.comboDomain.addItem(v)
self.domains=self.domainsGetterAction.getChoices()
if e.param == "scalar_data":
# first is none
numVar = len(self.variables)-1
if self.comboNumVar.count()==0 or numVar >= self.comboNumVar.count():
self.comboNumVar.clear()
for i in range(numVar):
self.comboNumVar.addItem(str(i+1))
self.numVariables = self.comboNumVar.count()-1
self.comboNumVar.setCurrentIndex (self.numVariables)
if e.param == "vector_data":
# first is none
numVar = len(self.variables)-1
if self.comboNumVar.count()==0 or numVar >= self.comboNumVar.count():
self.comboNumVar.clear()
for i in range(numVar):
self.comboNumVar.addItem(str(i+1))
self.numVariables = self.comboNumVar.count()-1
self.comboNumVar.setCurrentIndex (self.numVariables)
if e.param == "boundary_scalar_data":
# first is none
numVar = len(self.variables)-1
if self.comboNumVar.count()==0 or numVar >= self.comboNumVar.count():
self.comboNumVar.clear()
for i in range(numVar):
self.comboNumVar.addItem(str(i+1))
self.numVariables = self.comboNumVar.count()-1
self.comboNumVar.setCurrentIndex (self.numVariables)
if e.param == "boundary_vector_data":
# first is none
numVar = len(self.variables)-1
if self.comboNumVar.count()==0 or numVar >= self.comboNumVar.count():
self.comboNumVar.clear()
for i in range(numVar):
self.comboNumVar.addItem(str(i+1))
self.numVariables = self.comboNumVar.count()-1
self.comboNumVar.setCurrentIndex (self.numVariables)
if e.type() == ERROR_EVENT:
if self.outputFilePath:
text="ERROR: "+e.error+"\n"
self.statusText.append(text)
def fileOpen(self):
fd = QtWidgets.QFileDialog(self)#, 'Open Cfx File',self.currentFilePath,'cfx file (*.plt *.dat)')
fd.setMinimumWidth(1050)
fd.setMinimumHeight(700)
fd.setNameFilter('cfx file (*.res)')
fd.setWindowTitle('Open Cfx File')
fd.setDirectory(self.currentFilePath)
acceptedOrRejected = fd.exec_()
if acceptedOrRejected != QtWidgets.QDialog.Accepted :
return
filenamesQt = fd.selectedFiles()
if filenamesQt.isEmpty():
return
self.currentFilePath = os.path.dirname(str(filenamesQt[0]))
self.fileName = (os.path.basename(str(filenamesQt[0])))[0:-4]
fullCfxCaseName = str(filenamesQt[0])
#
# try to open file
#
if not os.access(fullCfxCaseName, os.R_OK):
self.statusText.append("ERROR: Could not open file "+fullCfxCaseName+ " - not readable")
else:
#self.setCaption(os.path.basename(fullCfxCaseName))
#
# set filename
#
self.ReadCfx_1.set_result( fullCfxCaseName )
#self.ReadCFX_1.set_read_grid("false")
#
# disable file open
#
self.fileOpenAction.setEnabled(False)
#
# set output File path
#
self.outputDirFrame.setEnabled(True)
self.outputFilePath = self.currentFilePath + "/CoviseDaten"
self.outputDirLineEdit.setText(self.outputFilePath)
#
# enable format
#
#enable all frames
self.gridFrame.setEnabled(True)
self.reduceFrame.setEnabled(True)
self.variableFrame.setEnabled(True)
self.settingsFrame.setEnabled(True)
self.startConversionFrame.setEnabled(True)
self.outputDirFrame.setEnabled(True)
self.aBoundaryCollectorAction.waitForBoundaryInfoFinished()
def fileExit(self):
sys.exit()
def calculatePDYN(self, caseFileItem):
if not self.calculatePDYNFlag:
return
ptot_filename = ""
pres_filename = ""
for (varName, varFile, varDimension) in caseFileItem.variables_:
if (varName == "PTOT") and (varDimension == SCALARVARIABLE):
ptot_filename = varFile
if (varName == "PRES") and (varDimension == SCALARVARIABLE):
pres_filename = varFile
if (ptot_filename != "") and (pres_filename != ""):
pdyn_filename = ptot_filename.replace("-PTOT-", "-PDYN-")
# calculate
os.spawnlp(os.P_WAIT, "calcCovise", "calcCovise", pdyn_filename, "s1-s2", ptot_filename, pres_filename)
# add
caseFileItem.addVariableAndFilename("PDYN", pdyn_filename, SCALARVARIABLE)
def convertBegin(self):
self.cocase = CoviseCaseFile()
if self.coCaseFile != "None":
inputFile = open(self.coCaseFile, 'rb')
self.cocase = pickle.load(inputFile)
inputFile.close()
self.cocasename = (os.path.basename(self.coCaseFile))[0:-7]
else:
self.cocasename=self.fileName
logFileName = self.outputFilePath + '/' + self.cocasename + '.log'
self.logFile = open(logFileName, 'w')
self.logFile.write("Options:\n")
self.logFile.write("Covise Case Name = %s\n"%(self.cocasename,))
self.logFile.write("Covise Data Directory = %s\n"%(self.outputFilePath,))
self.logFile.write("scale = %s\n"%(self.scale))
self.logFile.write("\n")
self.logFile.flush()
def convertEnd(self):
self.pickleFile = self.outputFilePath + '/' + self.cocasename + '.cocase'
output = open(self.pickleFile, 'wb')
pickle.dump(self.cocase,output)
output.close()
self.logFile.write("\ncocasefile = %s\n"%(self.pickleFile,))
self.logFile.flush()
self.logFile.write("\nConversion finished\n")
self.logFile.flush()
self.logFile.close()
def convert(self, domainname, domainchoice, processGrid, processBoundaries):
# write logfile
self.logFile.write("\nprocessing %s\n"%(domainname))
self.logFile.flush()
text = "\nprocessing %s"%(domainname)
self.statusText.append(text)
# reset wait variable
self.scalar_dataGetterAction.resetWait()
self.vector_dataGetterAction.resetWait()
self.boundary_scalar_dataGetterAction.resetWait()
# select the domain
self.ReadCfx_1.set_domains( domainchoice )
# wait for choices to be updated by the module
self.scalar_dataGetterAction.waitForChoices()
self.vector_dataGetterAction.waitForChoices()
self.boundary_scalar_dataGetterAction.waitForChoices()
# read chocies
scalarVariablesTuple = self.scalar_dataGetterAction.getChoices()
vectorVariablesTuple = self.vector_dataGetterAction.getChoices()
scalarVariables = {}
vectorVariables = {}
#first choice is none
varChoice = 2
for svar in scalarVariablesTuple:
if not 'boundary' in svar:
scalarVariables[varChoice] = svar
varChoice += 1
varChoice = 2
for vvar in vectorVariablesTuple:
if not 'boundary' in vvar:
vectorVariables[varChoice] = vvar
varChoice += 1
#get boundaries from message
if processBoundaries:
boundaries = self.aBoundaryCollectorAction.getBoundaryNames(domainname)
else:
boundaries = []
#
# CONVERT GRID
#
# connect grid
gridPort = (self.ReadCfx_1, "GridOut0")
if (self.scale != 1.0):
theNet.connect( gridPort[0], gridPort[1], self.Transform_1, "geo_in" )
gridPort = (self.Transform_1, "geo_out")
if (self.mirror != 0):
theNet.connect( gridPort[0], gridPort[1], self.Transform_2, "geo_in" )
gridPort = (self.Transform_2, "geo_out")
if (self.rotAngle != 0.0):
theNet.connect( gridPort[0], gridPort[1], self.Transform_3, "geo_in" )
gridPort = (self.Transform_3, "geo_out")
theNet.connect( gridPort[0], gridPort[1], self.RWCovise_1, "mesh_in" )
# set variables to None
self.ReadCfx_1.set_scalar_data( 1 )
self.ReadCfx_1.set_vector_data( 1 )
self.ReadCfx_1.set_boundary_scalar_data( 1 )
covisename = domainname + "-3D.covise"
# create the cocase file item
item3D = None
if processGrid:
self.ReadCfx_1.set_readGrid('True')
item3D = CoviseCaseFileItem(domainname, GEOMETRY_3D, covisename)
# write logfile
self.logFile.write("\n\tconverting grid %s ...\n"%(domainname))
self.logFile.flush()
text = "\n\tconverting grid "+ domainname + " ..."
self.statusText.append( text )
# clean the domainname
if "/" in domainname:
self.logFile.write("\t! Attention: Replacing the / in domainname = %s\n"%(domainname,))
self.logFile.flush()
text = "\t! Attention: Replacing the / in domainname = "+ domainname
self.statusText.append(text)
domainname=domainname.replace("/","per")
if "\x7f" in domainname:
self.logFile.write("\t! Attention: Replacing a special character in domainname = %s\n"%(domainname,))
self.logFile.flush()
text = "\t! Attention: Removing a special character in domainname = "+ domainname
self.statusText.append(text)
domainname=domainname.replace("\x7f","_")
# create the RWCovise name
self.RWCovise_1.set_grid_path( self.outputFilePath + '/' +covisename )
# execute
self.ReadCfx_1.execute()
theNet.finishedBarrier()
# write logfile
self.logFile.write("\t... conversion successful! File: %s\n"%(covisename,))
self.logFile.flush()
text = "\t... conversion successful! File: "+covisename
self.statusText.append(text)
# disconnect grid
theNet.disconnectAllFromModule(self.ReadCfx_1)
theNet.disconnectAllFromModule(self.RWCovise_1)
if (self.scale != 1.0):
theNet.disconnectAllFromModule(self.Transform_1)
if (self.mirror != 0):
theNet.disconnectAllFromModule(self.Transform_2)
if (self.rotAngle != 0.0):
theNet.disconnectAllFromModule(self.Transform_3)
self.ReadCfx_1.set_readGrid("False")
else:
self.ReadCfx_1.set_readGrid('False')
item3D = CoviseCaseFileItem(domainname, GEOMETRY_3D, covisename)
for item in self.cocase.items_:
text = "name "+item.name_
self.statusText.append( text)
text = "covisename "+domainname
self.statusText.append( text)
if item.name_ == domainname:
item3D = item
break
self.ReadCfx_1.execute()
theNet.finishedBarrier()
timesteps = self.timestepsGetterAction.getInt()
if timesteps == 0:
timesteps = None
#
# CONVERT BOUNDARIES
#
# workaround for bug in readCFX, some parts are not convertes correctly,
# but "all" parts are allways correct, therefore we use all parts
# and extract the parts with GetSubset
item2D={}
if processBoundaries:
self.ReadCfx_1.set_readBoundaries("True")
#
# RWCovise
#
self.RWCovise_2.set_stepNo( 0 )
self.RWCovise_2.set_rotate_output( "FALSE" )
self.RWCovise_2.set_rotation_axis( 3 )
self.RWCovise_2.set_rot_speed( 2.000000 )
# connect boundaries
outPort = (self.ReadCfx_1, "GridOut2")
if timesteps==None:
theNet.connect( outPort[0], outPort[1], self.GetSubset_1, "DataIn0" )
theNet.connect( self.GetSubset_1, "DataOut0", self.FixUsg_1, "GridIn0" )
outPort = (self.FixUsg_1, "GridIn0")
if self.reduce:
theNet.connect( outPort[0], outPort[1], self.SimplifySurface_1, "meshIn" )
outPort = (self.SimplifySurface_1, "meshOut")
if (self.scale != 1.0):
theNet.connect( outPort[0], outPort[1], self.Transform_1, "geo_in" )
outPort = (self.Transform_1, "geo_out")
if (self.mirror != 0):
theNet.connect( outPort[0], outPort[1], self.Transform_2, "geo_in" )
outPort = (self.Transform_2, "geo_out")
if (self.rotAngle != 0.0):
theNet.connect( outPort[0], outPort[1], self.Transform_3, "geo_in" )
outPort = (self.Transform_3, "geo_out")
theNet.connect( outPort[0], outPort[1], self.RWCovise_2, "mesh_in" )
subset=0
boundchoice=1
for boundname in boundaries:
boundchoice = int(boundaries[boundname])
self.ReadCfx_1.set_BoundarySelection(str(boundchoice))
# ommit names "None" "all"
#boundchoice+=1
if int(boundchoice) > 0 :
# write logfile
self.logFile.write("\n\tconverting surface %s ...\n"%(boundname,))
self.logFile.flush()
text = "\n\tconverting surface %s ..."%(boundname,)
self.statusText.append( text)
bname=boundname
# clean boundname
if "/" in boundname:
self.logFile.write("\t! Attention: Replacing the / in boundname = %s\n"%(boundname,))
self.logFile.flush()
text = "\t! Attention: Replacing the / in boundname = "+ boundname
self.statusText.append( text)
bname=boundname.replace("/","per")
if "\x7f" in boundname:
self.logFile.write("\t! Attention: Replacing a special character in boundname = %s\n"%(boundname,))
self.logFile.flush()
text = "\t! Attention: Replacing a special character in boundname = ", boundname
self.statusText.append( text)
bname=boundname.replace("\x7f","_")
# set the subset
self.GetSubset_1.set_selection( str(0) )
# create RWCovise name
bname = bname.replace(' ','_')
covisename = domainname + "-boundary-" + bname + "-2D.covise"
self.RWCovise_2.set_grid_path( self.outputFilePath + '/' +covisename )
# execute
self.ReadCfx_1.execute()
#if timesteps==None:
# GetSubset_1.execute()
#else :
# GetSetelem_1.set_stepNo(1)
# GetSetelem_1.execute()
theNet.finishedBarrier()
# write logfile
self.logFile.write("\t... conversion successful! Filen: %s\n"%(covisename,))
self.logFile.flush()
text = "\t... conversion successful! File: "+covisename
self.statusText.append( text)
# create cocase item
item2D[boundname] = CoviseCaseFileItem(domainname + "-" + bname, GEOMETRY_2D, covisename)
subset+=1
# disconnect boundaries
theNet.disconnectAllFromModule(self.ReadCfx_1)
theNet.disconnectAllFromModule(self.RWCovise_2)
if self.reduce:
theNet.disconnectAllFromModule(self.SimplifySurface_1)
if timesteps==None:
theNet.disconnectAllFromModule(self.GetSubset_1)
theNet.disconnectAllFromModule(self.FixUsg_1)
if (self.scale != 1.0):
theNet.disconnectAllFromModule(self.Transform_1)
if (self.mirror != 0):
theNet.disconnectAllFromModule(self.Transform_2)
if (self.rotAngle != 0.0):
theNet.disconnectAllFromModule(self.Transform_3)
#theNet.remove( RWCovise_2 )
#theNet.remove( GetSubset_1 )
#theNet.remove( FixUsg_1 )
#if not timesteps==None:
# theNet.remove( GetSetelem_1 )
# theNet.remove( self.PipelineCollect_1 )
#
# CONVERT SCALAR VARIABLES
#
# connect the 3D scalar data
theNet.connect( self.ReadCfx_1, "DataOut0", self.RWCovise_1, "mesh_in" )
# loop through the scalar variables
# select the variable, ommit variable "none"
countVar = 0
for varchoice in scalarVariables:
svar = scalarVariables[varchoice]
#bsvar = boundScalarVariables[varchoice]
# convert only the first numVariables variables
countVar += 1
#if ( fixresult=="None" and int(varchoice) < (int(self.numVariables)+2) ) or svar==fixresult :
if countVar <= self.numVariables :
#
# CONVERT SCALAR VARIABLES OF GRID
#
self.logFile.write("\n\tconverting scalar variable %s on grid %s...\n"%(svar,domainname))
self.logFile.flush()
text = "\n\tconverting scalar variable "+ svar + " on grid " + domainname + "..."
self.statusText.append( text)
# clean variablename
if "/" in svar:
self.logFile.write("\t! Attention: Replacing the / in svar = %s\n"%(svar,))
self.logFile.flush()
text = "\t! Attention: Replacing the / in svar = "+ svar
self.statusText.append( text)
svar=svar.replace("/","per")
if "\x7f" in svar:
self.logFile.write("\t! Attention: Replacing a special character in svar = %s\n"%(svar,))
self.logFile.flush()
text = "\t! Attention: Replacing a special character in svar = "+ svar
self.statusText.append( text)
svar=svar.replace("\x7f","_")
# select variable
self.ReadCfx_1.set_scalar_data( varchoice )
self.ReadCfx_1.set_boundary_scalar_data( varchoice )
self.ReadCfx_1.set_readGrid("false")
covisename = domainname + "-" + svar + "-3D.covise"
#create RWCovise name
self.RWCovise_1.set_grid_path( self.outputFilePath + '/' +covisename )
# execute
self.ReadCfx_1.execute()
theNet.finishedBarrier()
# write logile
self.logFile.write("\t... conversion successful! Filename: %s\n"%(covisename,))
self.logFile.flush()
text = "\t... conversion successful! Filename: "+covisename
self.statusText.append( text)
# add variable to cocase item
item3D.addVariableAndFilename(svar, covisename, SCALARVARIABLE)
#
# CONVERT SCALAR VARIABLES OF BOUNDARIES
#
if processBoundaries:
#
# RWCovise
#
self.RWCovise_2.set_stepNo( 0 )
self.RWCovise_2.set_rotate_output( "FALSE" )
self.RWCovise_2.set_rotation_axis( 3 )
self.RWCovise_2.set_rot_speed( 2.000000 )
# connect the boundary scalar data
gridPort = (self.ReadCfx_1, "GridOut2")
dataPort = (self.ReadCfx_1, "DataOut3")
if timesteps==None:
theNet.connect( gridPort[0], gridPort[1], self.GetSubset_1, "DataIn0" )
theNet.connect( dataPort[0], dataPort[1], self.GetSubset_1, "DataIn1" )
theNet.connect( self.GetSubset_1, "DataOut0", self.FixUsg_1, "GridIn0" )
theNet.connect( self.GetSubset_1, "DataOut1", self.FixUsg_1, "DataIn0" )
gridPort = (self.FixUsg_1, "GridOut0")
dataPort = (self.FixUsg_1, "DataOut0")
if self.reduce:
theNet.connect( gridPort[0], gridPort[1], self.SimplifySurface_1, "meshIn")
theNet.connect( dataPort[0], dataPort[1], self.SimplifySurface_1, "dataIn_0")
gridPort = (self.SimplifySurface_1, "meshOut")
dataPort = (self.SimplifySurface_1, "dataOut_0")
theNet.connect( dataPort[0], dataPort[1], self.RWCovise_2, "mesh_in" )
subset=0
boundchoice=1
for boundname in boundaries:
boundchoice = int(boundaries[boundname])
self.ReadCfx_1.set_BoundarySelection(str(boundchoice))
# ommit names "None" "all"
#boundchoice+=1
if int(boundchoice) > 0 :
self.logFile.write("\n\tconverting scalar variable %s on surface %s %d...\n"%(svar,boundname, boundchoice))
self.logFile.flush()
text = "\n\tconverting scalar variable "+ svar + " on surface " + boundname + "..."
self.statusText.append( text)
bname=boundname
# clean boundname
if "/" in boundname:
self.logFile.write("\t! Attention: Replacing the / in boundname = %s\n"%(boundname,))
self.logFile.flush()
text = "\t! Attention: Replacing the / in boundname = "+ boundname
self.statusText.append( text)
bname=boundname.replace("/","per")
if "\x7f" in boundname:
self.logFile.write("\t! Attention: Replacing a special character in boundname = %s\n"%(boundname,))
self.logFile.flush()
text = "\t! Attention: Replacing a special character in boundname = "+ boundname
self.statusText.append( text)
bname=boundname.replace("\x7f","_")
# clean variablename
if "/" in svar:
self.logFile.write("\t! Attention: Replacing the / in svar = %s\n"%(svar,))
self.logFile.flush()
text = "\t! Attention: Replacing the / in svar = "+ svar
self.statusText.append( text)
svar=svar.replace("/","per")
if "\x7f" in svar:
self.logFile.write("\t! Attention: Replacing a special character in svar = %s\n"%(svar,))
self.logFile.flush()
text = "\t! Attention: Replacing a special character in svar = "+ svar
self.statusText.append( text)
svar=svar.replace("\x7f","_")
text = "\t! new svar = ", svar
self.statusText.append( text)
# set the subset
self.GetSubset_1.set_selection( str(0) )
# create RWCovise name
bname = bname.replace(' ', '_')
svar = svar.replace(' ', '_')
covisename = domainname + "-boundary-" + bname + "-" + svar + "-2D.covise"
self.RWCovise_2.set_grid_path( self.outputFilePath + '/' +covisename )
# execute
self.ReadCfx_1.execute()
#if timesteps==None:
# self.ReadCfx_1.execute()
#else :
# self.GetSetelem_1.set_stepNo(1)
# self.GetSetelem_1.execute()
theNet.finishedBarrier()
# write logfile
self.logFile.write("\t... conversion successful: Filename %s\n"%(covisename,))
self.logFile.flush()
text = "\t... conversion successful: "+covisename
self.statusText.append( text)
# append variable to cocase item
if boundname in item2D:
item2D[boundname].addVariableAndFilename(svar, covisename, SCALARVARIABLE)
subset+=1
# disconnect the boundaries
gridPort = (self.ReadCfx_1, "GridOut2")
dataPort = (self.ReadCfx_1, "DataOut3")
if timesteps==None:
theNet.disconnect( gridPort[0], gridPort[1], self.GetSubset_1, "DataIn0" )
theNet.disconnect( dataPort[0], dataPort[1], self.GetSubset_1, "DataIn1" )
theNet.disconnect( self.GetSubset_1, "DataOut0", self.FixUsg_1, "GridIn0" )
theNet.disconnect( self.GetSubset_1, "DataOut1", self.FixUsg_1, "DataIn0" )
gridPort = (self.FixUsg_1, "GridOut0")
dataPort = (self.FixUsg_1, "DataOut0")
if self.reduce:
theNet.disconnect( gridPort[0], gridPort[1], self.SimplifySurface_1, "meshIn")
theNet.disconnect( dataPort[0], dataPort[1], self.SimplifySurface_1, "dataIn_0")
gridPort = (self.SimplifySurface_1, "meshOut")
dataPort = (self.SimplifySurface_1, "dataOut_0")
theNet.disconnect( dataPort[0], dataPort[1], self.RWCovise_2, "mesh_in" )
#theNet.remove( RWCovise_2 )
#theNet.remove( GetSubset_1 )
#theNet.remove( FixUsg_1 )
#if not timesteps==None:
# theNet.remove( GetSetelem_1 )
# theNet.remove( self.PipelineCollect_1 )
# disconnect the grid
theNet.disconnect( self.ReadCfx_1, "DataOut0", self.RWCovise_1, "mesh_in" )
#
# convert the vector variables
#
# read no boundaries
self.ReadCfx_1.set_readBoundaries( "False" )
if (self.scale == 1.0) and (self.mirror == 0) and (self.rotAngle == 0.0):
self.ReadCfx_1.set_readGrid("false")
else:
self.ReadCfx_1.set_readGrid("true")
# connect the modules
gridPort = (self.ReadCfx_1, "GridOut0")
dataPort = (self.ReadCfx_1, "DataOut1")
if (self.scale != 1.0):
theNet.connect( gridPort[0], gridPort[1], self.Transform_1, "geo_in" )
theNet.connect( dataPort[0], dataPort[1], self.Transform_1, "data_in0" )
gridPort = (self.Transform_1, "geo_out")
dataPort = (self.Transform_1, "data_out0")
if (self.mirror != 0):
theNet.connect( gridPort[0], gridPort[1], self.Transform_2, "geo_in" )
theNet.connect( dataPort[0], dataPort[1], self.Transform_2, "data_in0" )
gridPort = (self.Transform_2, "geo_out")
dataPort = (self.Transform_2, "data_out0")
if (self.rotAngle != 0.0):
theNet.connect( gridPort[0], gridPort[1], self.Transform_3, "geo_in" )
theNet.connect( dataPort[0], dataPort[1], self.Transform_3, "data_in0" )
gridPort = (self.Transform_3, "geo_out")
dataPort = (self.Transform_3, "data_out0")
theNet.connect( dataPort[0], dataPort[1], self.RWCovise_1, "mesh_in" )
# loop though the variables
# ommit variable "none"
countVar = 0
for varchoice in vectorVariables:
vvar = vectorVariables[varchoice]
# select only the first numVariables variables
#if ( fixresult=="None" and int(varchoice) < (int(numVariables)+2) ) or vvar==fixresult :
countVar +=1
if countVar <= self.numVariables :
self.logFile.write("\n\tconverting vector variable %s ...\n"%(vvar,))
self.logFile.flush()
text = "\n\tconverting vector variable "+ vvar + " ..."
self.statusText.append( text)
# clean variablename
if "/" in vvar:
self.logFile.write("\t! Attention: Replacing the / in vvar = %s\n"%(vvar,))
self.logFile.flush()
text = "\t! Attention: Replacing the / in vvar = "+ vvar
self.statusText.append( text)
vvar=vvar.replace("/","per")
if "\x7f" in vvar:
self.logFile.write("\t! Attention: Replacing a special character in vvar = %s\n"%(vvar,))
self.logFile.flush()
text = "\t! Attention: Replacing a special character in vvar = "+ vvar
self.statusText.append( text)
vvar=vvar.replace("\x7f","_")
text = "\t! new vvar = ", vvar
self.statusText.append( text)
# select variable
self.ReadCfx_1.set_vector_data( varchoice )
# create RWCovise name
covisename = domainname + "-" + vvar + "-3D.covise"
self.RWCovise_1.set_grid_path(self.outputFilePath + '/' + covisename )
# execute
self.ReadCfx_1.execute()
theNet.finishedBarrier()
# write logfile
self.logFile.write("\t... conversion successful! Filename: %s\n"%(covisename,))
self.logFile.flush()
text = "\t... conversion successful! Filename: "+covisename
self.statusText.append( text)
# append variable to cocase item
item3D.addVariableAndFilename(vvar, covisename, VECTOR3DVARIABLE)
# disconnect the modules
theNet.disconnectAllFromModule(self.ReadCfx_1)
theNet.disconnectAllFromModule(self.RWCovise_1)
if (self.scale != 1.0):
theNet.disconnectAllFromModule(self.Transform_1)
if (self.mirror != 0):
theNet.disconnectAllFromModule(self.Transform_2)
if (self.rotAngle != 0.0):
theNet.disconnectAllFromModule(self.Transform_3)
#
# add Grid to coCase
#
if processGrid:
# add to cocase
self.cocase.add(item3D)
# add the boundary item do the case file
if processBoundaries:
for boundname in boundaries:
# ommit names "None" "all"
boundchoice = int(boundaries[boundname])
if int(boundchoice) > 0 :
self.calculatePDYN(item2D[boundname])
self.cocase.add(item2D[boundname])
def startModules(self):
global theNet
# Module Transform (scaling)
#
if (self.scale != 1.0):
self.Transform_1 = Transform()
theNet.add( self.Transform_1 )
self.Transform_1.set_Transform( 5 )
self.Transform_1.set_scaling_factor( self.scale )
self.Transform_1.set_createSet( "FALSE" )
# Module Transform (mirror)
#
if (self.mirror != 0):
self.Transform_2 = Transform()
theNet.add( self.Transform_2 )
self.Transform_2.set_Transform( 2 )
if (self.mirror == 1):
self.Transform_2.set_normal_of_mirror_plane(1.0, 0.0, 0.0)
elif (self.mirror == 2):
self.Transform_2.set_normal_of_mirror_plane(0.0, 1.0, 0.0)
elif (self.mirror == 3):
self.Transform_2.set_normal_of_mirror_plane(0.0, 0.0, 1.0)
self.Transform_2.set_MirroredAndOriginal( "FALSE" )
self.Transform_2.set_createSet( "FALSE" )
# Module Transform (rotation)
#
if (self.rotAngle != 0.0):
self.Transform_3 = Transform()
theNet.add( self.Transform_3 )
self.Transform_3.set_Transform( 4 )
self.Transform_3.set_axis_of_rotation(self.rotAxisX, self.rotAxisY, self.rotAxisZ)
self.Transform_3.set_angle_of_rotation( self.rotAngle )
self.Transform_3.set_createSet( "FALSE" )
# Module SimplifySurface
#
if self.reduce:
self.SimplifySurface_1 = SimplifySurface()
theNet.add( self.SimplifySurface_1 )
self.SimplifySurface_1.set_ignore_data( "TRUE" )
self.SimplifySurface_1.set_percent( self.reductionFactor )
#
# MODULE: RWCovise
#
self.RWCovise_1 = RWCovise()
theNet.add( self.RWCovise_1 )
self.RWCovise_1.set_stepNo( 0 )
self.RWCovise_1.set_rotate_output( "FALSE" )
self.RWCovise_1.set_rotation_axis( 3 )
self.RWCovise_1.set_rot_speed( 2.000000 )
self.RWCovise_2 = RWCovise()
theNet.add( self.RWCovise_2 )
#
# Module GetSubset
#
self.GetSubset_1 = GetSubset()
theNet.add( self.GetSubset_1 )
#
# Module FixUsg
#
self.FixUsg_1 = FixUsg()
theNet.add( self.FixUsg_1 )
# self.GetSetelem_1 = GetSetelem()
# theNet.add( self.GetSetelem_1 )
# self.PipelineCollect_1 = PipelineCollect()
# theNet.add( self.PipelineCollect_1 )
def startConversion(self):
global theNet
if os.path.isdir(self.outputFilePath):
pass
else:
try:
os.mkdir(self.outputFilePath)
except(OSError):
self.statusText.append("ERROR: Could not create directory "+str(self.outputFilePath)+" check permissions and enter again or select another directory")
return
# reduction
self.reduce = self.reduceCheckBox.isChecked()
self.reductionFactor=float(str(self.leReductionFactor.text()))
# scale
self.scale=float(str(self.leScaleX.text()))
# mirror
self.mirror=self.comboMirror.currentIndex()
# rotation
self.rotAxisX=float(str(self.leRotAxisX.text()))
self.rotAxisY=float(str(self.leRotAxisY.text()))
self.rotAxisZ=float(str(self.leRotAxisZ.text()))
self.rotAngle=float(str(self.leRotAngle.text()))
self.statusText.append("Starting conversion...")
self.startModules()
self.convertBegin()
#
# loop through the domains parts
# ('all', 'Domain\x7f1', '')
#
domainchoice=1
#
# read the domain values
#
for domainname in self.domains:
domainchoice+=1
if self.fixdomain=="None" or self.fixdomain==domainname:
self.convert(domainname, domainchoice, (not self.noGrid), self.processBoundaries)
#
# create composed grid
#
if (not self.noGrid) and (self.composedGrid):
self.convert("all", 1, True, False)
self.convertEnd()
self.repaint()
text="\n\n...conversion finished!\n"
self.statusText.append(text)
from ChoiceGetterAction import ChoiceGetterAction
from IntGetterAction import IntGetterAction
print("Covise Case Name = ", cocasename)
print(" ")
print("fullCfxCaseName ", fullCfxCaseName)
domainsGetterAction = ChoiceGetterAction()
regionsGetterAction = ChoiceGetterAction()
boundariesGetterAction = ChoiceGetterAction()
scalarVariablesGetterAction = ChoiceGetterAction()
vectorVariablesGetterAction = ChoiceGetterAction()
timestepsGetterAction = IntGetterAction()
#
# MODULE: ReadCfx
#
ReadCFX_1 = ReadCFX()
theNet.add( ReadCFX_1 )
#
# hang in variable-getters
#
ReadCFX_1.addNotifier('domains', domainsGetterAction)
ReadCFX_1.addNotifier('regions', regionsGetterAction)
ReadCFX_1.addNotifier('boundaries', boundariesGetterAction)
ReadCFX_1.addNotifier('scalar_variables', scalarVariablesGetterAction)
ReadCFX_1.addNotifier('vector_variables', vectorVariablesGetterAction)
ReadCFX_1.addNotifier('timesteps', timestepsGetterAction)
#
# set parameter values
#