def LArCalibPedMonConfig(inputFlags,
gain="",
doAccDigit=False,
doCalibDigit=False,
doAccCalibDigit=False):
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'LArCalibPedMonCfg')
from LArMonitoring.GlobalVariables import lArDQGlobals
from AthenaConfiguration.ComponentFactory import CompFactory
larPedMonAlg = helper.addAlgorithm(CompFactory.LArCalibPedMonAlg,
'larCalibPedMonAlg')
if gain != "":
if doAccDigit:
larPedMonAlg.LArAccumulatedDigitContainerKey = gain
elif doAccCalibDigit:
larPedMonAlg.LArAccumulatedCalibDigitContainerKey = gain
elif doCalibDigit:
larPedMonAlg.LArCalibDigitContainerKey = gain
GroupName = "PedMonGroup"
larPedMonAlg.LArPedGroupName = GroupName
Group = helper.addGroup(larPedMonAlg, GroupName, '/LAr/' + GroupName + '/')
#Summary histos
summary_hist_path = 'Summary/'
Group.defineHistogram(
'nbChan;NbOfReadoutChannelsGlobal',
title='# of readout channels',
type='TH1I',
path=summary_hist_path,
xbins=lArDQGlobals.N_FEB * lArDQGlobals.FEB_N_channels + 5,
xmin=-0.5,
xmax=lArDQGlobals.N_FEB * lArDQGlobals.FEB_N_channels + 4.5)
return helper.result()
def TrigBjetMonConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
# from AthenaCommon.Logging import logging
# log = logging.getLogger( 'TrigBjetMonitorAlgorithm.py' )
### STEP 1 ###
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
# EN: Not needed for the moment
# from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
# result = ComponentAccumulator()
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'TrigBjetAthMonitorCfg')
### STEP 2 ###
# Adding an algorithm to the helper. Here, we will use the example
# algorithm in the AthenaMonitoring package. Just pass the type to the
# helper. Then, the helper will instantiate an instance and set up the
# base class configuration following the inputFlags. The returned object
# is the algorithm.
#The added algorithm must exist as a .h file
from AthenaConfiguration.ComponentFactory import CompFactory
trigBjetMonAlg = helper.addAlgorithm(CompFactory.TrigBjetMonitorAlgorithm,
'TrigBjetMonAlg')
# You can actually make multiple instances of the same algorithm and give
# them different configurations
#shifterTrigBjetMonAlg = helper.addAlgorithm(TrigBjetMonitorAlgorithm,'ShifterTrigBjetMonAlg')
# # If for some really obscure reason you need to instantiate an algorithm
# # yourself, the AddAlgorithm method will still configure the base
# # properties and add the algorithm to the monitoring sequence.
# helper.AddAlgorithm(myExistingAlg)
### STEP 3 ###
# Edit properties of a algorithm
# some generic property
# trigBjetMonAlg.RandomHist = True
# to enable a trigger filter, for example:
#trigBjetMonAlg.TriggerChain = 'HLT_mu26_ivarmedium'
#trigBjetMonAlg.TriggerChain = 'HLT_e24_lhtight_nod0'
trigBjetMonAlg.TriggerChain = ''
### STEP 4 ###
# Read in the Bjet trigger chain names
# Directly from TrigBjetMonitCategory
#from TrigBjetMonitoring import TrigBjetMonitCategory
#bjet_triglist = TrigBjetMonitCategory.monitoring_bjet
#bjet_triglist += TrigBjetMonitCategory.monitoring_mujet
#print " ==> bjet_triglist: ", bjet_triglist
# From the hltmonList where TrigHLTMonitoring filtered the run type
from TrigHLTMonitoring.HLTMonTriggerList import hltmonList
bjet_triglist = hltmonList.monitoring_bjet
bjet_triglist += hltmonList.monitoring_mujet
# print " ==> bjet_triglist: ", bjet_triglist
# Add some tools. N.B. Do not use your own trigger decion tool. Use the
# standard one that is included with AthMonitorAlgorithm.
# # First, add a tool that's set up by a different configuration function.
# # In this case, CaloNoiseToolCfg returns its own component accumulator,
# # which must be merged with the one from this function.
# from CaloTools.CaloNoiseToolConfig import CaloNoiseToolCfg
# caloNoiseAcc, caloNoiseTool = CaloNoiseToolCfg(inputFlags)
# result.merge(caloNoiseAcc)
# trigBjetMonAlg.CaloNoiseTool = caloNoiseTool
# # Then, add a tool that doesn't have its own configuration function. In
# # this example, no accumulator is returned, so no merge is necessary.
# from MyDomainPackage.MyDomainPackageConf import MyDomainTool
# trigBjetMonAlg.MyDomainTool = MyDomainTool()
# Add a generic monitoring tool (a "group" in old language). The returned
# object here is the standard GenericMonitoringTool.
BjetMonGroup = helper.addGroup(trigBjetMonAlg, 'TrigBjetMonitor',
'HLT/BjetMon/')
# Add a GMT for the other example monitor algorithm
#shifterGroup = helper.addGroup(shifterTrigBjetMonAlg,'TrigBjetMonitor','HLT/BjetMon/Shifter/')
### STEP 5 ###
# Configure histograms
#NB! The histograms defined here must match the ones in the cxx file exactly
# Offline PV histograms - common for all trigger chains
BjetMonGroup.defineHistogram(
'Off_NVtx',
title='Number of Offline Vertices;NVtx;Events',
path='Shifter/Offline',
xbins=100,
xmin=0.0,
xmax=100.)
BjetMonGroup.defineHistogram('Off_xVtx',
title='Offline xVtx;xVtx;Events',
path='Shifter/Offline',
xbins=200,
xmin=-1.5,
xmax=+1.5)
BjetMonGroup.defineHistogram('Off_yVtx',
title='Offline yVtx;yVtx;Events',
path='Shifter/Offline',
xbins=200,
xmin=-1.5,
xmax=+1.5)
BjetMonGroup.defineHistogram('Off_zVtx',
title='Offline zVtx;zVtx;Events',
path='Shifter/Offline',
xbins=500,
xmin=-250.0,
xmax=+250.0)
# Histograms which depend on the trigger chain
# mu-jet histograms
AllChains = []
for chain in bjet_triglist:
AllChains.append(chain[2:])
# print " inside bjet_triglist chain[2:8] : " , chain[2:8]
if chain[2:8] == 'HLT_mu': # mu-jets
# print " mu-jet histogram is defined for ", chain[2:]
HistName = 'jetPt_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of Pt_jet;Pt_jet;Events',
path='Expert/' + chain[2:],
xbins=100,
xmin=0.0,
xmax=750.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of Pt_jet;Pt_jet;Events',
path='Shifter/' + chain[2:],
xbins=100,
xmin=0.0,
xmax=750.0)
continue
else: # b-jets
# print " b-jet histogram is defined for ", chain[2:]
# b-jet histograms
# Primary vertex histograms
# PV associated to jets
HistName = 'PVz_jet_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title=
'Distribution of online zPV from jets;zPV from jets;Events',
path='Expert/' + chain[2:],
xbins=500,
xmin=-250.0,
xmax=250.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title=
'Distribution of online zPV from jets;zPV from jets;Events',
path='Shifter/' + chain[2:],
xbins=500,
xmin=-250.0,
xmax=250.0)
HistName = 'PVx_jet_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title=
'Distribution of online xPV from jets;xPV from jets;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=-1.5,
xmax=+1.5)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title=
'Distribution of online xPV from jets;xPV from jets;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=-1.5,
xmax=+1.5)
HistName = 'PVy_jet_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title=
'Distribution of online yPV from jets;yPV from jets;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=-1.5,
xmax=+1.5)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title=
'Distribution of online yPV from jets;yPV from jets;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=-1.5,
xmax=+1.5)
# PV directly from SG
HistName = 'nPV_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Number of online PV per event;nPV;Events',
path='Expert/' + chain[2:],
xbins=101,
xmin=-1.0,
xmax=100.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Number of online PV per event;nPV;Events',
path='Shifter/' + chain[2:],
xbins=101,
xmin=-1.0,
xmax=100.0)
HistName = 'PVz_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of online zPV;zPV;Events',
path='Expert/' + chain[2:],
xbins=500,
xmin=-250.0,
xmax=250.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of online zPV;zPV;Events',
path='Shifter/' + chain[2:],
xbins=500,
xmin=-250.0,
xmax=250.0)
HistName = 'PVx_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of online xPV;xPV from jets;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=-1.5,
xmax=+1.5)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of online xPV;xPV from jets;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=-1.5,
xmax=+1.5)
HistName = 'PVy_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of online yPV;yPV from jets;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=-1.5,
xmax=+1.5)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of online yPV;yPV from jets;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=-1.5,
xmax=+1.5)
# track histograms
HistName = 'nTrack_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Number of tracks;nTrack;Events',
path='Expert/' + chain[2:],
xbins=40,
xmin=0.0,
xmax=40.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Number of tracks;nTrack;Events',
path='Shifter/' + chain[2:],
xbins=40,
xmin=0.0,
xmax=40.0)
HistName = 'trkPt_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(HistName,
title='Pt of tracks;Pt;Events',
path='Expert/' + chain[2:],
xbins=100,
xmin=0.0,
xmax=50.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(HistName,
title='Pt of tracks;Pt;Events',
path='Shifter/' + chain[2:],
xbins=100,
xmin=0.0,
xmax=50.0)
HistName = 'trkEta_' + chain[2:] + ',trkPhi_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
type='TH2F',
title='Phi vs Eta of tracks;Eta;Phi',
path='Expert/' + chain[2:],
xbins=20,
xmin=-5.0,
xmax=+5.0,
ybins=20,
ymin=-3.1416,
ymax=+3.1416)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
type='TH2F',
title='Phi vs Eta of tracks;Eta;Phi',
path='Shifter/' + chain[2:],
xbins=20,
xmin=-5.0,
xmax=+5.0,
ybins=20,
ymin=-3.1416,
ymax=+3.1416)
HistName = 'd0_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of d0;d0;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=-2.0,
xmax=2.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of d0;d0;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=-2.0,
xmax=2.0)
HistName = 'ed0_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of sig(d0);sig(d0);Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=0.,
xmax=1.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of sig(d0);sig(d0);Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=0.,
xmax=1.0)
HistName = 'z0_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of z0;z0;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=-250.0,
xmax=250.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of z0;z0;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=-250.0,
xmax=250.0)
HistName = 'ez0_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of sig(z0);sig(z0);Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=0.,
xmax=5.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of sig(z0);sig(z0);Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=0.,
xmax=5.0)
# jet histograms
HistName = 'nJet_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Number of jets;nJet;Events',
path='Expert/' + chain[2:],
xbins=40,
xmin=0.0,
xmax=40.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Number of jets;nJet;Events',
path='Shifter/' + chain[2:],
xbins=40,
xmin=0.0,
xmax=40.0)
HistName = 'jetPt_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of Pt_jet;Pt_jet;Events',
path='Expert/' + chain[2:],
xbins=100,
xmin=0.0,
xmax=750.0)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of Pt_jet;Pt_jet;Events',
path='Shifter/' + chain[2:],
xbins=100,
xmin=0.0,
xmax=750.0)
HistName = 'jetEta_' + chain[2:] + ',jetPhi_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
type='TH2F',
title='Phi vs Eta of jets;Eta_jet;Phi_jet',
path='Expert/' + chain[2:],
xbins=20,
xmin=-5.0,
xmax=+5.0,
ybins=20,
ymin=-3.1416,
ymax=+3.1416)
# print " ==> histogram ",HistName," is defined for Expert folder"
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
type='TH2F',
title='Phi vs Eta of jets;Eta_jet;Phi_jet',
path='Shifter/' + chain[2:],
xbins=20,
xmin=-5.0,
xmax=+5.0,
ybins=20,
ymin=-3.1416,
ymax=+3.1416)
# b-tagging quantities
HistName = 'IP3D_pu_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='IP3D_pu probability distribution;IP3D_pu;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=0.0,
xmax=1.0)
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='IP3D_pu probability distribution;IP3D_pu;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=0.0,
xmax=1.0)
HistName = 'IP3D_pb_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='IP3D_pb probability distribution;IP3D_pb;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=0.0,
xmax=1.0)
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='IP3D_pb probability distribution;IP3D_pb;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=0.0,
xmax=1.0)
HistName = 'IP3D_pc_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='IP3D_pc probability distribution;IP3D_pc;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=0.0,
xmax=1.0)
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='IP3D_pc probability distribution;IP3D_pc;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=0.0,
xmax=1.0)
HistName = 'wIP3D_Rbu_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title=
'LogLH IP3D_pb/IP3D_pu probability ratio distribution;LogLH IP3D_pb/IP3D_pu;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=-4.0,
xmax=6.0)
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title=
'LogLH IP3D_pb/IP3D_pu probability ratio distribution;LogLH IP3D_pb/IP3D_pu;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=-4.0,
xmax=6.0)
HistName = 'wSV1_Rbu_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title=
'LogLH SV1_pb/SV1_pu probability ratio distribution;LogLH SV1_pb/SV1_pu;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=-4.0,
xmax=6.0)
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title=
'LogLH SV1_pb/SV1_pu probability ratio distribution;LogLH SV1_pb/SV1_pu;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=-4.0,
xmax=6.0)
HistName = 'wCOMB_Rbu_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title=
'LogLH IP3D+SV1 probability ratio distribution;LogLH IP3D+SV1 probability ratio;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=-4.0,
xmax=6.0)
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title=
'LogLH IP3D+SV1 probability ratio distribution;LogLH IP3D+SV1 probability ratio;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=-4.0,
xmax=6.0)
HistName = 'wMV2c10_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of MV2c10 discriminant;MV2c10;Events',
path='Expert/' + chain[2:],
xbins=200,
xmin=-1.0,
xmax=1.0)
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='Distribution of MV2c10 discriminant;MV2c10;Events',
path='Shifter/' + chain[2:],
xbins=200,
xmin=-1.0,
xmax=1.0)
HistName = 'xMVtx_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='SV1 mass distribution;SV1 mass;Events',
path='Expert/' + chain[2:],
xbins=50,
xmin=0.0,
xmax=10.0)
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='SV1 mass distribution;SV1 mass;Events',
path='Shifter/' + chain[2:],
xbins=50,
xmin=0.0,
xmax=10.0)
HistName = 'xEVtx_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title='SV1 E-fraction distribution;SV1 E-fraction;Events',
path='Expert/' + chain[2:],
xbins=50,
xmin=0.0,
xmax=1.0)
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title='SV1 E-fraction distribution;SV1 E-fraction;Events',
path='Shifter/' + chain[2:],
xbins=50,
xmin=0.0,
xmax=1.0)
HistName = 'xNVtx_tr_' + chain[2:]
if chain[0:1] == "E":
BjetMonGroup.defineHistogram(
HistName,
title=
'Distribution of number of 2-track SV1;Number of 2-track SV1;Events',
path='Expert/' + chain[2:],
xbins=40,
xmin=0.0,
xmax=40.0)
if chain[0:1] == "S":
BjetMonGroup.defineHistogram(
HistName,
title=
'Distribution of number of 2-track SV1;Number of 2-track SV1;Events',
path='Shifter/' + chain[2:],
xbins=40,
xmin=0.0,
xmax=40.0)
continue
# print " ==> In TrigBjetMonitorAlgorithm.py: AllChains list: ", AllChains
trigBjetMonAlg.AllChains = AllChains
### STEP 6 ###
# Finalize. The return value should be a tuple of the ComponentAccumulator
# and the sequence containing the created algorithms. If we haven't called
# any configuration other than the AthMonitorCfgHelper here, then we can
# just return directly (and not create "result" above)
return helper.result()
def TileJetMonitoringConfig(flags, **kwargs):
''' Function to configure TileJetMonitorAlgorithm algorithm in the monitoring system.'''
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
from TileGeoModel.TileGMConfig import TileGMCfg
result.merge(TileGMCfg(flags))
from LArGeoAlgsNV.LArGMConfig import LArGMCfg
result.merge(LArGMCfg(flags))
from TileConditions.TileCablingSvcConfig import TileCablingSvcCfg
result.merge(TileCablingSvcCfg(flags))
from TileConditions.TileBadChannelsConfig import TileBadChanToolCfg
badChanTool = result.popToolsAndMerge(TileBadChanToolCfg(flags))
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(flags, 'TileMonitoring')
# Adding an TileJetMonitorAlgorithm algorithm to the helper
from AthenaConfiguration.ComponentFactory import CompFactory
tileJetMonAlg = helper.addAlgorithm(CompFactory.TileJetMonitorAlgorithm,
'TileJetMonAlg')
tileJetMonAlg.TileBadChanTool = badChanTool
tileJetMonAlg.TriggerChain = ''
for k, v in kwargs.items():
setattr(tileJetMonAlg, k, v)
DoEnergyProfiles = kwargs.get(
'DoEnergyProfiles',
tileJetMonAlg._descriptors['DoEnergyProfiles'].default)
Do1DHistograms = kwargs.get(
'Do1DHistograms', tileJetMonAlg._descriptors['Do1DHistograms'].default)
DoEnergyDiffHistograms = kwargs.get(
'DoEnergyDiffHistograms',
tileJetMonAlg._descriptors['DoEnergyDiffHistograms'].default)
if flags.DQ.DataType not in ('heavyioncollisions', 'cosmics'):
jvtTool = CompFactory.JetVertexTaggerTool()
jetContainer = kwargs.get(
'JetContainer', tileJetMonAlg._descriptors['JetContainer'].default)
jvtTool.JetContainer = jetContainer
tileJetMonAlg.JVT = jvtTool
jetCleaningTool = CompFactory.JetCleaningTool()
jetCleaningTool.CutLevel = "LooseBad"
jetCleaningTool.DoUgly = False
tileJetMonAlg.JetCleaningTool = jetCleaningTool
result.addPublicTool(jetCleaningTool)
jetPtMin = 20000
jetTrackingEtaLimit = 2.4
eventCleaningTool = CompFactory.ECUtils.EventCleaningTool()
eventCleaningTool.JetCleaningTool = jetCleaningTool
eventCleaningTool.PtCut = jetPtMin
eventCleaningTool.EtaCut = jetTrackingEtaLimit
eventCleaningTool.JvtDecorator = "passJvt"
eventCleaningTool.OrDecorator = "passOR"
eventCleaningTool.CleaningLevel = jetCleaningTool.CutLevel
tileJetMonAlg.EventCleaningTool = eventCleaningTool
tileJetMonAlg.JetTrackingEtaLimit = jetTrackingEtaLimit
tileJetMonAlg.JetPtMin = jetPtMin
tileJetMonAlg.DoEventCleaning = True
tileJetMonAlg.DoJetCleaning = True
else:
tileJetMonAlg.DoEventCleaning = False
tileJetMonAlg.DoJetCleaning = False
# 1) Configure histogram with TileJetMonAlg algorithm execution time
executeTimeGroup = helper.addGroup(tileJetMonAlg, 'TileJetMonExecuteTime',
'Tile/')
executeTimeGroup.defineHistogram(
'TIME_execute',
path='Jet',
type='TH1F',
title='Time for execute TileJetMonAlg algorithm;time [#mus]',
xbins=300,
xmin=0,
xmax=300000)
from TileMonitoring.TileMonitoringCfgHelper import addValueVsModuleAndChannelMaps, getPartitionName
runNumber = flags.Input.RunNumber[0]
# 2) Configure 2D histograms (profiles/maps) with Tile channel time vs module and channel per partion (DQ summary)
channelTimeDQGroup = helper.addGroup(tileJetMonAlg, 'TileJetChanTimeDQ',
'Tile/Jet/')
addValueVsModuleAndChannelMaps(channelTimeDQGroup,
name='tileJetChanTime',
title='Average time with jets',
path='DQ',
type='TProfile2D',
value='time',
run=str(runNumber))
gains = ['LG', 'HG']
partitions = ['LBA', 'LBC', 'EBA', 'EBC']
# 3a) Configure 1D histograms with Tile channel time per partition
channelTimeGroup = helper.addGroup(tileJetMonAlg, 'TileJetChanTime',
'Tile/Jet/ChanTime/')
for partition in partitions:
title = 'Partition ' + partition + ': Tile Channel Time;time [ns];N'
name = 'channelTime' + partition
path = partition
channelTimeGroup.defineHistogram(name,
title=title,
path=path,
type='TH1F',
xbins=600,
xmin=-30.0,
xmax=30.0)
# 3b) Configure 1D histograms with Tile channel time per partition for extended barrels without scintillators
for partition in ['EBA', 'EBC']:
title = 'Partition ' + partition + ': Tile Channel Time (without scintillators);time [ns];N'
name = 'channelTime' + partition + '_NoScint'
path = partition
channelTimeGroup.defineHistogram(name,
title=title,
path=path,
type='TH1F',
xbins=600,
xmin=-30.0,
xmax=30.0)
# Energy upper limits of the cell-time histograms
energiesHG = [
500, 1000, 2000, 4000, 6000, 8000, 10000, 13000, 16000, 20000
]
energiesLG = [25000, 30000, 40000, 50000, 65000, 80000]
energiesALL = {'LG': energiesLG, 'HG': energiesHG}
tileJetMonAlg.CellEnergyUpperLimitsHG = energiesHG
tileJetMonAlg.CellEnergyUpperLimitsLG = energiesLG
# 4) Configure histograms with Tile cell time in energy slices per partition and gain
cellTimeGroup = helper.addGroup(tileJetMonAlg, 'TileJetCellTime',
'Tile/Jet/CellTime/')
for partition in partitions:
for gain in gains:
index = 0
energies = energiesALL[gain]
for index in range(0, len(energies) + 1):
toEnergy = energies[index] if index < len(energies) else None
fromEnergy = energies[index - 1] if index > 0 else None
name = 'Cell_time_' + partition + '_' + gain + '_slice_' + str(
index)
title = 'Partition ' + partition + ': ' + gain + ' Tile Cell time in energy range'
if not toEnergy:
title += ' > ' + str(fromEnergy) + ' MeV; time [ns]'
elif not fromEnergy:
title += ' < ' + str(toEnergy) + ' MeV; time [ns]'
else:
title += ' [' + str(fromEnergy) + ' .. ' + str(
toEnergy) + ') MeV; time [ns]'
cellTimeGroup.defineHistogram(name,
title=title,
path=partition,
type='TH1F',
xbins=600,
xmin=-30.0,
xmax=30.0)
if DoEnergyProfiles:
# 5) Configure 1D histograms (profiles) with Tile cell energy profile in energy slices per partition and gain
cellEnergyProfileGroup = helper.addGroup(tileJetMonAlg,
'TileJetCellEnergyProfile',
'Tile/Jet/CellTime/')
for partition in partitions:
for gain in gains:
name = 'index_' + partition + '_' + gain
name += ',energy_' + partition + '_' + gain
name += ';Cell_ene_' + partition + '_' + gain + '_prof'
title = 'Partition ' + partition + ': ' + gain + ' Tile Cell energy profile;Slice;Energy [MeV]'
xmax = len(energiesALL[gain]) + 0.5
nbins = len(energiesALL[gain]) + 1
cellEnergyProfileGroup.defineHistogram(name,
title=title,
path=partition,
type='TProfile',
xbins=nbins,
xmin=-0.5,
xmax=xmax)
else:
# 6) Configure 1D histograms with Tile cell energy in energy slices per partition, gain and slice
cellEnergyGroup = helper.addGroup(tileJetMonAlg, 'TileJetCellEnergy',
'Tile/Jet/CellTime/')
for partition in partitions:
for gain in gains:
energies = energiesALL[gain]
for index in range(0, len(energies) + 1):
toEnergy = energies[index] if index < len(
energies) else 2 * energies[index - 1]
fromEnergy = energies[index - 1] if index > 0 else -1000
name = 'Cell_ene_' + partition + '_' + gain + '_slice_' + str(
index)
title = 'Partition ' + partition + ': ' + gain + ' Tile Cell Energy'
title += ' in energy range [' + str(
fromEnergy) + ' .. ' + str(
toEnergy) + ') MeV;Energy [MeV]'
cellEnergyGroup.defineHistogram(name,
title=title,
path=partition,
type='TH1F',
xbins=100,
xmin=fromEnergy,
xmax=toEnergy)
from TileCalibBlobObjs.Classes import TileCalibUtils as Tile
if Do1DHistograms:
# 7) Configure 1D histograms with Tile channel time per channel
channelTime1DGroup = helper.addGroup(tileJetMonAlg,
'TileJetChanTime1D',
'Tile/Jet/ChanTime/')
for ros in range(1, Tile.MAX_ROS):
for module in range(0, Tile.MAX_DRAWER):
for channel in range(0, Tile.MAX_CHAN):
moduleName = Tile.getDrawerString(ros, module)
title = 'Time in ' + moduleName + ' channel ' + str(
channel) + ';time [ns];N'
name = moduleName + '_ch_' + str(channel) + '_1d'
path = getPartitionName(ros) + '/' + moduleName
channelTime1DGroup.defineHistogram(name,
title=title,
path=path,
type='TH1F',
xbins=600,
xmin=-30.0,
xmax=30.0)
if DoEnergyDiffHistograms:
# 7) Configure 1D histograms with Tile cell relative energy difference between two channels per even channel
energyDiffGroup = helper.addGroup(tileJetMonAlg, 'TileJetEnergyDiff',
'Tile/Jet/EnergyDiff/')
for ros in range(1, Tile.MAX_ROS):
for module in range(0, Tile.MAX_DRAWER):
for channel in range(0, Tile.MAX_CHAN):
if not channel % 2:
for gain in gains:
moduleName = Tile.getDrawerString(ros, module)
title = 'Tile Cell Energy difference in ' + moduleName + ' channel ' + str(
channel) + ' ' + gain
title += ';#frac{ene1 - ene2}{ene1 + ene2}'
name = moduleName + '_enediff_' + gain + '_ch1_' + str(
channel)
path = getPartitionName(ros) + '/' + moduleName
energyDiffGroup.defineHistogram(name,
title=title,
path=path,
type='TH1F',
xbins=100,
xmin=-1.0,
xmax=1.0)
accumalator = helper.result()
result.merge(accumalator)
return result
def TileClusterMonitoringConfig(flags, **kwargs):
''' Function to configure TileClusterMonitorAlgorithm algorithm in the monitoring system.'''
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
from TileMonitoring.TileTopoClusterConfig import TileTopoClusterCfg
result.merge(TileTopoClusterCfg(flags))
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(flags, 'TileClusterMonitoring')
# Adding an TileCellMonitorAlgorithm algorithm to the helper
from AthenaConfiguration.ComponentFactory import CompFactory
tileClusterMonAlg = helper.addAlgorithm(
CompFactory.TileClusterMonitorAlgorithm, 'TileClusterMonAlg')
tileClusterMonAlg.TriggerChain = ''
# from AthenaCommon.SystemOfUnits import MeV
#kwargs.setdefault('EnergyThreshold', 50.0 * MeV)
# L1Trigger Type Bits:
# bit0_RNDM, bit1_ZeroBias, bit2_L1Cal, bit3_Muon,
# bit4_RPC, bit5_FTK, bit6_CTP, bit7_Calib, AnyPhysTrig
kwargs.setdefault('fillHistogramsForL1Triggers',
['AnyPhysTrig', 'bit7_Calib'])
l1Triggers = kwargs['fillHistogramsForL1Triggers']
kwargs.setdefault('fillTimingHistograms', flags.Common.isOnline)
fillTimingHistograms = kwargs['fillTimingHistograms']
for k, v in kwargs.items():
setattr(tileClusterMonAlg, k, v)
run = str(flags.Input.RunNumber[0])
# 1) Configure histogram with TileClusterMonAlg algorithm execution time
executeTimeGroup = helper.addGroup(tileClusterMonAlg,
'TileClusterMonExecuteTime', 'Tile/')
executeTimeGroup.defineHistogram(
'TIME_execute',
path='Cluster',
type='TH1F',
title='Time for execute TileClusterMonAlg algorithm;time [#mus]',
xbins=100,
xmin=0,
xmax=1000)
from TileCalibBlobObjs.Classes import TileCalibUtils as Tile
from TileMonitoring.TileMonitoringCfgHelper import addTileEtaPhiMapsArray
# ) Configure histograms with most energetic Tile tower position
addTileEtaPhiMapsArray(helper,
tileClusterMonAlg,
name='TileClusterEtaPhi',
type='TH2D',
title='Most energetic Tile Cluster position',
path='Tile/Cluster',
run=run,
triggers=l1Triggers,
perSample=False)
# ) Configure histograms with most energetic Tile tower position
addTileEtaPhiMapsArray(helper,
tileClusterMonAlg,
name='TileAllClusterEtaPhi',
type='TH2D',
title='All Tile Cluster position',
path='Tile/Cluster',
run=run,
triggers=l1Triggers,
perSample=False)
# ) Configure histograms with most energetic Tile tower position
addTileEtaPhiMapsArray(helper,
tileClusterMonAlg,
name='TileAllClusterEneEtaPhi',
type='TProfile2D',
value='energy',
title='All Tile Cluster everage energy [MeV]',
path='Tile/Cluster',
run=run,
triggers=l1Triggers,
perSample=False)
# ) Configure histograms with position correlation of Tile cluster opposite to most energetic cluster
addTileEtaPhiMapsArray(
helper,
tileClusterMonAlg,
name='TileClusterEtaPhiDiff',
type='TH2D',
title=
'Position correlation of Tile Cluster opposite to most energetic cluster',
path='Tile/Cluster',
run=run,
triggers=l1Triggers,
perSample=False,
etaTitle='#Delta #eta',
etabins=21,
etamin=-2.025,
etamax=2.025,
phiTitle='#Delta #phi',
phibins=Tile.MAX_DRAWER,
phimin=0.0,
phimax=6.4)
from TileMonitoring.TileMonitoringCfgHelper import addTile1DHistogramsArray
# ) Configure histograms with all Tile towers energy per partition
addTile1DHistogramsArray(
helper,
tileClusterMonAlg,
name='TileClusterEnergy',
xvalue='energy',
title='Energy in most energetic Tile Cluster [MeV]',
path='Tile/Cluster',
xbins=80,
xmin=0.,
xmax=20000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=True,
perSample=False,
perGain=False,
subDirectory=True,
allPartitions=True)
# ) Configure histograms with Et in most energetic Tile tower per partition
addTile1DHistogramsArray(
helper,
tileClusterMonAlg,
name='TileClusterEt',
xvalue='Et',
title='E_{T} [MeV] in most energetic Tile Cluster',
path='Tile/Cluster',
xbins=80,
xmin=0.,
xmax=20000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# ) Configure histograms with all Tile towers energy per partition
addTile1DHistogramsArray(
helper,
tileClusterMonAlg,
name='TileClusterNCells',
xvalue='nCells',
title='Number of cells in most energetic Tile Cluster',
path='Tile/Cluster',
xbins=100,
xmin=0.,
xmax=100.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# ) Configure histograms with all Tile towers energy per partition
addTile1DHistogramsArray(helper,
tileClusterMonAlg,
name='TileAllClusterEnergy',
xvalue='energy',
title='All Tile Cluster Energy [MeV]',
path='Tile/Cluster',
xbins=80,
xmin=0.,
xmax=20000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# ) Configure histograms with all Tile towers energy per partition
addTile1DHistogramsArray(helper,
tileClusterMonAlg,
name='TileNClusters',
xvalue='nClusters',
title='Number of Tile Clusters',
path='Tile/Cluster',
xbins=200,
xmin=0.,
xmax=200.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# ) Configure histograms with all Tile towers energy per partition
addTile1DHistogramsArray(helper,
tileClusterMonAlg,
name='TileClusterSumPx',
xvalue='sumPx',
title='Tile Clusters SumPx [MeV]',
path='Tile/Cluster',
xbins=101,
xmin=-10000.,
xmax=10000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# ) Configure histograms with all Tile towers energy per partition
addTile1DHistogramsArray(helper,
tileClusterMonAlg,
name='TileClusterSumPy',
xvalue='sumPy',
title='Tile Clusters SumPy [MeV]',
path='Tile/Cluster',
xbins=101,
xmin=-10000.,
xmax=10000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# ) Configure histograms with all Tile towers energy per partition
addTile1DHistogramsArray(helper,
tileClusterMonAlg,
name='TileClusterSumEt',
xvalue='sumEt',
title='Tile Clusters SumEt [MeV]',
path='Tile/Cluster',
xbins=100,
xmin=0.,
xmax=20000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# ) Configure histograms with all Tile towers energy per partition
timeDiffTitle = 'Tile time correlation of cluster opposite to most energetic cluster; Time difference [ns]'
addTile1DHistogramsArray(helper,
tileClusterMonAlg,
name='TileClusterTimeDiff',
xvalue='timeDiff',
title=timeDiffTitle,
path='Tile/Cluster',
xbins=200,
xmin=-100.,
xmax=100.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# ) Configure histograms with all Tile towers energy per partition
eneDiffTitle = 'Tile energy correlation of cluster opposite to most energetic cluster; Time energy [MeV]'
addTile1DHistogramsArray(helper,
tileClusterMonAlg,
name='TileClusterEneDiff',
xvalue='energyDiff',
title=eneDiffTitle,
path='Tile/Cluster',
xbins=200,
xmin=-10000.,
xmax=10000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
if fillTimingHistograms:
# ) Configure histograms with Tile partition time vs lumiBlock per partition
titlePartitionTime = 'Tile partition time vs luminosity block;LumiBlock;t[ns]'
addTile1DHistogramsArray(helper,
tileClusterMonAlg,
name='TilePartitionTimeLB',
xvalue='lumiBlock',
value='time',
title=titlePartitionTime,
path='Tile/Cluster',
xbins=1000,
xmin=-0.5,
xmax=999.5,
type='TProfile',
run=run,
triggers=[],
subDirectory=False,
perPartition=True,
perSample=False,
perGain=False,
allPartitions=True)
accumalator = helper.result()
result.merge(accumalator)
return result
def METMonitoringConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
### STEP 1 ###
# If you need to set up special tools, etc., you will need your own ComponentAccumulator;
# uncomment the following 2 lines and use the last three lines of this function instead of the ones
# just before
# from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
# result = ComponentAccumulator()
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags,'ExampleAthMonitorCfg')
### STEP 2 ###
# Adding an algorithm to the helper. Here, we will use the example
# algorithm in the AthenaMonitoring package. Just pass the type to the
# helper. Then, the helper will instantiate an instance and set up the
# base class configuration following the inputFlags. The returned object
# is the algorithm.
from AthenaMonitoring.AthenaMonitoringConf import ExampleMonitorAlgorithm
exampleMonAlg = helper.addAlgorithm(ExampleMonitorAlgorithm,'ExampleMonAlg')
# metMonTool = METMonTool(name = "METMonTool_")
# exampleMonAlg = helper.addAlgorithm(metMonTool,'ExampleMonAlg')
# You can actually make multiple instances of the same algorithm and give
# them different configurations
anotherExampleMonAlg = helper.addAlgorithm(ExampleMonitorAlgorithm,'AnotherExampleMonAlg')
# # If for some really obscure reason you need to instantiate an algorithm
# # yourself, the AddAlgorithm method will still configure the base
# # properties and add the algorithm to the monitoring sequence.
# helper.AddAlgorithm(myExistingAlg)
### STEP 3 ###
# Edit properties of a algorithm
# some generic property
# exampleMonAlg.RandomHist = True
# to enable a trigger filter, for example:
exampleMonAlg.TriggerChain = 'HLT_mu26_ivarmedium'
### STEP 4 ###
# Add some tools. N.B. Do not use your own trigger decion tool. Use the
# standard one that is included with AthMonitorAlgorithm.
# # First, add a tool that's set up by a different configuration function.
# # In this case, CaloNoiseToolCfg returns its own component accumulator,
# # which must be merged with the one from this function.
# from CaloTools.CaloNoiseToolConfig import CaloNoiseToolCfg
# caloNoiseAcc, caloNoiseTool = CaloNoiseToolCfg(inputFlags)
# result.merge(caloNoiseAcc)
# exampleMonAlg.CaloNoiseTool = caloNoiseTool
# # Then, add a tool that doesn't have its own configuration function. In
# # this example, no accumulator is returned, so no merge is necessary.
# from MyDomainPackage.MyDomainPackageConf import MyDomainTool
# exampleMonAlg.MyDomainTool = MyDomainTool()
# Add a generic monitoring tool (a "group" in old language). The returned
# object here is the standard GenericMonitoringTool.
myGroup = helper.addGroup(
exampleMonAlg,
'ExampleMonitor',
'OneRing/'
)
# Add a GMT for the other example monitor algorithm
anotherGroup = helper.addGroup(anotherExampleMonAlg,'ExampleMonitor')
### STEP 5 ###
# Configure histograms
# myGroup.defineHistogram( "Et;Et_" + src, title="Et Distribution (%s);MET Et (GeV);Events" % src, xbins = nEtBins, xmin = 0.0, xmax = etRange ),
myGroup.defineHistogram('lumiPerBCID',title='Luminosity,WithCommaInTitle;L/BCID;Events',
path='ToRuleThemAll',xbins=10,xmin=0.0,xmax=10.0)
myGroup.defineHistogram('lb', title='Luminosity Block;lb;Events',
path='ToFindThem',xbins=1000,xmin=-0.5,xmax=999.5,weight='testweight')
# myGroup.defineHistogram('random', title='LB;x;Events',
# path='ToBringThemAll',xbins=30,xmin=0,xmax=1,opt='kLBNHistoryDepth=10')
# myGroup.defineHistogram('random', title='title;x;y',path='ToBringThemAll',
# xbins=[0,.1,.2,.4,.8,1.6])
# myGroup.defineHistogram('random,pT', type='TH2F', title='title;x;y',path='ToBringThemAll',
# xbins=[0,.1,.2,.4,.8,1.6],ybins=[0,10,30,40,60,70,90])
# myGroup.defineHistogram('pT_passed,pT',type='TEfficiency',title='Test TEfficiency;x;Eff',
# path='AndInTheDarkness',xbins=100,xmin=0.0,xmax=50.0)
anotherGroup.defineHistogram('lbWithFilter',title='Lumi;lb;Events',
path='top',xbins=1000,xmin=-0.5,xmax=999.5)
# anotherGroup.defineHistogram('run',title='Run Number;run;Events',
# path='top',xbins=1000000,xmin=-0.5,xmax=999999.5)
# Example defining an array of histograms. This is useful if one seeks to create a
# number of histograms in an organized manner. (For instance, one plot for each ASIC
# in the subdetector, and these components are mapped in eta, phi, and layer.) Thus,
# one might have an array of TH1's such as quantity[etaIndex][phiIndex][layerIndex].
for alg in [exampleMonAlg,anotherExampleMonAlg]:
# Using an array of groups
array = helper.addArray([2],alg,'ExampleMonitor')
array.defineHistogram('a,b',title='AB',type='TH2F',path='Eta',
xbins=10,xmin=0.0,xmax=10.0,
ybins=10,ymin=0.0,ymax=10.0)
array.defineHistogram('c',title='C',path='Eta',
xbins=10,xmin=0.0,xmax=10.0)
array = helper.addArray([4,2],alg,'ExampleMonitor')
array.defineHistogram('a',title='A',path='EtaPhi',
xbins=10,xmin=0.0,xmax=10.0)
# Using a map of groups
layerList = ['layer1','layer2']
clusterList = ['clusterX','clusterB']
array = helper.addArray([layerList],alg,'ExampleMonitor')
array.defineHistogram('c',title='C',path='Layer',
xbins=10,xmin=0,xmax=10.0)
array = helper.addArray([layerList,clusterList],alg,'ExampleMonitor')
array.defineHistogram('c',title='C',path='LayerCluster',
xbins=10,xmin=0,xmax=10.0)
### STEP 6 ###
# Finalize. The return value should be a tuple of the ComponentAccumulator
# and the sequence containing the created algorithms. If we haven't called
# any configuration other than the AthMonitorCfgHelper here, then we can
# just return directly (and not create "result" above)
return helper.result()
def SCTHitEffMonAlgConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
### STEP 1 ###
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'SCTHitEffMonCfg')
### STEP 2 ###
# Adding an algorithm to the helper. Here, we will use the example
# algorithm in the AthenaMonitoring package. Just pass the type to the
# helper. Then, the helper will instantiate an instance and set up the
# base class configuration following the inputFlags. The returned object
# is the algorithm.
from AthenaConfiguration.ComponentFactory import CompFactory
myMonAlg = helper.addAlgorithm(CompFactory.SCTHitEffMonAlg,
'SCTHitEffMonAlg')
# # If for some really obscure reason you need to instantiate an algorithm
# # yourself, the AddAlgorithm method will still configure the base
# # properties and add the algorithm to the monitoring sequence.
# helper.AddAlgorithm(myExistingAlg)
### STEP 3 ###
# Edit properties of a algorithm
myMonAlg.TriggerChain = ''
from LumiBlockComps.BunchCrossingCondAlgConfig import BunchCrossingCondAlgCfg
result.merge(BunchCrossingCondAlgCfg(inputFlags))
from MagFieldServices.MagFieldServicesConfig import MagneticFieldSvcCfg
result.merge(MagneticFieldSvcCfg(inputFlags))
### STEP 4 ###
# Add some tools. N.B. Do not use your own trigger decion tool. Use the
# standard one that is included with AthMonitorAlgorithm.
# set up geometry / conditions
from AtlasGeoModel.InDetGMConfig import InDetGeometryCfg
result.merge(InDetGeometryCfg(inputFlags))
# Add a generic monitoring tool (a "group" in old language). The returned
# object here is the standard GenericMonitoringTool.
from ROOT import SCT_Monitoring as sctMon
myMonGroup = [
helper.addGroup(myMonAlg, "SCTHitEffMonitorEC", "SCT/SCTEC/"),
helper.addGroup(myMonAlg, "SCTHitEffMonitorB", "SCT/SCTB/"),
helper.addGroup(myMonAlg, "SCTHitEffMonitorEA", "SCT/SCTEA/"),
helper.addGroup(myMonAlg, "SCTHitEffMonitor", "SCT/GENERAL/")
]
### STEP 5 ###
# Configure histograms
# Conversion of ROOT.vector of ROOT.TString to list of str
subDetName = []
for i in range(len(sctMon.subDetName)):
subDetName.append(sctMon.subDetName[i].Data())
mapName = ["m_eff_", "eff_", "p_eff_"]
ineffmapName = ["ineffm_", "ineff_", "ineffp_"]
sumEff = ["summaryeffm", "summaryeff", "summaryeffp"]
sumEffTitle = [
"Summary Module Efficiency in Endcap C",
"Summary Module Efficiency in Barrel",
"Summary Module Efficiency in Endcap A"
]
limit = [sctMon.N_DISKS * 2, sctMon.N_BARRELS * 2, sctMon.N_DISKS * 2]
# GENERAL
myMonGroup[sctMon.GENERAL_INDEX].defineHistogram(
varname="isub, eff;" + "SctTotalEff",
type="TProfile",
title="SCT Total Efficiency",
path="eff",
xbins=sctMon.N_REGIONS,
xmin=0.,
xmax=sctMon.N_REGIONS,
xlabels=subDetName)
myMonGroup[sctMon.GENERAL_INDEX].defineHistogram(
varname="isub, eff;" + "SctTotalEffBCID",
type="TProfile",
title="SCT Total Efficiency for First BCID",
path="eff",
xbins=sctMon.N_REGIONS,
xmin=0.,
xmax=sctMon.N_REGIONS,
xlabels=subDetName,
cutmask="isFirstBCID")
myMonGroup[sctMon.GENERAL_INDEX].defineHistogram(
varname="sideHash, eff;" + "effHashCode",
type="TProfile",
title="Efficiency vs module Hash code" +
";Module Hash Code;Efficiency",
path="eff",
xbins=sctMon.n_mod[sctMon.GENERAL_INDEX] * 2,
xmin=-0.5,
xmax=sctMon.n_mod[sctMon.GENERAL_INDEX] * 2 - 0.5)
myMonGroup[sctMon.GENERAL_INDEX].defineHistogram(
varname="LumiBlock, eff;" + "effLumiBlock",
type="TProfile",
title="Efficiency vs Luminosity block" + ";;Efficiency",
path="eff",
xbins=sctMon.NBINS_LBs,
xmin=0.5,
xmax=sctMon.NBINS_LBs + 0.5)
### This histogram should be filled by post processing ###
# myMonGroup[sctMon.GENERAL_INDEX].defineHistogram(varname= "eff;" + "SctEffDistribution",
# type= "TH1F",
# title= "SCT Efficiency Distribution"+";Efficiency;Links",
# path="eff",
# xbins= 500,
# xmin=0.,
# xmax=1.)
# SCTEC, SCTB, SCTEA
for isub in range(sctMon.N_REGIONS):
profileLabels = range(limit[isub])
for k in range(limit[isub]):
profileLabels[k] = dedicatedTitle(k, isub)
# Efficiency
myMonGroup[isub].defineHistogram(
varname="layerPlusHalfSide, eff;" + sumEff[isub],
type="TProfile",
title=sumEffTitle[isub] + ";;Efficiency",
path="eff",
xbins=2 * sctMon.n_layers[isub],
xmin=0.,
xmax=sctMon.n_layers[isub],
xlabels=profileLabels)
# Efficiency for first BCIDs
myMonGroup[isub].defineHistogram(
varname="layerPlusHalfSide, eff;" + sumEff[isub] + "BCID",
type="TProfile",
title=sumEffTitle[isub] + " for First BC" + ";;Efficiency",
path="eff",
xbins=2 * sctMon.n_layers[isub],
xmin=0.,
xmax=sctMon.n_layers[isub],
xlabels=profileLabels,
cutmask="isFirstBCID")
# Efficiency as a function of LB
myMonGroup[isub].defineHistogram(
varname="LumiBlock, eff;" +
"effLumiBlock", #different names for fill
type="TProfile",
title="Efficiency vs Luminosity block in " +
sctMon.subDetName[isub] + ";Luminosity block" + ";Efficiency",
path="eff",
xbins=sctMon.NBINS_LBs,
xmin=0.5,
xmax=sctMon.NBINS_LBs + 0.5)
# Disks for SCTEC and SCTEA and layers for SCTB
for layer_disk in range(sctMon.n_layers[isub]):
for side in range(2):
etaPhiSuffix = "_" + str(layer_disk) + "_" + str(side)
effName = mapName[isub] + str(layer_disk) + "_" + str(side)
ineffName = ineffmapName[isub] + str(layer_disk) + "_" + str(
side)
# Efficiency
myMonGroup[isub].defineHistogram(
varname="ieta" + etaPhiSuffix + ",iphi" + etaPhiSuffix +
",eff;" + effName,
type="TProfile2D",
title="Hit efficiency of" + sctMon.layerName[isub].Data() +
str(layer_disk) + " / side " + str(side) + " in " +
subDetName[isub] +
";Index in the direction of #eta;Index in the direction of #phi",
path="eff",
xbins=sctMon.n_etabins[isub],
xmin=sctMon.f_etabin[isub] - .5,
xmax=sctMon.l_etabin[isub] + .5,
ybins=sctMon.n_phibins[isub],
ymin=sctMon.f_phibin[isub] - .5,
ymax=sctMon.l_phibin[isub] + .5)
# Efficiency for first BCIDs
myMonGroup[isub].defineHistogram(
varname="ieta" + etaPhiSuffix + ",iphi" + etaPhiSuffix +
",eff;" + effName + "_bcid",
type="TProfile2D",
title="Hit efficiency of" + sctMon.layerName[isub].Data() +
str(layer_disk) + " / side " + str(side) + " in " +
subDetName[isub] + " for first BCID" +
";Index in the direction of #eta;Index in the direction of #phi",
path="eff",
xbins=sctMon.n_etabins[isub],
xmin=sctMon.f_etabin[isub] - .5,
xmax=sctMon.l_etabin[isub] + .5,
ybins=sctMon.n_phibins[isub],
ymin=sctMon.f_phibin[isub] - .5,
ymax=sctMon.l_phibin[isub] + .5,
cutmask="isFirstBCID")
# Inefficiency
myMonGroup[isub].defineHistogram(
varname="ieta" + etaPhiSuffix + ",iphi" + etaPhiSuffix +
",ineff;" + ineffName,
type="TProfile2D",
title="Hit inefficiency of" +
sctMon.layerName[isub].Data() + str(layer_disk) +
" / side " + str(side) + " in " + subDetName[isub] +
";Index in the direction of #eta;Index in the direction of #phi",
path="eff",
xbins=sctMon.n_etabins[isub],
xmin=sctMon.f_etabin[isub] - .5,
xmax=sctMon.l_etabin[isub] + .5,
ybins=sctMon.n_phibins[isub],
ymin=sctMon.f_phibin[isub] - .5,
ymax=sctMon.l_phibin[isub] + .5)
# Merge with result object and return
result.merge(helper.result())
return result
tgcRawDataMonAlg.TagAndProbe = False
tgcRawDataMonAlg.TagTrigList = 'HLT_mu26_ivarmedium'
tgcRawDataMonAlg.TagTrigList += ',HLT_mu26_ivarmedium'
tgcRawDataMonAlg.TagTrigList += ',HLT_mu26_ivarmedium_L1MU20'
tgcRawDataMonAlg.TagTrigList += ',HLT_mu6'
tgcRawDataMonAlg.TagTrigList += ',HLT_mu6_L1MU6'
tgcRawDataMonAlg.TagTrigList += ',HLT_mu20_mu8noL1;HLT_mu20'
mainDir = 'Muon/MuonRawDataMonitoring/TGC/'
pi = 3.14159265359
trigPath = 'Trig/'
myGroup = helper.addGroup(tgcRawDataMonAlg, 'TgcRawDataMonitor', mainDir)
myGroup.defineHistogram('thrNumber_barrel',
title='thrNumber_barrel;thrNumber;Events',
path=trigPath,
xbins=16,
xmin=0.0,
xmax=16.0)
myGroup.defineHistogram('thrNumber_endcap',
title='thrNumber_endcap;thrNumber;Events',
path=trigPath,
xbins=16,
xmin=0.0,
xmax=16.0)
myGroup.defineHistogram('thrNumber_forward',
title='thrNumber_forward;thrNumber;Events',
def TrigCaloMonConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
import math
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags,'TrigCaloAthMonitorCfg')
# Finalize. The return value should be a tuple of the ComponentAccumulator
# and the sequence containing the created algorithms. If we haven't called
# any configuration other than the AthMonitorCfgHelper here, then we can
# just return directly (and not create "result" above)
# Get BunchCrossingCondAlg
from LumiBlockComps.BunchCrossingCondAlgConfig import BunchCrossingCondAlgCfg
result=BunchCrossingCondAlgCfg(inputFlags)
################################
# HLT_FastCaloEMClusters #
################################
# Add monitor algorithm
from AthenaConfiguration.ComponentFactory import CompFactory
L2CaloEMClustersMonAlg = helper.addAlgorithm(CompFactory.HLTCalo_L2CaloEMClustersMonitor, 'HLT_FastCaloEMClustersMonAlg')
# Set properties
L2CaloEMClustersMonAlg.HLTContainer = 'HLT_FastCaloEMClusters'
L2CaloEMClustersMonAlg.OFFContainer = 'egammaClusters'
L2CaloEMClustersMonAlg.MonGroupName = 'TrigCaloMonitor'
L2CaloEMClustersMonAlg.OFFTypes = []
L2CaloEMClustersMonAlg.HLThighET= 10000.0
L2CaloEMClustersMonAlg.HLTMinET = -1.0
L2CaloEMClustersMonAlg.OFFMinET = -1.0
L2CaloEMClustersMonAlg.MaxDeltaR = 0.04
# Add group
L2CaloEMClustersMonGroup = helper.addGroup(L2CaloEMClustersMonAlg,'TrigCaloMonitor','HLT/HLTCalo')
########################
# HLT_Clusters #
########################
# Declare HLT histograms
hist_path='HLT_FastCaloEMClusters/HLT_Clusters'
L2CaloEMClustersMonGroup.defineHistogram('HLT_num',title='Number of HLT Clusters; Num Clusters; Entries',
path=hist_path,xbins=51,xmin=-0.5,xmax=50.5)
L2CaloEMClustersMonGroup.defineHistogram('HLT_eta,HLT_phi',title='Number of HLT Clusters; #eta; #phi; ', type='TH2F',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('HLT_et',title='HLT Clusters E_{T}; E_{T} [GeV]; Entries',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_eta',title='HLT Clusters #eta; #eta; Entries',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_phi',title='HLT Cluster #phi; #phi; Entries',
path=hist_path,xbins=64,xmin=-math.pi,xmax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('HLT_size',title='HLT Cluster Size; Number of Cells; Entries',
path=hist_path,xbins=91,xmin=-10.0,xmax=1810.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_bc,HLT_et;HLT_et_vs_BC',title='HLT Clusters E_{T} vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=hist_path,xbins=21,xmin=-0.5,xmax=20.5)
# Declare high-ET HLT histograms
L2CaloEMClustersMonGroup.defineHistogram('HLT_barrel_high_et_num',title='Number of high-E_{T} HLT Clusters; Num Clusters; Entries',
path=hist_path,xbins=101,xmin=-0.5,xmax=100.5)
L2CaloEMClustersMonGroup.defineHistogram('HLT_eta,HLT_phi;HLT_barrel_high_et_phi_vs_HLT_barrel_high_et_eta',cutmask="HLT_barrel_high_et",title='Number of high-E_{T} HLT Clusters; #eta; #phi; ', type='TH2F',
path=hist_path,xbins=50,xmin=-2.6,xmax=2.6,ybins=64,ymin=-math.pi,ymax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('HLT_et;HLT_barrel_high_et_et',cutmask="HLT_barrel_high_et",title='high-E_{T} HLT Clusters E_{T}; E_{T} [GeV]; Entries',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_eta;HLT_barrel_high_et_eta',cutmask="HLT_barrel_high_et",title='high-E_{T} HLT Clusters #eta; #eta; Entries',
path=hist_path,xbins=50,xmin=-2.6,xmax=2.6)
L2CaloEMClustersMonGroup.defineHistogram('HLT_phi;HLT_barrel_high_et_phi',cutmask="HLT_barrel_high_et",title='high-E_{T} HLT Cluster #phi; #phi; Entries',
path=hist_path,xbins=64,xmin=-math.pi,xmax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('HLT_size;HLT_barrel_high_et_size',cutmask="HLT_barrel_high_et",title='high-E_{T} HLT Cluster Size; Number of Cells; Entries',
path=hist_path,xbins=91,xmin=-10.0,xmax=1810.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_bc,HLT_et;HLT_barrel_high_et_vs_BC',cutmask="HLT_barrel_high_et",title='hight-E_{T} HLT Clusters E_{T} vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=hist_path,xbins=21,xmin=-0.5,xmax=20.5)
########################
# OFF_Clusters #
########################
# Declare OFF histograms
hist_path='HLT_FastCaloEMClusters/OFF_Clusters'
L2CaloEMClustersMonGroup.defineHistogram('OFF_num',title='Number of OFF Clusters; Num Clusters; Entries',
path=hist_path,xbins=101,xmin=-1.0,xmax=201.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_eta,OFF_phi',title='Number of OFF Clusters; #eta; #phi; ', type='TH2F',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('OFF_et',title='OFF Clusters E_{T}; E_{T} [GeV]; Entries',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_eta',title='OFF Clusters #eta; #eta; Entries',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_phi',title='OFF Cluster #phi; #phi; Entries',
path=hist_path,xbins=64,xmin=-math.pi,xmax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('OFF_type',title='OFF Cluster Type; Size Enum; Entries',
path=hist_path,xbins=16,xmin=0.5,xmax=16.5)
L2CaloEMClustersMonGroup.defineHistogram('HLT_bc,OFF_et;OFF_et_vs_BC',title='OFF Clusters E_{T} vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=hist_path,xbins=21,xmin=-0.5,xmax=20.5)
########################
# HLT matched to OFF #
########################
# Declare HLT matched HLT vs. OFF cluster histograms
hist_path='HLT_FastCaloEMClusters/HLT_Matched_to_OFF'
L2CaloEMClustersMonGroup.defineHistogram('HLT_matched_fraction',title='Fraction of HLT clusters matched to HLT clusters; Matched fraction; Entries',
path=hist_path,xbins=100,xmin=0.0,xmax=1.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_vs_OFF_minimum_delta_r',title='HLT vs OFF Cluster #DeltaR; #DeltaR; Entries',
path=hist_path,xbins=50,xmin=0.0,xmax=0.1)
L2CaloEMClustersMonGroup.defineHistogram('HLT_vs_OFF_minimum_delta_eta',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster #Delta#eta; #eta_{_{OFF}} - #eta_{_{HLT}}; Entries',
path=hist_path,xbins=50,xmin=-0.2,xmax=0.2)
L2CaloEMClustersMonGroup.defineHistogram('HLT_vs_OFF_minimum_delta_phi',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster #Delta#phi; #phi_{_{OFF}} - #phi_{_{HLT}}; Entries',
path=hist_path,xbins=50,xmin=-0.01,xmax=0.09)
L2CaloEMClustersMonGroup.defineHistogram('HLT_et,OFF_match_et;HLT_with_OFF_match_et_vs_OFF_match_et',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster E_{T}; E_{T_{OFF}} [GeV]; E_{T_{HLT}} [GeV]', type='TH2F',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0, ybins=100,ymin=0.0,ymax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_vs_OFF_resolution',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster #DeltaE_{T} / E_{T}; E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} [%]; Entries',
path=hist_path,xbins=100,xmin=-40.0,xmax=40.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_et,HLT_vs_OFF_resolution;HLT_vs_OFF_resolution_vs_HLT_with_OFF_match_et',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; E_{T,OFF} [GeV]; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_eta,HLT_vs_OFF_resolution;HLT_vs_OFF_resolution_vs_HLT_with_OFF_match_eta',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #eta_{_{ OFF}}; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=hist_path,xbins=20,xmin=-5.0,xmax=5.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_phi,HLT_vs_OFF_resolution;HLT_vs_OFF_resolution_vs_HLT_with_OFF_match_phi',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #phi_{_{ OFF}}; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=hist_path,xbins=16,xmin=-math.pi,xmax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('HLT_eta,HLT_phi,HLT_vs_OFF_resolution;HLT_vs_OFF_resolution_vs_HLT_with_OFF_match_phi_vs_HLT_with_OFF_match_eta',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #eta; #phi', type='TProfile2D',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
# Declare OFF histograms with HLT matches
L2CaloEMClustersMonGroup.defineHistogram('HLT_with_OFF_match_num',title='Number of HLT Clusters (With OFF Matches); Num Clusters; Entries',
path=hist_path,xbins=101,xmin=-1.0,xmax=201.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_eta,HLT_phi;HLT_with_OFF_match_eta_vs_HLT_with_OFF_match_phi',cutmask='HLT_with_OFF_match',title='Number of HLT Clusters (With OFF Matches); #eta; #phi; ', type='TH2F',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('HLT_et;HLT_with_OFF_match_et',cutmask='HLT_with_OFF_match',title='HLT Clusters E_{T} (With OFF Matches); E_{T} [GeV]; Entries',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_eta;HLT_with_OFF_match_eta',cutmask='HLT_with_OFF_match',title='HLT Clusters #eta (With OFF Matches); #eta; Entries',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_phi;HLT_with_OFF_match_phi',cutmask='HLT_with_OFF_match',title='HLT Cluster #phi (With OFF Matches); #phi; Entries',
path=hist_path,xbins=64,xmin=-math.pi,xmax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('HLT_bc,HLT_et;HLT_with_OFF_match_et_vs_BC',cutmask='HLT_with_OFF_match',title='HLT Clusters E_{T} (With OFF Matches) vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=hist_path,xbins=21,xmin=-0.5,xmax=20.5)
# Declare OFF histograms without HLT matches
L2CaloEMClustersMonGroup.defineHistogram('HLT_no_OFF_match_num',title='Number of HLT Clusters (No OFF Matches); Num Clusters; Entries',
path=hist_path,xbins=101,xmin=-1.0,xmax=201.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_eta,HLT_phi;HLT_no_OFF_match_eta_vs_HLT_no_OFF_match_phi',cutmask='HLT_no_OFF_match',title='Number of HLT Clusters (No OFF Matches); #eta; #phi; ', type='TH2F',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('HLT_et;HLT_no_OFF_match_et',cutmask='HLT_no_OFF_match',title='HLT Clusters E_{T} (No OFF Matches); E_{T} [GeV]; Entries',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_eta;HLT_no_OFF_match_eta',cutmask='HLT_no_OFF_match',title='HLT Clusters #eta (No OFF Matches); #eta; Entries',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0)
L2CaloEMClustersMonGroup.defineHistogram('HLT_phi;HLT_no_OFF_match_phi',cutmask='HLT_no_OFF_match',title='HLT Cluster #phi (No OFF Matches); #phi; Entries',
path=hist_path,xbins=64,xmin=-math.pi,xmax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('HLT_bc,HLT_et;HLT_no_OFF_match_et_vs_BC',cutmask='HLT_no_OFF_match',title='HLT Clusters E_{T} (No OFF Matches) vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=hist_path,xbins=21,xmin=-0.5,xmax=20.5)
########################
# OFF matched to HLT #
########################
# Declare OFF matched HLT vs. OFF cluster histograms
hist_path='HLT_FastCaloEMClusters/OFF_Matched_to_HLT'
L2CaloEMClustersMonGroup.defineHistogram('OFF_matched_fraction',title='Fraction of OFF clusters matched to HLT clusters; Matched fraction; Entries',
path=hist_path,xbins=100,xmin=0.0,xmax=1.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_vs_HLT_minimum_delta_r',title='HLT vs OFF Cluster #DeltaR; #DeltaR; Entries',
path=hist_path,xbins=50,xmin=0.0,xmax=0.1)
L2CaloEMClustersMonGroup.defineHistogram('OFF_vs_HLT_minimum_delta_eta',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster #Delta#eta; #eta_{_{OFF}} - #eta_{_{HLT}}; Entries',
path=hist_path,xbins=50,xmin=-0.2,xmax=0.2)
L2CaloEMClustersMonGroup.defineHistogram('OFF_vs_HLT_minimum_delta_phi',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster #Delta#phi; #phi_{_{OFF}} - #phi_{_{HLT}}; Entries',
path=hist_path,xbins=50,xmin=-0.01,xmax=0.09)
L2CaloEMClustersMonGroup.defineHistogram('OFF_et,HLT_match_et;HLT_match_et_vs_OFF_with_HLT_match_et',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster E_{T}; E_{T_{OFF}} [GeV]; E_{T_{HLT}} [GeV]', type='TH2F',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0, ybins=100,ymin=0.0,ymax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_vs_HLT_resolution',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster #DeltaE_{T} / E_{T}; E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} [%]; Entries',
path=hist_path,xbins=100,xmin=-40.0,xmax=40.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_et,OFF_vs_HLT_resolution;OFF_vs_HLT_resolution_vs_OFF_with_HLT_match_et',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; E_{T,OFF} [GeV]; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_eta,OFF_vs_HLT_resolution;OFF_vs_HLT_resolution_vs_OFF_with_HLT_match_eta',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #eta_{_{ OFF}}; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=hist_path,xbins=20,xmin=-5.0,xmax=5.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_phi,OFF_vs_HLT_resolution;OFF_vs_HLT_resolution_vs_OFF_with_HLT_match_phi',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #phi_{_{ OFF}}; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=hist_path,xbins=16,xmin=-math.pi,xmax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('OFF_eta,OFF_phi,OFF_vs_HLT_resolution;OFF_vs_HLT_resolution_vs_OFF_with_HLT_match_phi_vs_OFF_with_HLT_match_eta',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #eta; #phi', type='TProfile2D',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
# Declare OFF histograms with HLT matches
L2CaloEMClustersMonGroup.defineHistogram('OFF_with_HLT_match_num',title='Number of OFF Clusters (With HLT Matches); Num Clusters; Entries',
path=hist_path,xbins=101,xmin=-1.0,xmax=201.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_eta,OFF_phi;OFF_with_HLT_match_phi_vs_OFF_with_HLT_match_eta',cutmask='OFF_with_HLT_match',title='Number of OFF Clusters (With HLT Matches); #eta; #phi; ', type='TH2F',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('OFF_et;OFF_with_HLT_match_et',cutmask='OFF_with_HLT_match',title='OFF Clusters E_{T} (With HLT Matches); E_{T} [GeV]; Entries',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_eta;OFF_with_HLT_match_eta',cutmask='OFF_with_HLT_match',title='OFF Clusters #eta (With HLT Matches); #eta; Entries',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_phi;OFF_with_HLT_match_phi',cutmask='OFF_with_HLT_match',title='OFF Cluster #phi (With HLT Matches); #phi; Entries',
path=hist_path,xbins=64,xmin=-math.pi,xmax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('OFF_type;OFF_with_HLT_match_type',cutmask='OFF_with_HLT_match',title='OFF Cluster Type (With HLT Matches); Size Enum; Entries',
path=hist_path,xbins=16,xmin=0.5,xmax=16.5)
L2CaloEMClustersMonGroup.defineHistogram('HLT_bc,OFF_et;OFF_with_HLT_match_et_vs_BC',cutmask='OFF_with_HLT_match',title='OFF Clusters E_{T} (With HLT Matches) vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=hist_path,xbins=21,xmin=-0.5,xmax=20.5)
# Declare OFF histograms without HLT matches
L2CaloEMClustersMonGroup.defineHistogram('OFF_no_HLT_match_num',title='Number of OFF Clusters (No HLT Matches); Num Clusters; Entries',
path=hist_path,xbins=101,xmin=-1.0,xmax=201.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_eta,OFF_phi;OFF_no_HLT_match_phi_vs_OFF_no_HLT_match_eta',cutmask='OFF_no_HLT_match',title='Number of OFF Clusters (No HLT Matches); #eta; #phi; ', type='TH2F',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('OFF_et;OFF_no_HLT_match_et',cutmask='OFF_no_HLT_match',title='OFF Clusters E_{T} (No HLT Matches); E_{T} [GeV]; Entries',
path=hist_path,xbins=100,xmin=0.0,xmax=100.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_eta;OFF_no_HLT_match_eta',cutmask='OFF_no_HLT_match',title='OFF Clusters #eta (No HLT Matches); #eta; Entries',
path=hist_path,xbins=50,xmin=-5.0,xmax=5.0)
L2CaloEMClustersMonGroup.defineHistogram('OFF_phi;OFF_no_HLT_match_phi',cutmask='OFF_no_HLT_match',title='OFF Cluster #phi (No HLT Matches); #phi; Entries',
path=hist_path,xbins=64,xmin=-math.pi,xmax=math.pi)
L2CaloEMClustersMonGroup.defineHistogram('OFF_type;OFF_no_HLT_match_type',cutmask='OFF_no_HLT_match',title='OFF Cluster Type (No HLT Matches); Size Enum; Entries',
path=hist_path,xbins=16,xmin=0.5,xmax=16.5)
L2CaloEMClustersMonGroup.defineHistogram('HLT_bc,OFF_et;OFF_no_HLT_match_et_vs_BC',cutmask='OFF_no_HLT_match',title='OFF Clusters E_{T} (No HLT Matches) vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=hist_path,xbins=21,xmin=-0.5,xmax=20.5)
################################
# HLT_TopoCaloClusters #
################################
# Add monitor algorithm
TopoCaloClustersFSMonAlg = helper.addAlgorithm(CompFactory.HLTCalo_TopoCaloClustersMonitor, 'HLT_TopoCaloClustersFSMonAlg')
TopoCaloClustersRoIMonAlg = helper.addAlgorithm(CompFactory.HLTCalo_TopoCaloClustersMonitor, 'HLT_TopoCaloClustersRoIMonAlg')
TopoCaloClustersLCMonAlg = helper.addAlgorithm(CompFactory.HLTCalo_TopoCaloClustersMonitor, 'HLT_TopoCaloClustersLCMonAlg')
TopoCaloClustersFSMonAlg.HLTContainer = 'HLT_TopoCaloClustersFS'
TopoCaloClustersRoIMonAlg.HLTContainer = 'HLT_TopoCaloClustersRoI'
TopoCaloClustersLCMonAlg.HLTContainer = 'HLT_TopoCaloClustersLC'
# Loop over all three monitoring algorithms
algs = [TopoCaloClustersFSMonAlg, TopoCaloClustersRoIMonAlg, TopoCaloClustersLCMonAlg]
path_names = ['HLT_TopoCaloClustersFS', 'HLT_TopoCaloClustersRoI', 'HLT_TopoCaloClustersLC']
TopoCaloClustersMonGroup = []
for i in range(len(algs)):
# Set properties
algs[i].OFFContainer = 'CaloCalTopoClusters'
algs[i].MonGroupName = 'TrigCaloMonitor'
algs[i].HLTTypes = []
algs[i].OFFTypes = []
algs[i].HLThighET= 5000.0
algs[i].HLTMinET = 500.0
algs[i].OFFMinET = 500.0
algs[i].MatchType = False
algs[i].MaxDeltaR = 0.04
# Add group
TopoCaloClustersMonGroup.append(helper.addGroup(algs[i], 'TrigCaloMonitor','HLT/HLTCalo'))
########################
# HLT_Clusters #
########################
# Declare HLT histograms
TopoCaloClustersMonGroup[i].defineHistogram('HLT_num',title='Number of HLT Clusters; Num Clusters; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=101,xmin=-10.0,xmax=2010.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_eta,HLT_phi',title='Number of HLT Clusters; #eta; #phi; ', type='TH2F',
path=path_names[i]+'/HLT_Clusters',xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_et',title='HLT Clusters E_{T}; E_{T} [GeV]; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=100,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_eta',title='HLT Clusters #eta; #eta; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=50,xmin=-5.0,xmax=5.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_phi',title='HLT Cluster #phi; #phi; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=64,xmin=-math.pi,xmax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_type',title='HLT Cluster Type; Size Enum; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=16,xmin=0.5,xmax=16.5)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_time',title='HLT Cluster time; time; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=60,xmin=-10.0,xmax=10.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_et,HLT_time',title='Number of HLT Clusters; E_{T} [GeV]; Time', type='TProfile',
path=path_names[i]+'/HLT_Clusters',xbins=50,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_size',title='HLT Cluster Size; Number of Cells; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=91,xmin=-10.0,xmax=1810.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_bc,HLT_et;HLT_et_vs_BC',title='HLT Clusters E_{T} vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=path_names[i]+'/HLT_Clusters',xbins=21,xmin=-0.5,xmax=20.5)
# Declare high-ET HLT histograms
TopoCaloClustersMonGroup[i].defineHistogram('HLT_barrel_high_et_num',title='Number of high-E_{T} HLT Clusters; Num Clusters; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=101,xmin=-0.5,xmax=100.5)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_eta,HLT_phi;HLT_barrel_high_et_phi_vs_HLT_barrel_high_et_eta',cutmask="HLT_barrel_high_et",title='Number of high-E_{T} HLT Clusters; #eta; #phi; ', type='TH2F',
path=path_names[i]+'/HLT_Clusters',xbins=50,xmin=-2.6,xmax=2.6,ybins=64,ymin=-math.pi,ymax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_et;HLT_barrel_high_et_et',cutmask="HLT_barrel_high_et",title='high-E_{T} HLT Clusters E_{T}; E_{T} [GeV]; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=100,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_eta;HLT_barrel_high_et_eta',cutmask="HLT_barrel_high_et",title='high-E_{T} HLT Clusters #eta; #eta; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=50,xmin=-2.6,xmax=2.6)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_phi;HLT_barrel_high_et_phi',cutmask="HLT_barrel_high_et",title='high-E_{T} HLT Cluster #phi; #phi; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=64,xmin=-math.pi,xmax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_type;HLT_barrel_high_et_type',cutmask="HLT_barrel_high_et",title='high-E_{T} HLT Cluster Type; Size Enum; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=16,xmin=0.5,xmax=16.5)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_time;HLT_barrel_high_et_time',cutmask="HLT_barrel_high_et",title='high-E_{T} HLT Cluster time; time; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=60,xmin=-10.0,xmax=10.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_et,HLT_time;HLT_barrel_high_et_time_vs_HLT_barrel_high_et_et',cutmask="HLT_barrel_high_et",title='Number of high-E_{T} HLT Clusters; E_{T} [GeV]; Time', type='TProfile',
path=path_names[i]+'/HLT_Clusters',xbins=50,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_size;HLT_barrel_high_et_size',cutmask="HLT_barrel_high_et",title='high-E_{T} HLT Cluster Size; Number of Cells; Entries',
path=path_names[i]+'/HLT_Clusters',xbins=91,xmin=-10.0,xmax=1810.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_bc,HLT_et;HLT_barrel_high_et_vs_BC',cutmask="HLT_barrel_high_et",title='hight-E_{T} HLT Clusters E_{T} vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=path_names[i]+'/HLT_Clusters',xbins=21,xmin=-0.5,xmax=20.5)
########################
# OFF_Clusters #
########################
# Declare OFF histograms
TopoCaloClustersMonGroup[i].defineHistogram('OFF_num',title='Number of OFF Clusters; Num Clusters; Entries',
path=path_names[i]+'/OFF_Clusters',xbins=101,xmin=-10.0,xmax=2010.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_eta,OFF_phi',title='Number of OFF Clusters; #eta; #phi; ', type='TH2F',
path=path_names[i]+'/OFF_Clusters',xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_et',title='OFF Clusters E_{T}; E_{T} [GeV]; Entries',
path=path_names[i]+'/OFF_Clusters',xbins=100,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_eta',title='OFF Clusters #eta; #eta; Entries',
path=path_names[i]+'/OFF_Clusters',xbins=50,xmin=-5.0,xmax=5.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_phi',title='OFF Cluster #phi; #phi; Entries',
path=path_names[i]+'/OFF_Clusters',xbins=64,xmin=-math.pi,xmax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_time',title='OFF Cluster time; time; Entries',
path=path_names[i]+'/OFF_Clusters',xbins=75,xmin=-25.0,xmax=25.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_et,OFF_time',title='Number of OFF Clusters; E_{T} [GeV]; Time', type='TProfile',
path=path_names[i]+'/OFF_Clusters',xbins=50,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_type',title='HLT Cluster Type; Size Enum; Entries',
path=path_names[i]+'/OFF_Clusters',xbins=16,xmin=0.5,xmax=16.5)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_bc,OFF_et;OFF_et_vs_BC',title='OFF Clusters E_{T} vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=path_names[i]+'/OFF_Clusters',xbins=21,xmin=-0.5,xmax=20.5)
########################
# HLT matched to OFF #
########################
# Declare HLT matched HLT vs. OFF cluster histograms
TopoCaloClustersMonGroup[i].defineHistogram('HLT_matched_fraction',title='Fraction of HLT clusters matched to OFF clusters; Matched fraction; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=100,xmin=0.0,xmax=1.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_vs_OFF_minimum_delta_r',title='HLT vs OFF Cluster #DeltaR; #DeltaR; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=50,xmin=0.0,xmax=0.1)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_vs_OFF_delta_eta',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster #Delta#eta; #eta_{_{OFF}} - #eta_{_{HLT}}; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=50,xmin=-0.2,xmax=0.2)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_vs_OFF_delta_phi',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster #Delta#phi; #phi_{_{OFF}} - #phi_{_{HLT}}; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=50,xmin=0.0,xmax=0.02)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_vs_OFF_delta_time',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster time; Time; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=80,xmin=-20.0,xmax=20.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_et,OFF_match_et;OFF_match_et_vs_HLT_with_OFF_match_et',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster E_{T}; E_{T_{OFF}} [GeV]; E_{T_{HLT}} [GeV]', type='TH2F',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=100,xmin=0.0,xmax=100.0, ybins=100,ymin=0.0,ymax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_vs_OFF_resolution',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster #DeltaE_{T} / E_{T}; E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} [%]; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=100,xmin=-60.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_et,HLT_vs_OFF_resolution;HLT_vs_OFF_resolution_vs_HLT_with_OFF_match_et',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; E_{T,HLT} [GeV]; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=100,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_eta,HLT_vs_OFF_resolution;HLT_vs_OFF_resolution_vs_HLT_with_OFF_match_eta',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #eta_{_{ OFF}}; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=20,xmin=-5.0,xmax=5.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_phi,HLT_vs_OFF_resolution;HLT_vs_OFF_resolution_vs_HLT_with_OFF_match_phi',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #phi_{_{ OFF}}; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=16,xmin=-math.pi,xmax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_eta,HLT_phi,HLT_vs_OFF_resolution;HLT_vs_OFF_resolution_vs_HLT_with_OFF_match_phi_vs_HLT_with_OFF_match_eta',cutmask='HLT_with_OFF_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #eta; #phi', type='TProfile2D',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
# Declare HLT histograms with OFF matches
TopoCaloClustersMonGroup[i].defineHistogram('HLT_with_OFF_match_num',title='Number of HLT Clusters (With OFF Matches); Num Clusters; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=101,xmin=-10.0,xmax=2010.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_eta,HLT_phi;HLT_with_OFF_match_phi_vs_HLT_with_OFF_match_eta',cutmask='HLT_with_OFF_match',title='Number of HLT Clusters (With OFF Matches); #eta; #phi; ', type='TH2F',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_et;HLT_with_OFF_match_et',cutmask='HLT_with_OFF_match',title='HLT Clusters E_{T} (With OFF Matches); E_{T} [GeV]; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=100,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_eta;HLT_with_OFF_match_eta',cutmask='HLT_with_OFF_match',title='HLT Clusters #eta (With OFF Matches); #eta; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=50,xmin=-5.0,xmax=5.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_phi;HLT_with_OFF_match_phi',cutmask='HLT_with_OFF_match',title='HLT Cluster #phi (With OFF Matches); #phi; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=64,xmin=-math.pi,xmax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_time;HLT_with_OFF_match_time',cutmask='HLT_with_OFF_match',title='HLT Cluster time (With OFF Matches); time; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=75,xmin=-25.0,xmax=25.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_et,HLT_time;HLT_with_OFF_match_time_vs_HLT_with_OFF_match_et',cutmask='HLT_with_OFF_match',title='Number of HLT Clusters (With OFF Matches); E_{T} [GeV]; Time', type='TProfile',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=50,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_type;HLT_with_OFF_match_type',cutmask='HLT_with_OFF_match',title='HLT Cluster Type (With OFF Matches); Size Enum; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=16,xmin=0.5,xmax=16.5)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_bc,HLT_et;HLT_with_OFF_match_et_vs_BC',cutmask='HLT_with_OFF_match',title='HLT Clusters E_{T} (With OFF Matches) vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=21,xmin=-0.5,xmax=20.5)
# Declare HLT histograms without OFF matches
TopoCaloClustersMonGroup[i].defineHistogram('HLT_no_OFF_match_num',title='Number of HLT Clusters (No OFF Matches); Num Clusters; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=101,xmin=-10.0,xmax=2010.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_eta,HLT_phi;HLT_no_OFF_match_phi_vs_HLT_no_OFF_match_eta',cutmask='HLT_no_OFF_match',title='Number of HLT Clusters (No OFF Matches); #eta; #phi; ', type='TH2F',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_et;HLT_no_OFF_match_et',cutmask='HLT_no_OFF_match',title='HLT Clusters E_{T} (No OFF Matches); E_{T} [GeV]; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=100,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_eta;HLT_no_OFF_match_eta',cutmask='HLT_no_OFF_match',title='HLT Clusters #eta (No OFF Matches); #eta; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=50,xmin=-5.0,xmax=5.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_phi;HLT_no_OFF_match_phi',cutmask='HLT_no_OFF_match',title='HLT Cluster #phi (No OFF Matches); #phi; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=64,xmin=-math.pi,xmax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_time;HLT_no_OFF_match_time',cutmask='HLT_no_OFF_match',title='HLT Cluster time (No OFF Matches); time; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=75,xmin=-25.0,xmax=25.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_et,HLT_time;HLT_no_OFF_match_time_vs_HLT_no_OFF_match_et',cutmask='HLT_no_OFF_match',title='Number of HLT Clusters (No OFF Matches); E_{T} [GeV]; Time', type='TProfile',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=50,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_type;HLT_no_OFF_match_type',cutmask='HLT_no_OFF_match',title='HLT Cluster Type (No OFF Matches); Size Enum; Entries',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=16,xmin=0.5,xmax=16.5)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_bc,HLT_et;HLT_no_OFF_match_et_vs_BC',cutmask='HLT_no_OFF_match',title='HLT Clusters E_{T} (No OFF Matches) vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=path_names[i]+'/HLT_Matched_to_OFF',xbins=21,xmin=-0.5,xmax=20.5)
########################
# OFF matched to HLT #
########################
# Declare OFF matched HLT vs. OFF cluster histograms
TopoCaloClustersMonGroup[i].defineHistogram('OFF_matched_fraction',title='Fraction of OFF clusters matched to HLT clusters; Matched fraction; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=100,xmin=0.0,xmax=1.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_vs_HLT_minimum_delta_r',title='HLT vs OFF Cluster #DeltaR; #DeltaR; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=50,xmin=0.0,xmax=0.1)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_vs_HLT_delta_eta',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster #Delta#eta; #eta_{_{OFF}} - #eta_{_{HLT}}; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=50,xmin=-0.2,xmax=0.2)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_vs_HLT_delta_phi',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster #Delta#phi; #phi_{_{OFF}} - #phi_{_{HLT}}; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=50,xmin=0.0,xmax=0.02)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_vs_HLT_delta_time',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster time; Time; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=80,xmin=-20.0,xmax=20.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_et,HLT_match_et;HLT_match_et_vs_OFF_with_HLT_match_et',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster E_{T}; E_{T_{OFF}} [GeV]; E_{T_{HLT}} [GeV]', type='TH2F',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=100,xmin=0.0,xmax=100.0, ybins=100,ymin=0.0,ymax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_vs_HLT_resolution',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster #DeltaE_{T} / E_{T}; E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} [%]; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=100,xmin=-60.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_et,OFF_vs_HLT_resolution;OFF_vs_HLT_resolution_vs_OFF_with_HLT_match_et',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; E_{T,OFF} [GeV]; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=100,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_eta,OFF_vs_HLT_resolution;OFF_vs_HLT_resolution_vs_OFF_with_HLT_match_eta',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #eta_{_{ OFF}}; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=20,xmin=-5.0,xmax=5.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_phi,OFF_vs_HLT_resolution;OFF_vs_HLT_resolution_vs_OFF_with_HLT_match_phi',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #phi_{_{ OFF}}; < E_{T_{OFF}} - E_{T_{HLT}} / E_{T_{OFF}} >', type='TProfile',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=16,xmin=-math.pi,xmax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_eta,OFF_phi,OFF_vs_HLT_resolution;OFF_vs_HLT_resolution_vs_OFF_with_HLT_match_phi_vs_OFF_with_HLT_match_eta',cutmask='OFF_with_HLT_match',title='HLT vs OFF Cluster < #DeltaE_{T} / E_{T} >; #eta; #phi', type='TProfile2D',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
# Declare OFF histograms with HLT matches
TopoCaloClustersMonGroup[i].defineHistogram('OFF_with_HLT_match_num',title='Number of OFF Clusters (With HLT Matches); Num Clusters; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=101,xmin=-10.0,xmax=2010.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_eta,OFF_phi;OFF_with_HLT_match_phi_vs_OFF_with_HLT_match_eta',cutmask='OFF_with_HLT_match',title='Number of OFF Clusters (With HLT Matches); #eta; #phi; ', type='TH2F',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_et;OFF_with_HLT_match_et',cutmask='OFF_with_HLT_match',title='OFF Clusters E_{T} (With HLT Matches); E_{T} [GeV]; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=100,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_eta;OFF_with_HLT_match_eta',cutmask='OFF_with_HLT_match',title='OFF Clusters #eta (With HLT Matches); #eta; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=50,xmin=-5.0,xmax=5.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_phi;OFF_with_HLT_match_phi',cutmask='OFF_with_HLT_match',title='OFF Cluster #phi (With HLT Matches); #phi; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=64,xmin=-math.pi,xmax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_time;OFF_with_HLT_match_time',cutmask='OFF_with_HLT_match',title='OFF Cluster time (With HLT Matches); time; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=75,xmin=-25.0,xmax=25.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_et,OFF_time;OFF_with_HLT_match_time_vs_OFF_with_HLT_match_et',cutmask='OFF_with_HLT_match',title='Number of OFF Clusters (With HLT Matches); E_{T} [GeV]; Time', type='TProfile',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=50,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_type;OFF_with_HLT_match_type',cutmask='OFF_with_HLT_match',title='OFF Cluster Type (With HLT Matches); Size Enum; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=16,xmin=0.5,xmax=16.5)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_bc,OFF_et;OFF_with_HLT_match_et_vs_BC',cutmask='OFF_with_HLT_match',title='OFF Clusters E_{T} (With HLT Matches) vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=21,xmin=-0.5,xmax=20.5)
# Declare OFF histograms without HLT matches
TopoCaloClustersMonGroup[i].defineHistogram('OFF_no_HLT_match_num',title='Number of OFF Clusters (No HLT Matches); Num Clusters; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=101,xmin=-10.0,xmax=2010.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_eta,OFF_phi;OFF_no_HLT_match_phi_vs_OFF_no_HLT_match_eta',cutmask='OFF_no_HLT_match',title='Number of OFF Clusters (No HLT Matches); #eta; #phi; ', type='TH2F',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=50,xmin=-5.0,xmax=5.0,ybins=64,ymin=-math.pi,ymax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_et;OFF_no_HLT_match_et',cutmask='OFF_no_HLT_match',title='OFF Clusters E_{T} (No HLT Matches); E_{T} [GeV]; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=100,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_eta;OFF_no_HLT_match_eta',cutmask='OFF_no_HLT_match',title='OFF Clusters #eta (No HLT Matches); #eta; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=50,xmin=-5.0,xmax=5.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_phi;OFF_no_HLT_match_phi',cutmask='OFF_no_HLT_match',title='OFF Cluster #phi (No HLT Matches); #phi; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=64,xmin=-math.pi,xmax=math.pi)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_time;OFF_no_HLT_match_time',cutmask='OFF_no_HLT_match',title='OFF Cluster time (No HLT Matches); time; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=75,xmin=-25.0,xmax=25.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_et,OFF_time;OFF_no_HLT_match_time_vs_OFF_no_HLT_match_et',cutmask='OFF_no_HLT_match',title='Number of OFF Clusters (No HLT Matches); E_{T} [GeV]; Time', type='TProfile',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=50,xmin=0.0,xmax=100.0)
TopoCaloClustersMonGroup[i].defineHistogram('OFF_type;OFF_no_HLT_match_type',cutmask='OFF_no_HLT_match',title='OFF Cluster Type (No HLT Matches); Size Enum; Entries',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=16,xmin=0.5,xmax=16.5)
TopoCaloClustersMonGroup[i].defineHistogram('HLT_bc,OFF_et;OFF_no_HLT_match_et_vs_BC',cutmask='OFF_no_HLT_match',title='OFF Clusters E_{T} (No HLT Matches) vs BC; BCs from front of bunch train; <E_{T}> [GeV]', type='TProfile',
path=path_names[i]+'/OFF_Matched_to_HLT',xbins=21,xmin=-0.5,xmax=20.5)
result.merge(helper.result())
return result
def Run3AFPExampleMonitoringConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'Run3AFPMonitorCfg')
from AthenaConfiguration.ComponentFactory import CompFactory
#from Run3AFPMonitoring.Run3AFPMonitoringConf import AFPSiLayerAlgorithm
afpSiLayerAlgorithmFac = CompFactory.AFPSiLayerAlgorithm
afpSiLayerAlgorithm = helper.addAlgorithm(afpSiLayerAlgorithmFac,
'AFPSiLayerAlg')
#from Run3AFPMonitoring.Run3AFPMonitoringConf import AFPToFAlgorithm
afpToFAlgorithmFac = CompFactory.AFPToFAlgorithm
afpToFAlgorithm = helper.addAlgorithm(afpToFAlgorithmFac, 'AFPToFAlg')
# Add a generic monitoring tool (a "group" in old language). The returned
# object here is the standard GenericMonitoringTool.
AFPSiGroup = helper.addGroup(afpSiLayerAlgorithm, 'AFPSiLayerTool', 'AFP/')
AFPToFGroup = helper.addGroup(afpToFAlgorithm, 'AFPToFTool', 'AFP/')
AFPSiGroup.defineHistogram(
'lb,nSiHits',
title='Luminosity Block;lb;total number of Hits',
type='TProfile',
path='SiT/',
xbins=1000,
xmin=-0.5,
xmax=999.5)
AFPToFGroup.defineHistogram(
'lb,nTofHits',
title='Luminosity Block;lb;total number of Hits',
type='TProfile',
path='ToF/',
xbins=1000,
xmin=-0.5,
xmax=999.5)
AFPToFGroup.defineHistogram(
'numberOfHit_S0',
title='Number of hit per bar station 0;total number of Hits',
path='ToF/',
xbins=4,
xmin=-0.5,
xmax=3.5)
AFPToFGroup.defineHistogram(
'numberOfHit_S3',
title='Number of hit per bar station 3;total number of Hits',
path='ToF/',
xbins=4,
xmin=-0.5,
xmax=3.5)
# Using a map of groups
layerList = ['P0', 'P1', 'P2',
'P3'] ## TODO XXX adapt to the enum/xAOD namespace names
combinedList = ['farAside', 'nearAside', 'nearCside', 'farCside']
array = helper.addArray([combinedList, layerList],
afpSiLayerAlgorithm,
'AFPSiLayerTool',
topPath='AFP/SiT/')
array.defineHistogram('pixelColIDChip',
title='1D hitmap for {0} Layer {1};pixelColIDChip',
path='PixelColIDChip',
xbins=80,
xmin=0.5,
xmax=80.5)
array.defineHistogram('pixelRowIDChip',
title='1D hitmap for {0} Layer {1};pixelRowIDChip',
path='PixelRowIDChip',
xbins=336,
xmin=0.5,
xmax=336.5)
array.defineHistogram(
'pixelColIDChip,pixelRowIDChip',
title='hitmap for {0} Layer {1};pixelColIDChip;pixelRowIDChip',
type='TH2F',
path='pixelColRow2D',
xbins=80,
xmin=0.5,
xmax=80.5,
ybins=336,
ymin=0.5,
ymax=336.5)
array.defineHistogram(
'timeOverThreshold',
type='TH1F',
title='1D Time over threshold for {0} Layer {1};timeOverThreshold',
path='SiTimeOverThreshold',
xbins=60,
xmin=0,
xmax=20)
array.defineHistogram(
'clusterX,clusterY',
title='Cluster position in station {0} Layer {1};clusterX;clusterY',
type='TH2F',
path='Cluster',
xbins=80,
xmin=0.5,
xmax=80.5,
ybins=336,
ymin=0.5,
ymax=336.5)
array = helper.addArray([combinedList],
afpSiLayerAlgorithm,
'AFPSiLayerTool',
topPath='AFP/Track/')
array.defineHistogram(
'trackX,trackY',
title='Track posistion position in station {0};trackX;trackY',
type='TH2F',
path='Track',
xbins=80,
xmin=0.5,
xmax=80.5,
ybins=336,
ymin=0.5,
ymax=336.5)
arrayOneList = helper.addArray([combinedList],
afpToFAlgorithm,
'AFPToFTool',
topPath='AFP/ToF/')
arrayOneList.defineHistogram(
'trainID,barInTrainID',
title='ToF hit bar vs train {0};trainID;barInTrainID',
type='TH2F',
path='HitBarvsTrain/',
xbins=4,
xmin=-0.5,
xmax=3.5,
ybins=4,
ymin=-0.5,
ymax=3.5)
# Finalize. The return value should be a tuple of the ComponentAccumulator
return helper.result()
def TrigMinBias(configFlags):
from AthenaMonitoring import AthMonitorCfgHelper
monConfig = AthMonitorCfgHelper(configFlags, 'HLTMinBiasMonAlgMTAcc')
from AthenaConfiguration.ComponentFactory import CompFactory
alg = monConfig.addAlgorithm(CompFactory.HLTMinBiasMonAlgMT,
'HLTMinBiasMonAlgMT')
mbEffAllGroup = monConfig.addGroup(alg, 'EffAll', 'HLT/MinBiasMon/')
length = len(alg.triggerList)
mbEffAllGroup.defineHistogram("PurityPassed,whichTrigger",
type='TEfficiency',
title="PurityPassed;whichTrigger",
xbins=length,
xmin=0,
xmax=length,
xlabels=list(alg.triggerList))
mbEffAllGroup.defineHistogram("whichTrigger",
title="count of triggers;HLT",
xbins=length,
xmin=0,
xmax=length,
xlabels=list(alg.triggerList))
mbEffAllGroup.defineHistogram("whichTrigger;No. of events",
type='TH1I',
title='Event per Trigger;HLT',
xbins=length,
xmin=0,
xmax=length,
xlabels=list(alg.triggerList))
mbEffAllGroup.defineHistogram(
"decision,whichTrigger",
type='TEfficiency',
title='Efficiency of selecting Events with One Good Trk;TriggerName',
xbins=length,
xmin=0,
xmax=length,
xlabels=list(alg.triggerList))
for chain in alg.triggerList:
mbGroup = monConfig.addGroup(alg, chain,
'HLT/MinBiasMon/IDMinbias/' + chain + '/')
mbEffGroup = monConfig.addGroup(
alg, chain + '_Eff',
'HLT/MinBiasMon/Purities&Efficiencies/' + chain + '/')
# correct the titles of following histograms
mbGroup.defineHistogram(
"PixelSPLow",
title=
"Number of SP in whole Pixels detector for all events in low range",
xbins=100,
xmin=0,
xmax=100)
mbGroup.defineHistogram(
"PixelSPHigh",
title=
"Number of SP in whole Pixels detector for all events in high range",
xbins=100,
xmin=0,
xmax=30000)
mbGroup.defineHistogram("PixBarr_SP",
title="Number of SP for all events in Barrel",
xbins=100,
xmin=0,
xmax=30000)
mbGroup.defineHistogram("PixECA_SP",
title="Number of SP for all events in ECA",
xbins=100,
xmin=0,
xmax=30000)
mbGroup.defineHistogram("PixECC_SP",
title="Number of SP for all events in ECC",
xbins=100,
xmin=0,
xmax=30000)
mbGroup.defineHistogram(
"SctTot",
title="Number of SP in whole SCT detector for all events",
xbins=100,
xmin=0,
xmax=120000)
mbGroup.defineHistogram(
"SctBarr_SP",
title="Number of SCT_SP for all events in Barrel",
xbins=100,
xmin=0,
xmax=50000)
mbGroup.defineHistogram("SctECA_SP",
title="Number of SCT_SP for all events in ECA",
xbins=100,
xmin=0,
xmax=50000)
mbGroup.defineHistogram("SctECC_SP",
title="Number of SCT_SP for all events in ECC",
xbins=100,
xmin=0,
xmax=50000)
mbGroup.defineHistogram(
"nTrk",
title="Number of offline reconstructed Trk for all events",
xbins=100,
xmin=0,
xmax=30000)
mbGroup.defineHistogram(
"xaodnTrk",
title="Number of offline reconstructed xaod Trk for all events",
xbins=100,
xmin=0,
xmax=30000)
mbGroup.defineHistogram("nTrk,xaodnTrk",
type='TH2F',
title="nTrk;xaodnTrk",
xbins=100,
xmin=0,
xmax=2000,
ybins=100,
ymin=0,
ymax=2000)
mbGroup.defineHistogram("SctECA_SP,SctECC_SP",
type='TH2F',
title="SctECA_SP;SctECC_SP",
xbins=100,
xmin=0,
xmax=30000,
ybins=100,
ymin=0,
ymax=30000)
mbGroup.defineHistogram("PixECA_SP,PixECC_SP",
type='TH2F',
title="PixECA_SP;PixECC_SP",
xbins=100,
xmin=0,
xmax=30000,
ybins=100,
ymin=0,
ymax=30000)
mbGroup.defineHistogram("SctBarr_SP,PixBarr_SP",
type='TH2F',
title="SctBarr_SP;PixBarr_SP",
xbins=100,
xmin=0,
xmax=120000,
ybins=100,
ymin=0,
ymax=30000)
mbEffGroup.defineHistogram("NumGoodOnlineTracks",
title="NumGoodOnlineTracks",
xbins=100,
xmin=0,
xmax=2000)
mbEffGroup.defineHistogram("NumGoodOfflineTracks",
title="NumGoodOfflineTracks",
xbins=100,
xmin=0,
xmax=2000)
mbEffGroup.defineHistogram(
"NumGoodOnlineTracks,NumGoodOfflineTracks",
type='TH2F',
title="NumGoodOnlineTracks;NumGoodOfflineTracks",
xbins=100,
xmin=0,
xmax=2000,
ybins=100,
ymin=0,
ymax=2000)
mbEffGroup.defineHistogram("decision,NumGoodOfflineTracks",
type='TEfficiency',
title='Efficiency;Offline Good nTrk',
xbins=1000,
xmin=0,
xmax=1000)
mbEffGroup.defineHistogram("decision,nTrk",
type='TEfficiency',
title="Efficiency;nTrk",
xbins=1000,
xmin=0,
xmax=1000)
return monConfig.result()
def JetTagMonitorConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
### STEP 1 ###
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
#from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
#result = ComponentAccumulator()
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'JetTagAthMonitorCfg')
### STEP 2 ###
# Adding an algorithm to the helper. Here, we will use the jetTagging
# algorithm in the AthenaMonitoring package. Just pass the type to the
# helper. Then, the helper will instantiate an instance and set up the
# base class configuration following the inputFlags. The returned object
# is the algorithm.
# You can actually make multiple instances of the same algorithm and give
# them different configurations
from AthenaConfiguration.ComponentFactory import CompFactory
#jetTagGeneral = helper.addAlgorithm(JetTagMonitorAlgorithm,'JetTagGeneral')
jetTagMonAlg = helper.addAlgorithm(CompFactory.JetTagMonitorAlgorithm,
'JetTagMonAlg')
#anotherJetTagMonAlg = helper.addAlgorithm(JetTagMonitorAlgorithm,'AnotherJetTagMonAlg')
# If for some really obscure reason you need to instantiate an algorithm
# yourself, the AddAlgorithm method will still configure the base
# properties and add the algorithm to the monitoring sequence.
# helper.AddAlgorithm(myExistingAlg)
### STEP 3 ###
# Edit properties of an algorithm
# Declare properties
jetTagMonAlg.ElectronTrigger_201X = "HLT_e[2-9][0-9]_.*" # electrons 20-99 GeV
jetTagMonAlg.MuonTrigger_201X = "HLT_mu[2-9][0-9].*" # muons 20-99 GeV
jetTagMonAlg.TriggerChain = ''
#jetTagMonAlg.TriggerChain = 'HLT_mu26_ivarmedium'
#jetTagMonAlg.TriggerChain = 'HLT_e24_lhtight_nod0'
#jetTagMonAlg.RandomHist = True
### STEP 4 ###
# Add some tools. N.B. Do not use your own trigger decision tool. Use the
# standard one that is included with AthMonitorAlgorithm.
# First, add a tool that's set up by a different configuration function.
# In this case, CaloNoiseToolCfg returns its own component accumulator,
# which must be merged with the one from this function.
# from CaloTools.CaloNoiseToolConfig import CaloNoiseToolCfg
# caloNoiseAcc, caloNoiseTool = CaloNoiseToolCfg(inputFlags)
# result.merge(caloNoiseAcc)
# jetTagMonAlg.CaloNoiseTool = caloNoiseTool
# Then, add a tool that doesn't have its own configuration function. In
# this jetTagging, no accumulator is returned, so no merge is necessary.
# from MyDomainPackage.MyDomainPackageConf import MyDomainTool
# jetTagMonAlg.MyDomainTool = MyDomainTool()
# Add a generic monitoring tool (a "group" in old language). The returned
# object here is the standard GenericMonitoringTool.
#GeneralGroup = helper.addGroup(jetTagGeneral,'JetTagMonitor')
GeneralGroup = helper.addGroup(jetTagMonAlg, 'JetTagMonitor', 'JetTagging')
#JetGroup = helper.addGroup(jetTagMonAlg,'JetTagMonitor')
#AnotherGroup = helper.addGroup(anotherJetTagMonAlg,'JetTagMonitor')
# Add a GMT for the other jetTagging monitor algorithm
#shifterGroup = helper.addGroup(shifterTrigEgammaMonAlg,'TrigEgammaMonitor','HLT/EgammaMon/Shifter/')
### STEP 5 ###
#title is for plot, x-axis, y-axis
#type is type of plot?
#path is for folder structure of root output file
### General histograms <-----
GeneralGroup.defineHistogram(
'Event_CutFlow',
title='Event CutFlow;Pass Event CutFlow;Events',
path='Cutflow_plots',
xbins=10,
xmin=-0.5,
xmax=9.5)
GeneralGroup.defineHistogram(
'Trigger_CutFlow',
title='Trigger CutFlow;Pass Trigger CutFlow;Events',
path='Cutflow_plots',
xbins=10,
xmin=-0.5,
xmax=9.5)
GeneralGroup.defineHistogram('Jet_CutFlow',
title='Jet CutFlow;Pass Jet CutFlow;Jets',
path='Cutflow_plots',
xbins=10,
xmin=-0.5,
xmax=9.5)
GeneralGroup.defineHistogram('run',
title='Run number;Run;Event',
path='Run_plots',
xbins=500000,
xmin=-0.5,
xmax=499999.5)
GeneralGroup.defineHistogram('lb',
title='Lumi Block;LB;Events',
path='Run_plots',
xbins=1000,
xmin=-0.5,
xmax=999.5)
GeneralGroup.defineHistogram('mu',
title='Mu;<mu>;Events',
path='Run_plots',
xbins=100,
xmin=0,
xmax=100.0)
GeneralGroup.defineHistogram('nPrimVtx',
title='Primary vertices;PV;Events',
path='Run_plots',
xbins=100,
xmin=0,
xmax=100.0)
GeneralGroup.defineHistogram('xPrimVtx',
title='Primary vertices X position;X;Events',
path='Run_plots',
xbins=40,
xmin=-2.0,
xmax=2.0)
GeneralGroup.defineHistogram('yPrimVtx',
title='Primary vertices Y position;Y;Events',
path='Run_plots',
xbins=40,
xmin=-2.0,
xmax=2.0)
GeneralGroup.defineHistogram('zPrimVtx',
title='Primary vertices Z position;Z;Events',
path='Run_plots',
xbins=100,
xmin=-250,
xmax=250.0)
GeneralGroup.defineHistogram(
'nTracks_PV',
title='Number of tracks in PV;Tracks in PV;Number of tracks',
path='Run_plots',
xbins=150,
xmin=-0.5,
xmax=149.5)
GeneralGroup.defineHistogram(
'nTracks',
title='Track multiplicity;Tracks per event;Number of events',
path='Run_plots',
xbins=100,
xmin=0,
xmax=1000)
GeneralGroup.defineHistogram(
'nHitsBLayer',
title='Number of IBL hits;Hits on track;Number of IBL hits on track',
path='Run_plots',
xbins=5,
xmin=0,
xmax=5)
GeneralGroup.defineHistogram(
'nHitsPixel',
title=
'Number of Pixel hits;Hits on track;Number of Pixel hits on track',
path='Run_plots',
xbins=10,
xmin=0,
xmax=10)
GeneralGroup.defineHistogram(
'nHitsSCT',
title='Number of SCT hits;Hits on track;Number of SCT hits on track',
path='Run_plots',
xbins=15,
xmin=0,
xmax=15)
GeneralGroup.defineHistogram(
'nHitsSi',
title=
'Number of PIX+SCT hits;Hits on track;Number of PIX+SCT hits on track',
path='Run_plots',
xbins=25,
xmin=0,
xmax=25)
GeneralGroup.defineHistogram(
'nHitsTRT',
title='Number of TRT hits;Hits on track;Number of TRT hits on track',
path='Run_plots',
xbins=100,
xmin=0,
xmax=100)
GeneralGroup.defineHistogram(
'nHitsID',
title='Number of ID hits;Hits on track;Number of ID hits on track',
path='Run_plots',
xbins=150,
xmin=0,
xmax=150)
GeneralGroup.defineHistogram(
'JetTracks_n',
title='Track multiplicity in jet;Tracks;Number of tracks per jet',
path='Run_plots',
xbins=50,
xmin=0,
xmax=50)
GeneralGroup.defineHistogram('JetTracks_pt',
title='pT of tracks in jet;pT;Tracks in jets',
path='Run_plots',
xbins=100,
xmin=0,
xmax=100)
GeneralGroup.defineHistogram(
'JetTracks_eta',
title='#eta of tracks in jet;#eta;Tracks in jets',
path='Run_plots',
xbins=100,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'JetTracks_phi',
title='#phi of tracks in jet;#phi;Tracks in jets',
path='Run_plots',
xbins=100,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'JetTracks_d0',
title='d_0 of tracks in jet;d_0;Tracks in jets',
path='Run_plots',
xbins=100,
xmin=-5,
xmax=5)
GeneralGroup.defineHistogram(
'JetTracks_z0',
title='z_0 of tracks in jet;z_0;Tracks in jets',
path='Run_plots',
xbins=100,
xmin=-300,
xmax=300)
GeneralGroup.defineHistogram(
'JetTracks_nHitsBLayer',
title=
'Number of IBL hits on tracks in jets;Hits on track;Number of IBL hits on track',
path='Run_plots',
xbins=5,
xmin=0,
xmax=5)
GeneralGroup.defineHistogram(
'JetTracks_nHitsPixel',
title=
'Number of Pixel hits on tracks in jets;Hits on track;Number of Pixel hits on track',
path='Run_plots',
xbins=10,
xmin=0,
xmax=10)
GeneralGroup.defineHistogram(
'JetTracks_nHitsSCT',
title=
'Number of SCT hits on tracks in jets;Hits on track;Number of SCT hits on track',
path='Run_plots',
xbins=15,
xmin=0,
xmax=15)
### is ttbar histograms <-----
#registerHist(*m_monGr_shift, m_jet_mv_w_top = TH1F_LW::create("jet_MV_top",(m_mv_algorithmName+" Tag Weight of Jets in Top Events; "+m_mv_algorithmName+" tag weight").c_str(),int(m_mv_nBins/2),m_mv_rangeStart,m_mv_rangeStop));
#registerHist(*m_monGr_shift, m_jet_top_eff = TH1F_LW::create("jet_top_eff","Fraction of b-tagged Jets in Top Events",1,-0.5,0.5));
#registerHist(*m_monGr_shift, m_jet_pt_top_eff = TH1F_LW::create("jet_pt_top_eff","Fraction of b-tagged Jets in Top Events vs pT; pT [GeV]",10,0.,200.));
GeneralGroup.defineHistogram('muon_PT',
title='Muon pT;Muon pT;Events',
path='TTbar_plots',
xbins=100,
xmin=0.0,
xmax=200000.0)
GeneralGroup.defineHistogram('electron_PT',
title='Electron pT;Electron pT;Events',
path='TTbar_plots',
xbins=100,
xmin=0.0,
xmax=200000.0)
GeneralGroup.defineHistogram(
'nIsoMuons',
title='Number of isolated Muons;Isolated muons;Number of events',
path='TTbar_plots',
xbins=3,
xmin=-0.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'nIsoElectrons',
title=
'Number of isolated Electrons;Isolated electrons;Number of events',
path='TTbar_plots',
xbins=3,
xmin=-0.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'nTTbarGoodJets',
title=
'Number of good jets in ttbar events;Good jets per event;Number of events',
path='TTbar_plots',
xbins=10,
xmin=-0.5,
xmax=9.5)
GeneralGroup.defineHistogram(
'mvTTbarJets',
title='MV of jets in ttbar events;Jet MV;Number of jets',
path='TTbar_plots',
xbins=50,
xmin=-1,
xmax=1)
GeneralGroup.defineHistogram(
'nTTbarJets',
title='Total number of ttbar jets;Number of jets;Number of events',
path='TTbar_plots',
xbins=1,
xmin=-0.5,
xmax=0.5)
GeneralGroup.defineHistogram(
'nTTbarJets_60tag',
title=
'Number of ttbar jets passing 60 tag WP; Jets passing 60 tag WP;Number of ttbar jets',
path='TTbar_plots',
xbins=1,
xmin=-0.5,
xmax=0.5)
GeneralGroup.defineHistogram(
'nTTbarJets_70tag',
title=
'Number of ttbar jets passing 70 tag WP; Jets passing 70 tag WP;Number of ttbar jets',
path='TTbar_plots',
xbins=1,
xmin=-0.5,
xmax=0.5)
GeneralGroup.defineHistogram(
'nTTbarJets_77tag',
title=
'Number of ttbar jets passing 77 tag WP; Jets passing 77 tag WP;Number of ttbar jets',
path='TTbar_plots',
xbins=1,
xmin=-0.5,
xmax=0.5)
GeneralGroup.defineHistogram(
'nTTbarJets_85tag',
title=
'Number of ttbar jets passing 85 tag WP; Jets passing 60 tag WP;Number of ttbar jets',
path='TTbar_plots',
xbins=1,
xmin=-0.5,
xmax=0.5)
GeneralGroup.defineHistogram(
'pass60n,nTTbarJets',
type='TEfficiency',
title='TTbar jets 60 tag WP Efficiency;ttbar jets;60 tag WP Efficiency',
path='Jet_Eff',
xbins=1,
xmin=-0.5,
xmax=0.5)
GeneralGroup.defineHistogram(
'pass70n,nTTbarJets',
type='TEfficiency',
title='TTbar jets 70 tag WP Efficiency;ttbar jets;70 tag WP Efficiency',
path='Jet_Eff',
xbins=1,
xmin=-0.5,
xmax=0.5)
GeneralGroup.defineHistogram(
'pass77n,nTTbarJets',
type='TEfficiency',
title='TTbar jets 77 tag WP Efficiency;ttbar jets;77 tag WP Efficiency',
path='Jet_Eff',
xbins=1,
xmin=-0.5,
xmax=0.5)
GeneralGroup.defineHistogram(
'pass85n,nTTbarJets',
type='TEfficiency',
title='TTbar jets 85 tag WP Efficiency;ttbar jets;85 tag WP Efficiency',
path='Jet_Eff',
xbins=1,
xmin=-0.5,
xmax=0.5)
GeneralGroup.defineHistogram(
'ptTTbarJets',
title='Number of ttbar jets vs pT;ttbar jet pT;Number of ttbar jets',
path='TTbar_plots',
xbins=40,
xmin=0,
xmax=200)
GeneralGroup.defineHistogram(
'ptTTbarJets_60tag',
title=
'Number of ttbar jets passing 60 tag WP vs pT;ttbar jet pT;Number of ttbar jets',
path='TTbar_plots',
xbins=40,
xmin=0,
xmax=200)
GeneralGroup.defineHistogram(
'ptTTbarJets_70tag',
title=
'Number of ttbar jets passing 70 tag WP vs pT;ttbar jet pT;Number of ttbar jets',
path='TTbar_plots',
xbins=40,
xmin=0,
xmax=200)
GeneralGroup.defineHistogram(
'ptTTbarJets_77tag',
title=
'Number of ttbar jets passing 77 tag WP vs pT;ttbar jet pT;Number of ttbar jets',
path='TTbar_plots',
xbins=40,
xmin=0,
xmax=200)
GeneralGroup.defineHistogram(
'ptTTbarJets_85tag',
title=
'Number of ttbar jets passing 85 tag WP vs pT;ttbar jet pT;Number of ttbar jets',
path='TTbar_plots',
xbins=40,
xmin=0,
xmax=200)
GeneralGroup.defineHistogram(
'pass60p,ptTTbarJets',
type='TEfficiency',
title=
'TTbar jets 60 tag WP Efficiency vs pT;ttbar jet pT;60 tag WP Efficiency',
path='Jet_Eff',
xbins=40,
xmin=0.0,
xmax=200.0)
GeneralGroup.defineHistogram(
'pass70p,ptTTbarJets',
type='TEfficiency',
title=
'TTbar jets 70 tag WP Efficiency vs pT;ttbar jet pT;70 tag WP Efficiency',
path='Jet_Eff',
xbins=40,
xmin=0.0,
xmax=200.0)
GeneralGroup.defineHistogram(
'pass77p,ptTTbarJets',
type='TEfficiency',
title=
'TTbar jets 77 tag WP Efficiency vs pT;ttbar jet pT;77 tag WP Efficiency',
path='Jet_Eff',
xbins=40,
xmin=0.0,
xmax=200.0)
GeneralGroup.defineHistogram(
'pass85p,ptTTbarJets',
type='TEfficiency',
title=
'TTbar jets 85 tag WP Efficiency vs pT;ttbar jet pT;85 tag WP Efficiency',
path='Jet_Eff',
xbins=40,
xmin=0.0,
xmax=200.0)
### is SMT jet histograms <-----
GeneralGroup.defineHistogram(
'nSoftMuons',
title='Number of Soft Muons;Muons per event;Number of muons',
path='SMT_plots',
xbins=3,
xmin=-0.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'nSMTJets',
title='Number of SMT Jets;Jets per event;Number of jets',
path='SMT_plots',
xbins=3,
xmin=-0.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'drSMT',
title='DeltaR between jet and soft muon;DR;Number of SMT candidates',
path='SMT_plots',
xbins=40,
xmin=0,
xmax=0.4)
GeneralGroup.defineHistogram(
'ptSMT_mu',
title='pT of SMT Muons;Muon pT [GeV];Number of muons',
path='SMT_plots',
xbins=50,
xmin=0,
xmax=100)
GeneralGroup.defineHistogram(
'ptSMT_jet',
title='pT of SMT Jets;Jet pT [GeV];Number of jets',
path='SMT_plots',
xbins=100,
xmin=0,
xmax=300)
GeneralGroup.defineHistogram(
'ptSMT_ratio',
title='pT ratio of SMT Jets (mu/jet);pT ratio;Number of SMT jets',
path='SMT_plots',
xbins=50,
xmin=0,
xmax=1)
GeneralGroup.defineHistogram(
'pTrelSMT',
title='pTrel of SMT Jets;pTrel;Number of jets',
path='SMT_plots',
xbins=50,
xmin=0,
xmax=5)
GeneralGroup.defineHistogram('mvSMT',
title='MV of SMT Jets;MV;Number of jets',
path='SMT_plots',
xbins=50,
xmin=-1,
xmax=1)
### jet quality cutflow histograms <-----
#Distributions before selection (all jets from selected events)
GeneralGroup.defineHistogram(
'nJets',
title='Jet multiplicity;Number of jets;Events',
path='Jet_quality',
xbins=50,
xmin=0,
xmax=50)
GeneralGroup.defineHistogram('jet_PT',
title='Jet pT;Jet pT [GeV];Jets',
path='Jet_quality',
xbins=100,
xmin=0.0,
xmax=200.0)
GeneralGroup.defineHistogram('jet_ETA',
title='Jet eta;Jet #eta;Jets',
path='Jet_quality',
xbins=100,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram('jet_PHI',
title='Jet phi;Jet #phi;Jets',
path='Jet_quality',
xbins=100,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram('jet_MV',
title='Jet MV;Jet MV;Jets',
path='Jet_quality',
xbins=100,
xmin=-1.0,
xmax=1.0)
#2D maps during selection
GeneralGroup.defineHistogram('jet_eta_all,jet_phi_all;jet_MAP_all',
title='2D MAP of all jets;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_quality',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'jet_eta_quality,jet_phi_quality;jet_MAP_quality',
title='2D MAP of quality jets;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_quality',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'jet_eta_kin,jet_phi_kin;jet_MAP_kin',
title='2D MAP of jets passing kinematic selection;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_quality',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'jet_eta_jvt,jet_phi_jvt;jet_MAP_jvt',
title='2D MAP of jets passing JVT;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_quality',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'jet_eta_overlap,jet_phi_overlap;jet_MAP_overlap',
title='2D MAP of not overlapping jets;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_quality',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram('jet_eta_good,jet_phi_good;jet_MAP_good',
title='2D MAP of good jets;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_quality',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'jet_eta_suspect,jet_phi_suspect;jet_MAP_suspect',
title='2D MAP of suspect jets;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_quality',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram('jet_eta_bad,jet_phi_bad;jet_MAP_bad',
title='2D MAP of bad jets;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_quality',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram('jet_eta_smt,jet_phi_smt;jet_MAP_smt',
title='2D MAP of SMT jets;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_quality',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
#GeneralGroup.defineHistogram('jet_MV_JVT_bef',title='Jet MV before JVT;Jet MV;Jets',path='Jet_quality',xbins=100,xmin=-1.0,xmax=1.0)
#GeneralGroup.defineHistogram('jet_MV_JVT_aft',title='Jet MV after JVT;Jet MV;Jets',path='Jet_quality',xbins=100,xmin=-1.0,xmax=1.0)
###Distributions for good jets (passing Good/Suspect/Bad selection)
GeneralGroup.defineHistogram('jet_pT_good',
title='Good jets pT;Good Jet pT [GeV];Jets',
path='Jet_MV',
xbins=100,
xmin=0.0,
xmax=200.0)
GeneralGroup.defineHistogram('jet_eta_good',
title='Good jets #eta;Good Jet #eta;Jets',
path='Jet_MV',
xbins=100,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram('jet_phi_good',
title='Good jets #phi;Good Jet #phi;Jets',
path='Jet_MV',
xbins=100,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram('jet_MV_good',
title='Good jets MV;Good Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
### tag weight histograms <-----
GeneralGroup.defineHistogram(
'jet_MV_mu_0_30',
title='Jet MV in mu bin 1 : <mu> = [0,30];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_mu_30_50',
title='Jet MV in mu bin 2 : <mu> = [30,50];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_mu_50_100',
title='Jet MV in mu bin 3 : <mu> = [50,100];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_pt_0_20',
title='Jet MV in pT bin 1 : pT = [0,20];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_pt_20_40',
title='Jet MV in pT bin 2 : pT = [20,40];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_pt_40_70',
title='Jet MV in pT bin 3 : pT = [40,70];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_pt_70_100',
title='Jet MV in pT bin 4 : pT = [70,100];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_pt_100_150',
title='Jet MV in pT bin 5 : pT = [100,150];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_pt_150_200',
title='Jet MV in pT bin 6 : pT = [150,200];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_pt_200_1000',
title='Jet MV in pT bin 7 : pT = [200,1000];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_eta_00_05',
title='Jet MV in #eta bin 1 : #eta = [0.0,0.5];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_eta_05_10',
title='Jet MV in #eta bin 2 : #eta = [0.5,1.0];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_eta_10_15',
title='Jet MV in #eta bin 3 : #eta = [1.0,1.5];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_eta_15_20',
title='Jet MV in #eta bin 4 : #eta = [1.5,2.0];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_eta_20_25',
title='Jet MV in #eta bin 5 : #eta = [2.0,2.5];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_phi_00_05',
title='Jet MV in #phi bin 1 : #phi = [0.0,0.5];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_phi_05_10',
title='Jet MV in #phi bin 2 : #phi = [0.5,1.0];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_phi_10_15',
title='Jet MV in #phi bin 3 : #phi = [1.0,1.5];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_phi_15_20',
title='Jet MV in #phi bin 4 : #phi = [1.5,2.0];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_phi_20_25',
title='Jet MV in #phi bin 5 : #phi = [2.0,2.5];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'jet_MV_phi_25_31',
title='Jet MV in #phi bin 6 : #phi = [2.5,3.1];Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
#jets passing WPs in eta and phi bins, 2D map and efficiency
GeneralGroup.defineHistogram(
'jet_eta_60tag',
title=
'Number of jets passing 60 tag WP vs #eta;Jet #eta;Number of jets',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'jet_eta_70tag',
title=
'Number of jets passing 70 tag WP vs #eta;Jet #eta;Number of jets',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'jet_eta_77tag',
title=
'Number of jets passing 77 tag WP vs #eta;Jet #eta;Number of jets',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'jet_eta_85tag',
title=
'Number of jets passing 85 tag WP vs #eta;Jet #eta;Number of jets',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'jet_phi_60tag',
title=
'Number of jets passing 60 tag WP vs #phi;Jet #phi;Number of jets',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'jet_phi_70tag',
title=
'Number of jets passing 70 tag WP vs #phi;Jet #phi;Number of jets',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'jet_phi_77tag',
title=
'Number of jets passing 77 tag WP vs #phi;Jet #phi;Number of jets',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'jet_phi_85tag',
title=
'Number of jets passing 85 tag WP vs #phi;Jet #phi;Number of jets',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'jet_eta_60tag,jet_phi_60tag;jet_MAP_60tag',
title='2D MAP of jets passing 60 tag WP;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_MV',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'jet_eta_70tag,jet_phi_70tag;jet_MAP_70tag',
title='2D MAP of jets passing 70 tag WP;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_MV',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'jet_eta_77tag,jet_phi_77tag;jet_MAP_77tag',
title='2D MAP of jets passing 77 tag WP;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_MV',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'jet_eta_85tag,jet_phi_85tag;jet_MAP_85tag',
title='2D MAP of jets passing 85 tag WP;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_MV',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'jet_eta',
title=
'Number of jets before passing tag vs #eta;Jet #eta;Number of jets',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'pass60e,jet_eta',
type='TEfficiency',
title='Jets 60 tag WP Efficiency vs #eta;Jet #eta;60 tag WP Efficiency',
path='Jet_Eff',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'pass70e,jet_eta',
type='TEfficiency',
title='Jets 70 tag WP Efficiency vs #eta;Jet #eta;70 tag WP Efficiency',
path='Jet_Eff',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'pass77e,jet_eta',
type='TEfficiency',
title='Jets 77 tag WP Efficiency vs #eta;Jet #eta;77 tag WP Efficiency',
path='Jet_Eff',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'pass85e,jet_eta',
type='TEfficiency',
title='Jets 85 tag WP Efficiency vs #eta;Jet #eta;85 tag WP Efficiency',
path='Jet_Eff',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'jet_phi',
title=
'Number of jets before passing tag vs #phi;Jet #phi;Number of jets',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'pass60f,jet_phi',
type='TEfficiency',
title='Jets 60 tag WP Efficiency vs #phi;Jet #phi;60 tag WP Efficiency',
path='Jet_Eff',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'pass70f,jet_phi',
type='TEfficiency',
title='Jets 70 tag WP Efficiency vs #phi;Jet #phi;70 tag WP Efficiency',
path='Jet_Eff',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'pass77f,jet_phi',
type='TEfficiency',
title='Jets 77 tag WP Efficiency vs #phi;Jet #phi;77 tag WP Efficiency',
path='Jet_Eff',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'pass85f,jet_phi',
type='TEfficiency',
title='Jets 85 tag WP Efficiency vs #phi;Jet #phi;85 tag WP Efficiency',
path='Jet_Eff',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
#2D TEfficiency for 2D MAP of fraction of good jets
GeneralGroup.defineHistogram(
'passGood,jet_eta_all,jet_phi_all',
type='TEfficiency',
title='TEfficiency in 2D;Jet #eta;Jet #phi;Good Jet Efficiency',
path='Jet_Eff',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
### the same but with suspect jets
GeneralGroup.defineHistogram('sus_jet_MV',
title='Suspect Jet MV;Suspect Jet MV;Jets',
path='Jet_quality',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_pt_0_20',
title='Suspect Jet MV in pT bin 1 : pT = [0,20];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_pt_20_40',
title='Suspect Jet MV in pT bin 2 : pT = [20,40];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_pt_40_80',
title='Suspect Jet MV in pT bin 3 : pT = [40,80];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_pt_80_100',
title='Suspect Jet MV in pT bin 4 : pT = [80,100];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_pt_100_150',
title='Suspect Jet MV in pT bin 5 : pT = [100,150];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_pt_150_200',
title='Suspect Jet MV in pT bin 6 : pT = [150,200];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_pt_200_1000',
title=
'Suspect Jet MV in pT bin 7 : pT = [200,1000];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_eta_0_05',
title=
'Suspect Jet MV in #eta bin 1 : #eta = [0,0.5];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_eta_05_10',
title=
'Suspect Jet MV in #eta bin 2 : #eta = [0.5,1.0];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_eta_10_15',
title=
'Suspect Jet MV in #eta bin 3 : #eta = [1.0,1.5];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_eta_15_20',
title=
'Suspect Jet MV in #eta bin 4 : #eta = [1.5,2.0];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_eta_20_25',
title=
'Suspect Jet MV in #eta bin 5 : #eta = [2.0,2.5];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_phi_0_05',
title=
'Suspect Jet MV in #phi bin 1 : #phi = [0,0.5];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_phi_05_10',
title=
'Suspect Jet MV in #phi bin 2 : #phi = [0.5,1.0];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_phi_10_15',
title=
'Suspect Jet MV in #phi bin 3 : #phi = [1.0,1.5];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_phi_15_20',
title=
'Suspect Jet MV in #phi bin 4 : #phi = [1.5,2.0];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_phi_20_25',
title=
'Suspect Jet MV in #phi bin 5 : #phi = [2.0,2.5];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_MV_phi_25_31',
title=
'Suspect Jet MV in #phi bin 6 : #phi = [2.5,3.1];Suspect Jet MV;Jets',
path='Jet_MV',
xbins=100,
xmin=-1.0,
xmax=1.0)
GeneralGroup.defineHistogram(
'sus_jet_eta_pretag',
title=
'Number of suspect jets before passing tag vs #eta;Suspect Jet #eta;Number of suspect jets',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'sus_jet_eta_60tag',
title=
'Number of suspect jets passing 60 tag WP vs #eta;Suspect Jet #eta;Number of suspect jets',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'sus_jet_eta_70tag',
title=
'Number of suspect jets passing 70 tag WP vs #eta;Suspect Jet #eta;Number of suspect jets',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'sus_jet_eta_77tag',
title=
'Number of suspect jets passing 77 tag WP vs #eta;Suspect Jet #eta;Number of suspect jets',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'sus_jet_eta_85tag',
title=
'Number of suspect jets passing 85 tag WP vs #eta;Suspect Jet #eta;Number of suspect jets',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'sus_jet_eta_60tag,sus_jet_eta_pretag',
type='TEfficiency',
title=
'Jets 60 tag WP Efficiency vs #eta;Suspect Jet #eta;60 tag WP Efficiency',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'sus_jet_eta_70tag,sus_jet_eta_pretag',
type='TEfficiency',
title=
'Jets 70 tag WP Efficiency vs #eta;Suspect Jet #eta;70 tag WP Efficiency',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'sus_jet_eta_77tag,sus_jet_eta_pretag',
type='TEfficiency',
title=
'Jets 77 tag WP Efficiency vs #eta;Suspect Jet #eta;77 tag WP Efficiency',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'sus_jet_eta_85tag,sus_jet_eta_pretag',
type='TEfficiency',
title=
'Jets 85 tag WP Efficiency vs #eta;Suspect Jet #eta;85 tag WP Efficiency',
path='Jet_MV',
xbins=10,
xmin=-2.5,
xmax=2.5)
GeneralGroup.defineHistogram(
'sus_jet_phi_pretag',
title=
'Number of suspect jets before passing tag vs #phi;Suspect Jet #phi;Number of suspect jets',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_phi_60tag',
title=
'Number of suspect jets passing 60 tag WP vs #phi;Suspect Jet #phi;Number of suspect jets',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_phi_70tag',
title=
'Number of suspect jets passing 70 tag WP vs #phi;Suspect Jet #phi;Number of suspect jets',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_phi_77tag',
title=
'Number of suspect jets passing 77 tag WP vs #phi;Suspect Jet #phi;Number of suspect jets',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_phi_85tag',
title=
'Number of suspect jets passing 85 tag WP vs #phi;Suspect Jet #phi;Number of suspect jets',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_phi_60tag,sus_jet_phi_pretag',
type='TEfficiency',
title=
'Jets 60 tag WP Efficiency vs #phi;Suspect Jet #phi;60 tag WP Efficiency',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_phi_70tag,sus_jet_phi_pretag',
type='TEfficiency',
title=
'Jets 70 tag WP Efficiency vs #phi;Suspect Jet #phi;70 tag WP Efficiency',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_phi_77tag,sus_jet_phi_pretag',
type='TEfficiency',
title=
'Jets 77 tag WP Efficiency vs #phi;Suspect Jet #phi;77 tag WPEfficiency',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_phi_85tag,sus_jet_phi_pretag',
type='TEfficiency',
title=
'Jets 85 tag WP Efficiency vs #phi;Suspect Jet #phi;85 tag WP Efficiency',
path='Jet_MV',
xbins=12,
xmin=-1 * math.pi,
xmax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_eta_60tag,sus_jet_phi_60tag;sus_jet_MAP_60tag',
title='2D MAP of jets passing 60 tag WP;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_MV',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_eta_70tag,sus_jet_phi_70tag;sus_jet_MAP_70tag',
title='2D MAP of jets passing 70 tag WP;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_MV',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_eta_77tag,sus_jet_phi_77tag;sus_jet_MAP_77tag',
title='2D MAP of jets passing 77 tag WP;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_MV',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
GeneralGroup.defineHistogram(
'sus_jet_eta_85tag,sus_jet_phi_85tag;sus_jet_MAP_85tag',
title='2D MAP of jets passing 85 tag WP;Jet #eta;Jet #phi',
type='TH2F',
path='Jet_MV',
xbins=100,
xmin=-2.5,
xmax=2.5,
ybins=200,
ymin=-1 * math.pi,
ymax=math.pi)
#1D and 2D Tefficiency examples
#aGroup.defineHistogram('pT_passed,pT',type='TEfficiency',title='Test TEfficiency;x;Eff',path='AndInTheDarkness',xbins=100,xmin=0.0,xmax=50.0)
#aGroup.defineHistogram('pT_passed,pT,random',type='TEfficiency',title='Test TEfficiency 2D;x;y;Eff',path='AndInTheDarkness',xbins=100,xmin=0.0,xmax=50.0,ybins=10, ymin=0.0, ymax=2.0)
### STEP 6 ###
# Finalize. The return value should be a tuple of the ComponentAccumulator
# and the sequence containing the created algorithms. If we haven't called
# any configuration other than the AthMonitorCfgHelper here, then we can
# just return directly (and not create "result" above)
return helper.result()
def TileMuIdMonitoringConfig(flags, **kwargs):
''' Function to configure TileMuIdMonitorAlgorithm algorithm in the monitoring system.'''
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(flags, 'TileMuIdMonitoring')
# Adding an TileCellMonitorAlgorithm algorithm to the helper
from AthenaConfiguration.ComponentFactory import CompFactory
tileMuIdMonAlg = helper.addAlgorithm(CompFactory.TileMuIdMonitorAlgorithm,
'TileMuIdMonAlg')
tileMuIdMonAlg.TriggerChain = ''
# L1Trigger Type Bits:
# bit0_RNDM, bit1_ZeroBias, bit2_L1Cal, bit3_Muon,
# bit4_RPC, bit5_FTK, bit6_CTP, bit7_Calib, AnyPhysTrig
kwargs.setdefault('fillHistogramsForL1Triggers',
['AnyPhysTrig', 'bit7_Calib'])
l1Triggers = kwargs['fillHistogramsForL1Triggers']
for k, v in kwargs.items():
setattr(tileMuIdMonAlg, k, v)
run = str(flags.Input.RunNumber[0])
# 1) Configure histogram with TileMuIdMonAlg algorithm execution time
executeTimeGroup = helper.addGroup(tileMuIdMonAlg,
'TileMuIdMonExecuteTime', 'Tile/')
executeTimeGroup.defineHistogram(
'TIME_execute',
path='MuId',
type='TH1F',
title='Time for execute TileMuIdMonAlg algorithm;time [#mus]',
xbins=100,
xmin=0,
xmax=1000)
from TileCalibBlobObjs.Classes import TileCalibUtils as Tile
from TileMonitoring.TileMonitoringCfgHelper import addTileEtaPhiMapsArray
# 2) Configure histograms with most energetic Tile MuId muon position
addTileEtaPhiMapsArray(helper,
tileMuIdMonAlg,
name='TileMuIdEtaPhi',
type='TH2D',
title='Tile MuId muon position',
path='Tile/MuId',
run=run,
triggers=l1Triggers,
perSample=False)
# 3) Configure histograms with most energetic Tile MuId muon position when Tags=1
addTileEtaPhiMapsArray(helper,
tileMuIdMonAlg,
name='TileMuId1TagEtaPhi',
type='TH2D',
title='Tile MuId Tags=1 muon position',
path='Tile/MuId',
run=run,
triggers=l1Triggers,
perSample=False)
# 4) Configure histograms with most energetic Tile MuId muon position when Tags=2
addTileEtaPhiMapsArray(helper,
tileMuIdMonAlg,
name='TileMuId2TagEtaPhi',
type='TH2D',
title='Tile MuId Tags=2 muon position',
path='Tile/MuId',
run=run,
triggers=l1Triggers,
perSample=False)
from TileMonitoring.TileMonitoringCfgHelper import addTile2DHistogramsArray
# 5) Configure histograms with Tile MuId muon quality vs energy
addTile2DHistogramsArray(
helper,
tileMuIdMonAlg,
name='TileMuIdEneQuality',
xvalue='energy',
yvalue='quality',
type='TH2D',
title='Tile MuId muon quality vs energy [MeV];Energy [MeV];Quality',
path='Tile/MuId',
xbins=50,
xmin=0.,
xmax=10000.,
ybins=4,
ymin=-0.5,
ymax=1.5,
run=run,
triggers=l1Triggers)
# 6) Configure histograms with Tile MuId muon quality vs energy when Tags=1
addTile2DHistogramsArray(
helper,
tileMuIdMonAlg,
name='TileMuId1TagEneQuality',
xvalue='energy',
yvalue='quality',
type='TH2D',
title=
'Tile MuId Tags=1 muon quality vs energy [MeV];Energy [MeV];Quality',
path='Tile/MuId',
xbins=50,
xmin=0.,
xmax=10000.,
ybins=4,
ymin=-0.5,
ymax=1.5,
run=run,
triggers=l1Triggers)
# 7) Configure histograms with Tile MuId muon quality vs energy when Tags=2
addTile2DHistogramsArray(
helper,
tileMuIdMonAlg,
name='TileMuId2TagEneQuality',
xvalue='energy',
yvalue='quality',
type='TH2D',
title=
'Tile MuId Tags=2 muon quality vs energy [MeV];Energy [MeV];Quality',
path='Tile/MuId',
xbins=50,
xmin=0.,
xmax=10000.,
ybins=4,
ymin=-0.5,
ymax=1.5,
run=run,
triggers=l1Triggers)
from TileMonitoring.TileMonitoringCfgHelper import addTile1DHistogramsArray
# 8) Configure histograms with Tile MuId number of tags
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuIdTags',
xvalue='nTags',
title='Tile MuId number of tags',
path='Tile/MuId',
xbins=5,
xmin=-0.5,
xmax=4.5,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 9) Configure histograms with all Tile MuId energy
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuIdEnergy',
xvalue='energy',
title='Tile MuId Energy [MeV]',
path='Tile/MuId',
xbins=100,
xmin=0.,
xmax=10000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 10) Configure histograms with all Tile MuId muon quality
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuIdQuality',
xvalue='quality',
title='Tile MuId muon quality',
path='Tile/MuId',
xbins=4,
xmin=-0.5,
xmax=1.5,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 11) Configure histograms with all Tile MuId muon eta position
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuIdEta',
xvalue='eta',
title='Tile MuId muon #eta position;#eta',
path='Tile/MuId',
xbins=40,
xmin=-2.,
xmax=2.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 12) Configure histograms with all Tile MuId muon phi position
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuIdPhi',
xvalue='phi',
title='Tile MuId muon #phi position;#phi',
path='Tile/MuId',
xbins=Tile.MAX_DRAWER,
xmin=-3.15,
xmax=3.15,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 13) Configure histograms with all Tile MuId muon average energy vs eta
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuIdEneEta',
xvalue='eta',
value='energy',
title='Tile MuId muon average energy;#eta',
path='Tile/MuId',
xbins=40,
xmin=-2.,
xmax=2.,
type='TProfile',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 14) Configure histograms with all Tile MuId muon average energy vs phi
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuIdEnePhi',
xvalue='phi',
value='energy',
title='Tile MuId muon everage energy;#phi',
path='Tile/MuId',
xbins=Tile.MAX_DRAWER,
xmin=-3.15,
xmax=3.15,
type='TProfile',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 15) Configure histograms with all Tile MuId energy when Tags=1
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuId1TagEnergy',
xvalue='energy',
title='Tile MuId Tags=1 Energy [MeV]',
path='Tile/MuId',
xbins=100,
xmin=0.,
xmax=10000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 16) Configure histograms with all Tile MuId muon quality when Tags=1
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuId1TagQuality',
xvalue='quality',
title='Tile MuId Tags=1 muon quality',
path='Tile/MuId',
xbins=4,
xmin=-0.5,
xmax=1.5,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 17) Configure histograms with all Tile MuId muon average energy vs eta when Tags=1
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuId1TagEneEta',
xvalue='eta',
value='energy',
title='Tile MuId Tags=1 muon average energy;#eta',
path='Tile/MuId',
xbins=40,
xmin=-2.,
xmax=2.,
type='TProfile',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 18) Configure histograms with all Tile MuId muon average energy vs phi when Tags=1
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuId1TagEnePhi',
xvalue='phi',
value='energy',
title='Tile MuId Tags=1 muon everage energy;#phi',
path='Tile/MuId',
xbins=Tile.MAX_DRAWER,
xmin=-3.15,
xmax=3.15,
type='TProfile',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 19) Configure histograms with all Tile MuId energy when Tags=2
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuId2TagEnergy',
xvalue='energy',
title='Tile MuId Tags=2 Energy [MeV]',
path='Tile/MuId',
xbins=100,
xmin=0.,
xmax=10000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 20) Configure histograms with all Tile MuId muon quality when Tags=2
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuId2TagQuality',
xvalue='quality',
title='Tile MuId Tags=2 muon quality',
path='Tile/MuId',
xbins=4,
xmin=-0.5,
xmax=1.5,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 21) Configure histograms with all Tile MuId muon average energy vs eta when Tags=2
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuId2TagEneEta',
xvalue='eta',
value='energy',
title='Tile MuId Tags=2 muon average energy;#eta',
path='Tile/MuId',
xbins=40,
xmin=-2.,
xmax=2.,
type='TProfile',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
# 22) Configure histograms with all Tile MuId muon average energy vs phi when Tags=2
addTile1DHistogramsArray(helper,
tileMuIdMonAlg,
name='TileMuId2TagEnePhi',
xvalue='phi',
value='energy',
title='Tile MuId Tags=2 muon everage energy;#phi',
path='Tile/MuId',
xbins=Tile.MAX_DRAWER,
xmin=-3.15,
xmax=3.15,
type='TProfile',
run=run,
triggers=l1Triggers,
perPartition=False,
perSample=False,
perGain=False,
subDirectory=False,
allPartitions=False)
accumalator = helper.result()
result.merge(accumalator)
return result
def TileMuonFitMonitoringConfig(flags, **kwargs):
''' Function to configure TileMuonFitMonitorAlgorithm algorithm in the monitoring system.'''
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
result = ComponentAccumulator()
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(flags, 'TileMuonFitMonitoring')
# Adding an TileMuonFitMonitorAlgorithm algorithm to the helper
TileMuonFitMonitorAlgorithm = CompFactory.TileMuonFitMonitorAlgorithm
tileMuonFitMonAlg = helper.addAlgorithm(TileMuonFitMonitorAlgorithm,
'TileMuonFitMonAlg')
tileMuonFitMonAlg.TriggerChain = ''
# L1Trigger Type Bits:
# bit0_RNDM, bit1_ZeroBias, bit2_L1Cal, bit3_Muon,
# bit4_RPC, bit5_FTK, bit6_CTP, bit7_Calib, AnyPhysTrig
kwargs.setdefault('fillHistogramsForL1Triggers',
['AnyPhysTrig', 'bit7_Calib'])
l1Triggers = kwargs['fillHistogramsForL1Triggers']
for k, v in kwargs.items():
setattr(tileMuonFitMonAlg, k, v)
run = str(flags.Input.RunNumber[0])
# 1) Configure histogram with TileMuonFitMonAlg algorithm execution time
executeTimeGroup = helper.addGroup(tileMuonFitMonAlg,
'TileMuonFitMonExecuteTime', 'Tile/')
executeTimeGroup.defineHistogram(
'TIME_execute',
path='MuonFit',
type='TH1F',
title='Time for execute TileMuonFitMonAlg algorithm;time [#mus]',
xbins=100,
xmin=0,
xmax=10000)
from TileCalibBlobObjs.Classes import TileCalibUtils as Tile
from TileMonitoring.TileMonitoringCfgHelper import addTile2DHistogramsArray
# 2) Configure histograms with Tile MuonFit position at y=0
addTile2DHistogramsArray(
helper,
tileMuonFitMonAlg,
name='TileMuonFitPosition',
xvalue='zPosition',
yvalue='xPosition',
title='Tile MuonFit position at y=0;z [mm];x [mm]',
path='Tile/MuonFit',
xbins=69,
xmin=-6900,
xmax=6900.,
ybins=44,
ymin=-4400.,
ymax=4400.,
type='TH2D',
run=run,
triggers=l1Triggers)
# 3) Configure histograms with Tile MuonFit sinus of the angle in the y-z plane vs position
addTile2DHistogramsArray(
helper,
tileMuonFitMonAlg,
name='TileMuonFitPosDirectionTheta',
xvalue='zPosition',
yvalue='theta',
path='Tile/MuonFit',
title='Tile MuonFit vertical axis component;z [mm];sin(#theta)',
xbins=49,
xmin=-4900,
xmax=4900.,
ybins=50,
ymin=-0.,
ymax=1.,
type='TH2D',
run=run,
triggers=l1Triggers)
from TileMonitoring.TileMonitoringCfgHelper import addTile1DHistogramsArray
# 4) Configure histograms with number of Tile MuonFits reconstructed
addTile1DHistogramsArray(helper,
tileMuonFitMonAlg,
name='TileMuonFitNum',
xvalue='nMuons',
title='Number of Tile MuonFit reconstructed',
path='Tile/MuonFit',
xbins=10,
xmin=-0.5,
xmax=9.5,
type='TH1F',
run=run,
triggers=l1Triggers,
perPartition=False)
# 5) Configure histograms with number of Tile cells per MuonFit track
addTile1DHistogramsArray(helper,
tileMuonFitMonAlg,
name='TileMuonFitNCells',
xvalue='nCells',
title='Number of Tile cells per MuonFit track',
path='Tile/MuonFit',
xbins=10,
xmin=-0.5,
xmax=9.5,
type='TH1F',
run=run,
triggers=l1Triggers,
perPartition=False)
# 6) Configure histograms with Tile MuonFit total energy
addTile1DHistogramsArray(
helper,
tileMuonFitMonAlg,
name='TileMuonFitEnergy',
xvalue='energy',
title='Tile MuonFit total energy;Muon energy [MeV]',
path='Tile/MuonFit',
xbins=50,
xmin=0.,
xmax=10000.,
type='TH1F',
run=run,
triggers=l1Triggers,
perPartition=False)
# 7) Configure histograms with Tile MuonFit time at y=0 plane
addTile1DHistogramsArray(
helper,
tileMuonFitMonAlg,
name='TileMuonFitTime',
xvalue='time',
title='Tile MuonFit time at y=0 plane;Muon time [ns]',
path='Tile/MuonFit',
xbins=49,
xmin=-73.5,
xmax=73.5,
type='TH1F',
run=run,
triggers=l1Triggers,
perPartition=False)
# 8) Configure histograms with Tile MuonFit path
addTile1DHistogramsArray(
helper,
tileMuonFitMonAlg,
name='TileMuonFitPath',
xvalue='path',
title='Tile MuonFit total path length;Muon path length [mm]',
path='Tile/MuonFit',
xbins=50,
xmin=0.,
xmax=10000.,
type='TH1F',
run=run,
triggers=l1Triggers,
perPartition=False)
# 9) Configure histograms with Tile MuonFit energy density
addTile1DHistogramsArray(
helper,
tileMuonFitMonAlg,
name='TileMuonFitEneDensity',
xvalue='eneDensity',
title='Tile MuonFit energy density;Muon energy loss [MeV/mm]',
path='Tile/MuonFit',
xbins=50,
xmin=0.,
xmax=10.,
type='TH1F',
run=run,
triggers=l1Triggers,
perPartition=False)
# 10) Configure histograms with Tile MuonFit sinus of the angle in the x-y plane
addTile1DHistogramsArray(
helper,
tileMuonFitMonAlg,
name='TileMuonFitDirectionPhi',
xvalue='phi',
title='Tile MuonFit sinus of the angle in the x-y plane;sin(#phi)',
path='Tile/MuonFit',
xbins=100,
xmin=-1.,
xmax=1.,
type='TH1F',
run=run,
triggers=l1Triggers,
perPartition=False)
# 11) Configure histograms with Tile MuonFit sinus of the angle in the y-z plane
addTile1DHistogramsArray(
helper,
tileMuonFitMonAlg,
name='TileMuonFitDirectionTheta',
xvalue='theta',
title='Tile MuonFit sinus of the angle in the y-z plane;sin(#theta)',
path='Tile/MuonFit',
xbins=50,
xmin=0.,
xmax=1.,
type='TH1F',
run=run,
triggers=l1Triggers,
perPartition=False)
# 12) Configure histograms with Tile MuonFit sinus of the angle in the y-z plane
addTile1DHistogramsArray(
helper,
tileMuonFitMonAlg,
name='TileMuonFitPositionTime',
xvalue='zPosition',
value='time',
title=
'Tile MuonFit average time vs z position at y=0 plane;z [mm]; t [ns]',
path='Tile/MuonFit',
xbins=79,
xmin=-7900.,
xmax=7900.,
type='TProfile',
run=run,
triggers=l1Triggers,
perPartition=False)
from TileMonitoring.TileMonitoringCfgHelper import getPartitionName
# 13) Configure histograms with Tile MuonFit partition time
partitionLabels = [getPartitionName(ros) for ros in range(1, Tile.MAX_ROS)]
addTile1DHistogramsArray(
helper,
tileMuonFitMonAlg,
name='TileMuonFitPartitionTime',
xvalue='partition',
value='time',
title='Tile MuonFit average time vs partition at y=0 plane;; t [ns]',
path='Tile/MuonFit',
xbins=Tile.MAX_ROS - 1,
xmin=-0.5,
xmax=Tile.MAX_ROS - 1.5,
xlabels=partitionLabels,
type='TProfile',
run=run,
triggers=l1Triggers,
perPartition=False)
accumalator = helper.result()
result.merge(accumalator)
return result
def CpmMonitoringConfig(inputFlags):
'''Function to configure LVL1 Cpm algorithm in the monitoring system.'''
import math
# get the component factory - used for getting the algorithms
from AthenaConfiguration.ComponentFactory import CompFactory
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
# make the athena monitoring helper
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags,'CpmMonitoringCfg')
# get any algorithms
CpmMonAlg = helper.addAlgorithm(CompFactory.CpmMonitorAlgorithm,'CpmMonAlg')
# add any steering
groupName = 'CpmMonitor' # the monitoring group name is also used for the package name
CpmMonAlg.PackageName = groupName
crates = 4
CpmMonAlg.s_crates = crates
maxSlices = 5
CpmMonAlg.s_maxSlices = maxSlices
isolBits = 4
CpmMonAlg.s_isolBits = isolBits
tobsPerCPM = 5
CpmMonAlg.s_tobsPerCPM = tobsPerCPM
maxTobsPerCmx = 70
CpmMonAlg.MaxTOBsPerCMX = maxTobsPerCmx
# set up the directory structure
mainDir = 'L1Calo'
trigPath = 'CPM' # replaces m_rootDir
errorDir=trigPath+"/Errors/Hardware"
monDetailPath=errorDir+"/Detail/"
monCPMinputPath=trigPath+"/Input/"
monRoIPath=trigPath+"/Output/"
#monCMXPath=trigPath+"_CMX/Errors/Hardware/"
monCMXinPath=trigPath+"_CMX/Input/"
#monCMXoutPath=trigPath+"_CMX/Output/"
# add monitoring algorithm to group, with group name and main directory
myGroup = helper.addGroup(CpmMonAlg, groupName , mainDir)
#
# CPM Towers - monCPMinputPath
#
# Trigger Tower plots - for binning see TrigT1CaloLWHistogramTool::bookPPMEmEtaVsPhi
etabins_2d=66
etamin_2d=-3.3
etamax_2d=3.3
phibins_2d=64
phimin_2d=0.0
phimax_2d=64.0
# for 2D histograms x,y;histogram alias
myGroup.defineHistogram('etaTT,phiTT;ppm_em_2d_etaPhi_tt_Hitmap',title='PPM Trigger Tower EM eta/phi;Tower #eta; Tower #phi',type='TH2F',
cutmask='mask_em_TT',path=monCPMinputPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
myGroup.defineHistogram('etaTT,phiTT;ppm_had_2d_etaPhi_tt_Hitmap',title='PPM Trigger Tower HAD eta/phi;Tower #eta; Tower #phi',type='TH2F',
cutmask='mask_had_TT',path=monCPMinputPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
# CPMTower plots
maxEnergyRange = 256 # Maximum energy plotted
# EM 1d
myGroup.defineHistogram('etCpmTT_em;cpm_em_1d_tt_Et', title='CPM Tower EM Et;CPM Tower EM Energy;',
cutmask='',path=monCPMinputPath,xbins=maxEnergyRange,xmin=0,xmax=maxEnergyRange)
myGroup.defineHistogram('etaCpmTT_em;cpm_em_1d_tt_Eta', title='CPM Tower EM eta;CPM Tower EM #eta;',
cutmask='',path=monCPMinputPath,xbins=50,xmin=-2.5,xmax=2.5)
myGroup.defineHistogram('phiCpmTT_em;cpm_em_1d_tt_Phi', title='CPM Tower EM phi;CPM Tower EM #phi;',
cutmask='',path=monCPMinputPath,xbins=64,xmin=0,xmax=2*math.pi)
# EM 2d
myGroup.defineHistogram('etaCpmTT_em,phiScaledCpmTT_em;cpm_em_2d_etaPhi_tt_Hitmap',
title='CPM Tower EM eta/phi;Tower #eta; Tower #phi',type='TH2F',
cutmask='',path=monCPMinputPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
myGroup.defineHistogram('etaCpmTT_em,phiScaledCpmTT_em;cpm_em_2d_etaPhi_tt_EtWeighted',
title='CPM Tower EM eta/phi weighted;Tower #eta; Tower #phi',type='TH2F',
cutmask='',path=monCPMinputPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d, weight="etCpmTT_em")
# HAD 1d
myGroup.defineHistogram('etCpmTT_had;cpm_had_1d_tt_Et', title='CPM Tower HAD Et;CPM Tower HAD Energy;',
cutmask='',path=monCPMinputPath,xbins=maxEnergyRange,xmin=0,xmax=maxEnergyRange)
myGroup.defineHistogram('etaCpmTT_had;cpm_had_1d_tt_Eta', title='CPM Tower HAD eta;CPM Tower HAD #eta;',
cutmask='',path=monCPMinputPath,xbins=50,xmin=-2.5,xmax=2.5)
myGroup.defineHistogram('phiCpmTT_had;cpm_had_1d_tt_Phi', title='CPM Tower HAD phi;CPM Tower HAD #phi;',
cutmask='',path=monCPMinputPath,xbins=64,xmin=0,xmax=2*math.pi)
# HAD 2d
myGroup.defineHistogram('etaCpmTT_had,phiScaledCpmTT_had;cpm_had_2d_etaPhi_tt_Hitmap',
title='CPM Tower HAD eta/phi;Tower #eta; Tower #phi',type='TH2F',
cutmask='',path=monCPMinputPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
myGroup.defineHistogram('etaCpmTT_had,phiScaledCpmTT_had;cpm_had_2d_etaPhi_tt_EtWeighted'
,title='CPM Tower HAD eta/phi weighted;Tower #eta; Tower #phi',type='TH2F',
cutmask='',path=monCPMinputPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d, weight="etCpmTT_had")
xbinshist = int(crates * maxSlices)
myGroup.defineHistogram('sliceCpmTT_tot,peakCpmTT_tot;cpm_2d_tt_Slices'
,title='CPM Slices and Triggered Slice;Crate/Number of Slices;Triggered Slice',type='TH2F',
cutmask='',path=monCPMinputPath,
xbins=xbinshist,xmin=0,xmax=xbinshist,ybins=maxSlices,ymin=0,ymax=maxSlices)
#
# Errors - monDetailPath
#
# em - tot means addition of CPM and Overlap containers
myGroup.defineHistogram('etaCpmTT_em_tot,phiScaledCpmTT_em_tot;cpm_em_2d_etaPhi_tt_Parity'
,title='CPM Tower EM Parity Errors;Tower #eta; Tower #phi',type='TH2F',
cutmask='parityErrorCpmTT_em',path=monDetailPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
myGroup.defineHistogram('etaCpmTT_em_tot,phiScaledCpmTT_em_tot;cpm_em_2d_etaPhi_tt_LinkDown',
title='CPM Tower EM Link Down Errors;Tower #eta; Tower #phi',type='TH2F',
cutmask='linkDownErrorCpmTT_em',path=monDetailPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
# had
myGroup.defineHistogram('etaCpmTT_had_tot,phiScaledCpmTT_had_tot;cpm_had_2d_etaPhi_tt_Parity',
title='CPM Tower HAD Parity Errors;Tower #eta; Tower #phi',type='TH2F',
cutmask='parityErrorCpmTT_had',path=monDetailPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
myGroup.defineHistogram('etaCpmTT_had_tot,phiScaledCpmTT_had_tot;cpm_had_2d_etaPhi_tt_LinkDown',
title='CPM Tower HAD Link Down Errors;Tower #eta; Tower #phi',type='TH2F',
cutmask='linkDownErrorCpmTT_had',path=monDetailPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
#
# CPM TOB RoIs - monRoIPath
#
isolRange=32 # Maximum range for encoded isolation
myGroup.defineHistogram('energyTobRoIsEner;cpm_1d_roi_EnergyEm', title='CPM TOB RoI Cluster Energy EM;Cluster Energy;',
cutmask='mask_tobroi_ener_em',path=monRoIPath,
xbins=maxEnergyRange,xmin=0,xmax=maxEnergyRange)
myGroup.defineHistogram('energyTobRoIsEner;cpm_1d_roi_EnergyTau', title='CPM TOB RoI Cluster Energy Tau;Cluster Energy;',
cutmask='mask_tobroi_ener_tau',path=monRoIPath,
xbins=maxEnergyRange,xmin=0,xmax=maxEnergyRange)
myGroup.defineHistogram('energyTobRoIsIsol;cpm_1d_roi_IsolationEm', title='CPM TOB RoI Encoded Isolation Value EM;;',
cutmask='mask_tobroi_isol_em',path=monRoIPath,
xbins=isolRange,xmin=0,xmax=isolRange)
myGroup.defineHistogram('energyTobRoIsIsol;cpm_1d_roi_IsolationTau', title='CPM TOB RoI Encoded Isolation Value Tau;;',
cutmask='mask_tobroi_isol_tau',path=monRoIPath,
xbins=isolRange,xmin=0,xmax=isolRange)
# bit masks to be done
#myGroup.defineHistogram('bitsTobRoIsIsol;cpm_1d_roi_IsolationBitsEm', title='CPM TOB RoI Encoded Isolation Bits EM;;',
# cutmask='mask_tobroi_isol_em',path=monRoIPath,
# xbins=isolBits,xmin=0,xmax=isolBits)
# 2D
# For binning see TrigT1CaloLWHistogramTool::bookCPMRoIEtaVsPhi,fillCPMRoIEtaVsPhi m_shrinkEtaBins=true
# isolation
myGroup.defineHistogram('etaTobRoIsIsol,phiTobRoIsIsol;cpm_2d_etaPhi_roi_HitmapIsolEm',
title='CPM TOB RoIs EM Non-zero Isolation Hit Map;Tower #eta; Tower #phi',type='TH2F',
cutmask='mask_tobroi_isol_em',path=monRoIPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
myGroup.defineHistogram('etaTobRoIsIsol,phiTobRoIsIsol;cpm_2d_etaPhi_roi_HitmapIsolTau',
title='CPM TOB RoIs Tau Non-zero Isolation Hit Map;Tower #eta; Tower #phi',type='TH2F',
cutmask='mask_tobroi_isol_tau',path=monRoIPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
# energy
myGroup.defineHistogram('etaTobRoIsEner,phiTobRoIsEner;cpm_2d_etaPhi_roi_HitmapEm',
title='CPM TOB RoIs EM Hit Map;Tower #eta; Tower #phi',type='TH2F',
cutmask='mask_tobroi_ener_em',path=monRoIPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
myGroup.defineHistogram('etaTobRoIsEner,phiTobRoIsEner;cpm_2d_etaPhi_roi_EtWeightedEm',
title='CPM TOB RoIs EM Weighted by Energy;Tower #eta; Tower #phi',type='TH2F',
cutmask='mask_tobroi_ener_em',path=monRoIPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d, weight="energyTobRoIsEner")
myGroup.defineHistogram('etaTobRoIsEner,phiTobRoIsEner;cpm_2d_etaPhi_roi_HitmapTau',
title='CPM TOB RoIs Tau Hit Map;Tower #eta; Tower #phi',type='TH2F',
cutmask='mask_tobroi_ener_tau',path=monRoIPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d)
myGroup.defineHistogram('etaTobRoIsEner,phiTobRoIsEner;cpm_2d_etaPhi_roi_EtWeightedTau',
title='CPM TOB RoIs Tau Weighted by Energy;Tower #eta; Tower #phi',type='TH2F',
cutmask='mask_tobroi_ener_tau',path=monRoIPath,
xbins=etabins_2d,xmin=etamin_2d,xmax=etamax_2d,ybins=phibins_2d,ymin=phimin_2d,ymax=phimax_2d, weight="energyTobRoIsEner")
# TOBs per CPM
myGroup.defineHistogram('tobPerCPMEm;cpm_1d_roi_TOBsPerCPMEm', title='CPM TOB RoI TOBs per CPM EM;Number of TOBs;',
cutmask='',path=monRoIPath,
xbins=tobsPerCPM+1,xmin=1,xmax=tobsPerCPM+2)
myGroup.defineHistogram('tobPerCPMTau;cpm_1d_roi_TOBsPerCPMTau', title='CPM TOB RoI TOBs per CPM Tau;Number of TOBs;',
cutmask='',path=monRoIPath,
xbins=tobsPerCPM+1,xmin=1,xmax=tobsPerCPM+2)
# How to set labels e.g.
# m_h_cpm_1d_roi_TOBsPerCPMEm->GetXaxis()->SetBinLabel(s_tobsPerCPM + 1, "More");
#
# CMX-CP TOBs - monCMXinPath
#
myGroup.defineHistogram('enerTobCmxEner;cmx_1d_tob_TOBsPerCMXLeft', title='CMX-CP TOBs per CMX Left;Number of TOBs;',
cutmask='',path=monCMXinPath,
xbins=maxTobsPerCmx,xmin=0,xmax=maxTobsPerCmx)
acc = helper.result()
result.merge(acc)
return result
def METMonitoringConfig(inputFlags):
# '''Function to configures some algorithms in the monitoring system.'''
# from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
# result = ComponentAccumulator()
from AthenaMonitoring import AthMonitorCfgHelper
# helper = AthMonitorCfgHelper(inputFlags,'AthMonitorCfg')
helper = AthMonitorCfgHelper(inputFlags, 'METMonitor')
from AthenaConfiguration.ComponentFactory import CompFactory
METRefFinal_MonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'METRefFinal_MonAlg')
# anotherExampleMonAlg = helper.addAlgorithm(METMonitoringExampleAlg,'AnotherExampleMonAlg')
met_types = [
"MET_RefFinal", "MET_RefJet", "MET_Muon", "MET_RefEle", "MET_RefGamma",
"MET_RefTau", "MET_PVSoftTrk"
]
METRefFinal_MonAlg.METContainer = "MET_Reference_AntiKt4EMTopo"
METRefFinal_MonAlg.metKeys = met_types
METRefFinal_MonAlg.alltrigger = True
group = helper.addGroup(METRefFinal_MonAlg, "METMonitor",
"MissingEt/AllTriggers/MET_AntiKt4EMTopo/")
for mets in met_types:
defineHistograms(METRefFinal_MonAlg, group, helper, mets)
if inputFlags.DQ.DataType != 'cosmics':
METPflow_MonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'METPflow_MonAlg')
pfmet_types = [
"MET_PFlow", "MET_PFlow_RefJet", "MET_PFlow_Muon",
"MET_PFlow_RefEle", "MET_PFlow_RefGamma", "MET_PFlow_RefTau",
"MET_PFlow_PVSoftTrk"
]
METPflow_MonAlg.METContainer = "MET_Reference_AntiKt4EMPFlow"
METPflow_MonAlg.metKeys = pfmet_types
METPflow_MonAlg.alltrigger = True
group = helper.addGroup(METPflow_MonAlg, "METMonitor",
"MissingEt/AllTriggers/MET_AntiKt4EMPFlow/")
for mets in pfmet_types:
defineHistograms(METPflow_MonAlg, group, helper, mets)
METEMTopo_MonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'METEMTopo_MonAlg')
emtopomet_types = ["MET_Topo"]
METEMTopo_MonAlg.METContainer = "MET_EMTopo"
METEMTopo_MonAlg.metKeys = emtopomet_types
METEMTopo_MonAlg.alltrigger = True
group = helper.addGroup(METEMTopo_MonAlg, "METMonitor",
"MissingEt/AllTriggers/MET_Calo/EMTopo")
for mets in emtopomet_types:
defineHistograms(METEMTopo_MonAlg, group, helper, mets)
METCalo_MonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'METCalo_MonAlg')
metcalo_types = ["PEMB", "EMB", "PEME", "EME", "TILE", "HEC", "FCAL"]
METCalo_MonAlg.METContainer = "MET_Calo"
METCalo_MonAlg.METCaloKeys = metcalo_types
METCalo_MonAlg.alltrigger = True
group = helper.addGroup(METCalo_MonAlg, "METMonitor",
"MissingEt/AllTriggers/MET_Calo/MET_Cell")
for mets in metcalo_types:
defineHistogramsCalo(METCalo_MonAlg, group, helper, mets)
#trigger
METRefFinal_XE30_MonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'METRefFinal_XE30_MonAlg')
METRefFinal_XE30_MonAlg.METContainer = "MET_Reference_AntiKt4EMTopo"
METRefFinal_XE30_MonAlg.metTotalKey = "FinalTrk"
METRefFinal_XE30_MonAlg.metKeys = met_types
METRefFinal_XE30_MonAlg.dotrigger = True
group = helper.addGroup(METRefFinal_XE30_MonAlg, "METMonitor",
"MissingEt/TrigXE30/MET_AntiKt4EMTopo/")
for mets in met_types:
defineHistograms(METRefFinal_XE30_MonAlg, group, helper, mets)
if inputFlags.DQ.DataType != 'cosmics':
METPflow_XE30_MonAlg = helper.addAlgorithm(
CompFactory.METMonitoringAlg, 'METPflow_XE30_MonAlg')
METPflow_XE30_MonAlg.METContainer = "MET_Reference_AntiKt4EMPFlow"
METPflow_XE30_MonAlg.metTotalKey = "FinalTrk"
METPflow_XE30_MonAlg.metKeys = pfmet_types
METPflow_XE30_MonAlg.dotrigger = True
group = helper.addGroup(METPflow_XE30_MonAlg, "METMonitor",
"MissingEt/TrigXE30/MET_AntiKt4EMPflow/")
for mets in pfmet_types:
defineHistograms(METPflow_XE30_MonAlg, group, helper, mets)
METCalo_XE30_MonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'METCalo_XE30_MonAlg')
METCalo_XE30_MonAlg.METCaloContainer = "MET_Calo"
METCalo_XE30_MonAlg.METCaloKeys = metcalo_types
METCalo_XE30_MonAlg.dotrigger = True
group = helper.addGroup(METCalo_XE30_MonAlg, "METMonitor",
"MissingEt/TrigXE30/MET_Calo/MET_Cell")
for mets in metcalo_types:
defineHistogramsCalo(METCalo_XE30_MonAlg, group, helper, mets)
METEMTopo_XE30_MonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'METEMTopo_XE30_MonAlg')
METEMTopo_XE30_MonAlg.METContainer = "MET_EMTopo"
METEMTopo_XE30_MonAlg.METAntiKt4EMTopoContainer = "MET_Reference_AntiKt4EMTopo"
emtopomet_types = ["MET_Topo"]
METEMTopo_XE30_MonAlg.metKeys = emtopomet_types
METEMTopo_XE30_MonAlg.dotrigger = True
METEMTopo_XE30_group = helper.addGroup(
METEMTopo_XE30_MonAlg, "METMonitor",
"MissingEt/TrigXE30/MET_Calo/EMTopo")
for mets in emtopomet_types:
defineHistograms(METEMTopo_XE30_MonAlg, METEMTopo_XE30_group, helper,
mets)
# metcut
METRefFinal_METCut_MonAlg = helper.addAlgorithm(
CompFactory.METMonitoringAlg, 'METRefFinal_METCut_MonAlg')
METRefFinal_METCut_MonAlg.METContainer = "MET_Reference_AntiKt4EMTopo"
METRefFinal_METCut_MonAlg.metTotalKey = "FinalTrk"
METRefFinal_METCut_MonAlg.metKeys = met_types
METRefFinal_METCut_MonAlg.dometcut = True
METRefFinal_METCut_MonAlg.metcut = 80
group = helper.addGroup(METRefFinal_METCut_MonAlg, "METMonitor",
"MissingEt/CutMet80/MET_AntiKt4EMTopo/")
for mets in met_types:
defineHistograms(METRefFinal_METCut_MonAlg, group, helper, mets)
if inputFlags.DQ.DataType != 'cosmics':
METPflow_METCut_MonAlg = helper.addAlgorithm(
CompFactory.METMonitoringAlg, 'METPflow_METCut_MonAlg')
METPflow_METCut_MonAlg.METContainer = "MET_Reference_AntiKt4EMPFlow"
METPflow_METCut_MonAlg.metKeys = pfmet_types
METPflow_METCut_MonAlg.dometcut = True
METPflow_METCut_MonAlg.metcut = 80
group = helper.addGroup(METPflow_METCut_MonAlg, "METMonitor",
"MissingEt/CutMet80/MET_AntiKt4EMPflow/")
for mets in pfmet_types:
defineHistograms(METPflow_METCut_MonAlg, group, helper, mets)
METCalo_METCut_MonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'METCalo_METCut_MonAlg')
metcalo_types = ["PEMB", "EMB", "PEME", "EME", "TILE", "HEC", "FCAL"]
METCalo_METCut_MonAlg.METCaloContainer = "MET_Calo"
METCalo_METCut_MonAlg.METCaloKeys = metcalo_types
METCalo_METCut_MonAlg.dometcut = True
METCalo_METCut_MonAlg.metcut = 80
METCalo_METCut_group = helper.addGroup(
METCalo_METCut_MonAlg, "METMonitor",
"MissingEt/CutMet80/MET_Calo/MET_Cell")
for mets in metcalo_types:
defineHistogramsCalo(METCalo_METCut_MonAlg, METCalo_METCut_group,
helper, mets)
METEMTopo_METCut_MonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'METEMTopo_METCut_MonAlg')
METEMTopo_METCut_MonAlg.METContainer = "MET_EMTopo"
METEMTopo_METCut_MonAlg.METAntiKt4EMTopoContainer = "MET_Reference_AntiKt4EMTopo"
emtopomet_types = ["MET_Topo"]
METEMTopo_METCut_MonAlg.metKeys = emtopomet_types
METEMTopo_METCut_MonAlg.dometcut = True
METEMTopo_METCut_MonAlg.metcut = 80
METEMTopo_METCut_group = helper.addGroup(
METEMTopo_METCut_MonAlg, "METMonitor",
"MissingEt/CutMet80/MET_Calo/EMTopo")
for mets in emtopomet_types:
defineHistograms(METEMTopo_METCut_MonAlg, METEMTopo_METCut_group,
helper, mets)
# Jet cleaning
jetCleaningTool = CompFactory.JetCleaningTool()
jetCleaningTool.CutLevel = "LooseBad"
# jetCleaningTool.CutLevel = "TightBad"
jetCleaningTool.DoUgly = False
JetCleaning_METMonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'JetCleaning_METMonAlg')
JetCleaning_METMonAlg.metKeys = met_types
JetCleaning_METMonAlg.DoJetCleaning = True
JetCleaning_METMonAlg.JetCleaningTool = jetCleaningTool
JetCleaningGroup = helper.addGroup(
JetCleaning_METMonAlg, "METMonitor",
"MissingEt/Jetcleaning/MET_AntiKt4EMTopo/")
JetCleaning_METMonAlg.JetContainerName = "AntiKt4EMTopoJets"
for mets in met_types:
if mets == 'MET_PFlow_PVSoftTrk':
JetCleaning_METMonAlg.JetContainerName = "AntiKt4EMPFlowJets"
defineHistograms(JetCleaning_METMonAlg, JetCleaningGroup, helper, mets)
if inputFlags.DQ.DataType != 'cosmics':
PflowJetCleaning_METMonAlg = helper.addAlgorithm(
CompFactory.METMonitoringAlg, 'PflowJetCleaning_METMonAlg')
PflowJetCleaning_METMonAlg.METContainer = "MET_Reference_AntiKt4EMPFlow"
PflowJetCleaning_METMonAlg.metKeys = pfmet_types
PflowJetCleaning_METMonAlg.DoJetCleaning = True
PflowJetCleaning_METMonAlg.JetCleaningTool = jetCleaningTool
PflowJetCleaningGroup = helper.addGroup(
PflowJetCleaning_METMonAlg, "METMonitor",
"MissingEt/Jetcleaning/MET_AntiKt4EMPflow/")
PflowJetCleaning_METMonAlg.JetContainerName = "AntiKt4EMPFlowJets"
for mets in pfmet_types:
defineHistograms(PflowJetCleaning_METMonAlg, PflowJetCleaningGroup,
helper, mets)
METCaloJetCleaning_MonAlg = helper.addAlgorithm(
CompFactory.METMonitoringAlg, 'METCaloJetCleaning_MonAlg')
metcalo_types = ["PEMB", "EMB", "PEME", "EME", "TILE", "HEC", "FCAL"]
METCaloJetCleaning_MonAlg.METCaloContainer = "MET_Calo"
METCaloJetCleaning_MonAlg.METCaloKeys = metcalo_types
METCaloJetCleaning_MonAlg.DoJetCleaning = True
METCaloJetCleaning_MonAlg.JetCleaningTool = jetCleaningTool
group = helper.addGroup(METCaloJetCleaning_MonAlg, "METMonitor",
"MissingEt/Jetcleaning/MET_Calo/MET_Cell")
for mets in metcalo_types:
defineHistogramsCalo(METCaloJetCleaning_MonAlg, group, helper, mets)
METEMTopoJetCleaning_MonAlg = helper.addAlgorithm(
CompFactory.METMonitoringAlg, 'METEMTopoJetCleaning_MonAlg')
emtopomet_types = ["MET_Topo"]
METEMTopoJetCleaning_MonAlg.METContainer = "MET_EMTopo"
METEMTopoJetCleaning_MonAlg.metKeys = emtopomet_types
METEMTopoJetCleaning_MonAlg.DoJetCleaning = True
METEMTopoJetCleaning_MonAlg.JetCleaningTool = jetCleaningTool
group = helper.addGroup(METEMTopoJetCleaning_MonAlg, "METMonitor",
"MissingEt/Jetcleaning/MET_Calo/EMTopo/")
for mets in emtopomet_types:
defineHistograms(METEMTopoJetCleaning_MonAlg, group, helper, mets)
# Badjets
jetCleaningTool.CutLevel = "LooseBad"
# jetCleaningTool.CutLevel = "TightBad"
jetCleaningTool.DoUgly = False
BadJets_METMonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'BadJets_METMonAlg')
BadJets_METMonAlg.metKeys = met_types
BadJets_METMonAlg.DoJetCleaning = True
BadJets_METMonAlg.alltrigger = True
BadJets_METMonAlg.DoBadJets = True
BadJets_METMonAlg.JetCleaningTool = jetCleaningTool
BadJets_METMonAlg.JetContainerName = "AntiKt4EMTopoJets"
BadJetsGroup = helper.addGroup(
BadJets_METMonAlg, "METMonitor",
"MissingEt/AllTriggers/BadJets/MET_AntiKt4EMTopo")
for mets in met_types:
defineHistograms(BadJets_METMonAlg, BadJetsGroup, helper, mets)
if inputFlags.DQ.DataType != 'cosmics':
BadPFJets_METMonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'BadPFJets_METMonAlg')
BadPFJets_METMonAlg.METContainer = "MET_Reference_AntiKt4EMPFlow"
BadPFJets_METMonAlg.metKeys = pfmet_types
BadPFJets_METMonAlg.DoJetCleaning = True
BadPFJets_METMonAlg.alltrigger = True
BadPFJets_METMonAlg.DoBadJets = True
BadPFJets_METMonAlg.JetCleaningTool = jetCleaningTool
BadPFJets_METMonAlg.JetContainerName = "AntiKt4EMPFlowJets"
BadPFJetsGroup = helper.addGroup(
BadPFJets_METMonAlg, "METMonitor",
"MissingEt/AllTriggers/BadJets/MET_AntiKt4EMPflow/")
for mets in pfmet_types:
defineHistograms(BadPFJets_METMonAlg, BadPFJetsGroup, helper, mets)
BadJets_CaloMETMonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'BadJets_CaloMETMonAlg')
metcalo_types = ["PEMB", "EMB", "PEME", "EME", "TILE", "HEC", "FCAL"]
BadJets_CaloMETMonAlg.METCaloContainer = "MET_Calo"
BadJets_CaloMETMonAlg.METCaloKeys = metcalo_types
BadJets_CaloMETMonAlg.DoJetCleaning = True
BadJets_CaloMETMonAlg.alltrigger = True
BadJets_CaloMETMonAlg.DoBadJets = True
BadJets_CaloMETMonAlg.JetContainerName = "AntiKt4EMTopoJets"
BadJets_CaloMETMonAlg.JetCleaningTool = jetCleaningTool
BadJetsGroup_CaloMETMonAlg = helper.addGroup(
BadJets_CaloMETMonAlg, "METMonitor",
"MissingEt/AllTriggers/BadJets/MET_Calo/MET_Cell")
for mets in metcalo_types:
defineHistogramsCalo(BadJets_CaloMETMonAlg, BadJetsGroup_CaloMETMonAlg,
helper, mets)
BadJets_EMTopoMETMonAlg = helper.addAlgorithm(CompFactory.METMonitoringAlg,
'BadJets_EMTopoMETMonAlg')
BadJets_EMTopoMETMonAlg.metKeys = emtopomet_types
BadJets_EMTopoMETMonAlg.METContainer = "MET_EMTopo"
BadJets_EMTopoMETMonAlg.DoJetCleaning = True
BadJets_EMTopoMETMonAlg.alltrigger = True
BadJets_EMTopoMETMonAlg.DoBadJets = True
BadJets_EMTopoMETMonAlg.JetCleaningTool = jetCleaningTool
BadJetsGroup = helper.addGroup(
BadJets_EMTopoMETMonAlg, "METMonitor",
"MissingEt/AllTriggers/BadJets/MET_Calo/EMTopo")
for mets in emtopomet_types:
defineHistograms(BadJets_EMTopoMETMonAlg, BadJetsGroup, helper, mets)
return helper.result()
def tauMonitoringConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
### STEP 1 ###
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
cfgHelper = AthMonitorCfgHelper(inputFlags, monName='tauMonitorAlgFamily')
### STEP 2 ###
# Adding an algorithm to the helper. Here, we will use the example
# algorithm in the AthenaMonitoring package. Just pass the type to the
# helper. Then, the helper will instantiate an instance and set up the
# base class configuration following the inputFlags. The returned object
# is the algorithm.
from AthenaConfiguration.ComponentFactory import CompFactory
tauMonitorAlgorithm = CompFactory.tauMonitorAlgorithm
tauMonAlgBA = cfgHelper.addAlgorithm(tauMonitorAlgorithm,
name='tauMonAlgBA')
tauMonAlgCR = cfgHelper.addAlgorithm(tauMonitorAlgorithm,
name='tauMonAlgCR')
tauMonAlgEC = cfgHelper.addAlgorithm(tauMonitorAlgorithm,
name='tauMonAlgEC')
tauMonAlgGlobal = cfgHelper.addAlgorithm(tauMonitorAlgorithm,
name='tauMonAlgGlobal')
tauMonAlgTauTrig = cfgHelper.addAlgorithm(tauMonitorAlgorithm,
name='tauMonAlgTauTrig')
tauMonAlgEleTrig = cfgHelper.addAlgorithm(tauMonitorAlgorithm,
name='tauMonAlgEleTrig')
tauMonAlgJetTrig = cfgHelper.addAlgorithm(tauMonitorAlgorithm,
name='tauMonAlgJetTrig')
tauMonAlgHighPt = cfgHelper.addAlgorithm(tauMonitorAlgorithm,
name='tauMonAlgHighPt')
tauMonAlgHighPtBDTLoose = cfgHelper.addAlgorithm(
tauMonitorAlgorithm, name='tauMonAlgHighPtBDTLoose')
### STEP 3 ###
# Edit properties of a algorithm
# some generic property
# exampleMonAlg.RandomHist = True
# to enable a trigger filter, for example:
#exampleMonAlg.TriggerChain = 'HLT_mu26_ivarmedium'
tauMonAlgBA.etaMin = -1.
tauMonAlgBA.etaMax = 1.3
tauMonAlgCR.etaMin = 1.3
tauMonAlgCR.etaMax = 1.7
tauMonAlgEC.etaMin = 1.7
tauMonAlgEC.etaMax = 3.5
tauMonAlgGlobal.etaMin = -100
tauMonAlgGlobal.etaMax = 100
tauMonAlgTauTrig.etaMin = -100
tauMonAlgTauTrig.etaMax = 100
tauMonAlgEleTrig.etaMin = -100
tauMonAlgEleTrig.etaMax = 100
tauMonAlgJetTrig.etaMin = -100
tauMonAlgJetTrig.etaMax = 100
tauMonAlgHighPt.etaMin = -100
tauMonAlgHighPt.etaMax = 100
tauMonAlgHighPtBDTLoose.etaMin = -100
tauMonAlgHighPtBDTLoose.etaMax = 100
tauMonAlgBA.kinGroupName = 'tauMonKinGroupBA'
tauMonAlgCR.kinGroupName = 'tauMonKinGroupCR'
tauMonAlgEC.kinGroupName = 'tauMonKinGroupEC'
tauMonAlgGlobal.kinGroupName = 'tauMonKinGroupGlobal'
tauMonAlgTauTrig.kinGroupName = 'tauMonKinGroupTauTrig'
tauMonAlgEleTrig.kinGroupName = 'tauMonKinGroupEleTrig'
tauMonAlgJetTrig.kinGroupName = 'tauMonKinGroupJetTrig'
tauMonAlgHighPt.kinGroupName = 'tauMonKinGroupHighPt'
tauMonAlgHighPtBDTLoose.kinGroupName = 'tauMonKinGroupHighPtBDTLoose'
### STEP 4 ###
# Add some tools. N.B. Do not use your own trigger decion tool. Use the
# standard one that is included with AthMonitorAlgorithm.
# Add a generic monitoring tool (a "group" in old language). The returned
# object here is the standard GenericMonitoringTool.
myKinGroupBA = cfgHelper.addGroup(alg=tauMonAlgBA,
name='tauMonKinGroupBA',
topPath='Tau/TauB/')
myKinGroupCR = cfgHelper.addGroup(alg=tauMonAlgCR,
name='tauMonKinGroupCR',
topPath='Tau/TauCR/')
myKinGroupEC = cfgHelper.addGroup(alg=tauMonAlgEC,
name='tauMonKinGroupEC',
topPath='Tau/TauE/')
myKinGroupGlobal = cfgHelper.addGroup(alg=tauMonAlgGlobal,
name='tauMonKinGroupGlobal',
topPath='Tau/')
myKinGroupTauTrig = cfgHelper.addGroup(alg=tauMonAlgTauTrig,
name='tauMonKinGroupTauTrig',
topPath='Tau/Trigger/TauTrig')
myKinGroupEleTrig = cfgHelper.addGroup(alg=tauMonAlgEleTrig,
name='tauMonKinGroupEleTrig',
topPath='Tau/Trigger/EleTrig')
myKinGroupJetTrig = cfgHelper.addGroup(alg=tauMonAlgJetTrig,
name='tauMonKinGroupJetTrig',
topPath='Tau/Trigger/JetTrig')
myKinGroupHighPt = cfgHelper.addGroup(alg=tauMonAlgHighPt,
name='tauMonKinGroupHighPt',
topPath='Tau/')
myKinGroupHighPtBDTLoose = cfgHelper.addGroup(
alg=tauMonAlgHighPtBDTLoose,
name='tauMonKinGroupHighPtBDTLoose',
topPath='Tau/')
naming = {
'BA': "Tau_TauB_",
'CR': "Tau_TauCR_",
'EC': "Tau_TauE_",
'Global': "",
'HighPt': "",
'HighPtBDTLoose': "",
'EleTrig': "emTriggered_",
'JetTrig': "jetTriggered_",
'TauTrig': "tauTriggered_",
}
def namer(variables, histogramName, folder, algorithm):
if folder != "":
#This wouldn't have been necessary except the calo folder in the naming convention:
#This adds the Tau prefix to the histograms in the calo folder
if postfix == "Global" and (folder == "Calo" or folder == "Track"):
return variables + ";" + "Tau_" + naming[
algorithm] + folder + "_" + histogramName
else:
return variables + ";" + naming[
algorithm] + folder + "_" + histogramName
else:
return variables + ";" + naming[algorithm] + folder + histogramName
# Add a GMT for the other example monitor algorithm
# anotherGroup = cfgHelper.addGroup(anotherTauMonAlg,'tauMonitor')
### STEP 5 ###
# Configure histograms
for itup in [(myKinGroupBA, 'BA'), (myKinGroupCR, 'CR'),
(myKinGroupEC, 'EC'), (myKinGroupGlobal, 'Global'),
(myKinGroupHighPt, 'HighPt'),
(myKinGroupHighPtBDTLoose, 'HighPtBDTLoose'),
(myKinGroupEleTrig, 'EleTrig'),
(myKinGroupJetTrig, 'JetTrig'),
(myKinGroupTauTrig, 'TauTrig')]:
(igroup, postfix) = itup
PHIMIN = -pi
PHIMAX = pi
folder = ""
if (postfix == "BA" or postfix == "CR" or postfix == "EC"
or postfix == "Global" or postfix == "TauTrig"
or postfix == "EleTrig" or postfix == "JetTrig"):
igroup.defineHistogram(
namer('nTauCandidates', 'nTauCandidates', "", postfix),
title='Number of tau candidates;Number of Taus per Event',
xbins=30,
xmin=-0.5,
xmax=30.5,
path=folder)
igroup.defineHistogram(
namer('tauCharge', 'tauCharge', '', postfix),
title='Charge of tau candidates;Charge;Number of Candidates',
xbins=11,
xmin=-5.5,
xmax=5.5,
path=folder)
igroup.defineHistogram(
namer('tauEt', 'tauEt', '', postfix),
title=
'Et of tau candidates;Transverse Energy (GeV);Number of Candidates',
xbins=60,
xmin=0.,
xmax=300.,
path=folder)
igroup.defineHistogram(
namer('tauEta', 'tauEta', '', postfix),
title='Eta of tau candidates;Eta;Number of Candidates',
xbins=51,
xmin=-2.55,
xmax=2.55,
path=folder)
igroup.defineHistogram(namer('LB,tauEta', 'tauEtaVsLB', '',
postfix),
type='TH2F',
title='Tau Eta Vs Lumiblock;Lumiblock;eta',
xbins=1200,
xmin=0,
xmax=1200,
ybins=51,
ymin=-2.55,
ymax=2.55,
path=folder)
igroup.defineHistogram(
namer('tauPhi', 'tauPhi', '', postfix),
title='Phi of tau candidates;Phi;Number of Candidates',
xbins=65,
xmin=PHIMIN - 0.098174 / 2.,
xmax=PHIMAX + 0.098174 / 2.,
path=folder)
igroup.defineHistogram(namer('tauEta,tauPhi', 'tauPhiVsEta', '',
postfix),
type='TH2F',
title='PhiVsEtaTitle;Eta;Phi',
xbins=30,
xmin=-2.55,
xmax=2.55,
ybins=32,
ymin=PHIMIN,
ymax=PHIMAX,
path=folder)
igroup.defineHistogram(namer('LB,tauPhi', 'tauPhiVsLB', '',
postfix),
type='TH2F',
title='Tau Phi vs Lumiblock;Lumiblock;Phi',
xbins=1200,
xmin=0,
xmax=1200,
ybins=80,
ymin=PHIMIN,
ymax=PHIMAX,
path=folder)
if (postfix == "BA" or postfix == "CR" or postfix == "EC"
or postfix == "TauTrig"):
igroup.defineHistogram(
namer('tauPhiBDTLoose', 'phi', 'Identification_BDTLoose',
postfix),
title=
'Phi of tau candidates ( BDTLoose) ;Phi;Number of Candidates',
xbins=65,
xmin=PHIMIN - 0.098174 / 2.,
xmax=PHIMAX + 0.098174 / 2.,
path=folder + "Identification/BDTLoose")
igroup.defineHistogram(
namer('tauEtaBDTLoose', 'eta', 'Identification_BDTLoose',
postfix),
title=
'Eta of tau candidates ( BDTLoose) ;Eta;Number of Candidates',
xbins=51,
xmin=-2.55,
xmax=2.55,
path=folder + "Identification/BDTLoose")
igroup.defineHistogram(
namer('tauEtBDTLoose', 'et', 'Identification_BDTLoose',
postfix),
title=
'Et of tau candidates;Transverse Energy (GeV);Number of Candidates',
xbins=60,
xmin=0.,
xmax=300.,
path=folder + "Identification/BDTLoose")
igroup.defineHistogram(
namer('NumTracksBDTLoose', 'NumTracks',
'Identification_BDTLoose', postfix),
title=
'Number Of Tracks for Tau Candidates (BDTLoose);Number Of Tracks;Number Of Candidates',
xbins=21,
xmin=-0.5,
xmax=20.5,
path=folder + "Identification/BDTLoose")
igroup.defineHistogram(
namer('tauPhiBDTMedium', 'phi', 'Identification_BDTMedium',
postfix),
title=
'Phi of tau candidates ( BDTMedium) ;Phi;Number of Candidates',
xbins=65,
xmin=PHIMIN - 0.098174 / 2.,
xmax=PHIMAX + 0.098174 / 2.,
path=folder + "Identification/BDTMedium")
igroup.defineHistogram(
namer('tauEtaBDTMedium', 'eta', 'Identification_BDTMedium',
postfix),
title=
'Eta of tau candidates ( BDTMedium) ;Eta;Number of Candidates',
xbins=51,
xmin=-2.55,
xmax=2.55,
path=folder + "Identification/BDTMedium")
igroup.defineHistogram(
namer('tauEtBDTMedium', 'et', 'Identification_BDTMedium',
postfix),
title=
'Et of tau candidates;Transverse Energy (GeV);Number of Candidates',
xbins=60,
xmin=0.,
xmax=300.,
path=folder + "Identification/BDTMedium")
igroup.defineHistogram(
namer('NumTracksBDTMedium', 'NumTracks',
'Identification_BDTMedium', postfix),
title=
'Number Of Tracks for Tau Candidates (BDTMedium);Number Of Tracks;Number Of Candidates',
xbins=21,
xmin=-0.5,
xmax=20.5,
path=folder + "Identification/BDTMedium")
igroup.defineHistogram(
namer('tauPhiEt15BDTLoose', 'phi',
'Identification_BDTLoose15GeV', postfix),
title=
'Phi of tau candidates (Et>15, BDTLoose) ;Phi;Number of Candidates',
xbins=65,
xmin=PHIMIN - 0.098174 / 2.,
xmax=PHIMAX + 0.098174 / 2.,
path=folder + "Identification/BDTLoose15GeV")
igroup.defineHistogram(
namer('tauEtaEt15BDTLoose', 'eta',
'Identification_BDTLoose15GeV', postfix),
title=
'Eta of tau candidates (Et>15, BDTLoose) ;Eta;Number of Candidates',
xbins=51,
xmin=-2.55,
xmax=2.55,
path=folder + "Identification/BDTLoose15GeV")
igroup.defineHistogram(
namer('nClustersEt15BDTLoose', 'nCluster',
'Identification_BDTLoose15GeV', postfix),
title=
'Number Of CaloTopoClusters (Et>15,BDTLoose);Number Of Clusters;Number Of Candidates',
xbins=40,
xmin=0.,
xmax=40.,
path=folder + "Identification/BDTLoose15GeV")
igroup.defineHistogram(
namer('NumTracksEt15BDTLoose', 'NumTracks',
'Identification_BDTLoose15GeV', postfix),
title=
'Number Of Tracks for Tau Candidates (Et>15,BDTLoose);Number Of Tracks;Number Of Candidates',
xbins=21,
xmin=-0.5,
xmax=20.5,
path=folder + "Identification/BDTLoose15GeV")
igroup.defineHistogram(
namer('tauEtEt15BDTLoose', 'et',
'Identification_BDTLoose15GeV', postfix),
title=
'Et of tau candidates;Transverse Energy (GeV);Number of Candidates',
xbins=60,
xmin=0.,
xmax=300.,
path=folder + "Identification/BDTLoose15GeV")
igroup.defineHistogram(
namer('panModeEt15BDTLoose', 'panMode',
'Identification_BDTLoose15GeV', postfix),
title='tau decay mode from panTau upon JetBDTSigMedium;mode',
xbins=5,
xmin=0.,
xmax=5.,
path=folder + "Identification/BDTLoose15GeV",
xlabels=["1p0n", "1p1n", "1pXn", "3p0n", "3pXn"])
igroup.defineHistogram(
namer('jetSeedEta', 'jetSeedEta', 'Calo', postfix),
title=
'Calorimeter eta of tau candidates;Eta;Numbers of Candidates',
path=folder + "Calo",
xbins=50,
xmin=-2.5,
xmax=2.5)
igroup.defineHistogram(
namer('jetSeedPhi', 'jetSeedPhi', 'Calo', postfix),
title=
'Calorimeter phi of tau candidates;Phi;Numbers of Candidates',
path=folder + "Calo",
xbins=64,
xmin=PHIMIN,
xmax=PHIMAX)
igroup.defineHistogram(
namer('jetSeedPt', 'jetSeedPt', 'Calo', postfix),
title=
'Calorimeter pt of tau candidates;Et;Numbers of Candidates',
path=folder + "Calo",
xbins=100,
xmin=0.,
xmax=300)
igroup.defineHistogram(
namer('EMRadius', 'EMRadius', 'Calo', postfix),
title='Uncalibrated EM Radius;EM Radius;Number Of Candidates',
path=folder + "Calo",
xbins=50,
xmin=0.,
xmax=1.2)
igroup.defineHistogram(
namer('hadRadius', 'hadRadius', 'Calo', postfix),
title=
'Hadronic Radius of tau candidates;Hadronic Radius; Number Of Candidates',
path=folder + "Calo",
xbins=50,
xmin=0.,
xmax=1.)
igroup.defineHistogram(
namer('stripWidth2', 'stripWidth2', 'Calo', postfix),
title=
'Strip Width of tau candidates;Strip Width;Number of Candidates',
path=folder + "Calo",
xbins=50,
xmin=-0.1,
xmax=0.12)
igroup.defineHistogram(
namer('isolFrac', 'isolFrac', 'Calo', postfix),
title=
'Isolation Fraction;Et Isolation Fraction;Number of Candidates',
path=folder + "Calo",
xbins=51,
xmin=0.0,
xmax=1.02)
igroup.defineHistogram(
namer('nStrip', 'nStrip', 'Calo', postfix),
title=
'Number of strip cells of tau candidates;Number of Strip Cells;Number of Candidates',
path=folder + "Calo",
xbins=56,
xmin=-0.5,
xmax=55.5)
igroup.defineHistogram(
namer('etEMAtEMScale', 'etEMAtEMScale', 'Calo', postfix),
title=
'EM energy at the EM scale;EM Et (GeV) );Number of Candidates',
path=folder + "Calo",
xbins=50,
xmin=0.,
xmax=200.)
igroup.defineHistogram(
namer('etHadAtEMScale', 'etHadAtEMScale', 'Calo', postfix),
title=
'Hadronic Energy at the EM Scale;Had Et (GeV) );Number of Candidates',
path=folder + "Calo",
xbins=50,
xmin=0.,
xmax=200.)
igroup.defineHistogram(
namer('centFrac,LB', 'CentFracVsLB', 'Calo', postfix),
type='TH2F',
title=
'Centrality Fraction vs Lumiblock;Centrality Fraction;Lumiblock',
path=folder + "Calo",
xbins=51,
xmin=0,
xmax=1.02,
ybins=1200,
ymin=0.,
ymax=1200.)
igroup.defineHistogram(
'centFrac,LB',
type='TH2F',
title=
'Centrality Fraction vs Lumiblock;Centrality Fraction;Lumiblock',
path=folder + "Calo",
xbins=51,
xmin=0,
xmax=1.02,
ybins=1200,
ymin=0.,
ymax=1200.)
igroup.defineHistogram(
'isolFrac,LB',
type='TH2F',
title=
'Isolation Fraction vs Lumiblock;Isolation Fraction;Lumiblock',
path=folder + "Calo",
xbins=51,
xmin=0,
xmax=1.02,
ybins=1200,
ymin=0.,
ymax=1200.)
igroup.defineHistogram(
namer('BDTJetScore', 'BDTJetScore', 'Identification', postfix),
title='BDT Score for Jet Rejection;Boosted Decision Tree Score',
path=folder + "Identification",
xbins=48,
xmin=-1.1,
xmax=1.1)
igroup.defineHistogram(namer('JetBDTBkgMedium', 'JetBDTBkgMedium',
'Identification', postfix),
title='Loose EleBDT',
path=folder + "Identification",
xbins=2,
xmin=-0.5,
xmax=1.5,
xlabels=["False", "True"])
igroup.defineHistogram(
namer('BDTEleScoreSigTrans', 'BDTEleScoreSigTrans',
'Identification', postfix),
title=
' Flattened Signal Transformed BDT for Ele Rejection;Boosted Decision Tree Score',
path=folder + "Identification",
xbins=24,
xmin=-0.1,
xmax=1.1)
igroup.defineHistogram(
namer('BDTJetScoreSigTrans', 'BDTJetScoreSigTrans',
'Identification', postfix),
title=
'Flattened signal Transformed BDT Score for Jet Rejection;Boosted Decision Tree Score',
path=folder + "Identification",
xbins=48,
xmin=0,
xmax=1.1)
igroup.defineHistogram(namer('eleBDTMedium', 'eleBDTMedium',
'Identification', postfix),
title='Medium EleBDT',
path=folder + "Identification",
xbins=2,
xmin=-0.5,
xmax=1.5,
xlabels=["False", "True"])
igroup.defineHistogram(namer('eleBDTTight', 'eleBDTTight',
'Identification', postfix),
title='Tight EleBDT',
path=folder + "Identification",
xbins=2,
xmin=-0.5,
xmax=1.5,
xlabels=["False", "True"])
igroup.defineHistogram(namer('muonVeto', 'muonVeto',
'Identification', postfix),
title='Muon Veto',
path=folder + "Identification",
xbins=2,
xmin=-0.5,
xmax=1.5,
xlabels=["False", "True"])
igroup.defineHistogram(namer('tauBDTLoose', 'tauBDTLoose',
'Identification', postfix),
title='Identification Flag: tauBDTLoose',
path=folder + "Identification",
xbins=2,
xmin=-0.5,
xmax=1.5,
xlabels=["False", "True"])
igroup.defineHistogram(namer('tauBDTMedium', 'tauBDTMedium',
'Identification', postfix),
title='Identification Flag: tauBDTMedium',
path=folder + "Identification",
xbins=2,
xmin=-0.5,
xmax=1.5,
xlabels=["False", "True"])
igroup.defineHistogram(namer('tauBDTTight', 'tauBDTTight',
'Identification', postfix),
title='Identification Flag: tauBDTTight',
path=folder + "Identification",
xbins=2,
xmin=-0.5,
xmax=1.5,
xlabels=["False", "True"])
#Substructure Histograms
igroup.defineHistogram(
namer('panModeSubstructure', 'panMode', 'SubStructure',
postfix),
title='tau decay mode from PanTau upon JetBDTSigMedium;mode',
xbins=8,
xmin=0.,
xmax=8.,
path=folder + "SubStructure")
igroup.defineHistogram(
namer('BDTScoreAsP0', 'BDTScoreAsP0', 'SubStructure', postfix),
title='BDT score indentifying pion zero ; BDT score',
path=folder + "SubStructure",
xbins=15,
xmin=-0,
xmax=1.2)
igroup.defineHistogram(
namer('EMFracTrk', 'EMFracTrk', 'SubStructure', postfix),
title=
'Ratio of pt to shot electromagnetic energy for associated tracks; track pt ratio in EM',
path=folder + "SubStructure",
xbins=15,
xmin=0,
xmax=1.5)
igroup.defineHistogram(
namer('EfracL2EffCluster', 'EfracL2EffCluster', 'SubStructure',
postfix),
title=
'Energy fraction of leading two effective clusters in shot; energy fraction',
path=folder + "SubStructure",
xbins=15,
xmin=0,
xmax=1.5)
igroup.defineHistogram(
namer('EisoEffCluster', 'EisoEffCluster', 'SubStructure',
postfix),
title=
'Isolation Energy after correction in effective clusters ; isolation energy (GeV)',
path=folder + "SubStructure",
xbins=10,
xmin=0,
xmax=50.)
igroup.defineHistogram(
namer('InvMassEffClusters', 'InvMassEffClusters',
'SubStructure', postfix),
title=
'Invariant mass of effective clusters in shot; invariant mass (GeV)',
path=folder + "SubStructure",
xbins=40,
xmin=0,
xmax=8.)
igroup.defineHistogram(
namer('nNeutPFO', 'nNeutPFO', 'SubStructure', postfix),
title=
'_NumNeutPFO;Number of neutral ParticleFlow objects ; PFO number',
path=folder + "SubStructure",
xbins=20,
xmin=0,
xmax=20.)
igroup.defineHistogram(namer('nShot', 'nShot', 'SubStructure',
postfix),
title='number of shots ; shot number ',
path=folder + "SubStructure",
xbins=20,
xmin=0,
xmax=20.)
igroup.defineHistogram(
namer('panEta', 'panEta', 'SubStructure', postfix),
title='tau Eta from PanTau ; substructure Eta',
path=folder + "SubStructure",
xbins=16,
xmin=-3.2,
xmax=3.2)
igroup.defineHistogram(
namer('panPhi', 'panPhi', 'SubStructure', postfix),
title='tau Phi from PanTau ; substructure Phi',
path=folder + "SubStructure",
xbins=16,
xmin=PHIMIN,
xmax=PHIMAX)
igroup.defineHistogram(
namer('panPt', 'panPt', 'SubStructure', postfix),
title='tau Pt from PanTau ; substructure pt (GeV)',
path=folder + "SubStructure",
xbins=20,
xmin=0,
xmax=200)
igroup.defineHistogram(
namer('pt3', 'shots_pt3', 'SubStructure', postfix),
title='weighted cell pt in 3x3 window in shots; pt3 (GeV) ',
path=folder + "SubStructure",
xbins=24,
xmin=0,
xmax=12)
igroup.defineHistogram(
namer('PSSFrac', 'PSSFracEffCluster', 'SubStructure', postfix),
title=
'Energy fraction for PreSampling and sampling layers in effective clusters in shot;Sampling Energy Fraction',
path=folder + "SubStructure",
xbins=10,
xmin=0,
xmax=1.)
igroup.defineHistogram(
namer('ptRatioEflowApprox', 'ptRatioApprox', 'SubStructure',
postfix),
title=
'Ratio of pt to shot total energy for associated tracks; track pt ratio',
xbins=20,
xmin=0.,
xmax=2.,
path=folder + "SubStructure")
if (postfix == "BA" or postfix == "CR" or postfix == "EC"
or postfix == "TauTrig" or postfix == "Global"):
#Calo Histograms
igroup.defineHistogram(
namer('EMRadius', 'EMRadius', 'Calo', postfix),
title='Uncalibrated EM Radius;EM Radius;Number Of Candidates',
path=folder + "Calo",
xbins=50,
xmin=0.,
xmax=1.2)
igroup.defineHistogram(
namer('hadRadius', 'hadRadius', 'Calo', postfix),
title=
'Hadronic Radius of tau candidates;Hadronic Radius; Number Of Candidates',
path=folder + "Calo",
xbins=50,
xmin=0.,
xmax=1.)
igroup.defineHistogram(
namer('stripWidth2', 'stripWidth2', 'Calo', postfix),
title=
'Strip Width of tau candidates;Strip Width;Number of Candidates',
path=folder + "Calo",
xbins=50,
xmin=-0.1,
xmax=0.12)
igroup.defineHistogram(
namer('isolFrac', 'isolFrac', 'Calo', postfix),
title=
'Isolation Fraction;Et Isolation Fraction;Number of Candidates',
path=folder + "Calo",
xbins=51,
xmin=0.0,
xmax=1.02)
igroup.defineHistogram(
namer('nStrip', 'nStrip', 'Calo', postfix),
title=
'Number of strip cells of tau candidates;Number of Strip Cells;Number of Candidates',
path=folder + "Calo",
xbins=56,
xmin=-0.5,
xmax=55.5)
igroup.defineHistogram(
namer('etEMAtEMScale', 'etEMAtEMScale', 'Calo', postfix),
title=
'EM energy at the EM scale;EM Et (GeV) );Number of Candidates',
path=folder + "Calo",
xbins=50,
xmin=0.,
xmax=200.)
igroup.defineHistogram(
namer('etHadAtEMScale', 'etHadAtEMScale', 'Calo', postfix),
title=
'Hadronic Energy at the EM Scale;Had Et (GeV) );Number of Candidates',
path=folder + "Calo",
xbins=50,
xmin=0.,
xmax=200.)
igroup.defineHistogram(
namer('centFrac,LB', 'centFracVsLB', 'Calo', postfix),
type='TH2F',
title=
'Centrality Fraction vs Lumiblock;Centrality Fraction;Lumiblock',
path=folder + "Calo",
xbins=51,
xmin=0,
xmax=1.02,
ybins=1200,
ymin=0.,
ymax=1200.)
igroup.defineHistogram(
namer('isolFrac,LB', 'isolFracVsLB', 'Calo', postfix),
type='TH2F',
title=
'Isolation Fraction vs Lumiblock;Isolation Fraction;Lumiblock',
path=folder + "Calo",
xbins=51,
xmin=0,
xmax=1.02,
ybins=1200,
ymin=0.,
ymax=1200.)
igroup.defineHistogram(
namer('centFrac', "centralityFraction", "Calo", postfix),
title=
'Centrality Fraction;Centrality Fraction;Number Of Candidates',
xbins=70,
xmin=0.,
xmax=1.4,
path=folder + "Calo")
igroup.defineHistogram(
namer('dRmax', "dRmax", "Calo", postfix),
title='Maximum delta R;delta R;Number of Candidates',
xbins=42,
xmin=0.,
xmax=0.21,
path=folder + "Calo")
igroup.defineHistogram(
namer('tauEta', 'eta', 'Calo', postfix),
title='Eta of tau candidates;Eta;Number of Candidates',
xbins=51,
xmin=-2.55,
xmax=2.55,
path=folder + "Calo")
igroup.defineHistogram(
namer('tauPhi', 'phi', 'Calo', postfix),
title='Phi of tau candidates;Phi;Number of Candidates',
xbins=65,
xmin=PHIMIN,
xmax=PHIMAX,
path=folder + "Calo")
igroup.defineHistogram(
namer('trkAvgDist', 'trkAvgDist', 'Calo', postfix),
title=
'Average Track Distance from Calorimeter Seed;Distance (mm);Number of Candidates',
xbins=20,
xmin=0.,
xmax=1.,
path=folder + "Calo")
#Track Histograms!
igroup.defineHistogram(
namer('d0', 'd0', 'Track', postfix),
title='Track d0;Transverse Impact Parameter (mm)',
path=folder + "Track",
xbins=50,
xmin=-5.0,
xmax=5.0)
igroup.defineHistogram(
namer('z0PriVtx', 'z0PriVtx', 'Track', postfix),
title=' z0 respected to primary vertex ; Z0 SinTheta (mm)',
path=folder + "Track",
xbins=50,
xmin=-35.0,
xmax=35.0)
igroup.defineHistogram(namer('etaTrack', 'eta', 'Track', postfix),
title='Track Eta;Eta',
path=folder + "Track",
xbins=51,
xmin=-2.55,
xmax=2.55)
igroup.defineHistogram(
namer('leadTrkPt', 'leadTrkPt', 'Track', postfix),
title='Pt of Leading track;Transverse Momentum (GeV)',
path=folder + "Track",
xbins=50,
xmin=0.,
xmax=200.)
igroup.defineHistogram(
namer('nHighPtTaus', 'nHighPtTaus', 'Track', postfix),
title=
'Number of High Pt tau candidates;Number of Taus per Event',
xbins=15,
xmin=-0.5,
xmax=14.5,
path=folder + "Track")
igroup.defineHistogram(
namer('numberOfTRTHighThresholdHits',
'numberOfTRTHighThresholdHits', 'Track', postfix),
title=
'Number of TRT High Threshold Hits;Number of High Threshold TRT Hits',
path=folder + "Track",
xbins=15,
xmin=-0.5,
xmax=14.5)
igroup.defineHistogram(
namer('numberOfTRTHighThresholdOutliers',
'numberOfTRTHighThresholdOutliers', 'Track', postfix),
title=
"Number of TRT High Threshold Outliers;Number of TRT High Threshold Outliers",
path=folder + "Track",
xbins=26,
xmin=-0.5,
xmax=25.5)
igroup.defineHistogram(
namer('numberOfTRTHits', 'numberOfTRTHits', 'Track', postfix),
title=
'Number of TRT Low Threshold Hits;Number of Low Threshold TRT Hits',
path=folder + "Track",
xbins=101,
xmin=-0.5,
xmax=100.5)
igroup.defineHistogram(
namer('numberOfTRTOutliers', 'numberOfTRTOutliers', 'Track',
postfix),
title=
"Number of TRT Low Threshold Outliers;Number of TRT Low Threshold Outliers",
path=folder + "Track",
xbins=31,
xmin=-0.5,
xmax=25.5)
igroup.defineHistogram(namer('ptTrack', 'pT', 'Track', postfix),
title='Track pT;Transverse Momentum (GeV)',
path=folder + "Track",
xbins=60,
xmin=0,
xmax=300)
igroup.defineHistogram(namer('phiTrack', 'phi', 'Track', postfix),
title='Track Phi;Phi',
path=folder + "Track",
xbins=64,
xmin=PHIMIN,
xmax=PHIMAX)
igroup.defineHistogram(
namer('trkWidth2', 'trkWidth2', 'Track', postfix),
title=
'Weighted Track Width;Momentum-Weighted Width of Track System',
path=folder + "Track",
xbins=50,
xmin=0.0,
xmax=0.1)
igroup.defineHistogram(
namer('ipZ0SinThetaSigLeadTrk', 'ipZ0SinThetaSigLeadTrk',
'Track', postfix),
title=
'Impact Parameter z0 Sine Theta Significance of Leading Track;Z0SinTheta Significance',
path=folder + "Track",
xbins=50,
xmin=-10.0,
xmax=10.0)
igroup.defineHistogram(
namer('numberOfPixelHits', 'numberOfPixelHits', 'Track',
postfix),
title='Number of Pixel Hits;Number of Pixel Hits',
path=folder + "Track",
xbins=25,
xmin=-0.5,
xmax=25.5)
igroup.defineHistogram(
namer('numberOfSCTHits', 'numberOfSCTHits', 'Track', postfix),
title='Number of SCT Hits;Number of SCT Hits',
path=folder + "Track",
xbins=26,
xmin=0,
xmax=26)
igroup.defineHistogram(
namer('etOverPtLeadTrack', 'etOverPtLeadTrack', 'Track',
postfix),
title=
'Et over Pt of lead track of tau candidates;Et/Pt;Number of Candidates',
xbins=50,
xmin=0.,
xmax=12.,
path=folder + "Track")
igroup.defineHistogram(
namer('ipSigLeadTrk', 'ipSigLeadTrk', 'Track', postfix),
title=
'Impact Parameter Significance of Leading Track;Transverse Impact Parameter Significance',
xbins=100,
xmin=-5.,
xmax=5.,
path=folder + "Track")
igroup.defineHistogram(
namer('massTrkSys', 'massTrkSys', 'Track', postfix),
title='Mass of the Track System;Invariant Mass (GeV)',
xbins=30,
xmin=-1.,
xmax=5.,
path=folder + "Track")
igroup.defineHistogram(
namer('trFlightPathSig', 'trFlightPathSig', 'Track', postfix),
title=
'Track Transverse Flight Path Significance;Transverse Flight Path Significance',
xbins=125,
xmin=-4.5,
xmax=8.,
path=folder + "Track")
igroup.defineHistogram(
namer('z0', 'z0', 'Track', postfix),
title='Track z0;Longitudinal Impact Parameter (mm)',
path=folder + "Track",
xbins=50,
xmin=-35.0,
xmax=35.0)
if postfix == 'Global' or postfix == "TauTrig" or postfix == "EleTrig" or postfix == "JetTrig":
igroup.defineHistogram(
namer('LB', 'nTauPerLB', '', postfix),
title=
'Total number of tau candidates per LB);Luminosity Block);Number of Candidates',
xbins=1000,
xmin=0.,
xmax=1000.,
path=folder)
igroup.defineHistogram(
namer('nHighPtTauCandidates', 'nHightPtTauCandidates', '',
postfix),
title=
'Number of High Pt tau candidates;Number of Taus per Event',
xbins=15,
xmin=-0.5,
xmax=14.5,
path=folder)
igroup.defineHistogram(
namer('NumTracks', 'tauNumTracks', '', postfix),
title=
'Number Of Tracks for Tau Candidates;Number Of Tracks;Number Of Candidates',
xbins=21,
xmin=-0.5,
xmax=20.5,
path=folder)
igroup.defineHistogram(
namer('nClusters', 'nCluster', '', postfix),
title=
'Number Of CaloTopoClusters;Number Of Clusters;Number Of Candidates',
xbins=40,
xmin=0.,
xmax=40.,
path=folder)
igroup.defineHistogram(
namer('tauEta,tauEt', 'tauEtVsEta', '', postfix),
type='TH2F',
title='Tau Et Vs Eta;#eta;Transverse Energy (Gev)',
xbins=40,
xmin=-2.55,
xmax=2.55,
ybins=300,
ymin=0,
ymax=300,
path=folder)
igroup.defineHistogram(
namer('tauPhi,tauEt', 'tauEtVsPhi', '', postfix),
type='TH2F',
title='EtVsPhi;Phi;Transverse Energy (GeV);',
xbins=80,
xmin=PHIMIN,
xmax=PHIMAX,
ybins=300,
ymin=-0.,
ymax=300.,
path=folder)
if postfix == 'Global':
#Physics Histograms - I suspect these should be doing some kind of selection, not obvious in the old code.
igroup.defineHistogram(
namer('tauEta', 'tau_eta', '', postfix),
title='Eta of tau candidates;Eta;Number of Candidates',
xbins=51,
xmin=-2.55,
xmax=2.55,
path=folder + "Physics/Z")
igroup.defineHistogram(
namer('tauEta,tauEt', 'tau_pTVsEta', '', postfix),
type='TH2F',
title='Tau Et Vs Eta;#eta;Transverse Energy (Gev)',
xbins=40,
xmin=-2.55,
xmax=2.55,
ybins=300,
ymin=0,
ymax=300,
path=folder + "Physics/Z")
#will use different variable when not a placeholder
igroup.defineHistogram(
namer('tauEta', 'lepton_pTVsEta', '', postfix),
title=
'Placeholder for empty histogram;Eta;Number of Candidates',
xbins=51,
xmin=-2.55,
xmax=2.55,
path=folder + "Physics/Z")
igroup.defineHistogram(
namer('tauEta,tauEt', 'tau_pTVsEta', '', postfix),
type='TH2F',
title='Tau Et Vs Eta;#eta;Transverse Energy (Gev)',
xbins=40,
xmin=-2.55,
xmax=2.55,
ybins=300,
ymin=0,
ymax=300,
path=folder + "Physics/W")
if postfix == 'HighPt':
igroup.defineHistogram(namer('tauEtaEt15,tauPhiEt15',
'tauPhiVsEta_et15', '', postfix),
type='TH2F',
title='EtaVsEtTitle;Eta;Phi',
xbins=30,
xmin=-2.55,
xmax=2.55,
ybins=32,
ymin=PHIMIN,
ymax=PHIMAX)
if postfix == 'HighPtBDTLoose':
igroup.defineHistogram(
namer('tauEtaEt15BDTLoose,tauPhiEt15BDTLoose',
'tauPhiVsEta_et15_BDTLoose', '', postfix),
type='TH2F',
title='Phi vs Eta (Et>15, BDTLoose) ;Eta;Phi',
xbins=30,
xmin=-2.55,
xmax=2.55,
ybins=32,
ymin=PHIMIN,
ymax=PHIMAX)
### STEP 6 ###
# Finalize. The return value should be a tuple of the ComponentAccumulator
# and the sequence containing the created algorithms. If we haven't called
# any configuration other than the AthMonitorCfgHelper here, then we can
# just return directly (and not create "result" above)
return cfgHelper.result()
def TileRawChannelTimeMonitoringConfig(flags, **kwargs):
''' Function to configure TileRawChannelTimeMonitorAlgorithm algorithm in the monitoring system.'''
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
from TileRecUtils.TileDQstatusConfig import TileDQstatusAlgCfg
result.merge(TileDQstatusAlgCfg(flags))
from TileGeoModel.TileGMConfig import TileGMCfg
result.merge(TileGMCfg(flags))
from TileConditions.TileCablingSvcConfig import TileCablingSvcCfg
result.merge(TileCablingSvcCfg(flags))
from TileConditions.TileBadChannelsConfig import TileBadChannelsCondAlgCfg
result.merge(TileBadChannelsCondAlgCfg(flags, **kwargs))
kwargs.setdefault('CheckDCS', flags.Tile.useDCS)
if kwargs['CheckDCS']:
from TileConditions.TileDCSConfig import TileDCSCondAlgCfg
result.merge(TileDCSCondAlgCfg(flags))
kwargs.setdefault('TriggerChain', '')
# Partition pairs to monitor average time difference between partitions (ROS - 1)
partitionPairs = [[0, 1], [0, 2], [0, 3], [1, 2], [1, 3], [2, 3]]
kwargs.setdefault('PartitionTimeDiffferncePairs', partitionPairs)
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(flags, 'TileRawChannelTimeMonitoring')
# Adding an TileCellMonitorAlgorithm algorithm to the helper
from AthenaConfiguration.ComponentFactory import CompFactory
TileRawChannelTimeMonitorAlgorithm = CompFactory.TileRawChannelTimeMonitorAlgorithm
tileRawChanTimeMonAlg = helper.addAlgorithm(
TileRawChannelTimeMonitorAlgorithm, 'TileRawChanTimeMonAlg')
for k, v in kwargs.items():
setattr(tileRawChanTimeMonAlg, k, v)
run = str(flags.Input.RunNumber[0])
# 1) Configure histogram with TileRawChannelTimeMonAlg algorithm execution time
executeTimeGroup = helper.addGroup(tileRawChanTimeMonAlg,
'TileRawChanTimeMonExecuteTime',
'Tile/')
executeTimeGroup.defineHistogram(
'TIME_execute',
path='RawChannelTime',
type='TH1F',
title='Time for execute TileRawChanTimeMonAlg algorithm;time [#mus]',
xbins=100,
xmin=0,
xmax=100000)
from TileMonitoring.TileMonitoringCfgHelper import addTileModuleChannelMapsArray
# 2) Configure histograms with status of Tile channel time per partition
addTileModuleChannelMapsArray(helper,
tileRawChanTimeMonAlg,
name='TileAverageTime',
title='Tile average time',
path='Tile/RawChannelTime/Summary',
type='TProfile2D',
value='time',
run=run)
from TileMonitoring.TileMonitoringCfgHelper import addTile2DHistogramsArray
# 3) Configure histograms with Tile partition average time vs luminosity block per partition
addTile2DHistogramsArray(
helper,
tileRawChanTimeMonAlg,
name='TileAverageTimeLB',
xvalue='lumiBlock',
yvalue='time',
type='TH2D',
title='Tile Average time vs LumiBlock;LumiBlock;t [ns]',
path='Tile/RawChannelTime/Summary',
run=run,
perPartition=True,
xbins=3000,
xmin=-0.5,
xmax=2999.5,
ybins=149,
ymin=-74.5,
ymax=74.5)
from TileMonitoring.TileMonitoringCfgHelper import getPartitionName
# 4) Configure histograms with Tile partition average time difference vs luminosity block
partitionPairs = kwargs['PartitionTimeDiffferncePairs']
partTimeDiffVsLBArray = helper.addArray([len(partitionPairs)],
tileRawChanTimeMonAlg,
'TileAverageTimeDifferenceLB',
topPath='Tile/RawChannelTime')
for postfix, tool in partTimeDiffVsLBArray.Tools.items():
pairIdx = int(postfix.split('_').pop())
partitionName1, partitionName2 = [
getPartitionName(ros + 1) for ros in partitionPairs[pairIdx]
]
title = 'Run %s: Average time between %s and %s' % (
run, partitionName1, partitionName2)
title += ' vs luminosity block;LumiBlock;t [ns]'
name = 'lumiBlock,time;TileAverageTimeDifferenceLB_%s-%s' % (
partitionName1, partitionName2)
tool.defineHistogram(name,
title=title,
path='Summary',
type='TProfile',
xbins=1000,
xmin=-0.5,
xmax=999.5,
opt='kAddBinsDynamically')
from TileCalibBlobObjs.Classes import TileCalibUtils as Tile
# 5) Configure histograms with Tile digitizer time vs luminosity block per digitizer
maxDigitizer = 8
digiTimeVsLBArray = helper.addArray(
[int(Tile.MAX_ROS - 1),
int(Tile.MAX_DRAWER), maxDigitizer],
tileRawChanTimeMonAlg,
'TileDigitizerTimeLB',
topPath='Tile/RawChannelTime')
for postfix, tool in digiTimeVsLBArray.Tools.items():
ros, module, digitizer = [int(x) for x in postfix.split('_')[1:]]
moduleName = Tile.getDrawerString(ros + 1, module)
title = 'Run ' + run + ' ' + moduleName + ' Digitizer ' + str(
digitizer)
title += ': Time vs luminosity block;LumiBlock;t [ns]'
name = 'lumiBlock,time;TileDigitizerTimeLB_' + moduleName + '_DIGI_' + str(
digitizer)
path = getPartitionName(ros + 1) + '/' + moduleName
tool.defineHistogram(name,
title=title,
path=path,
type='TProfile',
xbins=1000,
xmin=-0.5,
xmax=999.5,
opt='kAddBinsDynamically')
accumalator = helper.result()
result.merge(accumalator)
return result
def TrigBjetMonConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
### STEP 1 ###
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
# EN: not needed here now
# from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
# result = ComponentAccumulator()
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags,'TrigBjetAthMonitorCfg')
### STEP 2 ###
# Adding an algorithm to the helper. Here, we will use the example
# algorithm in the AthenaMonitoring package. Just pass the type to the
# helper. Then, the helper will instantiate an instance and set up the
# base class configuration following the inputFlags. The returned object
# is the algorithm.
#The added algorithm must exist as a .h file
from TrigBjetMonitoring.TrigBjetMonitoringConf import TrigBjetMonitorAlgorithm
trigBjetMonAlg = helper.addAlgorithm(TrigBjetMonitorAlgorithm,'TrigBjetMonAlg')
# You can actually make multiple instances of the same algorithm and give
# them different configurations
shifterTrigBjetMonAlg = helper.addAlgorithm(TrigBjetMonitorAlgorithm,'ShifterTrigBjetMonAlg')
# # If for some really obscure reason you need to instantiate an algorithm
# # yourself, the AddAlgorithm method will still configure the base
# # properties and add the algorithm to the monitoring sequence.
# helper.AddAlgorithm(myExistingAlg)
### STEP 3 ###
# Edit properties of a algorithm
# some generic property
# trigBjetMonAlg.RandomHist = True
# to enable a trigger filter, for example:
#trigBjetMonAlg.TriggerChain = 'HLT_mu26_ivarmedium'
#trigBjetMonAlg.TriggerChain = 'HLT_e24_lhtight_nod0'
trigBjetMonAlg.TriggerChain = ''
### STEP 4 ###
# Read in the Bjet trigger chain names
# Directly from TrigBjetMonitCategory
#from TrigBjetMonitoring import TrigBjetMonitCategory
#bjet_triglist = TrigBjetMonitCategory.monitoring_bjet
# From the hltmonList where TrigHLTMonitoring filtered the run type
from TrigHLTMonitoring.HLTMonTriggerList import hltmonList
bjet_triglist = hltmonList.monitoring_bjet
bjet_triglist += hltmonList.monitoring_mujet
# print " ==> bjet_triglist: ", bjet_triglist
# Add some tools. N.B. Do not use your own trigger decion tool. Use the
# standard one that is included with AthMonitorAlgorithm.
# # First, add a tool that's set up by a different configuration function.
# # In this case, CaloNoiseToolCfg returns its own component accumulator,
# # which must be merged with the one from this function.
# from CaloTools.CaloNoiseToolConfig import CaloNoiseToolCfg
# caloNoiseAcc, caloNoiseTool = CaloNoiseToolCfg(inputFlags)
# result.merge(caloNoiseAcc)
# trigBjetMonAlg.CaloNoiseTool = caloNoiseTool
# # Then, add a tool that doesn't have its own configuration function. In
# # this example, no accumulator is returned, so no merge is necessary.
# from MyDomainPackage.MyDomainPackageConf import MyDomainTool
# trigBjetMonAlg.MyDomainTool = MyDomainTool()
# Add a generic monitoring tool (a "group" in old language). The returned
# object here is the standard GenericMonitoringTool.
myGroup = helper.addGroup(
trigBjetMonAlg,
'TrigBjetMonitor',
'HLT/BjetMon/Expert/'
)
# Add a GMT for the other example monitor algorithm
shifterGroup = helper.addGroup(shifterTrigBjetMonAlg,'TrigBjetMonitor','HLT/BjetMon/Shifter/')
### STEP 5 ###
# Configure histograms
#NB! The histograms defined here must match the ones in the cxx file exactly
# Offline PV histograms - common for all trigger chains
shifterGroup.defineHistogram('Off_NVtx', title='Number of Offline Vertices;NVtx;Events',
path='Offline',xbins=100,xmin=0.0,xmax=100.)
shifterGroup.defineHistogram('Off_xVtx', title='Offline xVtx;xVtx;Events',
path='Offline',xbins=200,xmin=-1.5,xmax=+1.5)
shifterGroup.defineHistogram('Off_yVtx', title='Offline yVtx;yVtx;Events',
path='Offline',xbins=200,xmin=-1.5,xmax=+1.5)
shifterGroup.defineHistogram('Off_zVtx', title='Offline zVtx;zVtx;Events',
path='Offline',xbins=200,xmin=-200.0,xmax=+200.0)
# Histograms which depend on the trigger chain
AllChains = []
for chain in bjet_triglist :
AllChains.append(chain[2:])
# print " inside bjet_triglist chain[2:8] : " , chain[2:8]
if chain[2:8] == 'HLT_mu' : # mu-jets
# print " mu-jet histogram is defined for ", chain[2:]
HistName = 'jetPt_' + chain[2:]
if chain[0:1] == "E" :
myGroup.defineHistogram(HistName, title='Distribution of Pt_jet;Pt_jet;Events',
path=chain[2:],xbins=100,xmin=-0.0,xmax=750.0)
# print " ==> histogam ",HistName," is defined for myGroup"
if chain[0:1] == "S" :
shifterGroup.defineHistogram(HistName, title='Distribution of Pt_jet;Pt_jet;Events',
path=chain[2:],xbins=100,xmin=-0.0,xmax=750.0)
# print " ==> histogam ",HistName," is defined for shifterGroup"
continue
else : # b-jets
# print " b-jet histogram is defined for ", chain[2:]
HistName = 'PVz_tr_' + chain[2:]
if chain[0:1] == "E" :
myGroup.defineHistogram(HistName, title='Distribution of online zPV;zPV;Events',
path=chain[2:],xbins=200,xmin=-200.0,xmax=200.0)
# print " ==> histogam ",HistName," is defined for myGroup"
if chain[0:1] == "S" :
shifterGroup.defineHistogram(HistName, title='Distribution of online zPV;zPV;Events',
path=chain[2:],xbins=200,xmin=-200.0,xmax=200.0)
# print " ==> histogam ",HistName," is defined for shifterGroup"
HistName = 'd0_' + chain[2:]
if chain[0:1] == "E" :
myGroup.defineHistogram(HistName, title='Distribution of d0;d0;Events',
path=chain[2:],xbins=200,xmin=-2.0,xmax=2.0)
# print " ==> histogam ",HistName," is defined for myGroup"
if chain[0:1] == "S" :
shifterGroup.defineHistogram(HistName, title='Distribution of d0;d0;Events',
path=chain[2:],xbins=200,xmin=-2.0,xmax=2.0)
# print " ==> histogam ",HistName," is defined for shifterGroup"
HistName = 'jetPt_' + chain[2:]
if chain[0:1] == "E" :
myGroup.defineHistogram(HistName, title='Distribution of Pt_jet;Pt_jet;Events',
path=chain[2:],xbins=100,xmin=-0.0,xmax=750.0)
# print " ==> histogam ",HistName," is defined for myGroup"
if chain[0:1] == "S" :
shifterGroup.defineHistogram(HistName, title='Distribution of Pt_jet;Pt_jet;Events',
path=chain[2:],xbins=100,xmin=-0.0,xmax=750.0)
# print " ==> histogam ",HistName," is defined for shifterGroup"
HistName = 'wMV2c20_' + chain[2:]
if chain[0:1] == "E" :
myGroup.defineHistogram(HistName, title='Distribution of MV2c20 discriminant;MV2c20;Events',
path=chain[2:],xbins=200,xmin=-1.0,xmax=1.0)
# print " ==> histogam ",HistName," is defined for myGroup"
if chain[0:1] == "S" :
shifterGroup.defineHistogram(HistName, title='Distribution of MV2c20 discriminant;MV2c20;Events',
path=chain[2:],xbins=200,xmin=-1.0,xmax=1.0)
# print " ==> histogam ",HistName," is defined for shifterGroup"
continue
# print " ==> In TrigBjetMonitorAlgorithm.py: AllChains list: ", AllChains
trigBjetMonAlg.AllChains = AllChains
shifterTrigBjetMonAlg.AllChains = AllChains
### STEP 6 ###
# Finalize. The return value should be a tuple of the ComponentAccumulator
# and the sequence containing the created algorithms. If we haven't called
# any configuration other than the AthMonitorCfgHelper here, then we can
# just return directly (and not create "result" above)
return helper.result()
def CscMonitoringConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
### STEP 1 ###
# If you need to set up special tools, etc., you will need your own ComponentAccumulator;
# uncomment the following 2 lines and use the last three lines of this function instead of the ones
# just before
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
# Make sure muon geometry is configured
from MuonConfig.MuonGeometryConfig import MuonGeoModelCfg
result.merge(MuonGeoModelCfg(inputFlags))
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'CscAthMonitorCfg')
### STEP 2 ###
# Adding an algorithm to the helper. Here, we will use the example
# algorithm in the AthenaMonitoring package. Just pass the type to the
# helper. Then, the helper will instantiate an instance and set up the
# base class configuration following the inputFlags. The returned object
# is the algorithm.
# This uses the new Configurables object system.
cscClusMonAlg = helper.addAlgorithm(CompFactory.CscClusterValMonAlg,
'CscClusMonAlg')
cscPrdMonAlg = helper.addAlgorithm(CompFactory.CscPrdValMonAlg,
'CscPrdMonAlg')
# cscSegmMonAlg = helper.addAlgorithm(CompFactory.CscSegmValMonAlg,'CscSegmValMonAlg')
### STEP 3 ###
# Edit properties of a algorithm
# some generic property
# exampleMonAlg.RandomHist = True
cscClusMonAlg.CSCQmaxCutADC = 100
cscPrdMonAlg.NoiseCutADC = 50
cscPrdMonAlg.MapYXandRZ = False
# to enable a trigger filter, for example:
#exampleMonAlg.TriggerChain = 'HLT_mu26_ivarmedium'
### STEP 4 ###
# Add some tools. N.B. Do not use your own trigger decion tool. Use the
# standard one that is included with AthMonitorAlgorithm.
# # Then, add a tool that doesn't have its own configuration function. In
# # this example, no accumulator is returned, so no merge is necessary.
# from MyDomainPackage.MyDomainPackageConf import MyDomainTool
# exampleMonAlg.MyDomainTool = MyDomainTool()
from MuonConfig.MuonCalibConfig import CscCalibToolCfg
calibtool = result.popToolsAndMerge(CscCalibToolCfg(inputFlags))
cscClusMonAlg.CscCalibTool = calibtool
from MuonConfig.MuonSegmentFindingConfig import CalibCscStripFitterCfg
stripfitter = result.popToolsAndMerge(CalibCscStripFitterCfg(inputFlags))
cscClusMonAlg.CSCStripFitter = stripfitter
cscPrdMonAlg.CSCStripFitter = stripfitter
# Add a generic monitoring tool (a "group" in old language). The returned
# object here is the standard GenericMonitoringTool.
cscClusGroup = helper.addGroup(cscClusMonAlg, 'CscClusMonitor',
'Muon/MuonRawDataMonitoring/CSC/')
cscPrdGroup = helper.addGroup(cscPrdMonAlg, 'CscPrdMonitor',
'Muon/MuonRawDataMonitoring/CSC/')
# cscSegmGroup = helper.addGroup(cscSegmMonAlg,'CscSegmMonitor','Muon/MuonRawDataMonitoring/CSC/')
### STEP 5 ###
# Configure histograms
qmaxCut = str(cscClusMonAlg.CSCQmaxCutADC)
#Cluster
cscClusGroup.defineHistogram('z,r;h2csc_clus_r_vs_z_hitmap',
type='TH2F',
title='R vs. Z Cluster hitmap;z(mm);R(mm)',
path='Clusters/Shift',
xbins=200,
xmin=-10000.,
xmax=10000.,
ybins=40,
ymin=0.,
ymax=4000.)
cscClusGroup.defineHistogram('y,x;h2csc_clus_y_vs_x_hitmap',
type='TH2F',
title='X vs. Y Cluster hitmap;y(mm);x(mm)',
path='Clusters/Shift',
xbins=100,
xmin=-5000.,
xmax=5000.,
ybins=100,
ymin=-5000,
ymax=5000)
cscClusGroup.defineHistogram(
'noStrips,secLayer;h2csc_clus_phicluswidth',
type='TH2F',
cutmask='clus_phi',
title='Phi-Cluster width;# strips;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=48,
xmin=0,
xmax=48,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'noStrips,secLayer;h2csc_clus_etacluswidth',
type='TH2F',
cutmask='clus_eta',
title='Eta-Cluster width;# strips;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=192,
xmin=0,
xmax=192,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'stripid,secLayer;h2csc_clus_hitmap',
type='TH2F',
title='Cluster occupancy;channel;[sector]+[0.2 #times layer]',
path='Clusters/Expert',
xbins=242,
xmin=-49.,
xmax=193.,
ybins=175,
ymin=-17.,
ymax=18.)
cscClusGroup.defineHistogram(
'fStripIDs_col,secLayer;h2csc_clus_hitmap_signal',
cutmask='signal_mon',
type='TH2F',
title='Cluster occupancy, Qmax > ' + qmaxCut +
' counts;channel;[sector] + [0.2 #times layer]',
path='Clusters/Shift',
xbins=242,
xmin=-49.,
xmax=193.,
ybins=175,
ymin=-17.,
ymax=18.)
cscClusGroup.defineHistogram(
'noStrips,secLayer;h2csc_clus_phicluswidth_signal',
type='TH2F',
cutmask='clus_phiSig',
title='#phi-cluster width, Qmax > ' + qmaxCut +
' counts;# strips;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=48,
xmin=0,
xmax=48,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'noStrips,secLayer;h2csc_clus_etacluswidth_signal',
type='TH2F',
cutmask='clus_etaSig',
title='#eta-cluster width, Qmax > ' + qmaxCut +
' counts;# strips;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=192,
xmin=0,
xmax=192,
ybins=175,
ymin=-17,
ymax=18)
thisLabelx = getCSCLabelx("labels_clus_occupancy_signal_EA")
cscClusGroup.defineHistogram('secLayer;h1csc_clus_occupancy_signal_EA',
type='TH1F',
cutmask='sideA',
title='EndCap A: Layer occupancy, Qmax > ' +
qmaxCut + ' counts;;entries/layer',
path='Overview/CSCEA/Cluster',
xbins=90,
xmin=0,
xmax=18,
xlabels=thisLabelx)
thisLabelx = getCSCLabelx("labels_clus_occupancy_signal_EC")
cscClusGroup.defineHistogram('secLayer;h1csc_clus_occupancy_signal_EC',
type='TH1F',
cutmask='sideC',
title='EndCap C: Layer occupancy, Qmax > ' +
qmaxCut + ' counts;;entries/layer',
path='Overview/CSCEC/Cluster',
xbins=85,
xmin=-17.,
xmax=0.,
xlabels=thisLabelx)
cscClusGroup.defineHistogram(
'fStripIDs_col,secLayer;h2csc_clus_hitmap_noise',
cutmask='noise_mon',
type='TH2F',
title='Cluster occupancy, Qmax #leq ' + qmaxCut +
' counts;channel;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=242,
xmin=-49.,
xmax=193.,
ybins=175,
ymin=-17.,
ymax=18.)
cscClusGroup.defineHistogram(
'noStrips,secLayer;h2csc_clus_phicluswidth_noise',
type='TH2F',
cutmask='clus_phiNoise',
title='#phi-cluster width, Qmax #leq ' + qmaxCut +
' counts;# strips;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=48,
xmin=0,
xmax=48,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'noStrips,secLayer;h2csc_clus_etacluswidth_noise',
type='TH2F',
cutmask='clus_etaNoise',
title='#eta-cluster width, Qmax #leq ' + qmaxCut +
' counts;# strips;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=192,
xmin=0,
xmax=192,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'QmaxADC,secLayer;h2csc_clus_qmax',
type='TH2F',
title=
'Cluster peak-strip charge, Qmax;counts;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=400,
xmin=0,
xmax=8000,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'QmaxADC,secLayer;h2csc_clus_qmax_signal',
cutmask='signal_mon',
type='TH2F',
title='Cluster peak-strip charge, Qmax > ' + qmaxCut +
' counts;counts;[sector] + [0.2 #times layer]',
path='Clusters/Shift',
xbins=400,
xmin=0,
xmax=8000,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'QmaxADC,secLayer;h2csc_clus_qmax_noise',
cutmask='noise_mon',
type='TH2F',
title='Cluster peak-strip charge, Qmax #leq ' + qmaxCut +
' counts;counts;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=400,
xmin=0,
xmax=8000,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'QmaxADC,secLayer;h2csc_clus_qmax_signal_EA',
cutmask='sideA',
type='TH2F',
title='EndCap A: Cluster peak-strip charge, Qmax > ' + qmaxCut +
' counts;counts;[sector] + [0.2 #times layer]',
path='Overview/CSCEA/Cluster',
xbins=400,
xmin=0,
xmax=8000,
ybins=90,
ymin=0,
ymax=18)
cscClusGroup.defineHistogram(
'QmaxADC;h1csc_clus_qmax_signal_EA_count',
cutmask='sideA',
type='TH1F',
title='EndCap A: Cluster peak-strip charge, Qmax > ' + qmaxCut +
' counts;counts;entries/20 counts;',
path='Overview/CSCEA/Cluster',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram(
'QmaxADC,secLayer;h2csc_clus_qmax_signal_EC',
cutmask='sideC',
type='TH2F',
title='EndCap C: Cluster peak-strip charge, Qmax > ' + qmaxCut +
' counts;counts;[sector] + [0.2 #times layer]',
path='Overview/CSCEC/Cluster',
xbins=400,
xmin=0,
xmax=8000,
ybins=90,
ymin=0,
ymax=18)
cscClusGroup.defineHistogram(
'QmaxADC;h1csc_clus_qmax_signal_EC_count',
cutmask='sideC',
type='TH1F',
title='EndCap C: Cluster peak-strip charge, Qmax > ' + qmaxCut +
' counts;counts;entries/20 counts;',
path='Overview/CSCEC/Cluster',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram(
'QsumADC,secLayer;h2csc_clus_qsum',
type='TH2F',
title='Cluster charge (Qsum);counts;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=400,
xmin=0,
xmax=8000,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'QsumADC,secLayer;h2csc_clus_qsum_signal',
cutmask='signal_mon',
type='TH2F',
title='Cluster charge(Qsum), Qmax > ' + qmaxCut +
' counts;counts;[sector] + [0.2 #times layer]',
path='Clusters/Shift',
xbins=400,
xmin=0,
xmax=8000,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'QsumADC,secLayer;h2csc_clus_qsum_signal_EA',
cutmask='sideA',
type='TH2F',
title='EndCap A: Cluster charge(Qsum), Qmax > ' + qmaxCut +
' counts;counts;[sector] + [0.2 #times layer]',
path='Overview/CSCEA/Cluster',
xbins=400,
xmin=0,
xmax=8000,
ybins=90,
ymin=0,
ymax=18)
cscClusGroup.defineHistogram(
'QsumADC;h1csc_clus_qsum_signal_EA_count',
cutmask='sideA',
type='TH1F',
title='EndCap A: Cluster charge(Qsum), Qmax > ' + qmaxCut +
' counts;counts;entries/20 counts;',
path='Overview/CSCEA/Cluster',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram(
'QsumADC;h2csc_clus_qsum_signal_EC',
cutmask='sideC',
type='TH1F',
title='EndCap C: Cluster charge(Qsum), Qmax > ' + qmaxCut +
' counts;counts;[sector] + [0.2 #times layer]',
path='Overview/CSCEC/Cluster',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram(
'QsumADC;h1csc_clus_qsum_signal_EC_count',
cutmask='sideC',
type='TH1F',
title='EndCap C: Cluster charge(Qsum), Qmax > ' + qmaxCut +
' counts;counts;entries/20 counts;',
path='Overview/CSCEC/Cluster',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram(
'QsumADC,secLayer;h2csc_clus_qsum_noise',
cutmask='noise_mon',
type='TH2F',
title='Cluster charge(Qsum), Qmax #leq ' + qmaxCut +
' counts;counts;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=400,
xmin=0,
xmax=8000,
ybins=175,
ymin=-17,
ymax=18)
cscClusGroup.defineHistogram(
'clu_time;h1csc_clus_transverse_time',
cutmask='clus_phi',
type='TH1F',
title='#phi-cluster sampling time;ns;entries/ns',
path='Clusters/Expert',
xbins=260,
xmin=-60,
xmax=200)
cscClusGroup.defineHistogram(
'clu_charge_kiloele;h1csc_clus_transverse_charge',
cutmask='clus_phi',
type='TH1F',
title='#phi-cluster charge;counts;entries/count',
path='Clusters/Expert',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram('clu_time;h1csc_clus_transverse_time_signal',
cutmask='clus_phiSig',
type='TH1F',
title='#phi-cluster sampling time, Qmax > ' +
qmaxCut + ' counts;ns;entries/ns',
path='Clusters/Expert',
xbins=260,
xmin=-60,
xmax=200)
cscClusGroup.defineHistogram(
'clu_charge_kiloele;h1csc_clus_transverse_charge_signal',
cutmask='clus_phiSig',
type='TH1F',
title='#phi-cluster charge, Qmax > ' + qmaxCut +
' counts;counts;entries/count',
path='Clusters/Expert',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram(
'clu_time;h1csc_clus_transverse_time_noise',
cutmask='clus_phiNoise',
type='TH1F',
title='#phi-cluster sampling time, Qmax #leq ' + qmaxCut +
' counts;ns;entries/ns',
path='Clusters/Expert',
xbins=260,
xmin=-60,
xmax=200)
cscClusGroup.defineHistogram(
'clu_charge_kiloele;h1csc_clus_transverse_charge_noise',
cutmask='clus_phiNoise',
type='TH1F',
title='#phi-cluster charge, Qmax #leq ' + qmaxCut +
' counts;counts;entries/count',
path='Clusters/Expert',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram(
'clu_time;h1csc_clus_precision_time',
cutmask='clus_eta',
type='TH1F',
title='#eta-cluster sampling time;ns;entries/ns',
path='Clusters/Expert',
xbins=260,
xmin=-60,
xmax=200)
cscClusGroup.defineHistogram(
'clu_charge_kiloele;h1csc_clus_precision_charge',
cutmask='clus_eta',
type='TH1F',
title='eta-cluster charge;counts;entries/count',
path='Clusters/Expert',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram('clu_time;h1csc_clus_precision_time_signal',
cutmask='clus_etaSig',
type='TH1F',
title='#eta-cluster sampling time, Qmax > ' +
qmaxCut + ' counts;ns;entries/ns',
path='Clusters/Shift',
xbins=260,
xmin=-60,
xmax=200)
cscClusGroup.defineHistogram(
'clu_charge_kiloele;h1csc_clus_precision_charge_signal',
cutmask='clus_etaSig',
type='TH1F',
title='#eta-cluster charge, Qmax > ' + qmaxCut +
' counts;counts;entries/count',
path='Clusters/Expert',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram(
'clu_time;h1csc_clus_precision_time_signal_EA',
cutmask='sideA',
type='TH1F',
title='EndCap A: #eta-cluster sampling time, Qmax > ' + qmaxCut +
' counts;ns;entries/ns',
path='Overview/CSCEA/Cluster',
xbins=260,
xmin=-60,
xmax=200)
cscClusGroup.defineHistogram(
'clu_time;h1csc_clus_precision_time_signal_EC',
cutmask='sideC',
type='TH1F',
title='EndCap C: #eta-cluster sampling time, Qmax > ' + qmaxCut +
' counts;ns;entries/ns',
path='Overview/CSCEC/Cluster',
xbins=260,
xmin=-60,
xmax=200)
cscClusGroup.defineHistogram(
'clu_time;h1csc_clus_precision_time_noise',
cutmask='clus_etaNoise',
type='TH1F',
title='#eta-cluster sampling time, Qmax #leq ' + qmaxCut +
' counts;ns;entries/ns',
path='Clusters/Expert',
xbins=260,
xmin=-60,
xmax=200)
cscClusGroup.defineHistogram(
'clu_charge_kiloele;h1csc_clus_precision_charge_noise',
cutmask='clus_etaNoise',
type='TH1F',
title='#eta-cluster charge, Qmax #leq ' + qmaxCut +
' counts;counts;entries/count',
path='Clusters/Expert',
xbins=400,
xmin=0,
xmax=8000)
cscClusGroup.defineHistogram(
'stripsSum_EA_mon;h1csc_clus_totalWidth_EA',
type='TH1F',
title=
'EndCap A: Cluster hits in all EA eta(#eta) & phi(#phi) strips;strips;cluster hits',
path='Overview/CSCEA/Cluster',
xbins=15360,
xmin=1.,
xmax=15361.)
cscClusGroup.defineHistogram(
'stripsSum_EC_mon;h1csc_clus_totalWidth_EC',
type='TH1F',
title=
'EndCap C: Cluster hits in all EC eta(#eta) & phi(#phi) strips;strips;cluster hits',
path='Overview/CSCEC/Cluster',
xbins=15360,
xmin=1.,
xmax=15361.)
cscClusGroup.defineHistogram(
'nPhiClusWidthCnt_mon,nEtaClusWidthCnt_mon;h2csc_clus_eta_vs_phi_cluswidth',
type='TH2F',
title=
'Eta vs. Phi Cluster width correlation;#varphi-cluster width;#eta-cluster width',
path='Clusters/Expert',
xbins=100,
xmin=0,
xmax=100,
ybins=100,
ymin=0,
ymax=100)
cscClusGroup.defineHistogram(
'count_mon,secLayer;h2csc_clus_phicluscount',
cutmask='mphi_true',
type='TH2F',
title='#phi-cluster count;# clusters;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=20,
xmin=0,
xmax=20,
ybins=175,
ymin=-17.,
ymax=18.)
cscClusGroup.defineHistogram(
'scount_mon,secLayer;h2csc_clus_phicluscount_signal',
cutmask='scount_phi_true',
type='TH2F',
title='#phi-cluster count;# clusters;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=20,
xmin=0,
xmax=20,
ybins=175,
ymin=-17.,
ymax=18.)
cscClusGroup.defineHistogram(
'count_diff,secLayer;h2csc_clus_phicluscount_noise',
cutmask='scount_phi_false',
type='TH2F',
title='#phi-cluster count, Qmax #leq ' + qmaxCut +
' counts;# clusters;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=20,
xmin=0,
xmax=20,
ybins=175,
ymin=-17.,
ymax=18.)
cscClusGroup.defineHistogram(
'count_mon,secLayer;h2csc_clus_etacluscount',
cutmask='mphi_false',
type='TH2F',
title='#eta-cluster count;# clusters;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=20,
xmin=0,
xmax=20,
ybins=175,
ymin=-17.,
ymax=18.)
cscClusGroup.defineHistogram(
'scount_mon,secLayer;h2csc_clus_etacluscount_signal',
cutmask='scount_eta_true',
type='TH2F',
title='#eta-cluster count;# clusters;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=20,
xmin=0,
xmax=20,
ybins=175,
ymin=-17.,
ymax=18.)
cscClusGroup.defineHistogram(
'count_diff,secLayer;h2csc_clus_etacluscount_noise',
cutmask='scount_eta_false',
type='TH2F',
title='#eta-cluster count, Qmax #leq ' + qmaxCut +
' counts;# clusters;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=20,
xmin=0,
xmax=20,
ybins=175,
ymin=-17.,
ymax=18.)
cscClusGroup.defineHistogram(
'segNum_mon,sec_mon;h2csc_clus_segmap_signal',
type='TH2F',
title='Segment occupancy, Qmax > ' + qmaxCut +
' counts;segment;[sector] + [0.2 #times layer]',
path='Clusters/Expert',
xbins=16,
xmin=-0.5,
xmax=15.5,
ybins=175,
ymin=-17.,
ymax=18.)
cscClusGroup.defineHistogram(
'numphi_numeta_mon;h1csc_clus_count',
type='TH1F',
title='Clusters per event;no.of clusters;entries',
path='Clusters/Expert',
xbins=26,
xmin=-1,
xmax=25)
cscClusGroup.defineHistogram(
'numphi_numeta_sig_mon;h1csc_clus_count_signal',
type='TH1F',
title='Clusters per event, Qmax > ' + qmaxCut +
' counts;no.of clusters;entries',
path='Clusters/Expert',
xbins=26,
xmin=-1,
xmax=25)
cscClusGroup.defineHistogram('num_num_noise_mon;h1csc_clus_count_noise',
type='TH1F',
title='Clusters per event, Qmax #leq ' +
qmaxCut + ' counts;no.of clusters;entries',
path='Clusters/Expert',
xbins=26,
xmin=-1,
xmax=25)
cscClusGroup.defineHistogram(
'numphi_mon,numeta_mon;h2csc_clus_eta_vs_phi_cluscount',
type='TH2F',
title=
'Eta vs. Phi Cluster count correlation;#varphi-cluster count;#eta-cluster count',
path='Clusters/Expert',
xbins=100,
xmin=0,
xmax=100,
ybins=100,
ymin=0,
ymax=100)
cscClusGroup.defineHistogram(
'numphi_sig_mon,numeta_sig_mon;h2csc_clus_eta_vs_phi_cluscount_signal',
type='TH2F',
title=
'Eta vs. Phi Signal-Cluster count correlation;#varphi-cluster count;#eta-cluster count',
path='Clusters/Expert',
xbins=100,
xmin=0,
xmax=100,
ybins=100,
ymin=0,
ymax=100)
cscClusGroup.defineHistogram(
'numphi_diff_mon,numeta_diff_mon;h2csc_clus_eta_vs_phi_cluscount_noise',
type='TH2F',
title=
'Eta vs. Phi Noise-Cluster count correlation;#varphi-cluster count;#eta-cluster count',
path='Clusters/Expert',
xbins=100,
xmin=0,
xmax=100,
ybins=100,
ymin=0,
ymax=100)
#PRD
cscPrdGroup.defineHistogram(
'spid, secLayer;h2csc_prd_hitmap',
type='TH2F',
title='Hit Occupancy; channel; [sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=242,
xmin=-49.,
xmax=193.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'noStrips,secLayer;h2csc_prd_phicluswidth',
type='TH2F',
cutmask='measphi',
title=
'PRD precision-cluster width;no.of strips;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=48,
xmin=0,
xmax=48,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'noStrips,secLayer;h2csc_prd_etacluswidth',
type='TH2F',
cutmask='measeta',
title=
'PRD precision-cluster width;no.of strips;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=192,
xmin=0,
xmax=192,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram('z,r;h2csc_prd_r_vs_z_hitmap',
type='TH2F',
title='R vs. Z Cluster hitmap;z(mm);R(mm)',
path='PRD/Shift',
xbins=200,
xmin=-10000.,
xmax=10000.,
ybins=40,
ymin=0.,
ymax=4000.)
cscPrdGroup.defineHistogram('y,x;h2csc_prd_y_vs_x_hitmap',
type='TH2F',
title='Y vs. X Cluster hitmap;x(mm);y(mm)',
path='PRD/Shift',
xbins=100,
xmin=-5000.,
xmax=5000.,
ybins=100,
ymin=-5000.,
ymax=5000.)
cscPrdGroup.defineHistogram(
'spid,secLayer;h2csc_prd_hitmap_signal',
cutmask='signal_mon',
type='TH2F',
title='Signal Occupancy;channel;[sector] + [0.2 #times layer]',
path='PRD/Shift',
xbins=242,
xmin=-49.,
xmax=193.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'spid,secLayer;h2csc_prd_hitmap_signal_EC',
cutmask='sideC',
type='TH2F',
title=
'EndCap C: Signal Occupancy;channel;[sector] + [0.2 #times layer]',
path='Overview/CSCEC/PRD',
xbins=242,
xmin=-49.,
xmax=193.,
ybins=85,
ymin=-17.,
ymax=0.)
cscPrdGroup.defineHistogram(
'spid;h1csc_prd_hitmap_signal_EC_count',
cutmask='sideC',
type='TH1F',
title='EndCap C: Signal Occupancy;channel;entries/channel;',
path='Overview/CSCEC/PRD',
xbins=242,
xmin=-49.,
xmax=193.)
thisLabelx = getCSCLabelx("labels_clus_occupancy_signal_EC")
cscPrdGroup.defineHistogram(
'secLayer;h1csc_prd_hitmap_signal_EC_occupancy',
cutmask='sideC',
type='TH1F',
title='EndCap C: Signal Occupancy;;entries/layer',
path='Overview/CSCEC/PRD',
xbins=85,
xmin=-17.,
xmax=0.,
xlabels=thisLabelx) #labels
cscPrdGroup.defineHistogram(
'lumiblock_mon,secLayer;h2csc_prd_occvslb_EC',
cutmask='sideC',
type='TH2F',
title=
'EndCap C: Layer Signal Occupancy Per LB;LB;[sector] + [0.2 #times layer]',
path='Overview/CSCEC/PRD',
xbins=2510,
xmin=-10.,
xmax=2500.,
ybins=85,
ymin=-17.,
ymax=0.)
cscPrdGroup.defineHistogram(
'spid,secLayer;h2csc_prd_hitmap_signal_EA',
cutmask='sideA',
type='TH2F',
title=
'EndCap A: Signal Occupancy;channel;[sector] + [0.2 #times layer]',
path='Overview/CSCEA/PRD',
xbins=242,
xmin=-49.,
xmax=193.,
ybins=90,
ymin=0.,
ymax=18.)
cscPrdGroup.defineHistogram(
'spid;h1csc_prd_hitmap_signal_EA_count',
cutmask='sideA',
type='TH1F',
title='EndCap A: Signal Occupancy;channel;entries/channel;',
path='Overview/CSCEA/PRD',
xbins=242,
xmin=-49.,
xmax=193.)
thisLabelx = getCSCLabelx("labels_clus_occupancy_signal_EA")
cscPrdGroup.defineHistogram(
'secLayer;h1csc_prd_hitmap_signal_EA_occupancy',
cutmask='sideA',
type='TH1F',
title='EndCap A: Signal Occupancy;;entries/layer',
path='Overview/CSCEA/PRD',
xbins=90,
xmin=0.,
xmax=18.,
xlabels=thisLabelx) #labels
cscPrdGroup.defineHistogram(
'lumiblock_mon,secLayer;h2csc_prd_occvslb_EA',
cutmask='sideA',
type='TH2F',
title=
'EndCap A: Layer Signal Occupancy Per LB;LB;[sector] + [0.2 #times layer]',
path='Overview/CSCEA/PRD',
xbins=2510,
xmin=-10.,
xmax=2500.,
ybins=90,
ymin=0.,
ymax=18.)
cscPrdGroup.defineHistogram(
'noStrips,secLayer;h2csc_prd_etacluswidth_signal',
cutmask='clus_etaSig',
type='TH2F',
title=
'PRD precision-cluster width;no.of strips;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=192,
xmin=0.,
xmax=192.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'noStrips,secLayer;h2csc_prd_phicluswidth_signal',
cutmask='clus_phiSig',
type='TH2F',
title=
'PRD precision-cluster width;no.of strips;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=48,
xmin=0.,
xmax=48.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'spid,secLayer;h2csc_prd_hitmap_noise',
cutmask='noise_mon',
type='TH2F',
title='Noise Occupancy;channel;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=242,
xmin=-49.,
xmax=193.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'noStrips,secLayer;h2csc_prd_etacluswidth_noise',
cutmask='clus_etaNoise',
type='TH2F',
title=
'PRD precision-cluster width;no.of strips;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=192,
xmin=0.,
xmax=192.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'noStrips,secLayer;h2csc_prd_phicluswidth_noise',
cutmask='clus_phiNoise',
type='TH2F',
title=
'PRD precision-cluster width;no.of strips;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=48,
xmin=0.,
xmax=48.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'count_mon,secLayer;h2csc_prd_phicluscount',
cutmask='mphi_true',
type='TH2F',
title=
'PRD transverse-cluster count;no.of clusters;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=20,
xmin=0.,
xmax=20.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'scount_mon,secLayer;h2csc_prd_phicluscount_signal',
cutmask='scount_phi_true',
type='TH2F',
title=
'PRD transverse-cluster count;no.of clusters;[sector] + [0.2 #times layer]',
path='PRD/Shift',
xbins=20,
xmin=0.,
xmax=20.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'tmp_val_mon,secLayer;h2csc_prd_phicluscount_noise',
cutmask='mphi_true',
type='TH2F',
title=
'PRD transverse-cluster count;no.of clusters;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=20,
xmin=0.,
xmax=20.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'count_mon,secLayer;h2csc_prd_etacluscount',
cutmask='mphi_false',
type='TH2F',
title=
'PRD precision-cluster count;no.of clusters;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=20,
xmin=0.,
xmax=20.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'scount_mon,secLayer;h2csc_prd_etacluscount_signal',
cutmask='scount_eta_true',
type='TH2F',
title=
'PRD precision-cluster count;no.of clusters;[sector] + [0.2 #times layer]',
path='PRD/Shift',
xbins=20,
xmin=0.,
xmax=20.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'tmp_val_mon,secLayer;h2csc_prd_etacluscount_noise',
cutmask='mphi_false',
type='TH2F',
title=
'PRD precision-cluster count;no.of clusters;[sector] + [0.2 #times layer]',
path='PRD/Expert',
xbins=20,
xmin=0.,
xmax=20.,
ybins=175,
ymin=-17.,
ymax=18.)
cscPrdGroup.defineHistogram(
'numphi_mon,numeta_mon;h2csc_prd_eta_vs_phi_cluscount',
type='TH2F',
title=
'Eta vs. Phi Cluster count correlation;#varphi-cluster count;#eta-cluster count',
path='PRD/Expert',
xbins=100,
xmin=0,
xmax=100,
ybins=100,
ymin=0,
ymax=100)
cscPrdGroup.defineHistogram(
'numphi_sig_mon,numeta_sig_mon;h2csc_prd_eta_vs_phi_cluscount_signal',
type='TH2F',
title=
'Eta vs. Phi Signal-Cluster count correlation;#varphi-cluster count;#eta-cluster count',
path='PRD/Expert',
xbins=100,
xmin=0,
xmax=100,
ybins=100,
ymin=0,
ymax=100)
cscPrdGroup.defineHistogram(
'numphi_diff_mon,numeta_diff_mon;h2csc_prd_eta_vs_phi_cluscount_noise',
type='TH2F',
title=
'Eta vs. Phi Noise-Cluster count correlation;#varphi-cluster count;#eta-cluster count',
path='PRD/Expert',
xbins=100,
xmin=0,
xmax=100,
ybins=100,
ymin=0,
ymax=100)
cscClusGroup.defineHistogram(
'nPhiClusWidthCnt_mon,nEtaClusWidthCnt_mon;h2csc_prd_eta_vs_phi_cluswidth',
type='TH2F',
title=
'Eta vs. Phi Cluster width correlation;#varphi-cluster width;#eta-cluster width',
path='PRD/Expert',
xbins=100,
xmin=0,
xmax=100,
ybins=100,
ymin=0,
ymax=100)
#myGroup.defineHistogram('lb', title='Luminosity Block;lb;Events',
# path='ToFindThem',xbins=1000,xmin=-0.5,xmax=999.5,weight='testweight')
#myGroup.defineHistogram('random', title='LB;x;Events',
# path='ToBringThemAll',xbins=30,xmin=0,xmax=1,opt='kLBNHistoryDepth=10')
#myGroup.defineHistogram('random', title='title;x;y',path='ToBringThemAll',
# xbins=[0,.1,.2,.4,.8,1.6])
##myGroup.defineHistogram('random,pT', type='TH2F', title='title;x;y',path='ToBringThemAll',
# xbins=[0,.1,.2,.4,.8,1.6],ybins=[0,10,30,40,60,70,90])
# TEfficiencies
##myGroup.defineHistogram('pT_passed,pT', type='TEfficiency', title='Test TEfficiency;x;Eff',
# path='AndInTheDarkness', xbins=100, xmin=0.0, xmax=50.0)
#myGroup.defineHistogram('pT_passed,pT,random', type='TEfficiency', title='Test TEfficiency 2D;x;y;Eff',
# path='AndInTheDarkness', xbins=100, xmin=0.0, xmax=50.0,
# ybins=10, ymin=0.0, ymax=2.0)
# # use a cutmask to only fill certain events
#myGroup.defineHistogram('pT;pT_with_cut', title='p_{T};p_{T};Events', path='AndInTheDarkness',
# xbins=50, xmin=0, xmax=50, cutmask='pT_passed')
# make a TTree
#myGroup.defineTree('pT,lb,pT_vec,strvec,str;testtree', path='BindThem',
# treedef='pT/F:lb/i:pT_vec/vector<float>:strvec/vector<string>:str/string')
#anotherGroup.defineHistogram('lbWithFilter',title='Lumi;lb;Events',
# path='top',xbins=1000,xmin=-0.5,xmax=999.5)
#anotherGroup.defineHistogram('run',title='Run Number;run;Events',
# path='top',xbins=1000000,xmin=-0.5,xmax=999999.5)
# Example defining an array of histograms. This is useful if one seeks to create a
# number of histograms in an organized manner. (For instance, one plot for each ASIC
# in the subdetector, and these components are mapped in eta, phi, and layer.) Thus,
# one might have an array of TH1's such as quantity[etaIndex][phiIndex][layerIndex].
# for alg in [exampleMonAlg,anotherExampleMonAlg]:
# Using an array of groups
# topPath = 'OneRing' if alg == exampleMonAlg else ''
# array = helper.addArray([2],alg,'ExampleMonitor', topPath=topPath)
# array.defineHistogram('a,b',title='AB',type='TH2F',path='Eta',
# xbins=10,xmin=0.0,xmax=10.0,
# ybins=10,ymin=0.0,ymax=10.0)
# array.defineHistogram('c',title='C',path='Eta',
# xbins=10,xmin=0.0,xmax=10.0)
# array = helper.addArray([4,2],alg,'ExampleMonitor', topPath=topPath)
# array.defineHistogram('a',title='A',path='EtaPhi',
# xbins=10,xmin=0.0,xmax=10.0)
# Using a map of groups
# layerList = ['layer1','layer2']
# clusterList = ['clusterX','clusterB']
# array = helper.addArray([layerList],alg,'ExampleMonitor', topPath=topPath)
# array.defineHistogram('c',title='C',path='Layer',
# xbins=10,xmin=0,xmax=10.0)
# array = helper.addArray([layerList,clusterList],alg,'ExampleMonitor', topPath=topPath)
# array.defineHistogram('c',title='C',path='LayerCluster',
# xbins=10,xmin=0,xmax=10.0)
### STEP 6 ###
# Finalize. The return value should be a tuple of the ComponentAccumulator
# and the sequence containing the created algorithms. If we haven't called
# any configuration other than the AthMonitorCfgHelper here, then we can
# just return directly (and not create "result" above)
#return helper.result()
# # Otherwise, merge with result object and return
acc = helper.result()
result.merge(acc)
return result
def SCTLorentzMonAlgConfig(inputFlags):
### STEP 1 ###
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'SCTLorentzMonCfg')
### STEP 2 ###
# Adding an algorithm to the helper. Here, we will use the example
# algorithm in the AthenaMonitoring package. Just pass the type to the
# helper. Then, the helper will instantiate an instance and set up the
# base class configuration following the inputFlags. The returned object
# is the algorithm.
from AthenaConfiguration.ComponentFactory import CompFactory
myMonAlg = helper.addAlgorithm(CompFactory.SCTLorentzMonAlg,
'SCTLorentzMonAlg')
# # If for some really obscure reason you need to instantiate an algorithm
# # yourself, the AddAlgorithm method will still configure the base
# # properties and add the algorithm to the monitoring sequence.
# helper.AddAlgorithm(myExistingAlg)
### STEP 3 ###
# Edit properties of a algorithm
myMonAlg.TriggerChain = ''
# myMonAlg.RandomHist = True
# Set InDetTrackSummaryTool to TrackSummaryTool of SCTLorentzMonAlg
from .TrackSummaryToolWorkaround import TrackSummaryToolWorkaround
myMonAlg.TrackSummaryTool = result.popToolsAndMerge(
TrackSummaryToolWorkaround(inputFlags))
### STEP 4 ###
# Add some tools. N.B. Do not use your own trigger decion tool. Use the
# standard one that is included with AthMonitorAlgorithm.
# set up geometry / conditions
from BeamPipeGeoModel.BeamPipeGMConfig import BeamPipeGeometryCfg
result.merge(BeamPipeGeometryCfg(inputFlags))
from AtlasGeoModel.InDetGMConfig import InDetGeometryCfg
result.merge(InDetGeometryCfg(inputFlags))
# # Then, add a tool that doesn't have its own configuration function. In
# # this example, no accumulator is returned, so no merge is necessary.
# from MyDomainPackage.MyDomainPackageConf import MyDomainTool
# myMonAlg.MyDomainTool = MyDomainTool()
# Add a generic monitoring tool (a "group" in old language). The returned
# object here is the standard GenericMonitoringTool.
myMonGroup = helper.addGroup(myMonAlg, "SCTLorentzMonitor", "SCT/GENERAL/")
### STEP 5 ###
# Configure histograms
N_BARRELS = 4
nSides = 2 # 0: Side 0, 1: Side 1
nSurfaces = 2 # 0: 100, 1: 111
surfaceNames = ["_100", "_111"]
surfaceNames2 = ["_100_", "_111_"]
surfaceTitles = ["100 - ", "111 - "]
sideNames = ["_0", "_1"]
for l in range(N_BARRELS):
for iSurface in range(nSurfaces):
for side in range(nSides):
xVar = "phiToWafer_" + str(
l) + surfaceNames[iSurface] + sideNames[side]
yVar = "nStrip_" + str(
l) + surfaceNames[iSurface] + sideNames[side]
histTitle = surfaceTitles[
iSurface] + "Inc. Angle vs nStrips for Layer Side" + str(
l) + str(side)
histName = "h_phiVsNstrips" + surfaceNames2[iSurface] + str(
l) + "Side" + str(side)
myMonGroup.defineHistogram(
varname=xVar + "," + yVar + ";" +
histName, # ; means alias
type="TProfile",
title=histTitle + ";#phi to Wafer;Num of Strips",
path="lorentz", # path cannot be "".
xbins=360,
xmin=-90.,
xmax=90.)
### STEP 6 ###
# Finalize. The return value should be a tuple of the ComponentAccumulator
# and the sequence containing the created algorithms. If we haven't called
# any configuration other than the AthMonitorCfgHelper here, then we can
# just return directly (and not create "result" above)
#return helper.result()
# # Otherwise, merge with result object and return
result.merge(helper.result())
return result
def TRTMonitoringRun3ESD_AlgConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
from TrkConfig.TrackCollectionReadConfig import TrackCollectionReadCfg
result.merge (TrackCollectionReadCfg (inputFlags, 'CombinedInDetTracks'))
result.merge (TrackCollectionReadCfg (inputFlags, 'Tracks'))
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'TRTMonitoringCfg')
from AthenaConfiguration.ComponentFactory import CompFactory
algTRTMonitoringRun3ESD = helper.addAlgorithm(CompFactory.TRTMonitoringRun3ESD_Alg,
'AlgTRTMonitoringRun3')
from AtlasGeoModel.AtlasGeoModelConfig import AtlasGeometryCfg
result.merge(AtlasGeometryCfg(inputFlags))
from IOVDbSvc.IOVDbSvcConfig import addFoldersSplitOnline
result.merge(addFoldersSplitOnline(inputFlags, "TRT","/TRT/Onl/Calib/errors2d","/TRT/Calib/errors2d",className="TRTCond::RtRelationMultChanContainer"))
result.merge(addFoldersSplitOnline(inputFlags, "TRT","/TRT/Onl/Calib/slopes","/TRT/Calib/slopes",className="TRTCond::RtRelationMultChanContainer"))
result.merge(addFoldersSplitOnline(inputFlags, "TRT","/TRT/Onl/Calib/RT","/TRT/Calib/RT",className="TRTCond::RtRelationMultChanContainer"))
result.merge(addFoldersSplitOnline(inputFlags, "TRT","/TRT/Onl/Calib/T0","/TRT/Calib/T0",className="TRTCond::StrawT0MultChanContainer"))
############################## WORKAROUND (START) ##########################
from SCT_Monitoring.TrackSummaryToolWorkaround import TrackSummaryToolWorkaround
algTRTMonitoringRun3ESD.TrackSummaryTool = result.popToolsAndMerge(TrackSummaryToolWorkaround(inputFlags))
############################## WORKAROUND (END) ############################
barrelOrEndcap = ('Barrel', 'EndCap')
beId = ('B', 'E')
sideId = ('A', 'C')
strawMax = (1642, 3840)
iChipMax = (104, 240)
numberOfStacks = (32, 32)
distToStraw = 0.4
nPhiBins = 360
minTRTHits = 10
for ibe in range(2):
oss_distance = distToStraw
distance = str(oss_distance)
regionTag = ' (' + barrelOrEndcap[ibe] + ')'
for i in range(numberOfStacks[ibe]*2):
trackGroup = helper.addGroup(algTRTMonitoringRun3ESD,'TRTTrackHistograms{0}{1}'.format(ibe,i))
nBarrelModules = 0
if ibe == 0:
if i < numberOfStacks[ibe]:
nBarrelModules = i + 1
oss = 'TRT/Barrel/Stack{0}A'.format(nBarrelModules)
elif i >= numberOfStacks[ibe]:
nBarrelModules = i + 1 - 32
oss = 'TRT/Barrel/Stack{0}C'.format(nBarrelModules)
elif ibe == 1:
if i < numberOfStacks[ibe]:
nBarrelModules = i + 1
oss = 'TRT/EndcapA/Sector{0}'.format(nBarrelModules)
elif i >= numberOfStacks[ibe]:
nBarrelModules = i + 1 - 32
oss = 'TRT/EndcapC/Sector{0}'.format(nBarrelModules)
trackGroup.defineHistogram('HitTronTMapS_x,HitTronTMapS_y;hHitTronTMapS',type='TProfile',title='Mean Trailing Edge on Track: Straws;Straw Number in Stack;Time (ns)',path=oss,xbins=strawMax[ibe],xmin=0,xmax=strawMax[ibe],duration='run')
trackGroup.defineHistogram('HitToTonTMapS_x,HitToTonTMapS_y;hHitToTonTMapS',type='TProfile',title='Mean ToT on Track: Straws;Straw Number in Stack;Time (ns)',path=oss,xbins=strawMax[ibe],xmin=0,xmax=strawMax[ibe],duration='run')
trackGroup.defineHistogram('ValidRawDriftTimeonTrkS_x,ValidRawDriftTimeonTrkS_y;hValidRawDriftTimeonTrk',type='TProfile',title='Valid Raw Drift Time on Track: Straws;Straw Number in Stack;Time (ns)',path=oss,xbins=strawMax[ibe],xmin=0,xmax=strawMax[ibe],duration='run')
trackGroup.defineHistogram('HitTronTwEPCMapS_x,HitTronTwEPCMapS_y;hHitTronTwEPCMapS',type='TProfile',title='Mean Trailing Edge on Track (with Event Phase Correction): Straws;Straw Number in Stack;Time (ns)',path=oss,xbins=strawMax[ibe],xmin=0,xmax=strawMax[ibe],duration='run')
trackGroup.defineHistogram('HitTronTMapC_x,HitTronTMapC_y;hHitTronTMapC',type='TProfile',title='Mean Trailing Edge on Track: Chips;Chip Number in Stack;Time (ns)',path=oss,xbins=iChipMax[ibe],xmin=0,xmax=iChipMax[ibe],duration='run')
trackGroup.defineHistogram('HitToTonTMapC_x,HitToTonTMapC_y;hHitToTonTMapC',type='TProfile',title='Chip Number in Stack;Time (ns);Chip Number in Stack;Time (ns)',path=oss,xbins=iChipMax[ibe],xmin=0,xmax=iChipMax[ibe],duration='run')
trackGroup.defineHistogram('ValidRawDriftTimeonTrkC_x,ValidRawDriftTimeonTrkC_y;hValidRawDriftTimeonTrkC',type='TProfile',title='Valid Raw Drift Time on Track: Chips;Chip Number in Stack;Time (ns)',path=oss,xbins=iChipMax[ibe],xmin=0,xmax=iChipMax[ibe],duration='run')
trackGroup.defineHistogram('HitTronTwEPCMapC_x,HitTronTwEPCMapC_y;hHitTronTwEPCMapC',type='TProfile',title='Mean Trailing Edge on Track (with Event Phase Correction): Chips;Chip Number in Stack;Time (ns)',path=oss,xbins=iChipMax[ibe],xmin=0,xmax=iChipMax[ibe],duration='run')
# Arrays for Aging
gas = ('in_A', 'in_B', 'out_A', 'out_B')
Mod = ('1', '2', '3', 'shortP', 'shortN')
for ibe in range(2):
shiftTrackGroup = helper.addGroup(algTRTMonitoringRun3ESD,'ShiftTRTTrackHistograms{0}'.format(ibe))
regionTag = ' (' + barrelOrEndcap[ibe] + ')'
if ibe == 0:
shiftTrackGroup.defineHistogram('EvtPhase;hEvtPhase',type='TH1F',title='Event Phase Correction Factor;Event Phase (ns);Entries',path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-50,xmax=50)
shiftTrackGroup.defineHistogram('EvtPhaseVsTrig_x,EvtPhaseVsTrig_y;hEvtPhaseVsTrig',type='TH2F',title='Event Phase vs L1 Trigger Item;Event Phase (ns);L1 Trigger Item',path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=300,xmin=-200,xmax=100,ybins=256,ymin=-0.5,ymax=255.5,duration='run')
shiftTrackGroup.defineHistogram('EvtPhaseDetPhi_B_x,EvtPhaseDetPhi_B_y;hEvtPhaseDetPhi',type='TProfile',title='Event Phase vs #phi (2D){0};#phi (deg);Event Phase from Tracks per Event'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=nPhiBins,xmin=0.,xmax=360.,duration='run')
shiftTrackGroup.defineHistogram('RtRelation_B_x,RtRelation_B_y;hrtRelation',type='TH2F',title='R(t) Relation for Xenon Straws{0};Measured Leading Edge (ns);Track-to-Wire Distance (mm)'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-12.5,xmax=81.25,ybins=50,ymin=0.,ymax=2.5,duration='run')
shiftTrackGroup.defineHistogram('NumHoTDetPhi_B_x,NumHoTDetPhi_B_y;hNumHoTDetPhi',type='TProfile',title='Number of Hits per Track with {0} mm Cut vs #phi{1};#phi (deg);Hits per Track, TRT Hits >= {2}'.format(distance,regionTag,minTRTHits),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=nPhiBins,xmin=0.,xmax=360.,duration='run')
shiftTrackGroup.defineHistogram('TronTDist_B;hTronTDist',type='TH1F',title='Trailing Edge Distribution on Track for Xenon Straws{0};Trailing Edge (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=26,xmin=-0.5,xmax=80.75,duration='run')
shiftTrackGroup.defineHistogram('DriftTimeonTrkDist_B;hDriftTimeonTrkDist',type='TH1F',title='Drift Time Distribution on Track for Xenon Straws{0};Drift Time (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=32,xmin=0,xmax=100,duration='run')
shiftTrackGroup.defineHistogram('NumTrksDetPhi_B;hNumTrksDetPhi_B',type='TH1F',title='Number of Reconstructed Tracks vs #phi (2D){0};#phi (deg);Number of Tracks'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=60,xmin=0,xmax=360,duration='run')
shiftTrackGroup.defineHistogram('DriftTimeonTrkDist_B_Ar;hDriftTimeonTrkDist_Ar',type='TH1F',title='Drift Time Distribution on Track for Argon Straws{0};Drift Time (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=32,xmin=0,xmax=100,duration='run')
shiftTrackGroup.defineHistogram('TronTDist_B_Ar;hTronTDist_Ar',type='TH1F',title='Trailing Edge Distribution on Track for Argon Straws{0};Trailing Edge (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=26,xmin=-0.5,xmax=80.75,duration='run')
shiftTrackGroup.defineHistogram('RtRelation_B_Ar_x,RtRelation_B_Ar_y;hrtRelation_Ar',type='TH2F',title='R(t) Relation for Argon Straws{0};Measured Leading Edge (ns);Track-to-Wire Distance (mm)'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-12.5,xmax=81.25,ybins=50,ymin=0,ymax=2.5,duration='run')
shiftTrackGroup.defineHistogram('Pull_Biased_Barrel;hPull_Biased_Barrel',type='TH1F',title='Biased Track Pulls for Barrel Hits;Pulls;Entries',path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='run')
shiftTrackGroup.defineHistogram('Residual_B_Ar;hResidual_Ar',type='TH1F',title='Residuals for Argon Straws{0};Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='lowStat')
shiftTrackGroup.defineHistogram('Residual_B_Ar;hResidual_Ar',type='TH1F',title='Residuals for Argon Straws{0};Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='run')
shiftTrackGroup.defineHistogram('Residual_B_Ar_20GeV;hResidual_Ar_20GeV',type='TH1F',title='Residuals for Argon Straws{0} (After 20GeV pT cut);Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='run')
shiftTrackGroup.defineHistogram('AvgTroTDetPhi_B_Ar_x,AvgTroTDetPhi_B_Ar_y;hAvgTroTDetPhi_Ar',type='TProfile',title='Avg. Trailing Edge on Track vs #phi (2D) for Argon{0};#phi (deg);Trailing Edge (ns)'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=nPhiBins,xmin=0,xmax=360,duration='run')
shiftTrackGroup.defineHistogram('TimeResidual_B_Ar;hTimeResidual_Ar',type='TH1F',title='Time Residuals for Argon Straws{0};Time Residual (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-20,xmax=20,duration='run')
shiftTrackGroup.defineHistogram('WireToTrkPosition_B_Ar;hWireToTrkPosition_Ar',type='TH1F',title='Track-to-Wire Distance for Argon{0};Track-to-Wire Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=100,xmin=-5,xmax=5,duration='run')
shiftTrackGroup.defineHistogram('Residual_B;hResidual_Xe',type='TH1F',title='Residuals for Xenon Straws{0};Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='lowStat')
shiftTrackGroup.defineHistogram('Residual_B;hResidual_Xe',type='TH1F',title='Residuals for Xenon Straws{0};Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='run')
shiftTrackGroup.defineHistogram('Residual_B_20GeV;hResidual_Xe_20GeV',type='TH1F',title='Residuals for Xenon Straws{0} (After 20GeV pT cut);Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='run')
shiftTrackGroup.defineHistogram('TimeResidual_B;hTimeResidual',type='TH1F',title='Time Residuals for Xenon Straws{0};Time Residual (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-20,xmax=20,duration='run')
shiftTrackGroup.defineHistogram('WireToTrkPosition_B;hWireToTrkPosition',type='TH1F',title='Track-to-Wire Distance for Xenon{0};Track-to-Wire Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=100,xmin=-5,xmax=5,duration='run')
shiftTrackGroup.defineHistogram('AvgTroTDetPhi_B_x,AvgTroTDetPhi_B_y;hAvgTroTDetPhi',type='TProfile',title='Avg. Trailing Edge on Track vs #phi (2D) for Xenon{0};#phi (deg);Trailing Edge (ns)'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=nPhiBins,xmin=0,xmax=360,duration='run')
elif ibe == 1:
shiftTrackGroup.defineHistogram('Pull_Biased_EndCap;hPull_Biased_EndCap',type='TH1F',title='Biased Track Pulls for EndCap Hits;Pulls;Entries',path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='run')
for iside in range(2):
regionTag = ' (' + beId[ibe] + sideId[iside] + ')'
shiftTrackEndcapGroup = helper.addGroup(algTRTMonitoringRun3ESD,'ShiftTRTTrackHistograms{0}{1}'.format(ibe,iside))
shiftTrackEndcapGroup.defineHistogram('EvtPhaseDetPhi_E_x,EvtPhaseDetPhi_E_y;hEvtPhaseDetPhi_{0}'.format(sideId[iside]),type='TProfile',title='Event Phase vs #phi (2D){0};#phi (deg);Event Phase from Tracks per Event'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=nPhiBins,xmin=0,xmax=360,duration='run')
shiftTrackEndcapGroup.defineHistogram('RtRelation_E_x,RtRelation_E_y;hrtRelation_{0}'.format(sideId[iside]),type='TH2F',title='R(t) Relation for Xenon Straws{0};Measured Leading Edge (ns);Track-to-Wire Distance (mm)'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-12.5,xmax=81.25,ybins=50,ymin=0,ymax=2.5,duration='run')
shiftTrackEndcapGroup.defineHistogram('NumHoTDetPhi_E_x,NumHoTDetPhi_E_y;hNumHoTDetPhi_{0}'.format(sideId[iside]),type='TProfile',title='Number of Hits per Track with {0} mm Cut vs #phi{1};#phi (deg);Hits per Track, TRT Hits> = {2}'.format(distance,regionTag,minTRTHits),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=nPhiBins,xmin=0,xmax=360,duration='run')
shiftTrackEndcapGroup.defineHistogram('TronTDist_E;hTronTDist_{0}'.format(sideId[iside]),type='TH1F',title='Trailing Edge Distribution on Track for Xenon Straws{0};Trailing Edge (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=26,xmin=-0.5,xmax=80.75,duration='run')
shiftTrackEndcapGroup.defineHistogram('DriftTimeonTrkDist_E;hDriftTimeonTrkDist_{0}'.format(sideId[iside]),type='TH1F',title='Drift Time Distribution on Track for Xenon Straws{0};Drift Time (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=32,xmin=0,xmax=100,duration='run')
shiftTrackEndcapGroup.defineHistogram('NumTrksDetPhi_E;hNumTrksDetPhi_{0}'.format(sideId[iside]),type='TH1F',title='Number of Reconstructed Tracks vs #phi (2D){0};#phi (deg);Number of Tracks'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=60,xmin=0,xmax=360,duration='run')
shiftTrackEndcapGroup.defineHistogram('Residual_E;hResidual_Xe_{0}'.format(sideId[iside]),type='TH1F',title='Residuals for Xenon Straws{0};Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='lowStat')
shiftTrackEndcapGroup.defineHistogram('Residual_E;hResidual_Xe_{0}'.format(sideId[iside]),type='TH1F',title='Residuals for Xenon Straws{0};Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='run')
shiftTrackEndcapGroup.defineHistogram('Residual_E_20GeV;hResidual_Xe_{0}_20GeV'.format(sideId[iside]),type='TH1F',title='Residuals for Xenon Straws{0} (After 20GeV pT cut);Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='run')
shiftTrackEndcapGroup.defineHistogram('TimeResidual_E;hTimeResidual_{0}'.format(sideId[iside]),type='TH1F',title='Time Residuals for Xenon Straws{0};Time Residual (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-20,xmax=20,duration='run')
shiftTrackEndcapGroup.defineHistogram('TronTDist_E_Ar;hTronTDist_Ar_{0}'.format(sideId[iside]),type='TH1F',title='Trailing Edge Distribution on Track for Argon Straws{0};Trailing Edge (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=26,xmin=-0.5,xmax=80.75,duration='run')
shiftTrackEndcapGroup.defineHistogram('AvgTroTDetPhi_E_Ar_x,AvgTroTDetPhi_E_Ar_y;hAvgTroTDetPhi_Ar_{0}'.format(sideId[iside]),type='TProfile',title='Avg. Trailing Edge on Track vs #phi (2D) for Argon{0};#phi (deg);Trailing Edge (ns)'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=nPhiBins,xmin=0,xmax=360,duration='run')
shiftTrackEndcapGroup.defineHistogram('RtRelation_E_Ar_x,RtRelation_E_Ar_y;hrtRelation_Ar_{0}'.format(sideId[iside]),type='TH2F',title='R(t) Relation for Argon Straws{0};Measured Leading Edge (ns);Track-to-Wire Distance (mm)'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-12.5,xmax=81.25,ybins=50,ymin=0,ymax=2.5,duration='run')
shiftTrackEndcapGroup.defineHistogram('DriftTimeonTrkDist_E_Ar;hDriftTimeonTrkDist_Ar_{0}'.format(sideId[iside]),type='TH1F',title='Drift Time Distribution on Track for Argon Straws{0};Drift Time (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=32,xmin=0,xmax=100,duration='run')
shiftTrackEndcapGroup.defineHistogram('Residual_E_Ar;hResidual_Ar_{0}'.format(sideId[iside]),type='TH1F',title='Residuals for Argon Straws{0};Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='lowStat')
shiftTrackEndcapGroup.defineHistogram('Residual_E_Ar;hResidual_Ar_{0}'.format(sideId[iside]),type='TH1F',title='Residuals for Argon Straws{0};Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='run')
shiftTrackEndcapGroup.defineHistogram('Residual_E_Ar_20GeV;hResidual_Ar_{0}_20GeV'.format(sideId[iside]),type='TH1F',title='Residuals for Argon Straws{0} (After 20GeV pT cut);Hit-to-Track Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-2.5,xmax=2.5,duration='run')
shiftTrackEndcapGroup.defineHistogram('TimeResidual_E_Ar;hTimeResidual_Ar_{0}'.format(sideId[iside]),type='TH1F',title='Time Residuals for Argon Straws{0};Time Residual (ns);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=200,xmin=-20,xmax=20,duration='run')
shiftTrackEndcapGroup.defineHistogram('WireToTrkPosition_E_Ar;hWireToTrkPosition_Ar_{0}'.format(sideId[iside]),type='TH1F',title='Track-to-Wire Distance for Argon{0};Track-to-Wire Distance (mm);Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=100,xmin=-5,xmax=5,duration='run')
shiftTrackEndcapGroup.defineHistogram('WireToTrkPosition_E;hWireToTrkPosition_{0}'.format(sideId[iside]),type='TH1F',title='Track-to-Wire Distance for Xenon{0};Track-to-Wire Distance (mm);Norm. Entries'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=100,xmin=-5,xmax=5,duration='run')
shiftTrackEndcapGroup.defineHistogram('AvgTroTDetPhi_E_x,AvgTroTDetPhi_E_y;hAvgTroTDetPhi_{0}'.format(sideId[iside]),type='TProfile',title='Avg. Trailing Edge on Track vs #phi (2D) for Xenon{0};#phi (deg);Trailing Edge (ns)'.format(regionTag),path='TRT/Shift/{0}'.format(barrelOrEndcap[ibe]),xbins=nPhiBins,xmin=0,xmax=360,duration='run')
#Initialize Aging plots
for iL in range(5):
for iSide in range(2):
if ibe == 0:
if iL < 3:
agingGroup = helper.addGroup(algTRTMonitoringRun3ESD,'TRTAgingHistograms0{0}{1}'.format(iL,iSide))
agingGroup.defineHistogram('Trackz_All;trackz_m{0}_{1}_All'.format(Mod[iL],sideId[iSide]),type='TH1F',title='Number All Hits side {0} Layer {1};z [mm];Number of Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-750.,xmax=750.,duration='run')
agingGroup.defineHistogram('Trackz_All;trackz_m{0}_{1}_All'.format(Mod[iL],sideId[iSide]),type='TH1F',title='Number All Hits side {0} Layer {1};z [mm];Number of Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-750.,xmax=750.,duration='lowStat')
agingGroup.defineHistogram('Trackz_HT;trackz_m{0}_{1}_HT'.format(Mod[iL],sideId[iSide]),type='TH1F',title='Number HT Hits side {0} Layer {1};z [mm];Number of HT Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-750.,xmax=750.,duration='run')
agingGroup.defineHistogram('Trackz_HT;trackz_m{0}_{1}_HT'.format(Mod[iL],sideId[iSide]),type='TH1F',title='Number HT Hits side {0} Layer {1};z [mm];Number of HT Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-750.,xmax=750.,duration='lowStat')
if iL == 3:
agingGroup = helper.addGroup(algTRTMonitoringRun3ESD,'TRTAgingHistograms03{0}'.format(iSide))
agingGroup.defineHistogram('Trackz_All;trackz_m1_{0}_All_{1}'.format(sideId[iSide],Mod[iL]),type='TH1F',title='Number All Hits side {0} Layer 1 {1};z [mm];Number of Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=0.,xmax=725.,duration='run')
agingGroup.defineHistogram('Trackz_All;trackz_m1_{0}_All_{1}'.format(sideId[iSide],Mod[iL]),type='TH1F',title='Number All Hits side {0} Layer 1 {1};z [mm];Number of Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=0.,xmax=725.,duration='lowStat')
agingGroup.defineHistogram('Trackz_HT;trackz_m1_{0}_HT_{1}'.format(sideId[iSide],Mod[iL]),type='TH1F',title='Number HT Hits side {0} Layer 1 {1};z [mm];Number of HT Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=0.,xmax=725.,duration='run')
agingGroup.defineHistogram('Trackz_HT;trackz_m1_{0}_HT_{1}'.format(sideId[iSide],Mod[iL]),type='TH1F',title='Number HT Hits side {0} Layer 1 {1};z [mm];Number of HT Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=0.,xmax=725.,duration='lowStat')
if iL == 4:
agingGroup = helper.addGroup(algTRTMonitoringRun3ESD,'TRTAgingHistograms04{0}'.format(iSide))
agingGroup.defineHistogram('Trackz_All;trackz_m1_{0}_All_{1}'.format(sideId[iSide],Mod[iL]),type='TH1F',title='Number All Hits side {0} Layer 1 {1};z [mm];Number of Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-725.,xmax=0.,duration='run')
agingGroup.defineHistogram('Trackz_All;trackz_m1_{0}_All_{1}'.format(sideId[iSide],Mod[iL]),type='TH1F',title='Number All Hits side {0} Layer 1 {1};z [mm];Number of Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-725.,xmax=0.,duration='lowStat')
agingGroup.defineHistogram('Trackz_HT;trackz_m1_{0}_HT_{1}'.format(sideId[iSide],Mod[iL]),type='TH1F',title='Number HT Hits side {0} Layer 1 {1};z [mm];Number of HT Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-725.,xmax=0.,duration='run')
agingGroup.defineHistogram('Trackz_HT;trackz_m1_{0}_HT_{1}'.format(sideId[iSide],Mod[iL]),type='TH1F',title='Number HT Hits side {0} Layer 1 {1};z [mm];Number of HT Hits'.format(sideId[iSide],Mod[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=-725.,xmax=0.,duration='lowStat')
elif ibe == 1:
# prevent double booking of histograms here
if iL < 4:
agingGroup = helper.addGroup(algTRTMonitoringRun3ESD,'TRTAgingHistograms1{0}{1}'.format(iL,iSide))
agingGroup.defineHistogram('Trackr_All;trackr_E{0}_{1}_All'.format(sideId[iSide],gas[iL]),type='TH1F',title='Number All Hits E{0} {1};r [mm];Number of Hits'.format(sideId[iSide],gas[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=644.,xmax=1004.,duration='run')
agingGroup.defineHistogram('Trackr_All;trackr_E{0}_{1}_All'.format(sideId[iSide],gas[iL]),type='TH1F',title='Number All Hits E{0} {1};r [mm];Number of Hits'.format(sideId[iSide],gas[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=644.,xmax=1004.,duration='lowStat')
agingGroup.defineHistogram('Trackr_HT;trackr_E{0}_{1}_HT'.format(sideId[iSide],gas[iL]),type='TH1F',title='Number HT Hits E{0} {1};r [mm];Number of HT Hits'.format(sideId[iSide],gas[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=644.,xmax=1004.,duration='run')
agingGroup.defineHistogram('Trackr_HT;trackr_E{0}_{1}_HT'.format(sideId[iSide],gas[iL]),type='TH1F',title='Number HT Hits E{0} {1};r [mm];Number of HT Hits'.format(sideId[iSide],gas[iL]),path='TRT/Aging/{0}'.format(barrelOrEndcap[ibe]),xbins=30,xmin=644.,xmax=1004.,duration='lowStat')
acc = helper.result()
result.merge(acc)
return result
def PprMonitoringConfig(inputFlags):
'''Function to configure LVL1 Ppr algorithm in the monitoring system.'''
import math
# get the component factory - used for getting the algorithms
from AthenaConfiguration.ComponentFactory import CompFactory
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
# any things that need setting up for job e.g.
#from AtlasGeoModel.AtlasGeoModelConfig import AtlasGeometryCfg
#result.merge(AtlasGeometryCfg(inputFlags))
# make the athena monitoring helper
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'PprMonitoringCfg')
# get any algorithms
PprMonAlg = helper.addAlgorithm(CompFactory.PprMonitorAlgorithm,
'PprMonAlg')
# add any steering
groupName = 'PprMonitor' # the monitoring group name is also used for the package name
PprMonAlg.PackageName = groupName
# Steering properties
threshADC = 50
PprMonAlg.TT_ADC_HitMap_Thresh = threshADC # ADC cut for hit maps
# Histogram paths
mainDir = 'L1Calo'
trigPath = 'PPM/'
# add monitoring algorithm to group, with group name and main directory
myGroup = helper.addGroup(PprMonAlg, groupName, mainDir)
# Trigger tower plots: eta-phi granularity
etabins = [
-4.9, -4.475, -4.050, -3.625, -3.2, -3.1, -2.9, -2.7, -2.5, -2.4, -2.3,
-2.2, -2.1, -2.0, -1.9, -1.8, -1.7, -1.6, -1.5, -1.4, -1.3, -1.2, -1.1,
-1.0, -0.9, -0.8, -0.7, -0.6, -0.5, -0.4, -0.3, -0.2, -0.1, 0.0, 0.1,
0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5,
1.6, 1.7, 1.8, 1.9, 2.0, 2.1, 2.2, 2.3, 2.4, 2.5, 2.7, 2.9, 3.1, 3.2,
3.625, 4.050, 4.475, 4.9
]
phibins = 64
phimin = 0
phimax_2d = 64
phimax_1d = 2. * math.pi
maxEnergyRange = 256
#######################
# PPM inputs (LUT-CP) #
#######################
histPath = trigPath + '/LUT-CP/Distributions'
# EM distributions
myGroup.defineHistogram(
'etaTT_EM;h_ppm_em_1d_tt_lutcp_Eta',
title='EM LUT-CP: Distribution of peak in #eta; #eta',
type='TH1F',
path=histPath,
xbins=etabins,
cutmask='mask_EM_cpET_0_noPhi')
myGroup.defineHistogram(
'phiTT_1d_EM;h_ppm_em_1d_tt_lutcp_Phi',
title='EM LUT-CP: Distribution of peak in #phi; #phi',
type='TH1F',
path=histPath,
xbins=phibins,
xmin=phimin,
xmax=phimax_1d,
cutmask='mask_EM_cpET_0_phiBins')
myGroup.defineHistogram(
'cpET_EM;h_ppm_em_1d_tt_lutcp_Et',
title='EM LUT-CP: Distribution of peak; EM LUT peak [GeV/2]',
type='TH1F',
path=histPath,
xbins=maxEnergyRange - 1,
xmin=1,
xmax=maxEnergyRange,
cutmask='mask_EM_cpET_0_noPhi')
# HAD distributions
myGroup.defineHistogram(
'etaTT_HAD;h_ppm_had_1d_tt_lutcp_Eta',
title='HAD LUT-CP: Distribution of peak in #eta; #eta',
type='TH1F',
path=histPath,
xbins=etabins,
cutmask='mask_HAD_cpET_0_noPhi')
myGroup.defineHistogram(
'phiTT_1d_HAD;h_ppm_had_1d_tt_lutcp_Phi',
title='HAD LUT-CP: Distribution of peak in #phi; #phi',
type='TH1F',
path=histPath,
xbins=phibins,
xmin=phimin,
xmax=phimax_1d,
cutmask='mask_HAD_cpET_0_phiBins')
myGroup.defineHistogram(
'cpET_HAD;h_ppm_had_1d_tt_lutcp_Et',
title='HAD LUT-CP: Distribution of peak; HAD LUT peak [GeV/2]',
type='TH1F',
path=histPath,
xbins=maxEnergyRange - 1,
xmin=1,
xmax=maxEnergyRange,
cutmask='mask_HAD_cpET_0_noPhi')
# Eta-phi maps
histPath = trigPath + '/LUT-CP/EtaPhiMaps'
myGroup.defineHistogram(
'etaTT_EM,phiTT_2d_EM;h_ppm_em_2d_etaPhi_tt_lutcp_AverageEt',
title='EM Average LUT-CP Et for Et > 5 GeV/2',
type='TH2F',
path=histPath,
xbins=etabins,
ybins=phibins,
ymin=phimin,
ymax=phimax_2d,
cutmask='mask_EM_cpET_5_phiBins',
weight='cpET_EM')
myGroup.defineHistogram(
'etaTT_HAD,phiTT_2d_HAD;h_ppm_had_2d_etaPhi_tt_lutcp_AverageEt',
title='HAD Average LUT-CP Et for Et > 5 GeV/2',
type='TH2F',
path=histPath,
xbins=etabins,
ybins=phibins,
ymin=phimin,
ymax=phimax_2d,
cutmask='mask_HAD_cpET_5_phiBins',
weight='cpET_HAD')
########################
# PPM inputs (LUT-JEP) #
########################
histPath = trigPath + '/LUT-JEP/Distributions'
# EM distributions
myGroup.defineHistogram('etaTT_EM;h_ppm_em_1d_tt_lutjep_Eta',
title='EM LUT-JEP: Distribution of peak in #eta',
type='TH1F',
path=histPath,
xbins=etabins,
cutmask='mask_EM_jepET_0_noPhi')
myGroup.defineHistogram(
'phiTT_1d_EM;h_ppm_em_1d_tt_lutjep_Phi',
title='EM LUT-JEP: Distribution of peak in #phi; #phi',
type='TH1F',
path=histPath,
xbins=phibins,
xmin=phimin,
xmax=phimax_1d,
cutmask='mask_EM_jepET_0_phiBins')
myGroup.defineHistogram(
'jepET_EM;h_ppm_em_1d_tt_lutjep_Et',
title='EM LUT-JEP: Distribution of peak; EM LUT peak [GeV]',
type='TH1F',
path=histPath,
xbins=maxEnergyRange - 1,
xmin=1,
xmax=maxEnergyRange,
cutmask='mask_EM_jepET_0_noPhi')
# HAD distributions
myGroup.defineHistogram('etaTT_HAD;h_ppm_had_1d_tt_lutjep_Eta',
title='HAD LUT-JEP: Distribution of peak in #eta',
type='TH1F',
path=histPath,
xbins=etabins,
cutmask='mask_HAD_jepET_0_noPhi')
myGroup.defineHistogram(
'phiTT_1d_HAD;h_ppm_had_1d_tt_lutjep_Phi',
title='HAD LUT-JEP: Distribution of peak in #phi; #phi',
type='TH1F',
path=histPath,
xbins=phibins,
xmin=phimin,
xmax=phimax_1d,
cutmask='mask_HAD_jepET_0_phiBins')
myGroup.defineHistogram(
'jepET_HAD;h_ppm_had_1d_tt_lutjep_Et',
title='HAD LUT-JEP: Distribution of peak; HAD LUT peak [GeV]',
type='TH1F',
path=histPath,
xbins=maxEnergyRange - 1,
xmin=1,
xmax=maxEnergyRange,
cutmask='mask_HAD_jepET_0_noPhi')
# Eta-phi maps
histPath = trigPath + '/LUT-JEP/EtaPhiMaps'
myGroup.defineHistogram(
'etaTT_EM,phiTT_2d_EM;h_ppm_em_2d_etaPhi_tt_lutjep_AverageEt',
title='EM Average LUT-JEP Et for Et > 5 GeV',
type='TH2F',
path=histPath,
xbins=etabins,
ybins=phibins,
ymin=phimin,
ymax=phimax_2d,
cutmask='mask_EM_jepET_5_phiBins',
weight='jepET_EM')
myGroup.defineHistogram(
'etaTT_HAD,phiTT_2d_HAD;h_ppm_had_2d_etaPhi_tt_lutjep_AverageEt',
title='HAD Average LUT-JEP Et for Et > 5 GeV',
type='TH2F',
path=histPath,
xbins=etabins,
ybins=phibins,
ymin=phimin,
ymax=phimax_2d,
cutmask='mask_HAD_jepET_5_phiBins',
weight='jepET_HAD')
####################
# PPM inputs (ADC) #
####################
histPath = trigPath + '/ADC/EtaPhiMaps'
# EM tower maps
myGroup.defineHistogram(
'etaTT_EM,phiTT_2d_EM;h_ppm_em_2d_etaPhi_tt_adc_HitMap',
title='#eta - #phi map of EM FADC > ' + str(threshADC) +
' for triggered timeslice; Tower #eta; Tower #phi',
type='TH2F',
path=histPath,
xbins=etabins,
ybins=phibins,
ymin=phimin,
ymax=phimax_2d,
cutmask='mask_EM_timeslice')
myGroup.defineHistogram(
'etaTT_EM,phiTT_2d_EM;h_ppm_em_2d_etaPhi_tt_adc_ProfileHitMap',
title='#eta - #phi profile map of EM FADC > ' + str(threshADC) +
' for triggered timeslice; Tower #eta; Tower #phi',
type='TH2F',
path=histPath,
xbins=etabins,
ybins=phibins,
ymin=phimin,
ymax=phimax_2d,
cutmask='mask_EM_timeslice',
weight='emTT_ADC')
# HAD tower maps
myGroup.defineHistogram(
'etaTT_HAD,phiTT_2d_HAD;h_ppm_had_2d_etaPhi_tt_adc_HitMap',
title='#eta - #phi map of HAD FADC > ' + str(threshADC) +
' for triggered timeslice; Tower #eta; Tower #phi',
type='TH2F',
path=histPath,
xbins=etabins,
ybins=phibins,
ymin=phimin,
ymax=phimax_2d,
cutmask='mask_HAD_timeslice')
myGroup.defineHistogram(
'etaTT_HAD,phiTT_2d_HAD;h_ppm_had_2d_etaPhi_tt_adc_ProfileHitMap',
title='#eta - #phi profile map of HAD FADC > ' + str(threshADC) +
' for triggered timeslice; Tower #eta; Tower #phi',
type='TH2F',
path=histPath,
xbins=etabins,
ybins=phibins,
ymin=phimin,
ymax=phimax_2d,
cutmask='mask_HAD_timeslice',
weight='hadTT_ADC')
acc = helper.result()
result.merge(acc)
return result
def TileRawChannelNoiseMonitoringConfig(flags, **kwargs):
''' Function to configure TileRawChannelNoiseMonitorAlgorithm algorithm in the monitoring system.'''
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
from TileRecUtils.TileDQstatusConfig import TileDQstatusAlgCfg
result.merge(TileDQstatusAlgCfg(flags))
from TileGeoModel.TileGMConfig import TileGMCfg
result.merge(TileGMCfg(flags))
from TileConditions.TileCablingSvcConfig import TileCablingSvcCfg
result.merge(TileCablingSvcCfg(flags))
from TileConditions.TileBadChannelsConfig import TileBadChannelsCondAlgCfg
result.merge(TileBadChannelsCondAlgCfg(flags, **kwargs))
if 'TileCondToolEmscale' not in kwargs:
from TileConditions.TileEMScaleConfig import TileCondToolEmscaleCfg
emScaleTool = result.popToolsAndMerge(TileCondToolEmscaleCfg(flags))
kwargs['TileCondToolEmscale'] = emScaleTool
kwargs.setdefault('CheckDCS', flags.Tile.useDCS)
if kwargs['CheckDCS']:
from TileConditions.TileDCSConfig import TileDCSCondAlgCfg
result.merge(TileDCSCondAlgCfg(flags))
#kwargs.setdefault('TriggerChain', 'HLT_noalg_cosmiccalo_L1RD1_EMPTY') #FIXME
kwargs.setdefault('TriggerTypes', [0x82])
kwargs.setdefault('Gain', 1)
kwargs.setdefault('TileRawChannelContainer',
flags.Tile.RawChannelContainer)
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(flags, 'TileRawChanNoiseMonitoring')
# Adding an TileCellMonitorAlgorithm algorithm to the helper
from AthenaConfiguration.ComponentFactory import CompFactory
TileRawChannelNoiseMonitorAlgorithm = CompFactory.TileRawChannelNoiseMonitorAlgorithm
tileRawChanNoiseMonAlg = helper.addAlgorithm(
TileRawChannelNoiseMonitorAlgorithm, 'TileRawChanNoiseMonAlg')
for k, v in kwargs.items():
setattr(tileRawChanNoiseMonAlg, k, v)
run = str(flags.Input.RunNumber[0])
# 1) Configure histogram with TileRawChanNoiseMonAlg algorithm execution time
executeTimeGroup = helper.addGroup(tileRawChanNoiseMonAlg,
'TileRawChanNoiseMonExecuteTime',
'Tile/')
executeTimeGroup.defineHistogram(
'TIME_execute',
path='RawChannelNoise',
type='TH1F',
title='Time for execute TileRawChanNoiseMonAlg algorithm;time [#mus]',
xbins=100,
xmin=0,
xmax=100000)
from TileCalibBlobObjs.Classes import TileCalibUtils as Tile
from TileMonitoring.TileMonitoringCfgHelper import getPartitionName, getCellName, getGainName
# 2) Configure histograms with Tile raw channel amplitude per channel
gainName = getGainName(kwargs['Gain'])
dimensions = [
int(Tile.MAX_ROS) - 1,
int(Tile.MAX_DRAWER),
int(Tile.MAX_CHAN)
]
chanAmpArray = helper.addArray(dimensions,
tileRawChanNoiseMonAlg,
'TileRawChannelNoise',
topPath='Tile/RawChannelNoise')
for postfix, tool in chanAmpArray.Tools.items():
ros, module, channel = [int(x) for x in postfix.split('_')[1:]]
partition = getPartitionName(ros + 1)
moduleName = Tile.getDrawerString(ros + 1, module)
cellName = getCellName(partition, channel)
title = 'Run %s %s: Tile cell %s / channel %s amplitude (%s);Amplitude [ADC]'
title = title % (run, moduleName, cellName, str(channel), gainName)
name = 'amplitude;TileRawChannelNoise_%s_%s_ch_%s_%s' % (
moduleName, cellName, str(channel), gainName)
tool.defineHistogram(name,
title=title,
path=partition,
type='TH1F',
xbins=81,
xmin=-20.25,
xmax=20.25)
accumalator = helper.result()
result.merge(accumalator)
return result
def TileTowerMonitoringConfig(flags, **kwargs):
''' Function to configure TileTowerMonitorAlgorithm algorithm in the monitoring system.'''
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
result = ComponentAccumulator()
from TileMonitoring.TileTowerBuilderConfig import TileTowerBuilderAlgCfg
result.merge(TileTowerBuilderAlgCfg(flags))
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(flags, 'TileTowerMonitoring')
# Adding an TileTowerMonitorAlgorithm algorithm to the helper
TileTowerMonitorAlgorithm = CompFactory.TileTowerMonitorAlgorithm
tileTowerMonAlg = helper.addAlgorithm(TileTowerMonitorAlgorithm,
'TileTowerMonAlg')
tileTowerMonAlg.TriggerChain = ''
# L1Trigger Type Bits:
# bit0_RNDM, bit1_ZeroBias, bit2_L1Cal, bit3_Muon,
# bit4_RPC, bit5_FTK, bit6_CTP, bit7_Calib, AnyPhysTrig
kwargs.setdefault('fillHistogramsForL1Triggers',
['AnyPhysTrig', 'bit7_Calib'])
l1Triggers = kwargs['fillHistogramsForL1Triggers']
for k, v in kwargs.items():
setattr(tileTowerMonAlg, k, v)
run = str(flags.Input.RunNumber[0])
# 1) Configure histogram with TileTowerMonAlg algorithm execution time
executeTimeGroup = helper.addGroup(tileTowerMonAlg,
'TileTowerMonExecuteTime', 'Tile/')
executeTimeGroup.defineHistogram(
'TIME_execute',
path='Tower',
type='TH1F',
title='Time for execute TileTowerMonAlg algorithm;time [#mus]',
xbins=100,
xmin=0,
xmax=100000)
from TileCalibBlobObjs.Classes import TileCalibUtils as Tile
from TileMonitoring.TileMonitoringCfgHelper import addTileEtaPhiMapsArray
# ) Configure histograms with most energetic Tile tower position
addTileEtaPhiMapsArray(helper,
tileTowerMonAlg,
name='TileTowerEtaPhi',
type='TH2D',
title='Most energetic Tile Tower position',
path='Tile/Tower',
run=run,
triggers=l1Triggers,
perSample=False)
# ) Configure histograms with position correlation of Tile tower opposite to most energetic tower
addTileEtaPhiMapsArray(
helper,
tileTowerMonAlg,
name='TileTowerEtaPhiDiff',
type='TH2D',
title=
'Position correlation of Tile Tower opposite to most energetic tower',
path='Tile/Tower',
run=run,
triggers=l1Triggers,
perSample=False,
etaTitle='#Delta #eta',
etabins=41,
etamin=-2.05,
etamax=2.05,
phiTitle='#Delta #phi',
phibins=Tile.MAX_DRAWER + 1,
phimin=-0.05,
phimax=6.45)
from TileMonitoring.TileMonitoringCfgHelper import addTile1DHistogramsArray
# ) Configure histograms with Et in most energetic Tile tower per partition
addTile1DHistogramsArray(helper,
tileTowerMonAlg,
name='TileTowerEt',
xvalue='Et',
title='E_{T} [MeV] in most energetic Tile Tower',
path='Tile/Tower',
xbins=80,
xmin=0.,
xmax=20000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=True,
perSample=False,
perGain=False,
subDirectory=True,
allPartitions=True)
# ) Configure histograms with all Tile towers energy per partition
addTile1DHistogramsArray(helper,
tileTowerMonAlg,
name='TileAllTowerEnergy',
xvalue='energy',
title='All Tile Towers Energy [MeV]',
path='Tile/Tower',
xbins=80,
xmin=0.,
xmax=20000.,
type='TH1D',
run=run,
triggers=l1Triggers,
perPartition=True,
perSample=False,
perGain=False,
subDirectory=True,
allPartitions=True)
accumalator = helper.result()
result.merge(accumalator)
return result
def CaloBaselineMonConfig(inputFlags, isTopLevel=True):
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags,'CaloBaselineMonCfg')
if not inputFlags.DQ.enableLumiAccess:
print('This algo needs Lumi access, returning empty config')
if isTopLevel:
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
cfg=ComponentAccumulator()
cfg.merge(helper.result())
return cfg
else:
return helper.result()
from LArGeoAlgsNV.LArGMConfig import LArGMCfg
cfg = LArGMCfg(inputFlags)
from TileGeoModel.TileGMConfig import TileGMCfg
cfg.merge(TileGMCfg(inputFlags))
from LArCellRec.LArCollisionTimeConfig import LArCollisionTimeCfg
cfg.merge(LArCollisionTimeCfg(inputFlags))
from CaloTools.CaloNoiseCondAlgConfig import CaloNoiseCondAlgCfg
cfg.merge(CaloNoiseCondAlgCfg(inputFlags))
caloBaselineMonAlg = helper.addAlgorithm(CompFactory.CaloBaselineMonAlg,'caloBaselineMonAlg')
GroupName="CaloBaseLineMon"
caloBaselineMonAlg.MonGroupName = GroupName
caloBaselineMonAlg.EnableLumi = True
partList = ["EM","HEC+FCal"]
caloBaselineMonAlg.partionList = partList
etaBins = [16,19]
caloBaselineMonAlg.nbOfEtaBins = etaBins
minEta = [0.,1.2]
caloBaselineMonAlg.minimumEta = minEta
maxEta = [3.2,5.]
caloBaselineMonAlg.maximumEta = maxEta
# config settings based on flags
tmp_CaloBaselineMon = {"useBadLBTool":False,
"useReadyFilterTool":False,
"useLArNoisyAlg":False,
"useBeamBackgroundRemoval":False,
"useLArCollisionFilter":False,
"pedestalMon_BCIDmin":0,
"bcidtoolMon_BCIDmax":0}
binlabels=["TotalEvents","ATLAS Ready","with Good LAr LB","with No LAr Collision","with No Beam Background", "with No Trigger Filter","with No LArError"]
if not (inputFlags.Common.isOnline == 'online' or inputFlags.Input.isMC ):
tmp_CaloBaselineMon["useBadLBTool"]=True
tmp_CaloBaselineMon["useReadyFilterTool"]=True
tmp_CaloBaselineMon["useLArNoisyAlg"] = True
# FIXME when trigger stream flag is added:
#if rec.triggerStream()=='CosmicCalo':
# tmp_CaloBaselineMon["useLArCollisionFilter"] = True
# tmp_CaloBaselineMon["pedestalMon_BCIDmin"] = 40
# tmp_CaloBaselineMon["TriggerChain"] = "HLT_noalg_cosmiccalo_L1RD1_EMPTY"
#if rec.triggerStream()=='ZeroBias':
tmp_CaloBaselineMon["bcidtoolMon_BCIDmax"] = 144
#tmp_CaloBaselineMon["TriggerChain"] = "HLT_noalg_zb_L1ZB"
tmp_CaloBaselineMon["TriggerChain"] = ""
from AthenaMonitoring.AtlasReadyFilterConfig import AtlasReadyFilterCfg
from AthenaMonitoring.BadLBFilterToolConfig import LArBadLBFilterToolCfg
caloBaselineMonAlg.useBadLBTool = tmp_CaloBaselineMon["useBadLBTool"]
caloBaselineMonAlg.BadLBTool = cfg.popToolsAndMerge(LArBadLBFilterToolCfg(inputFlags))
# FIXME Do not have yet new config for BunchCrossingTool, shoulkd be put back once available
#caloBaselineMonAlg.BunchCrossingTool = BunchCrossingTool("TrigConf" if not inputFlags.Input.isMC else "MC")
caloBaselineMonAlg.useReadyFilterTool = tmp_CaloBaselineMon["useReadyFilterTool"]
caloBaselineMonAlg.ReadyFilterTool = cfg.popToolsAndMerge(AtlasReadyFilterCfg(inputFlags))
caloBaselineMonAlg.useLArCollisionFilterTool = tmp_CaloBaselineMon["useLArCollisionFilter"]
caloBaselineMonAlg.useLArNoisyAlg = tmp_CaloBaselineMon["useLArNoisyAlg"]
caloBaselineMonAlg.useBeamBackgroundRemoval = tmp_CaloBaselineMon["useBeamBackgroundRemoval"]
caloBaselineMonAlg.pedestalMon_BCIDmin = tmp_CaloBaselineMon["pedestalMon_BCIDmin"]
caloBaselineMonAlg.bcidtoolMon_BCIDmax = tmp_CaloBaselineMon["bcidtoolMon_BCIDmax"]
caloBaselineMonAlg.TriggerChain = tmp_CaloBaselineMon["TriggerChain"]
if not caloBaselineMonAlg.useReadyFilterTool:
binlabels[1] = "ATLAS Ready-OFF"
if not caloBaselineMonAlg.useBadLBTool:
binlabels[2] = "Good LAr LB-OFF"
if not caloBaselineMonAlg.useLArCollisionFilterTool:
binlabels[3] = "LAr collision-OFF"
if not caloBaselineMonAlg.useBeamBackgroundRemoval:
binlabels[4] = "Beam backgr.-OFF"
if not caloBaselineMonAlg.useLArNoisyAlg:
binlabels[5] = "LAr Error Veto-OFF"
# eta bins computation (should be tha same as in C++ code
etaBinWidth = [None] * len(partList)
for i in range(0,len(partList)):
etaBinWidth[i] = (maxEta[i] - minEta[i]) / etaBins[i]
# bool to decide which monitoring to do
if caloBaselineMonAlg.pedestalMon_BCIDmin > 0:
doPedestalMon = True
else:
doPedestalMon = False
if caloBaselineMonAlg.bcidtoolMon_BCIDmax > 0:
doBcidtoolMon = True
else:
doBcidtoolMon = False
baselineGroup = helper.addGroup(
caloBaselineMonAlg,
GroupName,
'/CaloMonitoring/'+GroupName+'/'
)
gen_hist_path='General/'
from CaloMonitoring.CaloMonAlgBase import CaloBaseHistConfig
CaloBaseHistConfig(baselineGroup,gen_hist_path,binlabels)
BCID0_nbins=3563
LB_nbins=3000
baselineGroup.defineHistogram('BCID;h1BCID_pedestalMon',
title='BCID used for baseline monitoring;BCID;Nb of events / BCID',
type='TH1I', path=gen_hist_path,
xbins=BCID0_nbins+1, xmin=-0.5, xmax=BCID0_nbins+0.5)
baselineGroup.defineHistogram('BCID;h1BCID_BCIDToolMon',
title='BCID used for BCIDTool monitoring;BCID;Nb of events / BCID',
type='TH1I', path=gen_hist_path,
xbins=BCID0_nbins+1, xmin=-0.5, xmax=BCID0_nbins+0.5)
part_hist_path='AllCalo'+tmp_CaloBaselineMon["TriggerChain"]+'/'
idx=0
for part in partList:
if doPedestalMon:
str_auxTitle = " Empty BCID > "+str(tmp_CaloBaselineMon["pedestalMon_BCIDmin"])+"BCID away from last train"
baselineGroup.defineHistogram('pedEta_'+part+',sumPedEta_'+part+';hprof1d_pedestalMon_'+part+'_AllEta',
title='Pedestal baseline ( '+str_auxTitle+');Eta;E_T/(#Delta#eta.#Delta#phi.#mu)[MeV]',
type='TProfile', path=part_hist_path,
xbins=etaBins[idx], xmin=minEta[idx], xmax=maxEta[idx])
baselineGroup.defineHistogram('LB_'+part+',sumPedEta_'+part+';hprof1d_pedestalMon_'+part+'_LB',
title='Pedestal baseline ( '+str_auxTitle+');Luminosity block;E_T/(#Delta#eta.#Delta#phi.#mu)[MeV]',
type='TProfile', path=part_hist_path,
xbins=LB_nbins, xmin=0, xmax=LB_nbins)
if doBcidtoolMon:
str_auxTitle = " BCID in bunch train "
baselineGroup.defineHistogram('bcidEta_'+part+',sumBCIDEta_'+part+';hprof1d_bcidtoolMon_'+part+'_AllEta',
title='BCIDTool baseline ( '+str_auxTitle+');Eta;E_T/(#Delta#eta.#Delta#phi.#mu)[MeV]',
type='TProfile', path=part_hist_path,
xbins=etaBins[idx], xmin=minEta[idx], xmax=maxEta[idx])
baselineGroup.defineHistogram('LB_'+part+',sumBCIDEta_'+part+';hprof1d_bcidtoolMon_'+part+'_LB',
title='BCIDTool baseline ( '+str_auxTitle+');Luminosity block;E_T/(#Delta#eta.#Delta#phi.#mu)[MeV]',
type='TProfile', path=part_hist_path,
xbins=LB_nbins, xmin=0, xmax=LB_nbins)
part_hist_path='/CaloMonitoring/'+GroupName+'/AllCalo'+tmp_CaloBaselineMon["TriggerChain"]+'/'
idx=0
for part in partList:
darray = helper.addArray([etaBins[idx]],caloBaselineMonAlg,part)
if doPedestalMon:
str_auxTitle = " Empty BCID > "+str(tmp_CaloBaselineMon["pedestalMon_BCIDmin"])+"BCID away from last train"
darray.defineHistogram('etaBCID_'+part+',sumPedEta_'+part+';hprof_pedestalMon_'+part,
title='Pedestal baseline ( '+str_auxTitle+');Luminosity block;E_T/(#Delta#eta.#Delta#phi.#mu)[MeV]',
type='TProfile', path=part_hist_path,
xbins=BCID0_nbins+1, xmin=-0.5, xmax=BCID0_nbins+0.5)
if doBcidtoolMon:
str_auxTitle = " BCID in bunch train "
darray.defineHistogram('etaBCID_'+part+',sumBCIDEta_'+part+';hprof_bcidtoolMon_'+part,
title='BCIDTool baseline ( '+str_auxTitle+');Luminosity block;E_T/(#Delta#eta.#Delta#phi.#mu)[MeV]',
type='TProfile', path=part_hist_path,
xbins=BCID0_nbins+1, xmin=-0.5, xmax=BCID0_nbins+0.5)
idx=idx+1
#if isTopLevel:
cfg.merge(helper.result())
return cfg
def TrigBphysMonConfig(inputFlags):
'''Function to configures some algorithms in the monitoring system.'''
### STEP 1 ###
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
#from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
#result = ComponentAccumulator()
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags,'TrigBphysAthMonitorCfg')
### STEP 2 ###
# Adding an algorithm to the helper. Here, we will use the example
# algorithm in the AthenaMonitoring package. Just pass the type to the
# helper. Then, the helper will instantiate an instance and set up the
# base class configuration following the inputFlags. The returned object
# is the algorithm.
# The added algorithm must exist as a .h file
from AthenaConfiguration.ComponentFactory import CompFactory
trigBphysMonAlg = helper.addAlgorithm(CompFactory.TrigBphysMonitorAlgorithm,'TrigBphysMonAlg')
#from AthenaCommon.Constants import DEBUG,INFO
#trigBphysMonAlg.OutputLevel = INFO
# You can actually make multiple instances of the same algorithm and give
# them different configurations
#shifterTrigBphysMonAlg = helper.addAlgorithm(TrigBphysMonitorAlgorithm,'ShifterTrigBphysMonAlg')
# # If for some really obscure reason you need to instantiate an algorithm
# # yourself, the AddAlgorithm method will still configure the base
# # properties and add the algorithm to the monitoring sequence.
# helper.AddAlgorithm(myExistingAlg)
### STEP 3 ###
# Edit properties of a algorithm
# some generic property
# trigBphysMonAlg.RandomHist = True
# to enable a trigger filter, for example:
#trigBphysMonAlg.TriggerChain = 'HLT_mu26_ivarmedium'
#trigBphysMonAlg.TriggerChain = 'HLT_e24_lhtight_nod0'
monitored_chains = ['HLT_2mu10_bJpsimumu_L12MU10', 'HLT_2mu10_bUpsimumu_L12MU10']
monitored_containers = ['HLT_DimuEF']
trigBphysMonAlg.MonitoredChains = monitored_chains
trigBphysMonAlg.MonitoredContainers = monitored_containers
### STEP 4 ###
# Add some tools. N.B. Do not use your own trigger decision tool. Use the
# standard one that is included with AthMonitorAlgorithm.
# # First, add a tool that's set up by a different configuration function.
# # In this case, CaloNoiseToolCfg returns its own component accumulator,
# # which must be merged with the one from this function.
# from CaloTools.CaloNoiseToolConfig import CaloNoiseToolCfg
# caloNoiseAcc, caloNoiseTool = CaloNoiseToolCfg(inputFlags)
# result.merge(caloNoiseAcc)
# trigBphysMonAlg.CaloNoiseTool = caloNoiseTool
# # Then, add a tool that doesn't have its own configuration function. In
# # this example, no accumulator is returned, so no merge is necessary.
# from MyDomainPackage.MyDomainPackageConf import MyDomainTool
# trigBphysMonAlg.MyDomainTool = MyDomainTool()
# Add a generic monitoring tool (a "group" in old language). The returned
# object here is the standard GenericMonitoringTool.
expertGroup = helper.addGroup(
trigBphysMonAlg,
'TrigBphysMonitor',
'HLT/BphysMon/Expert/'
)
# Add a GMT for the other example monitor algorithm
#shifterGroup = helper.addGroup(shifterTrigBphysMonAlg,'TrigBphysMonitor','HLT/BphysMon/Shifter/')
### STEP 5 ###
# Configure histograms
#NB! The histograms defined here must match the ones in the cxx file exactly
for monitored_chain in monitored_chains :
# number of events histograms will be shown in root Containers/ folder
expertGroup.defineHistogram('ncandidates_Chain_'+monitored_chain,title='Number of Bphys candidates;number of candidates;Entries',
path='Chains',xbins=10,xmin=-0.5,xmax=9.5)
# the others in per-container folders
expertGroup.defineHistogram('dimu_mass_Chain_'+monitored_chain,title='Dimuon mass;m(#mu^{+}#mu^{-}) [GeV];Events / (0.1 GeV)',
path='Chains/'+monitored_chain,xbins=150,xmin=0.0,xmax=15.0)
expertGroup.defineHistogram('dimu_pt_Chain_'+monitored_chain,title='Dimuon transverse momentum;p_{T}(#mu^{+}#mu^{-}) [GeV];Events / (1 GeV)',
path='Chains/'+monitored_chain,xbins=40,xmin=0.0,xmax=40.0)
expertGroup.defineHistogram('dimu_chi2_Chain_'+monitored_chain,title='Dimuon #chi^{2};#chi^{2}(#mu^{+}#mu^{-});Events / (0.5)',
path='Chains/'+monitored_chain,xbins=80,xmin=0.0,xmax=40.0)
for monitored_container in monitored_containers :
# number of events histograms will be shown in root Containers/ folder
expertGroup.defineHistogram('ncandidates_Container_'+monitored_container,title='Number of Bphys candidates;number of candidates;Entries',
path='Containers',xbins=10,xmin=-0.5,xmax=9.5)
# the others in per-container folders
expertGroup.defineHistogram('dimu_mass_Container_'+monitored_container,title='Dimuon mass;m(#mu^{+}#mu^{-}) [GeV];Events / (0.1 GeV)',
path='Containers/'+monitored_container,xbins=150,xmin=0.0,xmax=15.0)
#shifterGroup.defineHistogram('run',title='Run Number;run;Events',
#path='SomePath',xbins=1000000,xmin=-0.5,xmax=999999.5)
### STEP 6 ###
# Finalize. The return value should be a tuple of the ComponentAccumulator
# and the sequence containing the created algorithms. If we haven't called
# any configuration other than the AthMonitorCfgHelper here, then we can
# just return directly (and not create "result" above)
return helper.result()
def TileCellMonitoringConfig(flags, **kwargs):
''' Function to configure TileCellMonitorAlgorithm algorithm in the monitoring system.'''
# Define one top-level monitoring algorithm. The new configuration
# framework uses a component accumulator.
from AthenaConfiguration.ComponentAccumulator import ComponentAccumulator
result = ComponentAccumulator()
from TileRecUtils.TileDQstatusConfig import TileDQstatusAlgCfg
result.merge(TileDQstatusAlgCfg(flags))
from TileGeoModel.TileGMConfig import TileGMCfg
result.merge(TileGMCfg(flags))
from LArGeoAlgsNV.LArGMConfig import LArGMCfg
result.merge(LArGMCfg(flags))
from TileConditions.TileCablingSvcConfig import TileCablingSvcCfg
result.merge(TileCablingSvcCfg(flags))
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(flags, 'TileMonitoring')
# Adding an TileCellMonitorAlgorithm algorithm to the helper
from AthenaConfiguration.ComponentFactory import CompFactory
tileCellMonAlg = helper.addAlgorithm(CompFactory.TileCellMonitorAlgorithm,
'TileCellMonAlg')
tileCellMonAlg.TriggerChain = ''
from AthenaCommon.SystemOfUnits import MeV, GeV, ns
kwargs.setdefault('EnergyThreshold', 300.0 * MeV)
kwargs.setdefault('NegativeEnergyThreshold', -2000.0 * MeV)
kwargs.setdefault('EnergyBalanceThreshold', 3)
kwargs.setdefault('TimeBalanceThreshold', 25 * ns)
kwargs.setdefault('fillTimeAndEnergyDiffHistograms', False)
if flags.Beam.Type in ('cosmics', 'singlebeam'):
kwargs.setdefault('fillTimeHistograms', True)
kwargs.setdefault('EnergyThresholdForTime', 150.0 * MeV)
else:
kwargs.setdefault('fillTimeHistograms', False)
kwargs.setdefault('EnergyThresholdForTime', 500.0 * MeV)
# L1Trigger Type Bits:
# bit0_RNDM, bit1_ZeroBias, bit2_L1Cal, bit3_Muon,
# bit4_RPC, bit5_FTK, bit6_CTP, bit7_Calib, AnyPhysTrig
kwargs.setdefault('fillHistogramsForL1Triggers',
['AnyPhysTrig', 'bit7_Calib'])
l1Triggers = kwargs['fillHistogramsForL1Triggers']
for k, v in kwargs.items():
setattr(tileCellMonAlg, k, v)
run = str(flags.Input.RunNumber[0])
# 1) Configure histogram with TileCellMonAlg algorithm execution time
executeTimeGroup = helper.addGroup(tileCellMonAlg,
'TileCellMonExecuteTime', 'Tile/')
executeTimeGroup.defineHistogram(
'TIME_execute',
path='Cell',
type='TH1F',
title='Time for execute TileCellMonAlg algorithm;time [#mus]',
xbins=100,
xmin=0,
xmax=100000)
from TileCalibBlobObjs.Classes import TileCalibUtils as Tile
from TileMonitoring.TileMonitoringCfgHelper import getPartitionName
# 2) Configure histogram with average number of Tile bad cells in partition
labelsPartitions = [
getPartitionName(ros) for ros in range(1, Tile.MAX_ROS)
]
badCellGroup = helper.addGroup(tileCellMonAlg, 'TileBadCell', 'Tile/')
badCellGroup.defineHistogram(
'Partition,nBadCells;TileBadCell',
path='Cell',
type='TProfile',
xlabels=labelsPartitions,
title=('Run %s: Average number of Bad Tile Cells' % run),
xbins=Tile.MAX_ROS - 1,
xmin=-0.5,
xmax=Tile.MAX_ROS - 1.5)
from TileMonitoring.TileMonitoringCfgHelper import addTileModulePartitionMapsArray
# 3) Configure histograms with energy ratio > threshold vs module and partion
eneBalModPartTitle = ('Tile Cell Energy Ratio > %s' %
kwargs['EnergyBalanceThreshold'])
addTileModulePartitionMapsArray(helper,
tileCellMonAlg,
name='TileCellEneBalModPart',
title=eneBalModPartTitle,
path='Tile/Cell',
type='TH2D',
run=run,
triggers=l1Triggers,
separator='_')
# 4) Configure histograms with Tile cell time difference over threshold vs module and partition
timeBalModPartTitle = (
'Tile Cell Time difference > %s ns. E_{ch} > %s [MeV]')
timeBalModPartTitle = (
timeBalModPartTitle %
(kwargs['TimeBalanceThreshold'], kwargs['EnergyThresholdForTime']))
addTileModulePartitionMapsArray(helper,
tileCellMonAlg,
name='TileCellTimeBalModPart',
title=timeBalModPartTitle,
path='Tile/Cell',
type='TH2D',
run=run,
triggers=l1Triggers,
separator='_')
from TileMonitoring.TileMonitoringCfgHelper import addTileModuleChannelMapsArray, addTileModuleDigitizerMapsArray
# 5) Configure histograms with everagy Tile channel time per partition
chanTimeTitle = ('TileCal Average Channel Time [ns]. E_{ch} > %s MeV' %
kwargs['EnergyThresholdForTime'])
addTileModuleChannelMapsArray(helper,
tileCellMonAlg,
name='TileChanPartTime',
type='TProfile2D',
value='time',
title=chanTimeTitle,
path='Tile/Cell',
subDirectory=True,
run=run,
triggers=l1Triggers,
separator='_')
# 6) Configure histograms with everagy Tile digitizer time per partition
digiTimeTitle = ('TileCal Average Digitizer Time [ns]. E_{ch} > %s MeV' %
kwargs['EnergyThresholdForTime'])
addTileModuleDigitizerMapsArray(helper,
tileCellMonAlg,
name='TileDigiPartTime',
type='TProfile2D',
value='time',
title=digiTimeTitle,
path='Tile/Cell',
subDirectory=True,
run=run,
triggers=l1Triggers,
separator='_')
# 7) Configure histograms with everagy energy maps per partition
addTileModuleChannelMapsArray(helper,
tileCellMonAlg,
name='TileCellDetailOccMap',
type='TProfile2D',
value='energy',
title='Occupancy Map [MeV]',
path='Tile/Cell',
subDirectory=True,
run=run,
triggers=l1Triggers,
separator='_')
# 8) Configure histograms with occupancy maps over threshold per partition
titleMapOvThr = ('Occupancy Map Over Threshod %s MeV' %
kwargs['EnergyThreshold'])
addTileModuleChannelMapsArray(helper,
tileCellMonAlg,
name='TileCellDetailOccMapOvThr',
weight='weight',
title=titleMapOvThr,
path='Tile/Cell',
subDirectory=True,
run=run,
triggers=l1Triggers,
separator='_')
# 9) Configure histograms with occupancy maps over threshold 30GeV per partition
addTileModuleChannelMapsArray(helper,
tileCellMonAlg,
name='TileCellDetailOccMapOvThr30GeV',
title='Occupancy Map Over Threshod 30 GeV',
path='Tile/Cell',
subDirectory=True,
run=run,
triggers=l1Triggers,
separator='_')
# 10) Configure histograms with occupancy maps over threshold 300GeV per partition
addTileModuleChannelMapsArray(helper,
tileCellMonAlg,
name='TileCellDetailOccMapOvThr300GeV',
title='Occupancy Map Over Threshod 300 GeV',
path='Tile/Cell',
subDirectory=True,
run=run,
triggers=l1Triggers,
separator='_')
# 11) Configure histograms with occupancy maps over threshold per partition
addTileModuleChannelMapsArray(helper,
tileCellMonAlg,
name='TileCellDetailOccMapOvThrGain',
weight='weight',
title=titleMapOvThr,
path='Tile/Cell',
subDirectory=True,
run=run,
triggers=l1Triggers,
perGain=True,
separator='_')
# 12) Configure histograms with status of Tile channels in DB per partition
addTileModuleChannelMapsArray(helper,
tileCellMonAlg,
name='TileCellStatusInDB',
title='Cell channel status in DB',
path='Tile/Cell',
run=run,
perGain=True,
separator='_')
# 13) Configure histograms with Tile channels masked on the fly per partition
addTileModuleChannelMapsArray(helper,
tileCellMonAlg,
name='TileCellStatusOnFly',
title='Channels masked on the fly',
path='Tile/Cell',
run=run,
perGain=False,
separator='_')
# 14) Configure histograms with occupancy map below negative threshold per partition
titleNegOcc = 'Occupancy Map Below %s GeV' % (
kwargs['NegativeEnergyThreshold'] / GeV)
addTileModuleChannelMapsArray(helper,
tileCellMonAlg,
name='TileCellDetailNegOccMap',
title=titleNegOcc,
path='Tile/Cell',
run=run,
separator='_')
# 15) Configure histograms with Tile module correlation per partition
from TileMonitoring.TileMonitoringCfgHelper import addTileModuleCorrelionMapsArray
addTileModuleCorrelionMapsArray(helper,
tileCellMonAlg,
name='TileCellModuleCorrelation',
title='Tile Cell Module correlation',
path='Tile/Cell',
weight='weight',
subDirectory=True,
run=run,
triggers=l1Triggers,
allPartitions=True,
separator='_')
from TileMonitoring.TileMonitoringCfgHelper import addTile1DHistogramsArray
# 16) Configure histograms with number of masked Tile channels on the fly vs lumi block per partition
titleMaskOnFlyLB = 'Number of masked channels on the fly'
titleMaskOnFlyLB += ';LumiBlock;Number of masked channels'
addTile1DHistogramsArray(helper,
tileCellMonAlg,
name='TileMaskChannelOnFlyLB',
path='Tile/Cell',
xvalue='lumiBlock',
value='nMaskedChannelsOnFly',
title=titleMaskOnFlyLB,
xbins=1000,
xmin=-0.5,
xmax=999.5,
type='TProfile',
run=run,
triggers=[],
perPartition=True,
perSample=False,
perGain=False,
subDirectory=False,
opt='kAddBinsDynamically')
# 17) Configure histograms with number of masked Tile cells on the fly vs lumi block per partition
titleMaskCellLB = 'Number of masked cells on the fly'
titleMaskCellLB += ';LumiBlock;Number of masked cells'
addTile1DHistogramsArray(helper,
tileCellMonAlg,
name='TileMaskCellLB',
path='Tile/Cell',
xvalue='lumiBlock',
value='nMaskedCells',
title=titleMaskCellLB,
xbins=1000,
xmin=-0.5,
xmax=999.5,
type='TProfile',
run=run,
triggers=[],
subDirectory=False,
perPartition=True,
perSample=False,
perGain=False,
opt='kAddBinsDynamically')
# 18) Configure histograms with number of masked Tile channels on the fly due to bad DQ status vs lumi block per partition
titleMaskDueDQ = 'Number of masked channels on the fly due to bad DQ status'
titleMaskDueDQ += ';LumiBlock;Number of masked channels'
addTile1DHistogramsArray(helper,
tileCellMonAlg,
name='TileMaskChannelDueDQvsLB',
path='Tile/Cell',
xvalue='lumiBlock',
value='nMaskedChannelsDueDQ',
title=titleMaskDueDQ,
xbins=1000,
xmin=-0.5,
xmax=999.5,
type='TProfile',
run=run,
triggers=[],
subDirectory=False,
perPartition=True,
perSample=False,
perGain=False,
opt='kAddBinsDynamically')
# 19) Configure histograms with number of masked Tile cells on the fly due to bad DQ status vs lumi block per partition
titleMaskCellDueDQ = 'Number of masked cells on the fly due to bad DQ status'
titleMaskCellDueDQ += ';LumiBlock;Number of masked cells'
addTile1DHistogramsArray(helper,
tileCellMonAlg,
name='TileMaskedCellDueDQvsLB',
path='Tile/Cell',
xvalue='lumiBlock',
value='nMaskedCellsDueDQ',
title=titleMaskCellDueDQ,
xbins=1000,
xmin=-0.5,
xmax=999.5,
type='TProfile',
run=run,
triggers=[],
subDirectory=False,
perPartition=True,
perSample=False,
perGain=False,
opt='kAddBinsDynamically')
# 20) Configure histograms with energy difference between Tile cells' PMTs per partition and sample
addTile1DHistogramsArray(
helper,
tileCellMonAlg,
name='TileCellEneDiff',
xvalue='energyDiff',
title='Energy difference [MeV] between PMTs;Energy difference [MeV]',
path='Tile/Cell',
xbins=50,
xmin=-1000.,
xmax=1000.,
type='TH1D',
run=run,
triggers=l1Triggers,
subDirectory=True,
perPartition=True,
perSample=True,
perGain=False)
# 21) Configure histograms with time difference between Tile cells' PMTs per partition and sample
titleTimeDiffSamp = 'Time difference [ns] between PMTs with '
titleTimeDiffSamp += 'E_{ch} > %s MeV' % (
kwargs['EnergyThresholdForTime'] / MeV)
titleTimeDiffSamp += ';time [ns]'
addTile1DHistogramsArray(helper,
tileCellMonAlg,
name='TileCellTimeDiff',
xvalue='timeDiff',
title=titleTimeDiffSamp,
path='Tile/Cell',
xbins=50,
xmin=-10.,
xmax=10.,
type='TH1D',
run=run,
triggers=l1Triggers,
subDirectory=True,
perPartition=True,
perSample=True,
perGain=False)
# Configure histograms with number of Tile cells vs lumiBlock per partition
titleCellsNumber = 'Tile Cells number per luminosity block;LumiBlock;Number of reconstructed cells'
addTile1DHistogramsArray(helper,
tileCellMonAlg,
name='TileCellsNumberLB',
xvalue='lumiBlock',
value='nCells',
title=titleCellsNumber,
path='Tile/Cell',
xbins=1000,
xmin=-0.5,
xmax=999.5,
type='TProfile',
run=run,
triggers=l1Triggers,
subDirectory=True,
perPartition=True,
perSample=False,
perGain=False,
allPartitions=True)
# 22) Configure histograms with number of Tile cells over threshold vs BCID per partition
titleCellsOvThrBCID = 'Tile Cell Occupancy over Threshold %s MeV' % (
kwargs['EnergyThresholdForTime'] / MeV)
titleCellsOvThrBCID += ';BCID;Average number of cells over threshold'
addTile1DHistogramsArray(helper,
tileCellMonAlg,
name='TileCellOccOvThrBCID',
xvalue='BCID',
value='nCells',
title=titleCellsOvThrBCID,
path='Tile/Cell',
xbins=3565,
xmin=0.,
xmax=3565.,
type='TProfile',
run=run,
triggers=l1Triggers,
subDirectory=True,
perPartition=True,
perSample=False,
perGain=False,
allPartitions=True)
# 23) Configure histograms with number of Tile E cell's energy per partition
titleEvEnergy = 'Tile Event SampE Energy;Event Energy [MeV]'
addTile1DHistogramsArray(helper,
tileCellMonAlg,
name='TileCellEventEnergySampE',
xvalue='energy',
title=titleEvEnergy,
path='Tile/Cell',
xbins=120,
xmin=-2000.,
xmax=10000.,
type='TH1D',
run=run,
triggers=l1Triggers,
subDirectory=True,
perPartition=True,
perSample=False,
perGain=False,
allPartitions=True)
# 24) Configure histograms with number of Tile E cell's energy
titleSynch = 'Tile Time of Flight - Tile measured;Time of Flight - Tile measured [ns]'
addTile1DHistogramsArray(helper,
tileCellMonAlg,
name='TileCellSynch',
xvalue='timeDifference',
title=titleSynch,
path='Tile/Cell',
xbins=50,
xmin=-100.,
xmax=100.,
type='TH1D',
run=run,
triggers=l1Triggers,
subDirectory=False,
perPartition=False,
perSample=False,
perGain=False)
from TileMonitoring.TileMonitoringCfgHelper import addTileEtaPhiMapsArray
# 25) Configure histograms with everage Tile cell energy vs eta and phy per sample
addTileEtaPhiMapsArray(helper,
tileCellMonAlg,
name='TileCellEneEtaPhi',
type='TProfile2D',
value='energy',
title='Energy Average depostion [MeV]',
path='Tile/Cell',
run=run,
triggers=l1Triggers,
perSample=True)
# 26) Configure histograms with number of Tile cells over threshold vs eta and phy per sample
titleEtaPhiOvThr = ('Position of cells over threshold %s MeV' %
kwargs['EnergyThreshold'])
addTileEtaPhiMapsArray(helper,
tileCellMonAlg,
name='TileCellEtaPhiOvThr',
type='TH2D',
title=titleEtaPhiOvThr,
path='Tile/Cell',
run=run,
triggers=l1Triggers,
perSample=True)
from TileMonitoring.TileMonitoringCfgHelper import addTileModuleArray
# 27) Configure histograms with energy difference between Tile cell's PMTs vs module per partition
titleEnergyBal = "Cell's PMTs Energy Balance"
titleEnergyBal += ";;Energy balance between cell's PMTs (u-d)/(u+d)"
addTileModuleArray(helper,
tileCellMonAlg,
name='TileCellEnergyBalance',
type='TProfile',
title=titleEnergyBal,
path='Tile/Cell',
value='energyBalance',
run=run)
# 28) Configure histograms with time difference between Tile cell's PMTs vs module per partition
titleTimeBal = "Cell's PMTs Time Difference with "
titleTimeBal += 'E_{ch} > %s MeV' % (kwargs['EnergyThresholdForTime'] /
MeV)
titleTimeBal += ";;Time balance between cell's PMTs [ns]"
addTileModuleArray(helper,
tileCellMonAlg,
name='TileCellTimeBalance',
type='TProfile',
title=titleTimeBal,
path='Tile/Cell',
value='timeBalance',
run=run)
accumalator = helper.result()
result.merge(accumalator)
return result
def TileCalCellMonAlgConfig(inputFlags, **kwargs):
''' Function to configure TileCalCellMonAlg algorithm in the monitoring system.'''
kwargs.setdefault('MonGroupName', 'TileEventFiter')
kwargs.setdefault('useBeamBackgroundRemoval', False)
kwargs.setdefault('useLArNoisyAlg', False)
kwargs.setdefault('useLArCollisionFilterTool', False)
if not (inputFlags.Common.isOnline == 'online' or inputFlags.Input.isMC):
kwargs.setdefault('useReadyFilterTool', True)
kwargs.setdefault(
'useBadLBTool',
False) # FIXME: when new LArBadLBFilterTool config is ready
else:
kwargs.setdefault('useReadyFilterTool', False)
kwargs.setdefault('useBadLBTool', False)
from AthenaCommon.SystemOfUnits import MeV
kwargs.setdefault('EnergyThreshold', 300.0 * MeV)
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'TileCalMonCfg')
from LArGeoAlgsNV.LArGMConfig import LArGMCfg
cfg = LArGMCfg(inputFlags)
from TileGeoModel.TileGMConfig import TileGMCfg
cfg.merge(TileGMCfg(inputFlags))
from CaloTools.CaloNoiseCondAlgConfig import CaloNoiseCondAlgCfg
cfg.merge(CaloNoiseCondAlgCfg(inputFlags))
if kwargs['useLArCollisionFilterTool']:
from LArCellRec.LArCollisionTimeConfig import LArCollisionTimeCfg
cfg.merge(LArCollisionTimeCfg(inputFlags))
if kwargs['useReadyFilterTool'] and 'ReadyFilterTool' not in kwargs:
from AthenaMonitoring.AtlasReadyFilterConfig import AtlasReadyFilterCfg
readyFilterTool = cfg.popToolsAndMerge(AtlasReadyFilterCfg(inputFlags))
kwargs['ReadyFilterTool'] = readyFilterTool
from AthenaConfiguration.ComponentFactory import CompFactory
tileCalCellMonAlg = helper.addAlgorithm(CompFactory.TileCalCellMonAlg,
'TileCalCellMonAlg')
for k, v in kwargs.items():
setattr(tileCalCellMonAlg, k, v)
binLabels = [
"TotalEvents", "ATLAS Ready", "with Good LAr LB",
"with No LAr Collision", "with No Beam Background",
"with No Trigger Filter", "with No LArError"
]
if not tileCalCellMonAlg.useReadyFilterTool:
binLabels[1] = "ATLAS Ready-OFF"
if not tileCalCellMonAlg.useBadLBTool:
binLabels[2] = "Good LAr LB-OFF"
if not tileCalCellMonAlg.useLArCollisionFilterTool:
binLabels[3] = "LAr collision-OFF"
if not tileCalCellMonAlg.useBeamBackgroundRemoval:
binLabels[4] = "Beam backgr.-OFF"
if not tileCalCellMonAlg.useLArNoisyAlg:
binLabels[5] = "LAr Error Veto-OFF"
topPath = '/CaloMonitoring/TileCellMon_NoTrigSel/General/'
tileFilterGroup = helper.addGroup(tileCalCellMonAlg,
tileCalCellMonAlg.MonGroupName, topPath)
from CaloMonitoring.CaloMonAlgBase import CaloBaseHistConfig
CaloBaseHistConfig(tileFilterGroup, 'Summary/', binLabels)
# 1) Configure histogram with TileCalCellMonAlg algorithm execution time
executeTimeGroup = helper.addGroup(tileCalCellMonAlg,
'TileCalCellMonExecuteTime', topPath)
executeTimeGroup.defineHistogram(
'TIME_execute',
path='Summary',
type='TH1F',
title='Time for execute TileCalCellMonAlg algorithm;time [#mus]',
xbins=100,
xmin=0,
xmax=100000)
# 2) Configure histograms with occupancy maps over threshold (4 noise sigma) per Tile sample
samplesWithoutE = ['A', 'BC', 'D', '']
noiseEtaPhiArray = helper.addArray([len(samplesWithoutE)],
tileCalCellMonAlg,
'CellsNoiseXEtaVSPhi',
topPath=topPath)
for postfix, tool in noiseEtaPhiArray.Tools.items():
sample = samplesWithoutE[int(postfix.split('_')[1])]
title = ('Number of Tile Cells %s' %
sample) + ' with E > 4 sigma (DB);#eta;#phi'
name = 'eta,phi;CellsNoiseXEtaVSPhi' + (sample +
'cells' if sample else '')
tool.defineHistogram(name,
title=title,
type='TH2F',
xbins=17,
xmin=-1.7,
xmax=1.7,
ybins=64,
ymin=-3.14,
ymax=3.14)
# 3) Configure histogram with number of 4 sigma seeds per Tile hash ID
noiseHashGroup = helper.addGroup(tileCalCellMonAlg, 'CellsXNoiseXHash',
topPath)
noiseHashGroup.defineHistogram(
'hash;CellsXNoiseXHash',
path='',
type='TH1F',
title='Number of 4 sigma seeds per hash;Tile Cell Hash ID;Events',
xbins=5184,
xmin=-0.5,
xmax=5183.5)
# 4) Configure histogram with Tile cell energy/noise (DB) ratio
noiseHashGroup = helper.addGroup(tileCalCellMonAlg, 'CellsNoiseTile',
topPath)
noiseHashGroup.defineHistogram(
'noise;CellsNoiseTile',
path='',
type='TH1F',
title='Energy/Noise (DB) of TileCal;Cell Energy / sigma (DB);Events',
xbins=200,
xmin=-10.0,
xmax=10.0)
# 5) Configure histogram with mean Tile cell noise (DB) vs eta
noiseEtaGroup = helper.addGroup(tileCalCellMonAlg, 'CellsNoiseXEta',
topPath)
noiseEtaGroup.defineHistogram(
'eta,noise;CellsNoiseXEta',
path='',
type='TProfile',
title=
'Tile Cell noise #sigma (DB) vs #eta;#eta;Mean Cell noise (DB) [MeV]',
xbins=17,
xmin=-1.7,
xmax=1.7)
# 6) Configure histogram with mean Tile cell noise (DB) vs phi
noisePhiGroup = helper.addGroup(tileCalCellMonAlg, 'CellsNoiseXPhi',
topPath)
noisePhiGroup.defineHistogram(
'phi,noise;CellsNoiseXPhi',
path='',
type='TProfile',
title=
'Tile Cell noise #sigma (DB) vs #phi;#phi;Mean Cell noise (DB) [MeV]',
xbins=64,
xmin=-3.14,
xmax=3.14)
# 7) Configure histogram with number of Tile cell over threshold
nCellsGroup = helper.addGroup(tileCalCellMonAlg, 'CellsXN', topPath)
nCellsGroup.defineHistogram(
'nCells;CellsXN',
path='',
type='TH1F',
title=
'Number of Tile Cells over threshold;Number of Tile Cells; Events',
xbins=250,
xmin=0,
xmax=500)
# 8) Configure histogram with Tile cell energy in GeV
energyGroup = helper.addGroup(tileCalCellMonAlg, 'CellsXE', topPath)
energyGroup.defineHistogram(
'energy;CellsXE',
path='',
type='TH1F',
title='Energy of Tile Cells;Tile Cell Energy [GeV]; Events',
xbins=50,
xmin=0,
xmax=20)
# 9) Configure histogram with mean Tile cell energy in GeV vs eta
energyEtaGroup = helper.addGroup(tileCalCellMonAlg, 'CellsXEta', topPath)
energyEtaGroup.defineHistogram(
'eta,energy;CellsXEta',
path='',
type='TProfile',
title='Tile Cell Energy vs #eta;#eta;Mean Cell Energy [GeV]',
xbins=17,
xmin=-1.7,
xmax=1.7)
# 10) Configure histogram with mean Tile cell energy in GeV vs phi
energyPhiGroup = helper.addGroup(tileCalCellMonAlg, 'CellsXPhi', topPath)
energyPhiGroup.defineHistogram(
'phi,energy;CellsXPhi',
path='',
type='TProfile',
title='Tile Cell Energy vs #phi;#phi;Mean Cell Energy [GeV]',
xbins=64,
xmin=-3.14,
xmax=3.14)
# 11) Configure histogram with mean Tile cell energy in GeV vs tower
energyTowerGroup = helper.addGroup(tileCalCellMonAlg, 'CellsXTower',
topPath)
energyTowerGroup.defineHistogram(
'tower,energy;CellsXTower',
path='',
type='TProfile',
title='Tile Cell Energy vs tower;Tower;Mean Cell Energy [GeV]',
xbins=18,
xmin=0,
xmax=18)
# 12) Configure histogram with occupancy map over threshold vs eta and phi
occupEtaPhiGroup = helper.addGroup(tileCalCellMonAlg, 'CellsXEtaVSPhi',
topPath)
occupEtaPhiTitle = (
'Number of Tile Cell above threshold %s MeV;#eta;#phi' %
kwargs['EnergyThreshold'])
occupEtaPhiGroup.defineHistogram('eta,phi;CellsXEtaVSPhi',
path='',
type='TH2F',
title=occupEtaPhiTitle,
xbins=17,
xmin=-1.7,
xmax=1.7,
ybins=64,
ymin=-3.14,
ymax=3.14)
# 13) Configure histograms with mean Tile cell energy vs module per sample
samples = ['A', 'BC', 'D', 'E']
energyModuleArray = helper.addArray([len(samples)],
tileCalCellMonAlg,
'CellsXModule',
topPath=topPath)
for postfix, tool in energyModuleArray.Tools.items():
sampleIdx = int(postfix.split('_')[1])
sample = samples[sampleIdx]
title = ('Tile Sampling %s' %
sample) + ';Module;Mean Cell Energy [GeV]'
name = 'module,energy;CellsXModuleS' + str(sampleIdx + 1)
tool.defineHistogram(name,
title=title,
type='TProfile',
xbins=64,
xmin=1,
xmax=65)
accumalator = helper.result()
cfg.merge(accumalator)
return cfg
def RpcMonitoringConfig(inputFlags):
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'RpcMonitoringConfig')
from AthenaConfiguration.ComponentFactory import CompFactory
RPCMonitorAlgorithm = CompFactory.RPCMonitorAlgorithm
rpcMonitorAlg = helper.addAlgorithm(RPCMonitorAlgorithm,
"RPCMonitorAlgorithmAlg")
# set properties of algorithm RPCMonitorAlgorithm
rpcMonitorAlg.MinRoIDR = 0.3
rpcMonitorAlg.MinPt = 2000
rpcMonitorAlg.MuQuality = 1
myGroup = helper.addGroup(rpcMonitorAlg, 'RPCMonitorAlgorithm',
'Muon/MuonRawDataMonitoring/RPC/')
myGroup.defineHistogram('run;Run',
title='Run Number;run;Events',
type='TH1I',
path='PlotCand',
xbins=1000000,
xmin=-0.5,
xmax=999999.5)
myGroup.defineHistogram('nMu;NMuon',
title='Number of Muons;nMuons;Events',
type='TH1I',
path='PlotCand',
xbins=10,
xmin=-0.5,
xmax=9.5)
myGroup.defineHistogram('nMuBarrel;NMuonBarrel',
title='Number of Barrel Muons;nMuons;Events',
type='TH1I',
path='PlotCand',
xbins=5,
xmin=-0.5,
xmax=4.5)
myGroup.defineHistogram('muPtCollection;MuonPt',
title='muon Pt;Pt[MeV];Muons',
type='TH1D',
path='PlotCand',
xbins=200,
xmin=0,
xmax=1000e3)
myGroup.defineHistogram('roiEtaCollection;roiEta',
title='roi eta;roi #eta;rois',
type='TH1D',
path='PlotCand',
xbins=50,
xmin=-2.5,
xmax=2.5)
myGroup.defineHistogram('roiBarrelEtaCollection;roiBarrelEta',
title='Barrel roi eta;roi #eta;rois',
type='TH1D',
path='PlotCand',
xbins=50,
xmin=-2.5,
xmax=2.5)
myGroup.defineHistogram('roiBarrelThrCollection;roiBarrelThrs',
title='Barrel roi threshold;roi threshold;rois',
type='TH1I',
path='PlotCand',
xbins=6,
xmin=0.5,
xmax=6.5)
myGroup.defineHistogram('ptDen;Pt',
title='muon Pt;Pt[MeV];Muons',
type='TH1D',
path='TriggerEff/Denominator',
xbins=150,
xmin=0.0,
xmax=150.0e3)
myGroup.defineHistogram('ptDen;Pt_bins',
title='muon Pt;Pt[MeV];Muons',
type='TH1D',
path='TriggerEff/Denominator',
xbins=[
0, 3.0e3, 4.0e3, 5.0e3, 6.0e3, 7.0e3, 8.0e3,
10.0e3, 12.0e3, 15.0e3, 20.0e3, 25.0e3, 30.0e3,
40.0e3, 60.0e3, 80.0e3, 81.0e3
])
myGroup.defineHistogram('ptNumThr1;Pt',
title='muon Pt;Pt[MeV];Muons',
type='TH1D',
path='TriggerEff/Thr1',
xbins=150,
xmin=0.0,
xmax=150.0e3)
myGroup.defineHistogram('ptNumThr1;Pt_bins',
title='muon Pt;Pt[MeV];Muons',
type='TH1D',
path='TriggerEff/Thr1',
xbins=[
0, 3.0e3, 4.0e3, 5.0e3, 6.0e3, 7.0e3, 8.0e3,
10.0e3, 12.0e3, 15.0e3, 20.0e3, 25.0e3, 30.0e3,
40.0e3, 60.0e3, 80.0e3, 81.0e3
])
myGroup.defineHistogram('etaDen,phiDen;barrel_eta_phi',
type='TH2D',
title='muons;#eta;#phi',
path='TriggerEff/Denominator',
xbins=42,
xmin=-1.05,
xmax=1.05,
ybins=32,
ymin=-3.1415926,
ymax=3.1415926)
myGroup.defineHistogram('etaNumThr1,phiNumThr1;barrel_eta_phi',
type='TH2D',
title='muons;#eta;#phi',
path='TriggerEff/Thr1',
xbins=42,
xmin=-1.05,
xmax=1.05,
ybins=32,
ymin=-3.1415926,
ymax=3.1415926)
myGroup.defineHistogram(
'isPassed,ptDen;eff_vs_Pt',
title='Trigger Efficiency;Pt[MeV];#epsilon',
type='TEfficiency',
path='TriggerEff',
#xbins=[0,3.0e3,4.0e3,5.0e3,6.0e3,7.0e3,8.0e3,10.0e3,12.0e3,15.0e3,20.0e3,25.0e3,30.0e3,40.0e3,60.0e3,80.0e3,81.0e3])
xbins=10,
xmin=0.0,
xmax=80.0e3)
myGroup.defineHistogram('isPassed,etaDen,phiDen;eff_vs_eta_phi',
title='Trigger Efficiency;#eta;#phi;#epsilon',
type='TEfficiency',
path='TriggerEff',
xbins=42,
xmin=-1.05,
xmax=1.05,
ybins=32,
ymin=-3.1415926,
ymax=3.1415926)
return helper.result()
def TrigHLTMonConfig(inputFlags):
'''Function to configure general HLT algorithms in the monitoring system.'''
################################
# HLT general monitoring
# The following class will make a sequence, configure algorithms, and link
# them to GenericMonitoringTools
from AthenaMonitoring import AthMonitorCfgHelper
helper = AthMonitorCfgHelper(inputFlags, 'TrigHLTAthMonitorCfg')
### STEP 2 ###
# Adding algorithms to the helper.
# The added algorithm must exist as a .h file
from AthenaConfiguration.ComponentFactory import CompFactory
#trigHLTMonAlg = helper.addAlgorithm(CompFactory.TrigHLTMonitorAlgorithm,'TrigHLTMonAlg')
cfgsvc = CompFactory.TrigConf.xAODConfigSvc('xAODConfigSvc')
helper.resobj.addService(cfgsvc)
trigHLTMonAlg = helper.addAlgorithm(CompFactory.TrigHLTMonitorAlgorithm,
'TrigHLTMonAlg')
trigHLTMonAlg.TrigConfigSvc = cfgsvc
#signatureTrigHLTMonAlg = helper.addAlgorithm(CompFactory.TrigHLTMonitorAlgorithm,'SignatureTrigHLTMonAlg')
### STEP 3 ###
# Edit properties of a algorithm
# Placeholder
### STEP 4 ###
# Add a generic monitoring tool (a "group" in old language).
hltGroup = helper.addGroup(trigHLTMonAlg, 'TrigHLTMonitor',
'HLT/ResultMon/')
# Add a GMT for the other example monitor algorithm
#signatureGroup = helper.addGroup(signatureTrigHLTMonAlg,'TrigHLTMonitor','HLT/ResultMon/')
### STEP 5 ###
# Configure histograms
#NB! The histograms defined here must match the ones in the cxx file exactly
hltGroup.defineHistogram('HLTResultHLT',
title='HLT Result PLACEHOLDER;result;Events',
path='',
xbins=3,
xmin=0,
xmax=3)
consistency_names = [
'SMK DB NULL', 'SMK BS NULL', 'SMK Inconsistent',
'HLT Prescale DB NULL', 'HLT Prescale BS NULL',
'HLT Prescale Inconsistent', 'No HLTResult'
]
hltGroup.defineHistogram('ConfigConsistency_HLT',
title='ConfigConsistency_HLT;;Events',
path='',
xbins=7,
xmin=1,
xmax=8,
xlabels=consistency_names)
hltGroup.defineHistogram('placeholder_hlt',
title='Placeholder;X;Y',
path='AllChains',
xbins=1000000,
xmin=-0.5,
xmax=999999.5)
#Summary histograms for the signatures
hltGroup.defineHistogram('placeholder_ele',
title='Placeholder;X;Y',
path='Electrons',
xbins=1000000,
xmin=-0.5,
xmax=999999.5)
### STEP 6 ###
# Finalize.
return helper.result()
