# Bytestream to TrigT1Calo objects conversions for data with Run 1 formats
include.block("TrigT1CaloByteStream/ReadLVL1CaloBSRun1_jobOptions.py")
# the following include is needed to load correctly the trigger towers on/off, TT/Cells maps
include("CaloConditions/CaloConditions_jobOptions.py")
# To setup correctly the LArCablingService when doLAr is off in the top option.
from RecExConfig.RecFlags import rec
if not rec.doLArg():
include("LArConditionsCommon/LArIdMap_comm_jobOptions.py")
include("LArIdCnv/LArIdCnv_joboptions.py")
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__CpByteStreamV1Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__CpmRoiByteStreamV1Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__JepByteStreamV1Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__JepRoiByteStreamV1Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__PpmByteStreamV1Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__PpmByteStreamReadV1V2Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__RodHeaderByteStreamTool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__L1CaloErrorByteStreamTool
ToolSvc = Service("ToolSvc")
ToolSvc += LVL1BS__CpByteStreamV1Tool("CpByteStreamV1Tool")
ToolSvc += LVL1BS__CpmRoiByteStreamV1Tool("CpmRoiByteStreamV1Tool")
ToolSvc += LVL1BS__JepByteStreamV1Tool("JepByteStreamV1Tool")
ToolSvc += LVL1BS__JepRoiByteStreamV1Tool("JepRoiByteStreamV1Tool")
ToolSvc += LVL1BS__PpmByteStreamV1Tool(
"PpmByteStreamV1Tool",
PpmMappingTool=
"LVL1::PpmCoolOrBuiltinMappingTool/PpmCoolOrBuiltinMappingTool")
ToolSvc += LVL1BS__PpmByteStreamReadV1V2Tool("PpmByteStreamReadV1V2Tool")
def setupMuonCalibNtuple():
global topSequence, muonRecFlags, beamFlags, ToolSvc, rec, DetFlags
if not rec.doMuon() or not DetFlags.Muon_on():
logMuon.warning(
"Not setting up requested Muon Calibration Ntuple because Muons are off"
)
return
logMuon.info("Setting up Muon Calibration Ntuple")
try:
configs = getCalibConfigs()
# MuonSegmentToCalibSegment is only needed if we want segments
if muonRecFlags.calibNtupleSegments and muonRecFlags.calibMuonStandalone:
MuonSegmentToCalibSegment = getMuonSegmentToCalibSegment()
# MuonCalibAlg is always needed
eventTag = "UNKNOWN"
if (muonRecFlags.calibNtupleSegments or muonRecFlags.calibNtupleTracks
) and muonRecFlags.calibMuonStandalone:
if len(configs) >= 1:
eventTag = configs[0]["eventTag"]
elif muonRecFlags.calibNtupleTrigger:
eventTag = "TRIG"
else:
eventTag = "HITS"
MuonCalibAlg = getMuonCalibAlg(eventTag)
# configure for writing ntuple
from MuonCalibTools.MuonCalibToolsConf import MuonCalib__PatternNtupleMaker
MuonCalibTool = MuonCalib__PatternNtupleMaker(
"MuonCalibPatternNtupleMaker")
MuonCalibTool.FillTruth = rec.doTruth()
MuonCalibTool.DoRawTGC = (muonRecFlags.doTGCs()
and muonRecFlags.calibNtupleRawTGC())
ToolSvc += MuonCalibTool
MuonCalibAlg.MuonCalibTool = MuonCalibTool
# MuonCalibExtraTree only if we want to write tracks
if muonRecFlags.calibNtupleTracks:
MuonCalibTool.DelayFinish = True
from MuonCalibExtraTreeAlg.MuonCalibExtraTreeAlgConf import MuonCalib__MuonCalibExtraTreeAlg
MuonCalibExtraTreeAlg = MuonCalib__MuonCalibExtraTreeAlg(
"MuonCalibExtraTreeAlg",
NtupleName="PatternNtupleMaker",
)
segmentOnTrackSelector = None
if hasattr(topSequence, "MuonSegmentToCalibSegment"):
from MuonCalibExtraTreeAlg.MuonCalibExtraTreeAlgConf import MuonCalib__SegmentOnTrackSelector
segmentOnTrackSelector = MuonCalib__SegmentOnTrackSelector()
segmentOnTrackSelector.PattternLocation = "PatternsForCalibration"
ToolSvc += segmentOnTrackSelector
MuonCalibExtraTreeAlg.SegmentOnTrackSelector = segmentOnTrackSelector
if not rec.doMuonCombined():
tool_nr = 0
from MuonCalibExtraTreeAlg.MuonCalibExtraTreeAlgConf import MuonCalib__ExtraTreeTrackFillerTool
resPullCalc = getPublicTool("ResidualPullCalculator")
for config in configs:
trackDumpTool = MuonCalib__ExtraTreeTrackFillerTool(
"ExtraTreeTrackFillerTool" + str(tool_nr))
trackDumpTool.TrackCollectionKey = config['tracksKey']
trackDumpTool.SegmentAuthors = [config['segmentAuthor']]
trackDumpTool.TrackAuthor = config['trackAuthor']
trackDumpTool.PullCalculator = resPullCalc
ToolSvc += trackDumpTool
MuonCalibExtraTreeAlg.TrackFillerTools.append(
trackDumpTool)
tool_nr += 1
# configure needed tools
# add to topSequence
topSequence += MuonCalibExtraTreeAlg
# MuonCalibExtraTreeTriggerAlg only if trigger is available
if muonRecFlags.calibNtupleTrigger: # and DetFlags.detdescr.LVL1_on() and DetFlags.haveRDO.LVL1_on():
# protect against running without AtlasTrigger project
doMuCTPI = True
if doMuCTPI:
try:
from TrigT1RPCRecRoiSvc import TrigT1RPCRecRoiConfig
from TrigT1TGCRecRoiSvc import TrigT1TGCRecRoiConfig
except ImportError:
logMuon.warning(
"MuonCalibExtraTreeTriggerAlg.doMuCTPI = False because AtlasTrigger is not available"
)
doMuCTPI = False
# delay writing of MuonCalibAlg
MuonCalibTool.DelayFinish = True
# also delay MuonCalibExtraTreeAlg if it is running
try:
topSequence.MuonCalibExtraTreeAlg.DelayFinish = True
except AttributeError:
pass
from MuonCalibExtraTreeAlg.MuonCalibExtraTreeAlgConf import MuonCalib__MuonCalibExtraTreeTriggerAlg
topSequence += MuonCalib__MuonCalibExtraTreeTriggerAlg(
'MuonCalibExtraTreeTriggerAlg',
doMuCTPI=doMuCTPI,
doLVL1Calo=rec.doTile() or rec.doLArg()
or DetFlags.haveRDO.Calo_on(),
doMBTS=rec.doTile() or DetFlags.haveRDO.Tile_on())
except:
from AthenaCommon.Resilience import treatException
treatException(
"Problem in MuonCalib - Muon Calibration Ntuple configuration probably incomplete"
)
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
# Bytestream to TrigT1Calo objects conversions for data with Run 2 formats
include.block("TrigT1CaloByteStream/ReadLVL1CaloBSRun2_jobOptions.py")
# the following include is needed to load correctly the trigger towers on/off, TT/Cells maps
include( "CaloConditions/CaloConditions_jobOptions.py" )
# To setup correctly the LArCablingService when doLAr is off in the top option.
from RecExConfig.RecFlags import rec
if not rec.doLArg():
include( "LArConditionsCommon/LArIdMap_comm_jobOptions.py" )
include( "LArIdCnv/LArIdCnv_joboptions.py" )
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__CpByteStreamV2Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__CpmRoiByteStreamV2Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__JepByteStreamV2Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__JepRoiByteStreamV2Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__PpmByteStreamV2Tool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__L1CaloByteStreamReadTool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__RodHeaderByteStreamTool
from TrigT1CaloByteStream.TrigT1CaloByteStreamConf import LVL1BS__L1CaloErrorByteStreamTool
ToolSvc = Service("ToolSvc")
ToolSvc += LVL1BS__CpByteStreamV2Tool("CpByteStreamV2Tool")
ToolSvc += LVL1BS__CpmRoiByteStreamV2Tool("CpmRoiByteStreamV2Tool")
ToolSvc += LVL1BS__JepByteStreamV2Tool("JepByteStreamV2Tool")
ToolSvc += LVL1BS__JepRoiByteStreamV2Tool("JepRoiByteStreamV2Tool")
ToolSvc += LVL1BS__PpmByteStreamV2Tool("PpmByteStreamTool",
PpmMappingTool="LVL1::PpmCoolOrBuiltinMappingTool/PpmCoolOrBuiltinMappingTool",
PrintCompStats=1
)
from CaloRec.CaloRecFlags import jobproperties
from AthenaCommon.Resilience import treatException
from RecExConfig.RecFlags import rec
from AthenaCommon.GlobalFlags import globalflags
from AthenaCommon.DetFlags import DetFlags
from AthenaCommon.Logging import logging
if globalflags.DataSource() == 'data':
if rec.projectName() == "data09_calophys":
# for data09_calophys project, force to use DSP output for the cell energy, perform reco like DSP, no dead cell correction
if rec.doLArg():
from LArROD.LArRODFlags import larRODFlags
larRODFlags.readDigits = False
if rec.doTile():
from TileRecUtils.TileRecFlags import jobproperties
jobproperties.TileRecFlags.readDigits = False
from CaloRec.CaloCellFlags import jobproperties
jobproperties.CaloCellFlags.doDeadCellCorr = False
jobproperties.CaloCellFlags.doLArCreateMissingCells = False
jobproperties.CaloCellFlags.doLArDeadOTXCorr = False
else:
if rec.doLArg() and globalflags.InputFormat(
) == 'bytestream' and jobproperties.CaloRecFlags.doLArAutoConfiguration(
):
# for bytestream reco of real data, autoconfigure based on the run format information
# use digits only when digits available for all cells (transparent or rawdataresult)
def configure(self):
from AthenaCommon.Logging import logging
mlog = logging.getLogger('CaloCellGetter_DigiHSTruth::configure:')
mlog.info('entering')
doStandardCellReconstruction = True
from CaloRec.CaloCellFlags import jobproperties
# get handle to upstream object
# handle tile
if doStandardCellReconstruction:
from LArROD.LArRODFlags import larRODFlags
# 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 Exception:
mlog.error("could not import CaloRec.CaloCellMaker")
print(traceback.format_exc())
return False
theCaloCellMaker = CaloCellMaker("CaloCellMaker_DigiHSTruth")
self._CaloCellMakerHandle = theCaloCellMaker
from AthenaCommon.AppMgr import ToolSvc
if doStandardCellReconstruction:
# configure CaloCellMaker here
# check LArCellMakerTool_jobOptions.py for full configurability
# FIXME
if rec.doLArg():
from LArCabling.LArCablingAccess import LArOnOffIdMapping
LArOnOffIdMapping()
try:
from LArCellRec.LArCellRecConf import LArCellBuilderFromLArRawChannelTool
theLArCellBuilder = LArCellBuilderFromLArRawChannelTool(
"LArCellBuilder_DigiHSTruth")
theLArCellBuilder.RawChannelsName = "LArRawChannels_DigiHSTruth"
except Exception:
mlog.error(
"could not get handle to LArCellBuilderFromLArRawChannel Quit"
)
print(traceback.format_exc())
return False
if jobproperties.CaloCellFlags.doLArCreateMissingCells():
theLArCellBuilder.addDeadOTX = True
# add the tool to list of tool ( should use ToolHandle eventually)
theCaloCellMaker += theLArCellBuilder
theCaloCellMaker.CaloCellMakerToolNames += [theLArCellBuilder]
if rec.doTile():
try:
from TileRecUtils.TileRecUtilsConf import TileCellBuilder
theTileCellBuilder = TileCellBuilder(
"TileCellBuilder_DigiHSTruth")
theTileCellBuilder.TileRawChannelContainer = "TileRawChannelCnt_DigiHSTruth"
theTileCellBuilder.E4prContainer = "E4prContainer2_DigiHSTruth"
theTileCellBuilder.MBTSContainer = "MBTSContainer2_DigiHSTruth"
theTileCellBuilder.TileDSPRawChannelContainer = "TileRawChannelCnt_DigiHSTruth"
theCaloCellMaker += theTileCellBuilder
theCaloCellMaker.CaloCellMakerToolNames += [
theTileCellBuilder
]
except Exception:
mlog.error("could not get handle to TileCellBuilder Quit")
print(traceback.format_exc())
return False
#
# CaloCellContainerFinalizerTool : closing container and setting up iterators
#
from CaloRec.CaloRecConf import CaloCellContainerFinalizerTool
theCaloCellContainerFinalizerTool = CaloCellContainerFinalizerTool(
"CaloCellContainerFinalizerTool_DigiHSTruth")
theCaloCellMaker += theCaloCellContainerFinalizerTool
theCaloCellMaker.CaloCellMakerToolNames += [
theCaloCellContainerFinalizerTool
]
#
# Mergeing of calo cellcontainer with sparse raw channel container with improved energies
#
doLArMerge = False
if doLArMerge:
try:
from LArCellRec.LArCellRecConf import LArCellMerger
theLArCellMerger = LArCellMerger()
except Exception:
mlog.error("could not get handle to LArCellMerge Quit")
print(traceback.format_exc())
return False
theLArCellMerger.RawChannelsName = larRODFlags.RawChannelFromDigitsContainerName(
)
theCaloCellMaker += 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 Exception:
mlog.error(
"could not get handle to LArCellNoiseMaskingTool Quit")
print(traceback.format_exc())
return False
if doSporadicMask:
try:
from LArBadChannelTool.LArBadChannelToolConf import LArBadChannelMasker
theLArSporadicNoiseMasker = LArBadChannelMasker(
"LArSporadicNoiseMasker")
except Exception:
mlog.error("could not access bad channel tool Quit")
print(traceback.format_exc())
return False
theLArSporadicNoiseMasker.DoMasking = True
theLArSporadicNoiseMasker.ProblemsToMask = [
"sporadicBurstNoise"
]
ToolSvc += theLArSporadicNoiseMasker
theLArCellNoiseMaskingTool.MaskingSporadicTool = theLArSporadicNoiseMasker
if doNoiseMask:
try:
from LArBadChannelTool.LArBadChannelToolConf import LArBadChannelMasker
theLArNoiseMasker = LArBadChannelMasker("LArNoiseMasker")
except Exception:
mlog.error("could not access bad channel tool Quit")
print(traceback.format_exc())
return False
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
theCaloCellMaker += theLArCellNoiseMaskingTool
theCaloCellMaker.CaloCellMakerToolNames += [
theLArCellNoiseMaskingTool
]
#
# masking of Feb problems
#
doBadFebMasking = False
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 Exception:
mlog.error("could not get handle to LArBadFebMaskingTool Quit")
print(traceback.format_exc())
return False
theCaloCellMaker += theLArBadFebMaskingTool
theCaloCellMaker.CaloCellMakerToolNames += [
theLArBadFebMaskingTool
]
#
# emulate gain pathologies on MC
#
doGainPathology = False
if jobproperties.CaloCellFlags.doLArCellGainPathology.statusOn and jobproperties.CaloCellFlags.doLArCellGainPathology(
):
if globalflags.DataSource() == 'geant4':
doGainPathology = True
if doGainPathology:
try:
from LArCellRec.LArCellRecConf import LArCellGainPathology
theLArCellGainPathology = LArCellGainPathology()
except Exception:
mlog.error("could not get handle to LArCellGainPatholog< Quit")
print(traceback.format_exc())
return False
theCaloCellMaker += 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
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 Exception:
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 Exception:
mlog.error("could not get handle to MisCalibTool Quit")
print(traceback.format_exc())
return False
theCaloCellMaker += theMisCalibTool
theCaloCellMaker.CaloCellMakerToolNames += [theMisCalibTool]
#
# Pedestal shift correction
#
doPedestalCorr = False
if jobproperties.CaloCellFlags.doPedestalCorr.statusOn:
if jobproperties.CaloCellFlags.doPedestalCorr() and (
jobproperties.CaloCellFlags.doPileupOffsetBCIDCorr):
doPedestalCorr = True
mlog.info("Apply cell level pedestal shift correction")
if doPedestalCorr:
try:
from CaloCellCorrection.CaloCellPedestalCorrDefault import CaloCellPedestalCorrDefault
theCaloCellPedestalCorr = CaloCellPedestalCorrDefault()
theCaloCellMaker += theCaloCellPedestalCorr
theCaloCellMaker.CaloCellMakerToolNames += [
theCaloCellPedestalCorr
]
except Exception:
mlog.error("could not get handle to CaloCellPedestalCorr")
print(traceback.format_exc())
#
# Correction for MinBias energy shift for MC pileup reco
#
doMinBiasAverage = False
if jobproperties.CaloCellFlags.doMinBiasAverage.statusOn:
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 Exception:
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 Exception:
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 Exception:
mlog.error(
"could not get handle to CaloCellContainerCorrectorTool/MBAverageTool Quit"
)
print(traceback.format_exc())
return False
theCaloCellMaker += 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 Exception:
mlog.error(
"could not get handle to CaloCellNeighborsAverageCorr Quit"
)
print(traceback.format_exc())
return False
theCaloCellMaker += 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 Exception:
mlog.error("could not get handle to LArCellDeadOTXCorr Quit")
print(traceback.format_exc())
theCaloCellMaker += theLArCellDeadOTXCorr
theCaloCellMaker.CaloCellMakerToolNames += [theLArCellDeadOTXCorr]
# 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
theCaloCellMaker += 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())
# Also note that we produce it as a transient output.
objKeyStore.addTransient(self.outputType(), self.outputKey())
from TileRecUtils.TileDQstatusAlgDefault import TileDQstatusAlgDefault
TileDQstatusAlgDefault()
# 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