示例#1
0
def LArRawChannelBuilderDefault():
    from AthenaCommon.AlgSequence import AlgSequence
    topSequence = AlgSequence()
    from AthenaCommon.AppMgr import ServiceMgr as svcMgr

    if larRODFlags.readDigits() and globalflags.InputFormat() == 'bytestream':
        if LArRawDataReadingAlg() not in topSequence:
            print("Adding LArRawDataReaderAlg")
            topSequence += LArRawDataReadingAlg()

        from LArRecUtils.LArADC2MeVCondAlgDefault import LArADC2MeVCondAlgDefault

        LArADC2MeVCondAlgDefault()

        from LArROD.LArRODConf import LArRawChannelBuilderAlg
        theLArRawChannelBuilder = LArRawChannelBuilderAlg()
        if larRODFlags.keepDSPRaw():
            theLArRawChannelBuilder.LArRawChannelKey = larRODFlags.RawChannelFromDigitsContainerName(
            )
        topSequence += theLArRawChannelBuilder
示例#2
0
    def configure(self):
        mlog = logging.getLogger( 'Py:LArRawChannelGetter::configure %s:' % self.__class__ )

        from AthenaCommon.AlgSequence import AlgSequence
        topSequence = AlgSequence()
        from AthenaCommon.AppMgr import ToolSvc


        # get LArDigitGetter in MC case
        from AthenaCommon.DetFlags import DetFlags
        if DetFlags.digitize.LAr_on() :
            try:
                from LArDigitization.LArDigitGetter import LArDigitGetter
                theLArDigitGetter = LArDigitGetter()
            except Exception as configException:
                mlog.error("could not get handle to LArDigitGetter Quit")
                import traceback
                mlog.error(traceback.format_exc())
                return False
            if not theLArDigitGetter.usable():
                mlog.error("LArDigitGetter unusable. Quite")
                return False

        from LArROD.LArRODFlags import larRODFlags

        from AthenaCommon.GlobalFlags import globalflags
        if globalflags.DataSource()=='data' or larRODFlags.forceIter() :

            # ADC2MeV tool
            from LArRecUtils.LArADC2MeVToolDefault import LArADC2MeVToolDefault
            theADC2MeVTool = LArADC2MeVToolDefault()
            ToolSvc += theADC2MeVTool


            from AthenaCommon.AppMgr import ServiceMgr as svcMgr

# Data case

            if larRODFlags.readDigits():

                from AthenaCommon.GlobalFlags import globalflags
                if globalflags.InputFormat() == 'bytestream':
                    if not larRODFlags.keepDSPRaw():
                        topSequence.LArRawDataReaderAlg.LArRawChannelKey=""

                if globalflags.DetGeo() == 'ctbh6' or globalflags.DetGeo() == 'ctbh8':        
                    from LArROD.LArRODConf import LArRawChannelBuilder
                    theLArRawChannelBuilder=LArRawChannelBuilder()
                    topSequence += theLArRawChannelBuilder
                    return True

                from LArROD.LArRODConf import LArRawChannelBuilderDriver

                theLArRawChannelBuilder=LArRawChannelBuilderDriver("LArRawChannelBuilder")
                topSequence += theLArRawChannelBuilder

                if larRODFlags.keepDSPRaw():
                    theLArRawChannelBuilder.LArRawChannelContainerName=larRODFlags.RawChannelFromDigitsContainerName()

                # bad channel masking if required
                if not larRODFlags.doBuildBadChannel():
                    # The first tool filters out bad channels
                    from LArROD.LArRODConf import LArRawChannelBuilderToolBadChannelTool
                    theLArRawChannelBuilderToolBadChannel=LArRawChannelBuilderToolBadChannelTool()
                    from LArBadChannelTool.LArBadChannelToolConf import LArBadChannelMasker
                    theLArRCBMasker=LArBadChannelMasker("LArRCBMasker")
                    theLArRCBMasker.DoMasking=True
                    theLArRCBMasker.ProblemsToMask=[
                       "deadReadout","deadPhys","almostDead","short",
                       "lowNoiseHG","highNoiseHG","unstableNoiseHG",
                       "lowNoiseMG","highNoiseMG","unstableNoiseMG",
                       "lowNoiseLG","highNoiseLG","unstableNoiseLG"
                      ]
                    theLArRawChannelBuilderToolBadChannel.BadChannelMask=theLArRCBMasker
                    theLArRawChannelBuilder.BuilderTools += [theLArRawChannelBuilderToolBadChannel]
                    ToolSvc+=theLArRawChannelBuilderToolBadChannel

               
                # Pulse reconstruction
                # main method: OFC iteration
                from LArROD.LArRODConf import LArRawChannelBuilderToolOFCIter
                theLArRawChannelBuilderToolOFCIter=LArRawChannelBuilderToolOFCIter()
                theLArRawChannelBuilderToolOFCIter.minSample = 2
                theLArRawChannelBuilderToolOFCIter.maxSample = 12
                theLArRawChannelBuilderToolOFCIter.minADCforIterInSigma=4 # ADCmax at least 4 sigma above noise for iteration
                theLArRawChannelBuilderToolOFCIter.minADCforIter=15 # min adc for iteration (only if no pedestalRMS found)
                theLArRawChannelBuilderToolOFCIter.defaultPhase=0    # starting delay, also the fixed delay for ADC below min.
                theLArRawChannelBuilderToolOFCIter.ECut=250.         # Energy to save quality
                theLArRawChannelBuilder.BuilderTools += [theLArRawChannelBuilderToolOFCIter]
                theLArRawChannelBuilder+=theLArRawChannelBuilderToolOFCIter 

                # no fallback when emulating exactly DSP computation
                if not larRODFlags.doDSP():
                    # fallback(1): cubic method
                    from LArROD.LArRODConf import LArRawChannelBuilderToolCubic
                    theLArRawChannelBuilderToolCubic=LArRawChannelBuilderToolCubic()
                    theLArRawChannelBuilderToolCubic.minADCforCubic=30 
                    theLArRawChannelBuilder.BuilderTools  += [theLArRawChannelBuilderToolCubic]
                    theLArRawChannelBuilder += theLArRawChannelBuilderToolCubic 

                    # fallback(2) averageing
                    from LArROD.LArRODConf import LArRawChannelBuilderToolAverage
                    theLArRawChannelBuilderToolAverage=LArRawChannelBuilderToolAverage()
                    theLArRawChannelBuilderToolAverage.NScan=0
                    theLArRawChannelBuilder.BuilderTools  += [theLArRawChannelBuilderToolAverage]
                    theLArRawChannelBuilder += theLArRawChannelBuilderToolAverage 


                # Pedestal
                # main method from database
                from LArROD.LArRODConf import LArRawChannelBuilderPedestalDataBase
                theLArRawChannelBuilderPedestalDataBase=LArRawChannelBuilderPedestalDataBase()
                theLArRawChannelBuilderPedestalDataBase.LArPedestalKey = "LArPedestal"
                theLArRawChannelBuilder.PedestalTools  = [theLArRawChannelBuilderPedestalDataBase]
                theLArRawChannelBuilder += theLArRawChannelBuilderPedestalDataBase 
                
                # no fallback when emulating exactly DSP computation
                if not larRODFlags.doDSP():
                    # fallback. sample 0
                    from LArROD.LArRODConf import LArRawChannelBuilderPedestalSampleZero
                    theLArRawChannelBuilderPedestalSampleZero=LArRawChannelBuilderPedestalSampleZero()
                    theLArRawChannelBuilder.PedestalTools  += [theLArRawChannelBuilderPedestalSampleZero]
                    theLArRawChannelBuilder += theLArRawChannelBuilderPedestalSampleZero

                # ADC to energy
                # main method from database
                from LArROD.LArRODConf import LArRawChannelBuilderADC2EDataBase
                theLArRawChannelBuilderADC2EDataBase=LArRawChannelBuilderADC2EDataBase()
                theLArRawChannelBuilder.ADCtoEnergyTools  = [theLArRawChannelBuilderADC2EDataBase]
                theLArRawChannelBuilderADC2EDataBase.ADC2MeVTool = theADC2MeVTool
                theLArRawChannelBuilder += theLArRawChannelBuilderADC2EDataBase 

                # no fallback when emulating exactly DSP computation
                if not larRODFlags.doDSP():
                    # fallback, constant conversion factors
                    from LArROD.LArRODConf import LArRawChannelBuilderADC2EConstants
                    theLArRawChannelBuilderADC2EConstants=LArRawChannelBuilderADC2EConstants()
                    theLArRawChannelBuilder.ADCtoEnergyTools += [theLArRawChannelBuilderADC2EConstants]
                    theLArRawChannelBuilder += theLArRawChannelBuilderADC2EConstants

                #more tools to be configured
                from LArRecUtils.LArRecUtilsConf import LArOFPeakRecoTool
                theLArOFPeakRecoTool=LArOFPeakRecoTool()
                from LArConditionsCommon.LArCondFlags import larCondFlags
                theLArOFPeakRecoTool.UseShape=larCondFlags.useShape()
                if larCondFlags.LArCoolChannelSelection.statusOn:
                    if len(larCondFlags.LArCoolChannelSelection())>0:
                        theLArOFPeakRecoTool.forceHighGain=larCondFlags.useOFCOnlyCoolChannelSelection()
                ToolSvc += theLArOFPeakRecoTool

                #
                # adjust default timing to match first sample information written in cool from Lar online configuration
                #
                nominalPeakSample=2
                if globalflags.DataSource()=='data':
                    from LArConditionsCommon.LArCool import larcool
                    if (larcool is not None):
                        nominalPeakSample = larcool.firstSample()
                        # don't use ramp intercept in calibration if gain type is not auto
                        if larcool.gainType() > 0 :
                            mlog.info(" Gain Type: %d  don't use intercept in ADC to Energy ramp calibration",larcool.gainType())
                            theLArRawChannelBuilderADC2EDataBase.UseHighGainRampIntercept = False
                            theLArRawChannelBuilderADC2EDataBase.UseMedGainRampIntercept = False
                            theLArRawChannelBuilderADC2EDataBase.UseLowGainRampIntercept = False
                        else :
                             mlog.info(" Gain Type: %d   use intercept in ADC to energy ramp calibraion ",larcool.gainType())
                if (nominalPeakSample > 1) :
                    theLArRawChannelBuilder.DefaultShiftTimeSample=nominalPeakSample-2
                else :
                    theLArRawChannelBuilder.DefaultShiftTimeSample=0
                theLArRawChannelBuilder.DataLocation    = "FREE"

            else:

                from AthenaCommon.GlobalFlags import globalflags
                if globalflags.InputFormat() == 'bytestream':
                    if not "LArRawChannelContainer/LArRawChannels" in svcMgr.ByteStreamAddressProviderSvc.TypeNames:
                        svcMgr.ByteStreamAddressProviderSvc.TypeNames+=["LArRawChannelContainer/LArRawChannels"]

            # In the case of DSP monitoring and reading rawchannels, need to give a different name to the LArRawChannels container
            # read from the bytestream ...
            # This name has to be coherent with the name in LArMonTools/LArRODMonTool_jobOptions.py
            if larRODFlags.doDSP() and larRODFlags.readRawChannels():  #Reading LArRawChannel
                print ("Reading RawChannels in DSP physics mode")
                # !!! The name of the LArRawChannels container read from the Bytestream is LArRawChannels_fB !!!
                if not "LArRawChannelContainer/LArRawChannels_fB" in svcMgr.ByteStreamAddressProviderSvc.TypeNames:
                    svcMgr.ByteStreamAddressProviderSvc.TypeNames+=["LArRawChannelContainer/LArRawChannels_fB"]
                print (svcMgr.ByteStreamAddressProviderSvc.TypeNames)
      
        else:

            # MC Case
            try:
                from AthenaCommon import CfgGetter
                topSequence += CfgGetter.getAlgorithm("LArRawChannelBuilder", tryDefaultConfigurable=True)
            except Exception as cfgException:
                mlog.error("Failed to retrieve LArRawChannelBuilder. Quit")
                import traceback
                mlog.error(traceback.format_exc())
                return False

        return True
    def configure(self):
        from AthenaCommon.Logging import logging
        mlog = logging.getLogger('CaloCellGetter::configure:')
        mlog.info('entering')

        doStandardCellReconstruction = True
        from CaloRec.CaloCellFlags import jobproperties

        if not jobproperties.CaloCellFlags.doFastCaloSim.statusOn:
            doFastCaloSim = False
            mlog.info("doFastCaloSim not set, so not using it")
        else:
            doFastCaloSim = jobproperties.CaloCellFlags.doFastCaloSim()
            if doFastCaloSim:
                mlog.info("doFastCaloSim requested")
                doStandardCellReconstruction = False
                if jobproperties.CaloCellFlags.doFastCaloSimAddCells():
                    doStandardCellReconstruction = True
                    mlog.info(
                        "doFastCaloSimAddCells requested: FastCaloSim is added to fullsim calorimeter"
                    )
                else:
                    mlog.info(
                        "doFastCaloSimAddCells not requested: Stand alone FastCaloSim is running"
                    )
            else:
                mlog.info("doFastCaloSim explicitly not requested")

        # get handle to upstream object
        # handle tile

        if doStandardCellReconstruction:
            # handle LAr
            import traceback
            try:
                from LArROD.LArRODFlags import larRODFlags
                from AthenaCommon.GlobalFlags import globalflags
                if larRODFlags.readDigits() and globalflags.DataSource(
                ) == 'data':
                    from AthenaCommon.KeyStore import CfgItemList
                    CfgItemList("KeyStore_inputFile").removeItem(
                        "LArRawChannelContainer#LArRawChannels")
                if (not larRODFlags.readDigits()
                    ) and globalflags.InputFormat() == 'bytestream':
                    from AthenaCommon.AppMgr import ServiceMgr as svcMgr
                    try:
                        if not "LArRawChannelContainer/LArRawChannels" in svcMgr.ByteStreamAddressProviderSvc.TypeNames:
                            svcMgr.ByteStreamAddressProviderSvc.TypeNames += [
                                "LArRawChannelContainer/LArRawChannels"
                            ]
                    except:
                        mlog.warning(
                            "Cannot remove LArRawChannelContainer/LArRawChannels from bytestream list"
                        )
                from LArROD.LArRawChannelGetter import LArRawChannelGetter
                theLArRawChannelGetter = LArRawChannelGetter()
            except:
                mlog.error("could not get handle to LArRawChannel Quit")
                print traceback.format_exc()
                return False

            if not theLArRawChannelGetter.usable():
                if not self.ignoreConfigError():
                    mlog.error("LArRawChannelGetter unusable. Quit.")
                    return False
                else:
                    mlog.error(
                        "LArRawChannelGetter unusable. Continue nevertheless")

        # writing of thinned digits
        if jobproperties.CaloCellFlags.doLArThinnedDigits.statusOn and jobproperties.CaloCellFlags.doLArThinnedDigits(
        ):
            from AthenaCommon.GlobalFlags import globalflags
            if globalflags.DataSource() == 'data':
                try:
                    from LArROD.LArDigits import DefaultLArDigitThinner
                    LArDigitThinner = DefaultLArDigitThinner(
                        'LArDigitThinner'
                    )  # automatically added to topSequence
                    LArDigitThinner.InputContainerName = "FREE"
                    LArDigitThinner.OutputContainerName = "LArDigitContainer_Thinned"
                except Exception:
                    treatException("Problem with LArDigitThinner ")

        # now configure the algorithm, part of this could be done in a separate class
        # cannot have same name
        try:
            from CaloRec.CaloRecConf import CaloCellMaker
        except:
            mlog.error("could not import CaloRec.CaloCellMaker")
            print traceback.format_exc()
            return False

        theCaloCellMaker = CaloCellMaker()
        self._CaloCellMakerHandle = theCaloCellMaker

        from AthenaCommon.AppMgr import ToolSvc

        if doStandardCellReconstruction:
            # configure CaloCellMaker here
            # check LArCellMakerTool_jobOptions.py for full configurability
            # FIXME

            from RecExConfig.RecFlags import rec

            if rec.doLArg():
                try:
                    from LArCellRec.LArCellRecConf import LArCellBuilderFromLArRawChannelTool
                    theLArCellBuilder = LArCellBuilderFromLArRawChannelTool()
                except:
                    mlog.error(
                        "could not get handle to LArCellBuilderFromLArRawChannel Quit"
                    )
                    print traceback.format_exc()
                    return False

                if jobproperties.CaloCellFlags.doLArCreateMissingCells():
                    # bad channel tools
                    try:
                        from LArBadChannelTool.LArBadChannelToolConf import LArBadChanTool
                        theLArBadChannelTool = LArBadChanTool()
                    except:
                        mlog.error("could not access bad channel tool Quit")
                        print traceback.format_exc()
                        return False
                    ToolSvc += theLArBadChannelTool
                    theLArCellBuilder.addDeadOTX = True
                    theLArCellBuilder.badChannelTool = theLArBadChannelTool

                # add the tool to list of tool ( should use ToolHandle eventually)
                ToolSvc += theLArCellBuilder
                theCaloCellMaker.CaloCellMakerToolNames += [theLArCellBuilder]

            if rec.doTile():

                from AthenaCommon.GlobalFlags import globalflags
                if globalflags.DataSource(
                ) == 'data' and globalflags.InputFormat() == 'bytestream':
                    from AthenaCommon.AppMgr import ServiceMgr as svcMgr
                    try:
                        svcMgr.ByteStreamCnvSvc.ROD2ROBmap = ["-1"]
                        if not "TileDigitsContainer/TileDigitsCnt" in svcMgr.ByteStreamAddressProviderSvc.TypeNames:
                            svcMgr.ByteStreamAddressProviderSvc.TypeNames += [
                                "TileBeamElemContainer/TileBeamElemCnt",
                                "TileDigitsContainer/TileDigitsCnt",
                                "TileL2Container/TileL2Cnt",
                                "TileLaserObject/TileLaserObj",
                                "TileMuonReceiverContainer/TileMuRcvCnt"
                            ]
                    except:
                        mlog.warning(
                            "Cannot add TileDigitsContainer/TileDigitsCnt et al. to bytestream list"
                        )

                    # set options for TileRawChannelMaker
                    from TileRecUtils.TileRecFlags import jobproperties
                    jobproperties.TileRecFlags.TileRunType = 1
                    # physics run type

                    # reading of digits can be disabled before calling CaloCellGetter
                    # if this is not done, but digits are not available in BS file
                    # reading of digits is automatically disabled at start of run
                    if jobproperties.TileRecFlags.readDigits()                \
                        and not (jobproperties.TileRecFlags.doTileFlat        \
                                 or jobproperties.TileRecFlags.doTileFit      \
                                 or jobproperties.TileRecFlags.doTileFitCool  \
                                 or jobproperties.TileRecFlags.doTileOpt      \
                                 or jobproperties.TileRecFlags.doTileOF1      \
                                 or jobproperties.TileRecFlags.doTileOpt2     \
                                 or jobproperties.TileRecFlags.doTileOptATLAS \
                                 or jobproperties.TileRecFlags.doTileMF):

                        from AthenaCommon.BeamFlags import jobproperties
                        # run Opt filter with iterations by default, both for cosmics and collisions before 2011
                        # run Opt filter without iterations for collisions in 2011 and later
                        if not 'doTileOpt2' in dir():
                            from RecExConfig.AutoConfiguration import GetRunNumber
                            rn = GetRunNumber()
                            if rn > 0 and rn < 171194:
                                doTileOpt2 = True
                            elif jobproperties.Beam.beamType() == 'collisions':
                                doTileOpt2 = False
                                # use OF without iterations for collisions
                            else:
                                doTileOpt2 = True
                                # always run OF with iterations for cosmics

                        # jobproperties.TileRecFlags.calibrateEnergy=True; # use pCb for RawChannels
                        # please, note that time correction and best phase are used only for collisions
                        if doTileOpt2:
                            jobproperties.TileRecFlags.doTileOpt2 = True
                            # run optimal filter with iterations
                            jobproperties.TileRecFlags.doTileOptATLAS = False
                            # disable optimal filter without iterations
                            jobproperties.TileRecFlags.correctAmplitude = False
                            # don't do parabolic correction
                            if jobproperties.Beam.beamType() == 'collisions':
                                jobproperties.TileRecFlags.correctTime = True
                                # apply time correction in physics runs
                                jobproperties.TileRecFlags.BestPhaseFromCOOL = False
                                # best phase is not needed for iterations
                        else:
                            jobproperties.TileRecFlags.doTileOpt2 = False
                            # disable optimal filter with iterations
                            jobproperties.TileRecFlags.doTileOptATLAS = True
                            # run optimal filter without iterations
                            jobproperties.TileRecFlags.correctAmplitude = True
                            # apply parabolic correction
                            if jobproperties.Beam.beamType() == 'collisions':
                                jobproperties.TileRecFlags.correctTime = False
                                # don't need time correction if best phase is used
                                jobproperties.TileRecFlags.BestPhaseFromCOOL = True
                                # use best phase stored in DB

                    try:
                        from TileRecUtils.TileRawChannelGetter import TileRawChannelGetter
                        theTileRawChannelGetter = TileRawChannelGetter()
                    except:
                        mlog.error("could not load TileRawChannelGetter Quit")
                        print traceback.format_exc()
                        return False

                    try:
                        from TileRecAlgs.TileRecAlgsConf import TileDigitsFilter
                        from AthenaCommon.AlgSequence import AlgSequence
                        topSequence = AlgSequence()
                        topSequence += TileDigitsFilter()
                    except:
                        mlog.error("Could not configure TileDigitsFilter")

                try:
                    from TileRecUtils.TileRecUtilsConf import TileCellBuilder
                    theTileCellBuilder = TileCellBuilder()
                    from TileRecUtils.TileRecFlags import jobproperties
                    theTileCellBuilder.TileRawChannelContainer = jobproperties.TileRecFlags.TileRawChannelContainer(
                    )

                    if not hasattr(ToolSvc, "TileBeamInfoProvider"):
                        from TileRecUtils.TileRecUtilsConf import TileBeamInfoProvider
                        ToolSvc += TileBeamInfoProvider()

                    if globalflags.DataSource(
                    ) == 'data' and globalflags.InputFormat() == 'bytestream':
                        if jobproperties.TileRecFlags.readDigits():
                            # everything is already corrected at RawChannel level
                            theTileCellBuilder.correctTime = False
                            theTileCellBuilder.correctAmplitude = False
                        else:
                            ToolSvc.TileBeamInfoProvider.TileRawChannelContainer = "TileRawChannelCnt"
                            # by default parameters are tuned for opt.filter without iterations
                            theTileCellBuilder.correctTime = jobproperties.TileRecFlags.correctTime(
                            )
                            theTileCellBuilder.correctAmplitude = jobproperties.TileRecFlags.correctAmplitude(
                            )
                            theTileCellBuilder.AmpMinForAmpCorrection = jobproperties.TileRecFlags.AmpMinForAmpCorrection(
                            )
                            if jobproperties.TileRecFlags.TimeMaxForAmpCorrection(
                            ) <= jobproperties.TileRecFlags.TimeMinForAmpCorrection(
                            ):
                                from AthenaCommon.BeamFlags import jobproperties
                                mlog.info(
                                    "adjusting min/max time of parabolic correction for %s"
                                    % jobproperties.Beam.bunchSpacing)
                                halfBS = jobproperties.Beam.bunchSpacing.get_Value(
                                ) / 2.
                                jobproperties.TileRecFlags.TimeMinForAmpCorrection = -halfBS
                                jobproperties.TileRecFlags.TimeMaxForAmpCorrection = halfBS
                            if jobproperties.TileRecFlags.TimeMaxForAmpCorrection(
                            ) > jobproperties.TileRecFlags.TimeMinForAmpCorrection(
                            ):
                                theTileCellBuilder.TimeMinForAmpCorrection = jobproperties.TileRecFlags.TimeMinForAmpCorrection(
                                )
                                theTileCellBuilder.TimeMaxForAmpCorrection = jobproperties.TileRecFlags.TimeMaxForAmpCorrection(
                                )

                    ToolSvc += theTileCellBuilder
                    theCaloCellMaker.CaloCellMakerToolNames += [
                        theTileCellBuilder
                    ]
                except:
                    mlog.error("could not get handle to TileCellBuilder Quit")
                    print traceback.format_exc()
                    return False

        if doFastCaloSim:
            mlog.info('configuring FastCaloSim here')

            try:
                from FastCaloSim.FastCaloSimConf import EmptyCellBuilderTool
                theEmptyCellBuilderTool = EmptyCellBuilderTool()
                ToolSvc += theEmptyCellBuilderTool
                theCaloCellMaker.CaloCellMakerToolNames += [
                    theEmptyCellBuilderTool
                ]

                print theEmptyCellBuilderTool
                mlog.info("configure EmptyCellBuilderTool worked")
            except:
                mlog.error("could not get handle to EmptyCellBuilderTool Quit")
                print traceback.format_exc()
                return False

            try:
                from FastCaloSim.FastCaloSimFactory import FastCaloSimFactory
                theFastShowerCellBuilderTool = FastCaloSimFactory()

                ToolSvc += theFastShowerCellBuilderTool
                theCaloCellMaker.CaloCellMakerToolNames += [
                    theFastShowerCellBuilderTool
                ]
                mlog.info("configure FastShowerCellBuilderTool worked")
            except:
                mlog.error(
                    "could not get handle to FastShowerCellBuilderTool Quit")
                print traceback.format_exc()
                return False

            doFastCaloSimNoise = jobproperties.CaloCellFlags.doFastCaloSimNoise(
            )
            if doFastCaloSimNoise:
                try:
                    from FastCaloSim.FastCaloSimConf import AddNoiseCellBuilderTool
                    theAddNoiseCellBuilderTool = AddNoiseCellBuilderTool()

                    from CaloTools.CaloNoiseToolDefault import CaloNoiseToolDefault
                    theCaloNoiseTool = CaloNoiseToolDefault()
                    from AthenaCommon.AppMgr import ToolSvc
                    ToolSvc += theCaloNoiseTool

                    theAddNoiseCellBuilderTool.CaloNoiseTool = theCaloNoiseTool.getFullName(
                    )

                    print theAddNoiseCellBuilderTool

                    ToolSvc += theAddNoiseCellBuilderTool
                    theCaloCellMaker.CaloCellMakerToolNames += [
                        theAddNoiseCellBuilderTool
                    ]
                    mlog.info("configure AddNoiseCellBuilderTool worked")
                except:
                    mlog.error(
                        "could not get handle to AddNoiseCellBuilderTool Quit")
                    print traceback.format_exc()
                    return False

        #
        # CaloCellContainerFinalizerTool : closing container and setting up iterators
        #

        from CaloRec.CaloRecConf import CaloCellContainerFinalizerTool
        theCaloCellContainerFinalizerTool = CaloCellContainerFinalizerTool()
        ToolSvc += theCaloCellContainerFinalizerTool
        theCaloCellMaker.CaloCellMakerToolNames += [
            theCaloCellContainerFinalizerTool
        ]

        #
        # Mergeing of calo cellcontainer with sparse raw channel container with improved energies
        #

        doLArMerge = False
        if globalflags.DataSource(
        ) == 'data' and jobproperties.CaloCellFlags.doLArRawChannelMerge.statusOn and jobproperties.CaloCellFlags.doLArRawChannelMerge(
        ):
            from LArROD.LArRODFlags import larRODFlags
            if larRODFlags.readDigits() and larRODFlags.keepDSPRaw():
                doLArMerge = True
        if doLArMerge:
            try:
                from LArCellRec.LArCellRecConf import LArCellMerger
                theLArCellMerger = LArCellMerger()
            except:
                mlog.error("could not get handle to LArCellMerge Quit")
                print traceback.format_exc()
                return False
            theLArCellMerger.RawChannelsName = larRODFlags.RawChannelFromDigitsContainerName(
            )
            ToolSvc += theLArCellMerger
            theCaloCellMaker.CaloCellMakerToolNames += [theLArCellMerger]

        #
        # masking of noisy and sporadic noisy cells in LAr
        #

        doNoiseMask = False
        if jobproperties.CaloCellFlags.doLArNoiseMasking.statusOn and jobproperties.CaloCellFlags.doLArNoiseMasking(
        ):
            doNoiseMask = True
        doSporadicMask = False
        if jobproperties.CaloCellFlags.doLArSporadicMasking.statusOn and jobproperties.CaloCellFlags.doLArSporadicMasking(
        ):
            doSporadicMask = True

        if doNoiseMask or doSporadicMask:
            try:
                from LArCellRec.LArCellRecConf import LArCellNoiseMaskingTool
                theLArCellNoiseMaskingTool = LArCellNoiseMaskingTool()
            except:
                mlog.error(
                    "could not get handle to LArCellNoiseMaskingTool Quit")
                print traceback.format_exc()
                return False

            # bad channel tools
            try:
                from LArBadChannelTool.LArBadChannelToolConf import LArBadChanTool
                theLArBadChannelTool = LArBadChanTool()
            except:
                mlog.error("could not access bad channel tool Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theLArBadChannelTool

            if doSporadicMask:
                try:
                    from LArBadChannelTool.LArBadChannelToolConf import LArBadChannelMasker
                    theLArSporadicNoiseMasker = LArBadChannelMasker(
                        "LArSporadicNoiseMasker")
                except:
                    mlog.error("could not access bad channel tool Quit")
                    print traceback.format_exc()
                    return False
                theLArSporadicNoiseMasker.TheLArBadChanTool = theLArBadChannelTool
                theLArSporadicNoiseMasker.DoMasking = True
                theLArSporadicNoiseMasker.ProblemsToMask = [
                    "sporadicBurstNoise"
                ]
                ToolSvc += theLArSporadicNoiseMasker
                theLArCellNoiseMaskingTool.MaskingSporadicTool = theLArSporadicNoiseMasker

            if doNoiseMask:
                try:
                    from LArBadChannelTool.LArBadChannelToolConf import LArBadChannelMasker
                    theLArNoiseMasker = LArBadChannelMasker("LArNoiseMasker")
                except:
                    mlog.error("could not access bad channel tool Quit")
                    print traceback.format_exc()
                    return False
                theLArNoiseMasker.TheLArBadChanTool = theLArBadChannelTool
                theLArNoiseMasker.DoMasking = True
                theLArNoiseMasker.ProblemsToMask = [
                    "highNoiseHG", "highNoiseMG", "highNoiseLG", "deadReadout",
                    "deadPhys"
                ]
                ToolSvc += theLArNoiseMasker
                theLArCellNoiseMaskingTool.MaskingTool = theLArNoiseMasker

            theLArCellNoiseMaskingTool.maskNoise = doNoiseMask
            theLArCellNoiseMaskingTool.maskSporadic = doSporadicMask
            # quality cut for sporadic noise masking
            theLArCellNoiseMaskingTool.qualityCut = 4000
            ToolSvc += theLArCellNoiseMaskingTool
            theCaloCellMaker.CaloCellMakerToolNames += [
                theLArCellNoiseMaskingTool
            ]

        #
        #  masking of Feb problems
        #
        doBadFebMasking = False
        if jobproperties.CaloCellFlags.doLArBadFebMasking.statusOn and jobproperties.CaloCellFlags.doLArBadFebMasking(
        ):
            from AthenaCommon.GlobalFlags import globalflags
            if globalflags.DataSource() == 'data':
                doBadFebMasking = True

        if doBadFebMasking:
            try:
                from LArCellRec.LArCellRecConf import LArBadFebMaskingTool
                theLArBadFebMaskingTool = LArBadFebMaskingTool()
                if (
                        rec.doExpressProcessing()
                        or athenaCommonFlags.isOnline()
                ):  # In online or express processing, EventInfo::LArError is triggered if >=4 FEB with data corrupted
                    theLArBadFebMaskingTool.minFebInError = 4
            except:
                mlog.error("could not get handle to LArBadFebMaskingTool Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theLArBadFebMaskingTool

            # bad channel tools
            try:
                from LArBadChannelTool.LArBadChannelToolConf import LArBadChanTool
                theLArBadChannelTool = LArBadChanTool()
            except:
                mlog.error("could not access bad channel tool Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theLArBadChannelTool

            theLArBadFebMaskingTool.badChannelTool = theLArBadChannelTool
            theCaloCellMaker.CaloCellMakerToolNames += [
                theLArBadFebMaskingTool
            ]

        #
        #  emulate gain pathologies on MC
        #
        doGainPathology = False
        if jobproperties.CaloCellFlags.doLArCellGainPathology.statusOn and jobproperties.CaloCellFlags.doLArCellGainPathology(
        ):
            from AthenaCommon.GlobalFlags import globalflags
            if globalflags.DataSource() == 'geant4':
                doGainPathology = True

        if doGainPathology:
            try:
                from LArCellRec.LArCellRecConf import LArCellGainPathology
                theLArCellGainPathology = LArCellGainPathology()
            except:
                mlog.error("could not get handle to LArCellGainPatholog< Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theLArCellGainPathology

            theCaloCellMaker.CaloCellMakerToolNames += [
                theLArCellGainPathology
            ]

        # lar miscalibration if MC only  (should be done after finalisation)

        if not jobproperties.CaloCellFlags.doLArCellEmMisCalib.statusOn:
            # the flag has not been set, so decide a reasonable default
            # this is the old global flags should use the new one as
            # soon as monitoring does
            from AthenaCommon.GlobalFlags import globalflags
            if globalflags.DataSource() == 'data':
                doLArCellEmMisCalib = False
                mlog.info(
                    "jobproperties.CaloCellFlags.doLArMisCalib not set and real data: do not apply LArCellEmMisCalibTool"
                )
            else:
                doLArCellEmMisCalib = True
                mlog.info(
                    "jobproperties.CaloCellFlags.doLArMisCalib not set and Monte Carlo: apply LArCellEmMisCalibTool"
                )
        else:
            doLArCellEmMisCalib = jobproperties.CaloCellFlags.doLArCellEmMisCalib(
            )
            if doLArCellEmMisCalib:
                mlog.info("LArCellEmMisCalibTool requested")
            else:
                mlog.info("LArCellEmMisCalibTool explicitly not requested")

        if doLArCellEmMisCalib:
            try:
                from LArCellRec.LArCellRecConf import LArCellEmMiscalib
                theLArCellEmMiscalib = LArCellEmMiscalib("LArCellEmMiscalib")
            except:
                mlog.error("could not get handle to LArCellEmMisCalib Quit")
                print traceback.format_exc()
                return False

            # examples on how to change miscalibration. Default values are 0.005 and 0.007
            #        theLArCellEmMiscalib.SigmaPerRegion = 0.005;
            #        theLArCellEmMiscalib.SigmaPerCell = 0.005;

            ToolSvc += theLArCellEmMiscalib

            try:
                from CaloRec.CaloRecConf import CaloCellContainerCorrectorTool
                from CaloIdentifier import SUBCALO
                theMisCalibTool = CaloCellContainerCorrectorTool(
                    "MisCalibTool",
                    CaloNums=[SUBCALO.LAREM],
                    CellCorrectionToolNames=[theLArCellEmMiscalib])
            except:
                mlog.error("could not get handle to MisCalibTool Quit")
                print traceback.format_exc()
                return False

            ToolSvc += theMisCalibTool
            theCaloCellMaker.CaloCellMakerToolNames += [theMisCalibTool]

        #
        # Pedestal shift correction
        #
        doPedestalCorr = False
        if jobproperties.CaloCellFlags.doPedestalCorr.statusOn:
            from AthenaCommon.GlobalFlags import globalflags
            if jobproperties.CaloCellFlags.doPedestalCorr() and (
                    globalflags.DataSource() == 'data'
                    or jobproperties.CaloCellFlags.doPileupOffsetBCIDCorr):
                doPedestalCorr = True
                mlog.info("Apply cell level pedestal shift correction")

        import os
        if doPedestalCorr:
            try:
                from CaloCellCorrection.CaloCellPedestalCorrDefault import CaloCellPedestalCorrDefault
                theCaloCellPedestalCorr = CaloCellPedestalCorrDefault()
                ToolSvc += theCaloCellPedestalCorr
                theCaloCellMaker.CaloCellMakerToolNames += [
                    theCaloCellPedestalCorr
                ]
            except:
                mlog.error("could not get handle to CaloCellPedestalCorr")
                print traceback.format_exc()

        #
        # HV correction for offline reprocessing, reading HV from Cool-DCS database
        #
        doHVCorr = False
        from AthenaCommon.DetFlags import DetFlags
        if DetFlags.dcs.LAr_on():
            if jobproperties.CaloCellFlags.doLArHVCorr.statusOn:
                from AthenaCommon.GlobalFlags import globalflags
                if jobproperties.CaloCellFlags.doLArHVCorr(
                ) and globalflags.DataSource() == 'data':
                    doHVCorr = True
                    mlog.info(
                        "Redoing HV correction at cell level from COOL/DCS database"
                    )

        if doHVCorr:
            from LArCellRec.LArCellHVCorrDefault import LArCellHVCorrDefault
            theLArCellHVCorr = LArCellHVCorrDefault()

            try:
                from CaloRec.CaloRecConf import CaloCellContainerCorrectorTool
                from CaloIdentifier import SUBCALO
                theHVCorrTool = CaloCellContainerCorrectorTool(
                    "HVCorrTool",
                    CaloNums=[SUBCALO.LAREM, SUBCALO.LARHEC, SUBCALO.LARFCAL],
                    CellCorrectionToolNames=[theLArCellHVCorr])
            except:
                mlog.error("could not get handle to HVCorrTool Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theHVCorrTool
            theCaloCellMaker.CaloCellMakerToolNames += [theHVCorrTool]

        #
        # correction to undo online calibration and apply new LAr electronics calibration for ADC->MeV conversion
        #
        doLArRecalibration = False
        if jobproperties.CaloCellFlags.doLArRecalibration.statusOn:
            from AthenaCommon.GlobalFlags import globalflags
            from LArConditionsCommon.LArCondFlags import larCondFlags
            if jobproperties.CaloCellFlags.doLArRecalibration(
            ) and globalflags.DataSource() == 'data' and (
                    not larCondFlags.SingleVersion()):
                doLArRecalibration = True
                mlog.info("Redoing LAr electronics calibration for ADC->MeV")

        if doLArRecalibration:

            # get tool for cell recalibration
            try:
                from LArCellRec.LArCellRecConf import LArCellRecalibration
                theLArCellRecalibration = LArCellRecalibration(
                    "LArCellRecalibration")
            except:
                mlog.error("could not get handle to LArCellRecalibration Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theLArCellRecalibration

            # get new ADC2MeVTool
            try:
                from LArRecUtils.LArADC2MeVToolDefault import LArADC2MeVToolDefault
                theLArADC2MeVToolDefault = LArADC2MeVToolDefault()
            except:
                mlog.error(
                    "Could not get handle to LArADC2MeVToolDefault Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theLArADC2MeVToolDefault

            # get old  ADC2MeVTool
            try:
                from LArRecUtils.LArADC2MeVToolOnline import LArADC2MeVToolOnline
                theLArADC2MeVToolOnline = LArADC2MeVToolOnline()
            except:
                mlog.error("Could not get handle to LArADC2MeVToolOnline Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theLArADC2MeVToolOnline

            theLArCellRecalibration.adc2MeVTool = theLArADC2MeVToolDefault
            theLArCellRecalibration.adc2MeVToolOnline = theLArADC2MeVToolOnline

            try:
                from CaloRec.CaloRecConf import CaloCellContainerCorrectorTool
                from CaloIdentifier import SUBCALO
                theLArRecalibrationTool = CaloCellContainerCorrectorTool(
                    "LArRecalibrationTool",
                    CaloNums=[SUBCALO.LAREM, SUBCALO.LARHEC, SUBCALO.LARFCAL],
                    CellCorrectionToolNames=[theLArCellRecalibration])
            except:
                mlog.error("could not get handle to HVCorrTool Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theLArRecalibrationTool
            theCaloCellMaker.CaloCellMakerToolNames += [
                theLArRecalibrationTool
            ]

        #
        # Correction for MinBias energy shift for MC pileup reco
        #
        doMinBiasAverage = False
        if jobproperties.CaloCellFlags.doMinBiasAverage.statusOn:
            from AthenaCommon.GlobalFlags import globalflags
            from AthenaCommon.BeamFlags import jobproperties
            if jobproperties.CaloCellFlags.doMinBiasAverage(
            ) and globalflags.DataSource() == 'geant4' and (
                    not jobproperties.Beam.zeroLuminosity()):
                doMinBiasAverage = True

        if doMinBiasAverage:

            try:
                from CaloTools.CaloMBAverageToolDefault import CaloMBAverageToolDefault
                theCaloMBAverageTool = CaloMBAverageToolDefault()
            except:
                mlog.error("could not get handle to CaloMBAverageTool  Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theCaloMBAverageTool

            try:
                from CaloCellCorrection.CaloCellCorrectionConf import CaloCellMBAverageCorr
                theCaloCellMBAverageCorr = CaloCellMBAverageCorr(
                    "CaloCellMBAverageCorr")
                theCaloCellMBAverageCorr.CaloMBAverageTool = theCaloMBAverageTool
            except:
                mlog.error(
                    "could not get handle to  CaloCellMBAverageCorr  Quit")
                print traceback.format_exc()
                return False
            ToolSvc += theCaloCellMBAverageCorr

            try:
                from CaloRec.CaloRecConf import CaloCellContainerCorrectorTool
                from CaloIdentifier import SUBCALO
                theMBAverageTool = CaloCellContainerCorrectorTool(
                    "MBAverageTool",
                    CaloNums=[SUBCALO.NSUBCALO],
                    CellCorrectionToolNames=[theCaloCellMBAverageCorr])
            except:
                mlog.error(
                    "could not get handle to CaloCellContainerCorrectorTool/MBAverageTool Quit"
                )
                print traceback.format_exc()
                return False

            ToolSvc += theMBAverageTool
            theCaloCellMaker.CaloCellMakerToolNames += [theMBAverageTool]

        #
        # Correction for dead cells, where we average the energy density of neighbor cells
        #
        doNeighborsAverage = False
        if jobproperties.CaloCellFlags.doDeadCellCorr.statusOn:
            if jobproperties.CaloCellFlags.doDeadCellCorr():
                doNeighborsAverage = True

        if doNeighborsAverage:
            try:
                from CaloCellCorrection.CaloCellCorrectionConf import CaloCellNeighborsAverageCorr
                theCaloCellNeighborsAverageCorr = CaloCellNeighborsAverageCorr(
                    "CaloCellNeighborsAverageCorr")
                theCaloCellNeighborsAverageCorr.testMode = False
            except:
                mlog.error(
                    "could not get handle to  CaloCellNeighborsAverageCorr  Quit"
                )
                print traceback.format_exc()
                return False
            ToolSvc += theCaloCellNeighborsAverageCorr
            theCaloCellMaker.CaloCellMakerToolNames += [
                theCaloCellNeighborsAverageCorr
            ]

        #
        # correction for missing Febs based on L1 readout
        doLArDeadOTXCorr = False
        if jobproperties.CaloCellFlags.doLArDeadOTXCorr.statusOn and jobproperties.CaloCellFlags.doLArCreateMissingCells.statusOn:
            if jobproperties.CaloCellFlags.doLArDeadOTXCorr(
            ) and jobproperties.CaloCellFlags.doLArCreateMissingCells(
            ) and doStandardCellReconstruction:
                if rec.doTrigger():
                    doLArDeadOTXCorr = True
                else:
                    mlog.warning(
                        "Trigger is switched off. Can't run deadOTX correction."
                    )

        if doLArDeadOTXCorr:

            try:
                from LArCellRec.LArCellDeadOTXCorrToolDefault import LArCellDeadOTXCorrToolDefault
                theLArCellDeadOTXCorr = LArCellDeadOTXCorrToolDefault()
            except:
                mlog.error("could not get handle to LArCellDeadOTXCorr Quit")
                print traceback.format_exc()

            ToolSvc += theLArCellDeadOTXCorr
            theCaloCellMaker.CaloCellMakerToolNames += [theLArCellDeadOTXCorr]

        doCaloEnergyRescaler = False
        if jobproperties.CaloCellFlags.doCaloCellEnergyCorr(
        ) and globalflags.DataSource(
        ) == 'data' and not athenaCommonFlags.isOnline():

            try:
                from CaloCellCorrection.CaloCellCorrectionConf import CaloCellEnergyRescaler
                theCCERescalerTool = CaloCellEnergyRescaler()
                theCCERescalerTool.Folder = "/LAR/CellCorrOfl/EnergyCorr"
                ToolSvc += theCCERescalerTool
                from IOVDbSvc.CondDB import conddb
                # conddb.addFolder("","/LAR/CellCorrOfl/EnergyCorr<tag>EnergyScale-00</tag><db>sqlite://;schema=escale.db;dbname=COMP200</db>")
                conddb.addFolder("LAR_OFL", "/LAR/CellCorrOfl/EnergyCorr")
                ToolSvc += theCCERescalerTool
                theCaloCellMaker.CaloCellMakerToolNames += [theCCERescalerTool]
            except:
                mlog.error(
                    "could not get handle to CaloCellEnergyRescaler Quit")
                print traceback.format_exc()
                return False
            pass

        if jobproperties.CaloCellFlags.doCaloCellTimeCorr(
        ) and globalflags.DataSource(
        ) == 'data' and not athenaCommonFlags.isOnline():
            try:
                from CaloRec.CaloRecConf import CaloCellContainerCorrectorTool
                from CaloCellCorrection.CaloCellCorrectionConf import CaloCellTimeCorrTool
                theLArTimeCorr = CaloCellTimeCorrTool()
                theLArTimeCorr.Folder = "/LAR/TimeCorrectionOfl/CellTimeOffset"
                ToolSvc += theLArTimeCorr
                from IOVDbSvc.CondDB import conddb
                # conddb.addFolder("","/LAR/TimeCorrectionOfl/CellTimeOffset<tag>LARTimeCorrectionOflCellTimeOffset-empty</tag><db>sqlite://;schema=timecorr.db;dbname=COMP200</db>")
                conddb.addFolder("LAR_OFL",
                                 "/LAR/TimeCorrectionOfl/CellTimeOffset")
                theCaloTimeCorrTool = CaloCellContainerCorrectorTool(
                    "LArTimeCorrTool",
                    CellCorrectionToolNames=[theLArTimeCorr])
                ToolSvc += theCaloTimeCorrTool
                theCaloCellMaker.CaloCellMakerToolNames += [
                    theCaloTimeCorrTool
                ]

            except:
                mlog.error("could not get handle to CaloCellTimeCorrTool Quit")
                print traceback.format_exc()
                return False

            pass

        # make lots of checks (should not be necessary eventually)
        # to print the check add:

        from CaloRec.CaloRecConf import CaloCellContainerCheckerTool
        theCaloCellContainerCheckerTool = CaloCellContainerCheckerTool()
        # FIXME
        # theCaloCellContainerCheckerTool.OutputLevel=DEBUG

        ToolSvc += theCaloCellContainerCheckerTool
        theCaloCellMaker.CaloCellMakerToolNames += [
            theCaloCellContainerCheckerTool
        ]

        #

        # sets output key
        theCaloCellMaker.CaloCellsOutputName = self.outputKey()

        # register output in objKeyStore
        from RecExConfig.ObjKeyStore import objKeyStore

        objKeyStore.addStreamESD(self.outputType(), self.outputKey())

        # now add algorithm to topSequence
        # this should always come at the end

        mlog.info(" now adding CaloCellMaker to topSequence")

        from AthenaCommon.AlgSequence import AlgSequence
        topSequence = AlgSequence()

        topSequence += theCaloCellMaker

        return True