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Functions | Variables
parallelization Namespace Reference

Functions

def adjust_pset (cmsrunfilename, savefilename, par_list)
 
def cleanupandexit (filelist)
 
def uint (string)
 

Variables

 action
 
 actual_int_jobs
 Integrate ##. More...
 
 args
 
 build_log
 
 build_name
 
 choices
 
 cleanupfiles
 
 default
 
 help
 
 int
 
 integration_log
 
 integration_name
 
 parameters
 Execute the different run modes. More...
 
 parser
 Get command line arguments. More...
 
 process
 
 processes
 Run mode ##. More...
 
 run_log
 
 run_name
 
 shell
 
 stderr
 
 stdout
 
 template_name
 
 type
 
 uint
 

Function Documentation

◆ adjust_pset()

def parallelization.adjust_pset (   cmsrunfilename,
  savefilename,
  par_list 
)
Takes the cmsRun filem, removes all occurences of runMode, jobs,
   maxJobs and integrationList parameters in the process.generator
   part.
   The the parameters in par_list are set instead and saved.

Definition at line 60 of file parallelization.py.

References FastTimerService_cff.range.

60 def adjust_pset(cmsrunfilename, savefilename, par_list):
61  """Takes the cmsRun filem, removes all occurences of runMode, jobs,
62  maxJobs and integrationList parameters in the process.generator
63  part.
64  The the parameters in par_list are set instead and saved.
65  """
66 
67  with open(cmsrunfilename, 'r') as readfile: parsestring = readfile.read()
68 
69  # get first opening bracket after process.generator
70  begin_gen_step = parsestring.find('(', parsestring.find('process.generator'))
71 
72  # find matching bracket
73  end_gen_step = begin_gen_step
74  bracket_counter = 1
75  for position in range(begin_gen_step+1, len(parsestring)):
76  if parsestring[position] == '(':
77  bracket_counter += 1
78  if parsestring[position] == ')':
79  bracket_counter -= 1
80  if not bracket_counter:
81  end_gen_step = position
82  break
83 
84  # get string between brackets
85  gen_string = parsestring[begin_gen_step+1:end_gen_step]
86 
87  # remove all parameters that would interfere
88  gen_string = re.sub(r',\s*runModeList\s*=\s*cms.untracked.string\((.*?)\)', '', gen_string)
89  gen_string = re.sub(r',\s*jobs\s*=\s*cms.untracked.int32\((.*?)\)', '', gen_string)
90  gen_string = re.sub(r',\s*integrationList\s*=\s*cms.untracked.string\((.*?)\)', '', gen_string)
91  gen_string = re.sub(r',\s*maxJobs\s*=\s*cms.untracked.uint32\((.*?)\)', '', gen_string)
92  gen_string = re.sub(r',\s*seed\s*=\s*cms.untracked.int32\((.*?)\)', '', gen_string)
93 
94 
95  # write the savefile with all parameters given in par_list
96  with open(savefilename,'w') as savefile:
97  savefile.write(parsestring[:begin_gen_step+1])
98  savefile.write(gen_string)
99  for item in par_list:
100  savefile.write(',\n')
101  savefile.write(item)
102  savefile.write(parsestring[end_gen_step:])
103 
104 
105 
106 
def adjust_pset(cmsrunfilename, savefilename, par_list)

◆ cleanupandexit()

def parallelization.cleanupandexit (   filelist)
Delete the files in filelist and exit

Definition at line 107 of file parallelization.py.

107 def cleanupandexit(filelist):
108  """Delete the files in filelist and exit"""
109  for filename in filelist:
110  os.remove(filename)
111  sys.exit(0)
112 
113 
114 
115 
def cleanupandexit(filelist)

◆ uint()

def parallelization.uint (   string)
Unsigned int type

Definition at line 50 of file parallelization.py.

References int, and uint.

50 def uint(string):
51  """Unsigned int type"""
52  value = int(string)
53  if value < 0:
54  msg = '{0} is negative'.format(string)
55  raise argparse.ArgumentTypeError(msg)
56  return value
57 
58 
59 
def uint(string)

Variable Documentation

◆ action

parallelization.action

Definition at line 126 of file parallelization.py.

◆ actual_int_jobs

parallelization.actual_int_jobs

Integrate ##.

Definition at line 192 of file parallelization.py.

◆ args

parallelization.args

Definition at line 132 of file parallelization.py.

◆ build_log

parallelization.build_log

Definition at line 172 of file parallelization.py.

◆ build_name

parallelization.build_name

Definition at line 159 of file parallelization.py.

◆ choices

parallelization.choices

Definition at line 123 of file parallelization.py.

◆ cleanupfiles

parallelization.cleanupfiles

Definition at line 135 of file parallelization.py.

◆ default

parallelization.default

Definition at line 123 of file parallelization.py.

◆ help

parallelization.help

Definition at line 122 of file parallelization.py.

◆ int

parallelization.int

Definition at line 123 of file parallelization.py.

Referenced by uint().

◆ integration_log

parallelization.integration_log

Definition at line 220 of file parallelization.py.

◆ integration_name

parallelization.integration_name

Definition at line 211 of file parallelization.py.

◆ parameters

parallelization.parameters

Execute the different run modes.

Build ##

Definition at line 154 of file parallelization.py.

◆ parser

parallelization.parser

Get command line arguments.

Definition at line 120 of file parallelization.py.

◆ process

parallelization.process

Definition at line 172 of file parallelization.py.

◆ processes

parallelization.processes

Run mode ##.

This part uses the parallelization of the run step provided by Herwig. At the moment it is not usable. if args.run != 0: parameters = ['runModeList = cms.untracked.string(\'run\')'] parameters.append('jobs = cms.untracked.int32(' + str(args.run) + ')')

run_name = template_name + '_run.py' adjust_pset(args.cmsRunfile, run_name, parameters) cleanupfiles.append(run_name)

print 'Setting up {0} run jobs.'.format(str(args.run)) print 'Calling
\'cmsRun ' + run_name + '\' the Herwig run step.'.format(str(args.run)) process = subprocess.Popen(['cmsRun ' + run_name], shell=True) process.wait() print '------------——' print 'Run step finished.' print '------------——' This is the alternative for a paralellized run step. cmsRun is called as often as give with the option -r/–run. So the total number of generated events is a corresponding multiple of the number of events given in the cmsRun file.

Definition at line 205 of file parallelization.py.

◆ run_log

parallelization.run_log

Definition at line 295 of file parallelization.py.

◆ run_name

parallelization.run_name

Definition at line 272 of file parallelization.py.

◆ shell

parallelization.shell

Definition at line 174 of file parallelization.py.

◆ stderr

parallelization.stderr

Definition at line 172 of file parallelization.py.

◆ stdout

parallelization.stdout

Definition at line 172 of file parallelization.py.

◆ template_name

parallelization.template_name

Definition at line 138 of file parallelization.py.

◆ type

parallelization.type

Definition at line 123 of file parallelization.py.

◆ uint

parallelization.uint

Definition at line 124 of file parallelization.py.

Referenced by SiStripMonitorDigi.AddApvShotsToSubDet(), FWRecoGeometryESProducer.addCaloGeometry(), L1Scalers.analyze(), SiStripMonitorHLT.analyze(), SiStripMonitorDigi.analyze(), MonitorTrackResidualsBase< pixel_or_strip >.analyze(), SiStripMonitorCluster.analyze(), SiPixelTrackResidualSource.analyze(), SiPixelHitEfficiencySource.analyze(), TkConvValidator.analyze(), SiStripNoisesFromDBMiscalibrator.analyze(), L1TS2PFJetInputPatternWriter.analyze(), MuIsoValidation.analyze(), L1Validator.analyze(), TrackingMonitor.analyze(), JetHTAnalyzer.analyze(), ZToMuMuGammaAnalyzer.analyze(), SplitVertexResolution.analyze(), PhotonAnalyzer.analyze(), OverlapValidation.analyzeTrajectory(), Phase2L1GMT::ROITempAssociator.associate(), reco::tau::PFRecoTauDiscriminationByMVAIsolationRun2.beginEvent(), SiPixelLorentzAnglePCLHarvester.beginRun(), PhotonOfflineClient.book2DHistoVector(), PhotonAnalyzer.book2DHistoVector(), PhotonOfflineClient.book3DHistoVector(), PhotonAnalyzer.book3DHistoVector(), L1Scalers.bookHistograms(), SiPixelPhase1MonitorTrackSoA.bookHistograms(), TrackingMonitor.bookHistograms(), PhotonAnalyzer.bookHistogramsEfficiency(), TriggerDQMBase.bookME(), TrackerOfflineValidation.bookSummaryHists(), CmsMTDConstruction< FilteredView >.buildBTLModule(), L1TPhase2GMTEndcapStubProcessor.buildCSCOnlyStub(), CmsMTDConstruction< FilteredView >.buildETLModule(), L1TPhase2GMTEndcapStubProcessor.buildRPCOnlyStub(), L1TPhase2GMTBarrelStubProcessor.buildStub(), L1TMuonBarrelKalmanStubProcessor.buildStub(), L1TPhase2GMTBarrelStubProcessor.buildStubNoEta(), L1MetPfProducer.CalcMetHLS(), tmtt::ChiSquaredFitBase.calculateChiSq(), L1TMuonBarrelKalmanAlgo.calculateEta(), GsfElectronAlgo.calculateShowerShape(), EffectiveAreas.checkConsistency(), riemannFit.circleFit(), FlagsCleanerECAL.clean(), L1TMuonBarrelKalmanAlgo.clean(), Phase2L1GMT::TrackMuonMatchAlgorithm.clean(), L1TMuonBarrelKalmanRegionModule.cleanHigher(), L1TMuonBarrelKalmanRegionModule.cleanLower(), Phase2L1GMT::TrackMuonMatchAlgorithm.cleanNeighbor(), L1TMuonBarrelKalmanLUTs.coarseEta(), L1TPhase2GMTEndcapStubProcessor.combineStubs(), riemannFit.computeRadLenUniformMaterial(), Phase2L1GMT::TrackConverter.convert(), EERecHitFromSoA.convert_soa_data_to_collection_(), HEFRecHitFromSoA.convert_soa_data_to_collection_(), HEBRecHitFromSoA.convert_soa_data_to_collection_(), JetCoreMCtruthSeedGenerator.coreTracksFilling(), JetCoreMCtruthSeedGenerator.coreTracksFillingDeltaR(), riemannFit.cov_carttorad(), riemannFit.cov_carttorad_prefit(), riemannFit.cov_radtocart(), GsfElectronAlgo.createElectron(), PFPhotonTranslator.createPhotons(), BeamSpotPI::BSParamsHelper< PayloadType >.diffCentralValues(), BeamSpotPI::BSParamsHelper< PayloadType >.diffErrors(), PFRecoTauDiscriminationByNProngs.discriminate(), CSCOfflineMonitor.doEfficiencies(), HLTMuonCertSummary.dqmEndJob(), EcalDAQTowerStatusXMLTranslator.dumpXML(), EcalDCSTowerStatusXMLTranslator.dumpXML(), L1TStage2InputPatternWriter.endJob(), L1TS2PFJetInputPatternWriter.endJob(), GlobalHitsProdHistStripper.endRun(), L1TMuonBarrelKalmanAlgo.estimateChiSquare(), L1TMuonBarrelKalmanAlgo.estimateCompatibility(), Phase2L1GMT::TrackConverter.etaLookup(), egammaTools::EgammaDNNHelper.evaluate(), reco::DeepSCGraphEvaluation.evaluate(), reco::EcalClustersGraph.evaluateScores(), VariableNTupler.fill(), StringBasedNTupler.fill(), SiStripMonitorDigi.FillApvShotsMap(), PixelVertexCollectionTrimmer.fillDescriptions(), PuppiProducer.fillDescriptions(), CTPPSPixelLocalTrackProducer.fillDescriptions(), TriggerObjectTableProducer.fillDescriptions(), PFECALSuperClusterProducer.fillDescriptions(), L2TauNNProducer.fillDescriptions(), TriggerDQMBase.fillHistoLSPSetDescription(), TriggerDQMBase.fillHistoPSetDescription(), PhotonProducer.fillPhotonCollection(), GEDPhotonProducer.fillPhotonCollection(), reco::EcalClustersGraph.fillVariables(), PythiaFilterMultiAncestor.filter(), L1Validator.FindBest(), L1TMuonBarrelKalmanAlgo.getByCode(), EffectiveAreas.getEffectiveArea(), ZElectronsSelector.getEffectiveArea(), TrackerOfflineValidation.getHistStructFromMap(), EffectiveAreas.getLinearEA(), PixelInactiveAreaFinder.getPhiSpanBarrel(), L1TTauOffline.getProbeTaus(), EffectiveAreas.getQuadraticEA(), reco::GsfElectron.hcalToRun2EffDepth(), riemannFit.helixFit(), HLTJetTimingFilter< T >.hltFilter(), egammaTools::EgammaDNNHelper.initScalerFiles(), reco::EcalClustersGraph.initWindows(), L1TowerCalibrator.L1TowerCalibrator(), riemannFit.lineFit(), PixelCPEGeneric.localError(), L1TMuonBarrelKalmanStubProcessor.makeStubs(), LowPtConversion.match(), L1TMuonBarrelKalmanAlgo.match(), SiStripTrackerMapCreator.paintTkMapFromAlarm(), EcalDAQTowerStatusXMLTranslator.plot(), EcalDCSTowerStatusXMLTranslator.plot(), PlotAlignmentValidation.plotDMRHistogram(), TrackerOfflineValidation.prepareSummaryHists(), BeamSpotPI::BSParamsHelper< PayloadType >.printDebug(), EffectiveAreas.printEffectiveAreas(), ZElectronsSelector.printEffectiveAreas(), reco::GraphMap.printGraphMap(), riemannFit.printIt(), l1t::Stage2Layer2DemuxSumsAlgoFirmwareImp1.processEvent(), Phase2L1GMT::TrackMuonMatchAlgorithm.processTrack(), Phase2L1TGMTProducer.produce(), L1TMuonBarrelKalmanTrackProducer.produce(), Phase2L1TGMTStubProducer.produce(), MultShiftMETcorrInputProducer.produce(), L1TMuonBarrelKalmanStubProducer.produce(), PuppiProducer.produce(), HiEvtPlaneFlatProducer.produce(), Phase2L1TGMTSAMuonProducer.produce(), HLTJetHFCleaner< JetType >.produce(), PixelJetPuId.produce(), JetCoreMCtruthSeedGenerator.produce(), EvtPlaneProducer.produce(), Phase2L1GMT::TrackMuonMatchAlgorithm.propagate(), Phase2L1GMT::TrackConverter.ptLookup(), PuppiProducer.PuppiProducer(), L1TMuonBarrelKalmanAlgo.rank(), L1TCaloParamsOnlineProd.readCaloLayer2OnlineSettings(), CompleteNTupler.registerleaves(), VariableNTupler.registerleaves(), StringBasedNTupler.registerleaves(), MuonTestSummary.ResidualCheck(), PhotonOfflineClient.retrieveHisto(), RPixPlaneCombinatoryTracking.RPixPlaneCombinatoryTracking(), PhotonOfflineClient.runClient(), riemannFit.scatter_cov_rad(), riemannFit.scatterCovLine(), reco::SCProducerCache.SCProducerCache(), JetCoreMCtruthSeedGenerator.seedParFilling(), HGCalConcentratorAutoEncoderImpl.select(), StringCutEventSelector< Object, any >.select(), StringCutsEventSelector< Object, existenceMatter >.select(), L1TMuonBarrelKalmanRegionModule.selfClean(), TrackingMonitor.setMaxMinBin(), TrackingMonitor.setNclus(), StringBasedNTupler.StringBasedNTupler(), StringBranchHelper< Object, Collection >.StringBranchHelper(), TauDiscriminantCutMultiplexerT< TauType, TauTypeRef, ParentClass >.TauDiscriminantCutMultiplexerT(), trklet::FitTrack.trackFitChisq(), uint(), l1t::stage1.unpack_em(), l1t::stage1.unpack_region(), RctRawToDigi.unpackCTP7(), L1TMuonBarrelKalmanAlgo.updateLUT(), VariableNTupler.VariableNTupler(), L1TMuonBarrelKalmanAlgo.vertexConstraintLUT(), and L1TMuonBarrelKalmanSectorProcessor.wedgeSort().