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###############################################################################
# Way to use this:
# cmsRun runHcalCellCountRun4_cfg.py geometry=D110
#
# Options for geometry D95, D96, D98, D99, D100, D101, D102, D103, D104,
# D105, D106, D107, D108, D109, D110, D111, D112, D113,
# D114, D115, D116
#
###############################################################################
import FWCore.ParameterSet.Config as cms
import os, sys, importlib, re
import FWCore.ParameterSet.VarParsing as VarParsing
####################################################################
### SETUP OPTIONS
options = VarParsing.VarParsing('standard')
options.register('geometry',
"D110",
VarParsing.VarParsing.multiplicity.singleton,
VarParsing.VarParsing.varType.string,
"geometry of operations: D95, D96, D98, D99, D100, D101, D102, D103, D104, D105, D106, D107, D108, D109, D110, D111, D112, D113, D114, D115, D116")
### get and parse the command line arguments
options.parseArguments()
print(options)
####################################################################
# Use the options
geomFile = "Configuration.Geometry.GeometryExtendedRun4" + options.geometry + "Reco_cff"
geomName = "Run4" + options.geometry
print("Geometry Name: ", geomName)
print("Geom file Name: ", geomFile)
import Configuration.Geometry.defaultPhase2ConditionsEra_cff as _settings
GLOBAL_TAG, ERA = _settings.get_era_and_conditions(geomName)
print("Global Tag Name: ", GLOBAL_TAG)
print("Era Name: ", ERA)
process = cms.Process('HcalCellCount',ERA)
process.load('Configuration.StandardSequences.Services_cff')
process.load('SimGeneral.HepPDTESSource.pythiapdt_cfi')
process.load('FWCore.MessageService.MessageLogger_cfi')
process.load('Configuration.EventContent.EventContent_cff')
process.load(geomFile)
process.load('Configuration.StandardSequences.MagneticField_cff')
process.load('Configuration.StandardSequences.Generator_cff')
process.load('IOMC.EventVertexGenerators.VtxSmearedRealisticHLLHC_cfi')
process.load('GeneratorInterface.Core.genFilterSummary_cff')
process.load('Configuration.StandardSequences.SimIdeal_cff')
process.load('Configuration.StandardSequences.EndOfProcess_cff')
process.load('Configuration.StandardSequences.FrontierConditions_GlobalTag_cff')
process.load('Geometry.HcalTowerAlgo.hcalCellCount_cfi')
process.MessageLogger.G4cout=dict()
process.maxEvents = cms.untracked.PSet(
input = cms.untracked.int32(1)
)
if hasattr(process,'MessageLogger'):
process.MessageLogger.HCalGeom=dict()
process.source = cms.Source("EmptySource")
process.generator = cms.EDProducer("FlatRandomPtGunProducer",
PGunParameters = cms.PSet(
PartID = cms.vint32(13),
MinEta = cms.double(-2.5),
MaxEta = cms.double(2.5),
MinPhi = cms.double(-3.14159265359),
MaxPhi = cms.double(3.14159265359),
MinPt = cms.double(9.99),
MaxPt = cms.double(10.01)
),
AddAntiParticle = cms.bool(False),
Verbosity = cms.untracked.int32(0),
firstRun = cms.untracked.uint32(1)
)
process.options = cms.untracked.PSet(
IgnoreCompletely = cms.untracked.vstring(),
Rethrow = cms.untracked.vstring(),
TryToContinue = cms.untracked.vstring(),
accelerators = cms.untracked.vstring('*'),
allowUnscheduled = cms.obsolete.untracked.bool,
canDeleteEarly = cms.untracked.vstring(),
deleteNonConsumedUnscheduledModules = cms.untracked.bool(True),
dumpOptions = cms.untracked.bool(False),
emptyRunLumiMode = cms.obsolete.untracked.string,
eventSetup = cms.untracked.PSet(
forceNumberOfConcurrentIOVs = cms.untracked.PSet(
allowAnyLabel_=cms.required.untracked.uint32
),
numberOfConcurrentIOVs = cms.untracked.uint32(0)
),
fileMode = cms.untracked.string('FULLMERGE'),
forceEventSetupCacheClearOnNewRun = cms.untracked.bool(False),
holdsReferencesToDeleteEarly = cms.untracked.VPSet(),
makeTriggerResults = cms.obsolete.untracked.bool,
modulesToCallForTryToContinue = cms.untracked.vstring(),
modulesToIgnoreForDeleteEarly = cms.untracked.vstring(),
numberOfConcurrentLuminosityBlocks = cms.untracked.uint32(0),
numberOfConcurrentRuns = cms.untracked.uint32(1),
numberOfStreams = cms.untracked.uint32(0),
numberOfThreads = cms.untracked.uint32(1),
printDependencies = cms.untracked.bool(False),
sizeOfStackForThreadsInKB = cms.optional.untracked.uint32,
throwIfIllegalParameter = cms.untracked.bool(True),
wantSummary = cms.untracked.bool(False)
)
process.ProductionFilterSequence = cms.Sequence(process.generator)
from Configuration.AlCa.GlobalTag import GlobalTag
process.GlobalTag = GlobalTag(process.GlobalTag, GLOBAL_TAG, '')
# Path and EndPath definitions
process.generation_step = cms.Path(process.pgen)
process.simulation_step = cms.Path(process.psim)
process.genfiltersummary_step = cms.EndPath(process.genFilterSummary)
process.endjob_step = cms.EndPath(process.endOfProcess)
process.analysis_step = cms.EndPath(process.hcalCellCount)
# Schedule definition
process.schedule = cms.Schedule(process.generation_step,
process.genfiltersummary_step,
process.simulation_step,
process.analysis_step,
process.endjob_step)
from PhysicsTools.PatAlgos.tools.helpers import associatePatAlgosToolsTask
associatePatAlgosToolsTask(process)
# filter all path with the production filter sequence
for path in process.paths:
getattr(process,path).insert(0, process.ProductionFilterSequence)
process.g4SimHits.UseMagneticField = False
process.g4SimHits.Physics.DefaultCutValue = 10.
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