#include <MuScleFit.h>
Public Member Functions | |
void | beginOfJobInConstructor () |
void | beginOfJobInConstructor () |
virtual void | duringFastLoop () |
virtual void | duringFastLoop () |
virtual edm::EDLooper::Status | duringLoop (const edm::Event &event, const edm::EventSetup &eventSetup) |
virtual edm::EDLooper::Status | duringLoop (const edm::Event &event, const edm::EventSetup &eventSetup) |
virtual void | endOfFastLoop (const unsigned int iLoop) |
virtual void | endOfFastLoop (const unsigned int iLoop) |
virtual void | endOfJob () |
virtual void | endOfJob () |
virtual edm::EDLooper::Status | endOfLoop (const edm::EventSetup &eventSetup, unsigned int iLoop) |
virtual edm::EDLooper::Status | endOfLoop (const edm::EventSetup &eventSetup, unsigned int iLoop) |
template<typename T > | |
std::vector< reco::LeafCandidate > | fillMuonCollection (const std::vector< T > &tracks) |
template<typename T > | |
std::vector< reco::LeafCandidate > | fillMuonCollection (const std::vector< T > &tracks) |
MuScleFit (const edm::ParameterSet &pset) | |
MuScleFit (const edm::ParameterSet &pset) | |
virtual void | startingNewLoop (unsigned int iLoop) |
virtual void | startingNewLoop (unsigned int iLoop) |
virtual | ~MuScleFit () |
virtual | ~MuScleFit () |
Protected Member Functions | |
void | applyBias (reco::Particle::LorentzVector &mu, const int charge) |
Apply the bias if needed using the function in MuScleFitUtils. | |
void | applyBias (reco::Particle::LorentzVector &mu, const int charge) |
Apply the bias if needed using the function in MuScleFitUtils. | |
void | applySmearing (reco::Particle::LorentzVector &mu) |
Apply the smearing if needed using the function in MuScleFitUtils. | |
void | applySmearing (reco::Particle::LorentzVector &mu) |
Apply the smearing if needed using the function in MuScleFitUtils. | |
bool | checkDeltaR (reco::Particle::LorentzVector &genMu, reco::Particle::LorentzVector &recMu) |
Check if two lorentzVector are near in deltaR. | |
bool | checkDeltaR (reco::Particle::LorentzVector &genMu, reco::Particle::LorentzVector &recMu) |
Check if two lorentzVector are near in deltaR. | |
void | checkParameters () |
void | checkParameters () |
void | fillComparisonHistograms (const reco::Particle::LorentzVector &genMu, const reco::Particle::LorentzVector &recoMu, const std::string &inputName, const int charge) |
Fill the reco vs gen and reco vs sim comparison histograms. | |
void | fillComparisonHistograms (const reco::Particle::LorentzVector &genMu, const reco::Particle::LorentzVector &recoMu, const std::string &inputName, const int charge) |
Fill the reco vs gen and reco vs sim comparison histograms. | |
void | selectMuons (const int maxEvents, const TString &treeFileName) |
void | selectMuons (const edm::Event &event) |
void | selectMuons (const int maxEvents, const TString &treeFileName) |
void | selectMuons (const edm::Event &event) |
bool | selGlobalMuon (const pat::Muon *aMuon) |
Function for onia selections. | |
bool | selGlobalMuon (const pat::Muon *aMuon) |
Function for onia selections. | |
bool | selTrackerMuon (const pat::Muon *aMuon) |
bool | selTrackerMuon (const pat::Muon *aMuon) |
template<typename T > | |
void | takeSelectedMuonType (const T &muon, std::vector< reco::Track > &tracks) |
Template method used to fill the track collection starting from reco::muons or pat::muons. | |
template<typename T > | |
void | takeSelectedMuonType (const T &muon, std::vector< reco::Track > &tracks) |
Template method used to fill the track collection starting from reco::muons or pat::muons. | |
Protected Attributes | |
bool | compareToSimTracks_ |
bool | fastLoop |
std::string | genParticlesName_ |
int | iev |
bool | ifGenPart |
bool | ifHepMC |
std::string | inputRootTreeFileName_ |
unsigned int | loopCounter |
int | maxEventsFromRootTree_ |
unsigned int | maxLoopNumber |
double | maxResMass_hwindow [6] |
double | minResMass_hwindow [6] |
std::auto_ptr < MuScleFitMuonSelector > | muonSelector_ |
bool | negateTrigger_ |
int | numberOfEwkZ |
int | numberOfSimMuons |
int | numberOfSimTracks |
int | numberOfSimVertices |
std::string | outputRootTreeFileName_ |
bool | PATmuons_ |
MuScleFitPlotter * | plotter |
reco::Particle::LorentzVector | recMu1 |
reco::Particle::LorentzVector | recMu2 |
bool | saveAllToTree_ |
edm::InputTag | simTracksCollection_ |
MuonServiceProxy * | theService |
int | totalEvents_ |
std::string | triggerPath_ |
std::vector< std::string > | triggerPath_ |
std::string | triggerResultsLabel_ |
std::string | triggerResultsProcess_ |
Analyzer of the Global muon tracks
Analyzer of the Global muon tracks
Definition at line 185 of file MuScleFit.cc.
MuScleFit::MuScleFit | ( | const edm::ParameterSet & | pset | ) |
Definition at line 359 of file MuScleFit.cc.
References MuScleFitUtils::backgroundHandler, beginOfJobInConstructor(), MuScleFitUtils::biasFunction, MuScleFitUtils::BiasType, checkParameters(), compareToSimTracks_, MuScleFitUtils::computeMinosErrors_, gather_cfg::cout, MuScleFitUtils::crossSectionHandler, MuScleFitUtils::debug, MuScleFitBase::debug_, MuScleFitUtils::debugMassResol_, MuScleFitUtils::deltaPhiMaxCut_, MuScleFitUtils::deltaPhiMinCut_, MuScleFitUtils::doBackgroundFit, MuScleFitUtils::doCrossSectionFit, MuScleFitUtils::doResolFit, MuScleFitUtils::doScaleFit, cmsRelvalreport::exit, fastLoop, MuScleFitUtils::FitStrategy, genParticlesName_, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), MuScleFitUtils::goodmuon, i, inputRootTreeFileName_, j, loopCounter, MuScleFitUtils::massWindowHalfWidth, maxEventsFromRootTree_, maxLoopNumber, MuScleFitUtils::maxMuonEtaFirstRange_, MuScleFitUtils::maxMuonEtaSecondRange_, MuScleFitUtils::maxMuonPt_, maxResMass_hwindow, MuScleFitUtils::minimumShapePlots_, MuScleFitUtils::minMuonEtaFirstRange_, MuScleFitUtils::minMuonEtaSecondRange_, MuScleFitUtils::minMuonPt_, minResMass_hwindow, muonSelector_, MuScleFitUtils::MuonType, MuScleFitUtils::MuonTypeForCheckMassWindow, negateTrigger_, MuScleFitUtils::normalizeLikelihoodByEventNumber_, outputRootTreeFileName_, MuScleFitUtils::parBgr, MuScleFitUtils::parBgrFix, MuScleFitUtils::parBgrOrder, MuScleFitUtils::parBias, MuScleFitUtils::parCrossSection, MuScleFitUtils::parCrossSectionFix, MuScleFitUtils::parCrossSectionOrder, MuScleFitUtils::parResol, MuScleFitUtils::parResolFix, MuScleFitUtils::parResolMax, MuScleFitUtils::parResolMin, MuScleFitUtils::parResolOrder, MuScleFitUtils::parResolStep, MuScleFitUtils::parScale, MuScleFitUtils::parScaleFix, MuScleFitUtils::parScaleMax, MuScleFitUtils::parScaleMin, MuScleFitUtils::parScaleOrder, MuScleFitUtils::parScaleStep, MuScleFitUtils::parSmear, PATmuons_, Pi, MuScleFitUtils::rapidityBinsForZ_, MuScleFitUtils::resfind, MuScleFitUtils::ResMass, MuScleFitUtils::ResolFitType, MuScleFitUtils::resolutionFunction, MuScleFitUtils::resolutionFunctionForVec, resolutionFunctionService(), resolutionFunctionVecService(), saveAllToTree_, MuScleFitUtils::ScaleFitType, MuScleFitUtils::scaleFunction, MuScleFitUtils::scaleFunctionForVec, scaleFunctionService(), scaleFunctionVecService(), MuScleFitUtils::separateRanges_, MuScleFitUtils::sherpa_, simTracksCollection_, MuScleFitUtils::smearFunction, smearFunctionService(), MuScleFitUtils::SmearType, MuScleFitUtils::speedup, mathSSE::sqrt(), MuScleFitUtils::startWithSimplex_, AlCaHLTBitMon_QueryRunRegistry::string, MuScleFitBase::theMuonLabel_, MuScleFitBase::theMuonType_, triggerPath_, triggerResultsLabel_, triggerResultsProcess_, MuScleFitUtils::useProbsFile_, and MuScleFitUtils::x.
: MuScleFitBase( pset ), totalEvents_(0) { MuScleFitUtils::debug = debug_; if (debug_>0) std::cout << "[MuScleFit]: Constructor" << std::endl; if ((theMuonType_<-4 || theMuonType_>5) && theMuonType_<10) { std::cout << "[MuScleFit]: Unknown muon type! Aborting." << std::endl; abort(); } loopCounter = 0; // Boundaries for h-function computation (to be improved!) // ------------------------------------------------------- minResMass_hwindow[0] = 71.1876; // 76.; maxResMass_hwindow[0] = 111.188; // 106.; minResMass_hwindow[1] = 10.15; maxResMass_hwindow[1] = 10.55; minResMass_hwindow[2] = 9.8; maxResMass_hwindow[2] = 10.2; minResMass_hwindow[3] = 9.25; maxResMass_hwindow[3] = 9.65; minResMass_hwindow[4] = 3.58; maxResMass_hwindow[4] = 3.78; minResMass_hwindow[5] = 3.0; maxResMass_hwindow[5] = 3.2; // Max number of loops (if > 2 then try to minimize likelihood more than once) // --------------------------------------------------------------------------- maxLoopNumber = pset.getUntrackedParameter<int>("maxLoopNumber", 2); fastLoop = pset.getUntrackedParameter<bool>("FastLoop", true); // Selection of fits according to loop MuScleFitUtils::doResolFit = pset.getParameter<std::vector<int> >("doResolFit"); MuScleFitUtils::doScaleFit = pset.getParameter<std::vector<int> >("doScaleFit"); MuScleFitUtils::doCrossSectionFit = pset.getParameter<std::vector<int> >("doCrossSectionFit"); MuScleFitUtils::doBackgroundFit = pset.getParameter<std::vector<int> >("doBackgroundFit"); // Bias and smear types // -------------------- int biasType = pset.getParameter<int>("BiasType"); MuScleFitUtils::BiasType = biasType; // No error, the scale functions are used also for the bias MuScleFitUtils::biasFunction = scaleFunctionVecService( biasType ); int smearType = pset.getParameter<int>("SmearType"); MuScleFitUtils::SmearType = smearType; MuScleFitUtils::smearFunction = smearFunctionService( smearType ); // Fit types // --------- int resolFitType = pset.getParameter<int>("ResolFitType"); MuScleFitUtils::ResolFitType = resolFitType; MuScleFitUtils::resolutionFunction = resolutionFunctionService( resolFitType ); MuScleFitUtils::resolutionFunctionForVec = resolutionFunctionVecService( resolFitType ); int scaleType = pset.getParameter<int>("ScaleFitType"); MuScleFitUtils::ScaleFitType = scaleType; MuScleFitUtils::scaleFunction = scaleFunctionService( scaleType ); MuScleFitUtils::scaleFunctionForVec = scaleFunctionVecService( scaleType ); // Initial parameters values // ------------------------- MuScleFitUtils::parBias = pset.getParameter<std::vector<double> >("parBias"); MuScleFitUtils::parSmear = pset.getParameter<std::vector<double> >("parSmear"); MuScleFitUtils::parResol = pset.getParameter<std::vector<double> >("parResol"); MuScleFitUtils::parResolStep = pset.getUntrackedParameter<std::vector<double> >("parResolStep", std::vector<double>()); MuScleFitUtils::parResolMin = pset.getUntrackedParameter<std::vector<double> >("parResolMin", std::vector<double>()); MuScleFitUtils::parResolMax = pset.getUntrackedParameter<std::vector<double> >("parResolMax", std::vector<double>()); MuScleFitUtils::parScale = pset.getParameter<std::vector<double> >("parScale"); MuScleFitUtils::parScaleStep = pset.getUntrackedParameter<std::vector<double> >("parScaleStep", std::vector<double>()); MuScleFitUtils::parScaleMin = pset.getUntrackedParameter<std::vector<double> >("parScaleMin", std::vector<double>()); MuScleFitUtils::parScaleMax = pset.getUntrackedParameter<std::vector<double> >("parScaleMax", std::vector<double>()); MuScleFitUtils::parCrossSection = pset.getParameter<std::vector<double> >("parCrossSection"); MuScleFitUtils::parBgr = pset.getParameter<std::vector<double> >("parBgr"); MuScleFitUtils::parResolFix = pset.getParameter<std::vector<int> >("parResolFix"); MuScleFitUtils::parScaleFix = pset.getParameter<std::vector<int> >("parScaleFix"); MuScleFitUtils::parCrossSectionFix = pset.getParameter<std::vector<int> >("parCrossSectionFix"); MuScleFitUtils::parBgrFix = pset.getParameter<std::vector<int> >("parBgrFix"); MuScleFitUtils::parResolOrder = pset.getParameter<std::vector<int> >("parResolOrder"); MuScleFitUtils::parScaleOrder = pset.getParameter<std::vector<int> >("parScaleOrder"); MuScleFitUtils::parCrossSectionOrder = pset.getParameter<std::vector<int> >("parCrossSectionOrder"); MuScleFitUtils::parBgrOrder = pset.getParameter<std::vector<int> >("parBgrOrder"); MuScleFitUtils::resfind = pset.getParameter<std::vector<int> >("resfind"); MuScleFitUtils::FitStrategy = pset.getParameter<int>("FitStrategy"); // Option to skip unnecessary stuff // -------------------------------- MuScleFitUtils::speedup = pset.getParameter<bool>("speedup"); // Option to skip simTracks comparison compareToSimTracks_ = pset.getParameter<bool>("compareToSimTracks"); simTracksCollection_ = pset.getUntrackedParameter<edm::InputTag>("SimTracksCollection", edm::InputTag("g4SimHits")); triggerResultsLabel_ = pset.getUntrackedParameter<std::string>("TriggerResultsLabel"); triggerResultsProcess_ = pset.getUntrackedParameter<std::string>("TriggerResultsProcess"); triggerPath_ = pset.getUntrackedParameter<std::vector<std::string> >("TriggerPath"); negateTrigger_ = pset.getUntrackedParameter<bool>("NegateTrigger", false); saveAllToTree_ = pset.getUntrackedParameter<bool>("SaveAllToTree", false); PATmuons_ = pset.getUntrackedParameter<bool>("PATmuons", false); genParticlesName_ = pset.getUntrackedParameter<std::string>("GenParticlesName", "genParticles"); // Use the probability file or not. If not it will perform a simpler selection taking the muon pair with // invariant mass closer to the pdf value and will crash if some fit is attempted. MuScleFitUtils::useProbsFile_ = pset.getUntrackedParameter<bool>("UseProbsFile", true); // This must be set to true if using events generated with Sherpa MuScleFitUtils::sherpa_ = pset.getUntrackedParameter<bool>("Sherpa", false); MuScleFitUtils::rapidityBinsForZ_ = pset.getUntrackedParameter<bool>("RapidityBinsForZ", true); // Set the cuts on muons to be used in the fit MuScleFitUtils::separateRanges_ = pset.getUntrackedParameter<bool>("SeparateRanges", true); MuScleFitUtils::maxMuonPt_ = pset.getUntrackedParameter<double>("MaxMuonPt", 100000000.); MuScleFitUtils::minMuonPt_ = pset.getUntrackedParameter<double>("MinMuonPt", 0.); MuScleFitUtils::minMuonEtaFirstRange_ = pset.getUntrackedParameter<double>("MinMuonEtaFirstRange", -6.); MuScleFitUtils::maxMuonEtaFirstRange_ = pset.getUntrackedParameter<double>("MaxMuonEtaFirstRange", 6.); MuScleFitUtils::minMuonEtaSecondRange_ = pset.getUntrackedParameter<double>("MinMuonEtaSecondRange", -100.); MuScleFitUtils::maxMuonEtaSecondRange_ = pset.getUntrackedParameter<double>("MaxMuonEtaSecondRange", 100.); MuScleFitUtils::deltaPhiMinCut_ = pset.getUntrackedParameter<double>("DeltaPhiMinCut", -100.); MuScleFitUtils::deltaPhiMaxCut_ = pset.getUntrackedParameter<double>("DeltaPhiMaxCut", 100.); MuScleFitUtils::debugMassResol_ = pset.getUntrackedParameter<bool>("DebugMassResol", false); // MuScleFitUtils::massResolComponentsStruct MuScleFitUtils::massResolComponents; // Check for parameters consistency // it will abort in case of errors. checkParameters(); // Generate array of gaussian-distributed numbers for smearing // ----------------------------------------------------------- if (MuScleFitUtils::SmearType>0) { std::cout << "[MuScleFit-Constructor]: Generating random values for smearing" << std::endl; TF1 G("G", "[0]*exp(-0.5*pow(x,2))", -5., 5.); double norm = 1/sqrt(2*TMath::Pi()); G.SetParameter (0,norm); for (int i=0; i<10000; i++) { for (int j=0; j<7; j++) { MuScleFitUtils::x[j][i] = G.GetRandom(); } } } MuScleFitUtils::goodmuon = 0; if(theMuonType_ > 0 && theMuonType_ < 4) { MuScleFitUtils::MuonTypeForCheckMassWindow = theMuonType_-1; MuScleFitUtils::MuonType = theMuonType_-1; } else if(theMuonType_ == 0 || theMuonType_ == 4 || theMuonType_ == 5 || theMuonType_ >= 10 || theMuonType_==-1 || theMuonType_==-2 || theMuonType_==-3 || theMuonType_==-4) { MuScleFitUtils::MuonTypeForCheckMassWindow = 2; MuScleFitUtils::MuonType = 2; } else{ std::cout<<"Wrong muon type "<<theMuonType_<<std::endl; exit(1); } // When using standalone muons switch to the single Z pdf if( theMuonType_ == 2 ) { MuScleFitUtils::rapidityBinsForZ_ = false; } // Initialize ResMaxSigma And ResHalfWidth - 0 = global, 1 = SM, 2 = tracker // ------------------------------------------------------------------------- MuScleFitUtils::massWindowHalfWidth[0][0] = 20.; MuScleFitUtils::massWindowHalfWidth[0][1] = 0.35; MuScleFitUtils::massWindowHalfWidth[0][2] = 0.35; MuScleFitUtils::massWindowHalfWidth[0][3] = 0.35; MuScleFitUtils::massWindowHalfWidth[0][4] = 0.2; MuScleFitUtils::massWindowHalfWidth[0][5] = 0.2; MuScleFitUtils::massWindowHalfWidth[1][0] = 50.; MuScleFitUtils::massWindowHalfWidth[1][1] = 2.5; MuScleFitUtils::massWindowHalfWidth[1][2] = 2.5; MuScleFitUtils::massWindowHalfWidth[1][3] = 2.5; MuScleFitUtils::massWindowHalfWidth[1][4] = 1.5; MuScleFitUtils::massWindowHalfWidth[1][5] = 1.5; MuScleFitUtils::massWindowHalfWidth[2][0] = 20.; MuScleFitUtils::massWindowHalfWidth[2][1] = 0.35; MuScleFitUtils::massWindowHalfWidth[2][2] = 0.35; MuScleFitUtils::massWindowHalfWidth[2][3] = 0.35; MuScleFitUtils::massWindowHalfWidth[2][4] = 0.2; MuScleFitUtils::massWindowHalfWidth[2][5] = 0.2; muonSelector_.reset(new MuScleFitMuonSelector(theMuonLabel_, theMuonType_, PATmuons_, MuScleFitUtils::resfind, MuScleFitUtils::speedup, genParticlesName_, compareToSimTracks_, simTracksCollection_, MuScleFitUtils::sherpa_, debug_)); MuScleFitUtils::backgroundHandler = new BackgroundHandler( pset.getParameter<std::vector<int> >("BgrFitType"), pset.getParameter<std::vector<double> >("LeftWindowBorder"), pset.getParameter<std::vector<double> >("RightWindowBorder"), MuScleFitUtils::ResMass, MuScleFitUtils::massWindowHalfWidth[MuScleFitUtils::MuonTypeForCheckMassWindow] ); MuScleFitUtils::crossSectionHandler = new CrossSectionHandler( MuScleFitUtils::parCrossSection, MuScleFitUtils::resfind ); // Build cross section scale factors // MuScleFitUtils::resfind MuScleFitUtils::normalizeLikelihoodByEventNumber_ = pset.getUntrackedParameter<bool>("NormalizeLikelihoodByEventNumber", true); if(debug_>0) std::cout << "End of MuScleFit constructor" << std::endl; inputRootTreeFileName_ = pset.getParameter<std::string>("InputRootTreeFileName"); outputRootTreeFileName_ = pset.getParameter<std::string>("OutputRootTreeFileName"); maxEventsFromRootTree_ = pset.getParameter<int>("MaxEventsFromRootTree"); MuScleFitUtils::startWithSimplex_ = pset.getParameter<bool>("StartWithSimplex"); MuScleFitUtils::computeMinosErrors_ = pset.getParameter<bool>("ComputeMinosErrors"); MuScleFitUtils::minimumShapePlots_ = pset.getParameter<bool>("MinimumShapePlots"); beginOfJobInConstructor(); }
MuScleFit::~MuScleFit | ( | ) | [virtual] |
Definition at line 577 of file MuScleFit.cc.
References gather_cfg::cout, MuScleFitBase::debug_, MuScleFitBase::genMuonPairs_, inputRootTreeFileName_, MuScleFitBase::muonPairs_, outputRootTreeFileName_, saveAllToTree_, MuScleFitUtils::SavedPair, findQualityFiles::size, MuScleFitUtils::speedup, MuScleFitBase::theMuonType_, totalEvents_, and RootTreeHandler::writeTree().
{ if (debug_>0) std::cout << "[MuScleFit]: Destructor" << std::endl; std::cout << "Total number of analyzed events = " << totalEvents_ << std::endl; if( !(outputRootTreeFileName_.empty()) ) { // Save the events to a root tree unless we are reading from the edm root file and the SavedPair size is different from the totalEvents_ if( !(inputRootTreeFileName_.empty() && (int(MuScleFitUtils::SavedPair.size()) != totalEvents_)) ) { std::cout << "Saving muon pairs to root tree" << std::endl; RootTreeHandler rootTreeHandler; if( MuScleFitUtils::speedup ) { // rootTreeHandler.writeTree(outputRootTreeFileName_, &(MuScleFitUtils::SavedPair), theMuonType_, 0, saveAllToTree_); rootTreeHandler.writeTree(outputRootTreeFileName_, &(muonPairs_), theMuonType_, 0, saveAllToTree_); } else { // rootTreeHandler.writeTree(outputRootTreeFileName_, &(MuScleFitUtils::SavedPair), theMuonType_, &(MuScleFitUtils::genPair), saveAllToTree_ ); rootTreeHandler.writeTree(outputRootTreeFileName_, &(muonPairs_), theMuonType_, &(genMuonPairs_), saveAllToTree_ ); } } else { std::cout << "ERROR: events in the vector = " << MuScleFitUtils::SavedPair.size() << " != totalEvents = " << totalEvents_ << std::endl; } } }
MuScleFit::MuScleFit | ( | const edm::ParameterSet & | pset | ) |
virtual MuScleFit::~MuScleFit | ( | ) | [virtual] |
void MuScleFit::applyBias | ( | reco::Particle::LorentzVector & | mu, |
const int | charge | ||
) | [protected] |
Apply the bias if needed using the function in MuScleFitUtils.
Definition at line 1260 of file MuScleFit.cc.
References MuScleFitUtils::BiasType, gather_cfg::cout, MuScleFitBase::debug_, and MuScleFitUtils::goodmuon.
Referenced by fillMuonCollection(), and selectMuons().
{ if( MuScleFitUtils::BiasType>0 ) { mu = MuScleFitUtils::applyBias( mu, charge ); if (debug_>0) std::cout << "Muon #" << MuScleFitUtils::goodmuon << ": after bias Pt = " << mu.Pt() << std::endl; } }
void MuScleFit::applyBias | ( | reco::Particle::LorentzVector & | mu, |
const int | charge | ||
) | [protected] |
Apply the bias if needed using the function in MuScleFitUtils.
void MuScleFit::applySmearing | ( | reco::Particle::LorentzVector & | mu | ) | [protected] |
Apply the smearing if needed using the function in MuScleFitUtils.
Definition at line 1251 of file MuScleFit.cc.
References gather_cfg::cout, MuScleFitBase::debug_, MuScleFitUtils::goodmuon, and MuScleFitUtils::SmearType.
Referenced by fillMuonCollection(), and selectMuons().
{ if( MuScleFitUtils::SmearType>0 ) { mu = MuScleFitUtils::applySmearing( mu ); if (debug_>0) std::cout << "Muon #" << MuScleFitUtils::goodmuon << ": after smearing Pt = " << mu.Pt() << std::endl; } }
void MuScleFit::applySmearing | ( | reco::Particle::LorentzVector & | mu | ) | [protected] |
Apply the smearing if needed using the function in MuScleFitUtils.
void MuScleFit::beginOfJobInConstructor | ( | ) |
Definition at line 603 of file MuScleFit.cc.
References gather_cfg::cout, MuScleFitPlotter::debug, MuScleFitBase::debug_, i, maxLoopNumber, plotter, MuScleFitBase::readProbabilityDistributionsFromFile(), dtT0Analyzer_cfg::rootFileName, AlCaHLTBitMon_QueryRunRegistry::string, MuScleFitBase::theFiles_, MuScleFitBase::theGenInfoRootFileName_, MuScleFitBase::theRootFileName_, and MuScleFitUtils::useProbsFile_.
Referenced by MuScleFit().
{ if (debug_>0) std::cout << "[MuScleFit]: beginOfJob" << std::endl; //if(maxLoopNumber>1) if( MuScleFitUtils::useProbsFile_ ) { readProbabilityDistributionsFromFile(); } if (debug_>0) std::cout << "[MuScleFit]: beginOfJob" << std::endl; // Create the root file // -------------------- for (unsigned int i=0; i<(maxLoopNumber); i++) { std::stringstream ss; ss << i; std::string rootFileName = ss.str() + "_" + theRootFileName_; theFiles_.push_back (new TFile(rootFileName.c_str(), "RECREATE")); } if (debug_>0) std::cout << "[MuScleFit]: Root file created" << std::endl; std::cout << "creating plotter" << std::endl; plotter = new MuScleFitPlotter(theGenInfoRootFileName_); plotter->debug = debug_; }
void MuScleFit::beginOfJobInConstructor | ( | ) |
bool MuScleFit::checkDeltaR | ( | reco::Particle::LorentzVector & | genMu, |
reco::Particle::LorentzVector & | recMu | ||
) | [protected] |
Check if two lorentzVector are near in deltaR.
bool MuScleFit::checkDeltaR | ( | reco::Particle::LorentzVector & | genMu, |
reco::Particle::LorentzVector & | recMu | ||
) | [protected] |
Check if two lorentzVector are near in deltaR.
Definition at line 1220 of file MuScleFit.cc.
References gather_cfg::cout, MuScleFitBase::debug_, MuScleFitUtils::deltaPhi(), deltaR(), and mathSSE::sqrt().
Referenced by duringFastLoop().
{ //first is always mu-, second is always mu+ double deltaR = sqrt(MuScleFitUtils::deltaPhi(recMu.Phi(),genMu.Phi()) * MuScleFitUtils::deltaPhi(recMu.Phi(),genMu.Phi()) + ((recMu.Eta()-genMu.Eta()) * (recMu.Eta()-genMu.Eta()))); if(deltaR<0.01) return true; else if( debug_ > 0 ) { std::cout<<"Reco muon "<<recMu<<" with eta "<<recMu.Eta()<<" and phi "<<recMu.Phi()<<std::endl <<" DOES NOT MATCH with generated muon from resonance: "<<std::endl <<genMu<<" with eta "<<genMu.Eta()<<" and phi "<<genMu.Phi()<<std::endl; } return false; }
void MuScleFit::checkParameters | ( | ) | [protected] |
Simple method to check parameters consistency. It aborts the job if the parameters are not consistent.
void MuScleFit::checkParameters | ( | ) | [protected] |
Simple method to check parameters consistency. It aborts the job if the parameters are not consistent.
Definition at line 1271 of file MuScleFit.cc.
References MuScleFitUtils::BiasType, gather_cfg::cout, MuScleFitUtils::doBackgroundFit, MuScleFitUtils::doCrossSectionFit, MuScleFitUtils::doResolFit, MuScleFitUtils::doScaleFit, maxLoopNumber, MuScleFitUtils::parBgr, MuScleFitUtils::parBgrFix, MuScleFitUtils::parBgrOrder, MuScleFitUtils::parBias, MuScleFitUtils::parCrossSection, MuScleFitUtils::parCrossSectionFix, MuScleFitUtils::parCrossSectionOrder, MuScleFitUtils::parResol, MuScleFitUtils::parResolFix, MuScleFitUtils::parResolOrder, MuScleFitUtils::parScale, MuScleFitUtils::parScaleFix, MuScleFitUtils::parScaleOrder, MuScleFitUtils::parSmear, MuScleFitUtils::resfind, findQualityFiles::size, and MuScleFitUtils::SmearType.
Referenced by MuScleFit().
{ // Fits selection dimension check if( MuScleFitUtils::doResolFit.size() != maxLoopNumber ) { std::cout << "[MuScleFit-Constructor]: wrong size of resolution fits selector = " << MuScleFitUtils::doResolFit.size() << std::endl; std::cout << "it must have as many values as the number of loops, which is = " << maxLoopNumber << std::endl; abort(); } if( MuScleFitUtils::doScaleFit.size() != maxLoopNumber ) { std::cout << "[MuScleFit-Constructor]: wrong size of scale fits selector = " << MuScleFitUtils::doScaleFit.size() << std::endl; std::cout << "it must have as many values as the number of loops, which is = " << maxLoopNumber << std::endl; abort(); } if( MuScleFitUtils::doCrossSectionFit.size() != maxLoopNumber ) { std::cout << "[MuScleFit-Constructor]: wrong size of cross section fits selector = " << MuScleFitUtils::doCrossSectionFit.size() << std::endl; std::cout << "it must have as many values as the number of loops, which is = " << maxLoopNumber << std::endl; abort(); } if( MuScleFitUtils::doBackgroundFit.size() != maxLoopNumber ) { std::cout << "[MuScleFit-Constructor]: wrong size of background fits selector = " << MuScleFitUtils::doBackgroundFit.size() << std::endl; std::cout << "it must have as many values as the number of loops, which is = " << maxLoopNumber << std::endl; abort(); } // Bias parameters: dimension check // -------------------------------- if ((MuScleFitUtils::BiasType==1 && MuScleFitUtils::parBias.size()!=2) || // linear in pt (MuScleFitUtils::BiasType==2 && MuScleFitUtils::parBias.size()!=2) || // linear in |eta| (MuScleFitUtils::BiasType==3 && MuScleFitUtils::parBias.size()!=4) || // sinusoidal in phi (MuScleFitUtils::BiasType==4 && MuScleFitUtils::parBias.size()!=3) || // linear in pt and |eta| (MuScleFitUtils::BiasType==5 && MuScleFitUtils::parBias.size()!=3) || // linear in pt and sinusoidal in phi (MuScleFitUtils::BiasType==6 && MuScleFitUtils::parBias.size()!=3) || // linear in |eta| and sinusoidal in phi (MuScleFitUtils::BiasType==7 && MuScleFitUtils::parBias.size()!=4) || // linear in pt and |eta| and sinusoidal in phi (MuScleFitUtils::BiasType==8 && MuScleFitUtils::parBias.size()!=4) || // linear in pt and parabolic in |eta| (MuScleFitUtils::BiasType==9 && MuScleFitUtils::parBias.size()!=2) || // exponential in pt (MuScleFitUtils::BiasType==10 && MuScleFitUtils::parBias.size()!=3) || // parabolic in pt (MuScleFitUtils::BiasType==11 && MuScleFitUtils::parBias.size()!=4) || // linear in pt and sin in phi with chg (MuScleFitUtils::BiasType==12 && MuScleFitUtils::parBias.size()!=6) || // linear in pt and para in plus sin in phi with chg (MuScleFitUtils::BiasType==13 && MuScleFitUtils::parBias.size()!=8) || // linear in pt and para in plus sin in phi with chg MuScleFitUtils::BiasType<0 || MuScleFitUtils::BiasType>13) { std::cout << "[MuScleFit-Constructor]: Wrong bias type or number of parameters: aborting!" << std::endl; abort(); } // Smear parameters: dimension check // --------------------------------- if ((MuScleFitUtils::SmearType==1 && MuScleFitUtils::parSmear.size()!=3) || (MuScleFitUtils::SmearType==2 && MuScleFitUtils::parSmear.size()!=4) || (MuScleFitUtils::SmearType==3 && MuScleFitUtils::parSmear.size()!=5) || (MuScleFitUtils::SmearType==4 && MuScleFitUtils::parSmear.size()!=6) || (MuScleFitUtils::SmearType==5 && MuScleFitUtils::parSmear.size()!=7) || (MuScleFitUtils::SmearType==6 && MuScleFitUtils::parSmear.size()!=16) || (MuScleFitUtils::SmearType==7 && MuScleFitUtils::parSmear.size()!=0) || MuScleFitUtils::SmearType<0 || MuScleFitUtils::SmearType>7) { std::cout << "[MuScleFit-Constructor]: Wrong smear type or number of parameters: aborting!" << std::endl; abort(); } // Protect against bad size of parameters // -------------------------------------- if (MuScleFitUtils::parResol.size()!=MuScleFitUtils::parResolFix.size() || MuScleFitUtils::parResol.size()!=MuScleFitUtils::parResolOrder.size()) { std::cout << "[MuScleFit-Constructor]: Mismatch in number of parameters for Resol: aborting!" << std::endl; abort(); } if (MuScleFitUtils::parScale.size()!=MuScleFitUtils::parScaleFix.size() || MuScleFitUtils::parScale.size()!=MuScleFitUtils::parScaleOrder.size()) { std::cout << "[MuScleFit-Constructor]: Mismatch in number of parameters for Scale: aborting!" << std::endl; abort(); } if (MuScleFitUtils::parCrossSection.size()!=MuScleFitUtils::parCrossSectionFix.size() || MuScleFitUtils::parCrossSection.size()!=MuScleFitUtils::parCrossSectionOrder.size()) { std::cout << "[MuScleFit-Constructor]: Mismatch in number of parameters for Bgr: aborting!" << std::endl; abort(); } if (MuScleFitUtils::parBgr.size()!=MuScleFitUtils::parBgrFix.size() || MuScleFitUtils::parBgr.size()!=MuScleFitUtils::parBgrOrder.size()) { std::cout << "[MuScleFit-Constructor]: Mismatch in number of parameters for Bgr: aborting!" << std::endl; abort(); } // Protect against an incorrect number of resonances // ------------------------------------------------- if (MuScleFitUtils::resfind.size()!=6) { std::cout << "[MuScleFit-Constructor]: resfind must have 6 elements (1 Z, 3 Y, 2 Psi): aborting!" << std::endl; abort(); } }
virtual void MuScleFit::duringFastLoop | ( | ) | [virtual] |
This method performs all needed operations on the muon pair. It reads the muons from SavedPair and uses the iev counter to keep track of the event number. The iev is incremented internally and reset to 0 in startingNewLoop.
void MuScleFit::duringFastLoop | ( | ) | [virtual] |
This method performs all needed operations on the muon pair. It reads the muons from SavedPair and uses the iev counter to keep track of the event number. The iev is incremented internally and reset to 0 in startingNewLoop.
Definition at line 966 of file MuScleFit.cc.
References CrossSectionHandler::addParameters(), MuScleFitUtils::applyScale(), checkDeltaR(), compareToSimTracks_, MuScleFitUtils::computeWeight(), gather_cfg::cout, MuScleFitUtils::crossSectionHandler, MuScleFitBase::debug_, MuScleFitUtils::debugMassResol_, MuScleFitUtils::doScaleFit, fillComparisonHistograms(), first, MuScleFitUtils::genPair, i, iev, MuScleFitUtils::iev_, funct::log(), loopCounter, MuScleFitBase::mapHisto_, MuScleFitUtils::massProb(), MuScleFitUtils::massResolComponents, MuScleFitUtils::massResolution(), MuScleFitUtils::parBgr, MuScleFitUtils::parCrossSection, MuScleFitUtils::parResol, MuScleFitUtils::parScale, MuScleFitUtils::parvalue, funct::pow(), recMu1, recMu2, MuScleFitUtils::ResFound, MuScleFitUtils::resolutionFunctionForVec, MuScleFitUtils::SavedPair, edm::second(), MuScleFitUtils::simPair, findQualityFiles::size, MuScleFitUtils::speedup, and CommonMethods::weight().
Referenced by duringLoop(), and endOfLoop().
{ // On loops>0 the two muons are directly obtained from the SavedMuon array // ----------------------------------------------------------------------- MuScleFitUtils::ResFound = false; recMu1 = (MuScleFitUtils::SavedPair[iev].first); recMu2 = (MuScleFitUtils::SavedPair[iev].second); if (recMu1.Pt()>0 && recMu2.Pt()>0) { MuScleFitUtils::ResFound = true; if (debug_>0) std::cout << "Ev = " << iev << ": found muons in tree with Pt = " << recMu1.Pt() << " " << recMu2.Pt() << std::endl; } if( debug_>0 ) std::cout << "About to start lik par correction and histo filling; ResFound is " << MuScleFitUtils::ResFound << std::endl; // If resonance found, do the hard work // ------------------------------------ if( MuScleFitUtils::ResFound ) { // Find weight and reference mass for this muon pair // ------------------------------------------------- // The last parameter = true means that we want to use always the background window to compute the weight, // otherwise the probability will be filled only for the resonance region. double weight = MuScleFitUtils::computeWeight( (recMu1+recMu2).mass(), iev, true ); if (debug_>0) { std::cout << "Loop #" << loopCounter << "Event #" << iev << ": before correction Pt1 = " << recMu1.Pt() << " Pt2 = " << recMu2.Pt() << std::endl; } // For successive iterations, correct the muons only if the previous iteration was a scale fit. // -------------------------------------------------------------------------------------------- if ( loopCounter>0 ) { if ( MuScleFitUtils::doScaleFit[loopCounter-1] ) { recMu1 = (MuScleFitUtils::applyScale(recMu1, MuScleFitUtils::parvalue[loopCounter-1], -1)); recMu2 = (MuScleFitUtils::applyScale(recMu2, MuScleFitUtils::parvalue[loopCounter-1], 1)); } } if (debug_>0) { std::cout << "Loop #" << loopCounter << "Event #" << iev << ": after correction Pt1 = " << recMu1.Pt() << " Pt2 = " << recMu2.Pt() << std::endl; } reco::Particle::LorentzVector bestRecRes( recMu1+recMu2 ); //Fill histograms //------------------ mapHisto_["hRecBestMu"]->Fill(recMu1, -1,weight); mapHisto_["hRecBestMuVSEta"]->Fill(recMu1); mapHisto_["hRecBestMu"]->Fill(recMu2, +1,weight); mapHisto_["hRecBestMuVSEta"]->Fill(recMu2); mapHisto_["hDeltaRecBestMu"]->Fill(recMu1, recMu2); // Reconstructed resonance mapHisto_["hRecBestRes"]->Fill(bestRecRes,+1, weight); mapHisto_["hRecBestResAllEvents"]->Fill(bestRecRes,+1, 1.); // // Fill histogram of Res mass vs muon variables // mapHisto_["hRecBestResVSMu"]->Fill (recMu1, bestRecRes, -1); // mapHisto_["hRecBestResVSMu"]->Fill (recMu2, bestRecRes, +1); // // Fill also the mass mu+/mu- comparisons // mapHisto_["hRecBestResVSMu"]->Fill(recMu1, recMu2, bestRecRes); mapHisto_["hRecBestResVSMu"]->Fill (recMu1, bestRecRes, -1, weight); mapHisto_["hRecBestResVSMu"]->Fill (recMu2, bestRecRes, +1, weight); // Fill also the mass mu+/mu- comparisons mapHisto_["hRecBestResVSMu"]->Fill(recMu1, recMu2, bestRecRes, weight); //-- rc 2010 filling histograms for mu+ /mu- ------ // mapHisto_["hRecBestResVSMuMinus"]->Fill (recMu1, bestRecRes, -1); // mapHisto_["hRecBestResVSMuPlus"]->Fill (recMu2, bestRecRes, +1); //-- rc 2010 filling histograms MassVsMuEtaPhi------ // mapHisto_["hRecBestResVSMuEtaPhi"]->Fill (recMu1, bestRecRes,-1); // mapHisto_["hRecBestResVSMuEtaPhi"]->Fill (recMu2, bestRecRes,+1); // Fill histogram of Res mass vs Res variables // mapHisto_["hRecBestResVSRes"]->Fill (bestRecRes, bestRecRes, +1); mapHisto_["hRecBestResVSRes"]->Fill (bestRecRes, bestRecRes, +1, weight); std::vector<double> * parval; std::vector<double> initpar; // Store a pointer to the vector of parameters of the last iteration, or the initial // parameters if this is the first iteration if (loopCounter==0) { initpar = MuScleFitUtils::parResol; initpar.insert( initpar.end(), MuScleFitUtils::parScale.begin(), MuScleFitUtils::parScale.end() ); initpar.insert( initpar.end(), MuScleFitUtils::parCrossSection.begin(), MuScleFitUtils::parCrossSection.end() ); initpar.insert( initpar.end(), MuScleFitUtils::parBgr.begin(), MuScleFitUtils::parBgr.end() ); parval = &initpar; } else { parval = &(MuScleFitUtils::parvalue[loopCounter-1]); } //Compute pt resolution w.r.t generated and simulated muons //-------------------------------------------------------- if( !MuScleFitUtils::speedup ) { //first is always mu-, second is always mu+ if(checkDeltaR(MuScleFitUtils::genPair[iev].first,recMu1)) { fillComparisonHistograms( MuScleFitUtils::genPair[iev].first, recMu1, "Gen", -1 ); } if(checkDeltaR(MuScleFitUtils::genPair[iev].second,recMu2)){ fillComparisonHistograms( MuScleFitUtils::genPair[iev].second, recMu2, "Gen", +1 ); } if( compareToSimTracks_ ) { //first is always mu-, second is always mu+ if(checkDeltaR(MuScleFitUtils::simPair[iev].first,recMu1)){ fillComparisonHistograms( MuScleFitUtils::simPair[iev].first, recMu1, "Sim", -1 ); } if(checkDeltaR(MuScleFitUtils::simPair[iev].second,recMu2)){ fillComparisonHistograms( MuScleFitUtils::simPair[iev].second, recMu2, "Sim", +1 ); } } } // ATTENTION: this was done only when a matching was found. Moved it outside because, genInfo or not, we still want to see the resolution function // Fill also the resolution histogramsm using the resolution functions: // the parameters are those from the last iteration, as the muons up to this point have also the corrections from the same iteration. // Need to use a different array (ForVec), containing functors able to operate on std::vector<double> mapHisto_["hFunctionResolPt"]->Fill( recMu1, MuScleFitUtils::resolutionFunctionForVec->sigmaPt(recMu1.Pt(), recMu1.Eta(), *parval ), -1 ); mapHisto_["hFunctionResolCotgTheta"]->Fill( recMu1, MuScleFitUtils::resolutionFunctionForVec->sigmaCotgTh(recMu1.Pt(), recMu1.Eta(), *parval ), -1 ); mapHisto_["hFunctionResolPhi"]->Fill( recMu1, MuScleFitUtils::resolutionFunctionForVec->sigmaPhi(recMu1.Pt(), recMu1.Eta(), *parval ), -1 ); mapHisto_["hFunctionResolPt"]->Fill( recMu2, MuScleFitUtils::resolutionFunctionForVec->sigmaPt(recMu2.Pt(), recMu2.Eta(), *parval ), +1 ); mapHisto_["hFunctionResolCotgTheta"]->Fill( recMu2, MuScleFitUtils::resolutionFunctionForVec->sigmaCotgTh(recMu2.Pt(), recMu2.Eta(), *parval ), +1 ); mapHisto_["hFunctionResolPhi"]->Fill( recMu2, MuScleFitUtils::resolutionFunctionForVec->sigmaPhi(recMu2.Pt(), recMu2.Eta(), *parval ), +1 ); // Compute likelihood histograms // ----------------------------- if( debug_ > 0 ) std::cout << "mass = " << bestRecRes.mass() << std::endl; if (weight!=0.) { double massResol; double prob; double deltalike; if (loopCounter==0) { std::vector<double> initpar; for (int i=0; i<(int)(MuScleFitUtils::parResol.size()); i++) { initpar.push_back(MuScleFitUtils::parResol[i]); } for (int i=0; i<(int)(MuScleFitUtils::parScale.size()); i++) { initpar.push_back(MuScleFitUtils::parScale[i]); } // for (int i=0; i<(int)(MuScleFitUtils::parCrossSection.size()); i++) { // initpar.push_back(MuScleFitUtils::parCrossSection[i]); // } MuScleFitUtils::crossSectionHandler->addParameters(initpar); for (int i=0; i<(int)(MuScleFitUtils::parBgr.size()); i++) { initpar.push_back(MuScleFitUtils::parBgr[i]); } massResol = MuScleFitUtils::massResolution( recMu1, recMu2, initpar ); // prob = MuScleFitUtils::massProb( bestRecRes.mass(), bestRecRes.Eta(), bestRecRes.Rapidity(), massResol, initpar, true ); prob = MuScleFitUtils::massProb( bestRecRes.mass(), bestRecRes.Eta(), bestRecRes.Rapidity(), massResol, initpar, true, recMu1.eta(), recMu2.eta() ); } else { massResol = MuScleFitUtils::massResolution( recMu1, recMu2, MuScleFitUtils::parvalue[loopCounter-1] ); // prob = MuScleFitUtils::massProb( bestRecRes.mass(), bestRecRes.Eta(), bestRecRes.Rapidity(), // massResol, MuScleFitUtils::parvalue[loopCounter-1], true ); prob = MuScleFitUtils::massProb( bestRecRes.mass(), bestRecRes.Eta(), bestRecRes.Rapidity(), massResol, MuScleFitUtils::parvalue[loopCounter-1], true, recMu1.eta(), recMu2.eta() ); } if( debug_ > 0 ) std::cout << "inside weight: mass = " << bestRecRes.mass() << ", prob = " << prob << std::endl; if (prob>0) { if( debug_ > 0 ) std::cout << "inside prob: mass = " << bestRecRes.mass() << ", prob = " << prob << std::endl; deltalike = log(prob)*weight; // NB maximum likelihood --> deltalike is maximized mapHisto_["hLikeVSMu"]->Fill(recMu1, deltalike); mapHisto_["hLikeVSMu"]->Fill(recMu2, deltalike); mapHisto_["hLikeVSMuMinus"]->Fill(recMu1, deltalike); mapHisto_["hLikeVSMuPlus"]->Fill(recMu2, deltalike); double recoMass = (recMu1+recMu2).mass(); if( recoMass != 0 ) { // IMPORTANT: massResol is not a relative resolution mapHisto_["hResolMassVSMu"]->Fill(recMu1, massResol, -1); mapHisto_["hResolMassVSMu"]->Fill(recMu2, massResol, +1); mapHisto_["hFunctionResolMassVSMu"]->Fill(recMu1, massResol/recoMass, -1); mapHisto_["hFunctionResolMassVSMu"]->Fill(recMu2, massResol/recoMass, +1); } if( MuScleFitUtils::debugMassResol_ ) { mapHisto_["hdMdPt1"]->Fill(recMu1, MuScleFitUtils::massResolComponents.dmdpt1, -1); mapHisto_["hdMdPt2"]->Fill(recMu2, MuScleFitUtils::massResolComponents.dmdpt2, +1); mapHisto_["hdMdPhi1"]->Fill(recMu1, MuScleFitUtils::massResolComponents.dmdphi1, -1); mapHisto_["hdMdPhi2"]->Fill(recMu2, MuScleFitUtils::massResolComponents.dmdphi2, +1); mapHisto_["hdMdCotgTh1"]->Fill(recMu1, MuScleFitUtils::massResolComponents.dmdcotgth1, -1); mapHisto_["hdMdCotgTh2"]->Fill(recMu2, MuScleFitUtils::massResolComponents.dmdcotgth2, +1); } if( !MuScleFitUtils::speedup ) { double genMass = (MuScleFitUtils::genPair[iev].first + MuScleFitUtils::genPair[iev].second).mass(); // Fill the mass resolution (computed from MC), we use the covariance class to compute the variance if( genMass != 0 ) { mapHisto_["hGenResVSMu"]->Fill((MuScleFitUtils::genPair[iev].first), (MuScleFitUtils::genPair[iev].first + MuScleFitUtils::genPair[iev].second), -1); mapHisto_["hGenResVSMu"]->Fill((MuScleFitUtils::genPair[iev].second), (MuScleFitUtils::genPair[iev].first + MuScleFitUtils::genPair[iev].second), +1); double diffMass = (recoMass - genMass)/genMass; // double diffMass = recoMass - genMass; // Fill if for both muons double pt1 = recMu1.pt(); double eta1 = recMu1.eta(); double pt2 = recMu2.pt(); double eta2 = recMu2.eta(); // This is to avoid nan if( diffMass == diffMass ) { // Mass relative difference vs Pt and Eta. To be used to extract the true mass resolution mapHisto_["hDeltaMassOverGenMassVsPt"]->Fill(pt1, diffMass); mapHisto_["hDeltaMassOverGenMassVsPt"]->Fill(pt2, diffMass); mapHisto_["hDeltaMassOverGenMassVsEta"]->Fill(eta1, diffMass); mapHisto_["hDeltaMassOverGenMassVsEta"]->Fill(eta2, diffMass); // This is used for the covariance comparison mapHisto_["hMassResolutionVsPtEta"]->Fill(pt1, eta1, diffMass, diffMass); mapHisto_["hMassResolutionVsPtEta"]->Fill(pt2, eta2, diffMass, diffMass); } else { std::cout << "Error, there is a nan: recoMass = " << recoMass << ", genMass = " << genMass << std::endl; } } // Fill with mass resolution from resolution function double massRes = MuScleFitUtils::massResolution(recMu1, recMu2, MuScleFitUtils::parResol); mapHisto_["hFunctionResolMass"]->Fill( recMu1, std::pow(massRes,2), -1 ); mapHisto_["hFunctionResolMass"]->Fill( recMu2, std::pow(massRes,2), +1 ); } mapHisto_["hMass_P"]->Fill(bestRecRes.mass(), prob); if( debug_ > 0 ) std::cout << "mass = " << bestRecRes.mass() << ", prob = " << prob << std::endl; mapHisto_["hMass_fine_P"]->Fill(bestRecRes.mass(), prob); mapHisto_["hMassProbVsRes"]->Fill(bestRecRes, bestRecRes, +1, prob); mapHisto_["hMassProbVsMu"]->Fill(recMu1, bestRecRes, -1, prob); mapHisto_["hMassProbVsMu"]->Fill(recMu2, bestRecRes, +1, prob); mapHisto_["hMassProbVsRes_fine"]->Fill(bestRecRes, bestRecRes, +1, prob); mapHisto_["hMassProbVsMu_fine"]->Fill(recMu1, bestRecRes, -1, prob); mapHisto_["hMassProbVsMu_fine"]->Fill(recMu2, bestRecRes, +1, prob); } } } // end if ResFound // Fill the pair // ------------- if (loopCounter>0) { if (debug_>0) std::cout << "[MuScleFit]: filling the pair" << std::endl; MuScleFitUtils::SavedPair[iev] = std::make_pair( recMu1, recMu2 ); } iev++; MuScleFitUtils::iev_++; // return kContinue; }
virtual edm::EDLooper::Status MuScleFit::duringLoop | ( | const edm::Event & | , |
const edm::EventSetup & | |||
) | [virtual] |
Called after all event modules have had a chance to process the edm::Event.
Implements edm::EDLooper.
edm::EDLooper::Status MuScleFit::duringLoop | ( | const edm::Event & | , |
const edm::EventSetup & | |||
) | [virtual] |
Called after all event modules have had a chance to process the edm::Event.
Implements edm::EDLooper.
Definition at line 748 of file MuScleFit.cc.
References gather_cfg::cout, MuScleFitBase::debug_, duringFastLoop(), fastLoop, edm::Event::getRun(), HltComparatorCreateWorkflow::hltConfig, i, HLTConfigProvider::init(), inputRootTreeFileName_, edm::EDLooperBase::kContinue, loopCounter, negateTrigger_, selectMuons(), findQualityFiles::size, edm::TriggerNames::size(), AlCaHLTBitMon_QueryRunRegistry::string, totalEvents_, HLTConfigProvider::triggerIndex(), edm::TriggerNames::triggerName(), edm::TriggerNames::triggerNames(), triggerPath_, patRefSel_triggerSelection_cff::triggerResults, triggerResultsLabel_, and triggerResultsProcess_.
{ edm::Handle<edm::TriggerResults> triggerResults; event.getByLabel(edm::InputTag(triggerResultsLabel_.c_str(), "", triggerResultsProcess_.c_str()), triggerResults); //event.getByLabel(InputTag(triggerResultsLabel_),triggerResults); bool isFired = false; if(triggerPath_[0] == "") isFired = true; else if(triggerPath_[0] == "All"){ isFired =triggerResults->accept(); if(debug_>0) std::cout<<"Trigger "<<isFired<<std::endl; } else{ bool changed; HLTConfigProvider hltConfig; hltConfig.init(event.getRun(), eventSetup, triggerResultsProcess_, changed); const edm::TriggerNames triggerNames = event.triggerNames(*triggerResults); for (unsigned i=0; i<triggerNames.size(); i++) { std::string hltName = triggerNames.triggerName(i); // match the path in the pset with the true name of the trigger for ( unsigned int ipath=0; ipath<triggerPath_.size(); ipath++ ) { if ( hltName.find(triggerPath_[ipath]) != std::string::npos ) { unsigned int triggerIndex( hltConfig.triggerIndex(hltName) ); // triggerIndex must be less than the size of HLTR or you get a CMSException: _M_range_check if (triggerIndex < triggerResults->size()) { isFired = triggerResults->accept(triggerIndex); if(debug_>0) std::cout << triggerPath_[ipath] <<" "<< hltName << " " << isFired<<std::endl; } } // end if (matching the path in the pset with the true trigger name } } } if( negateTrigger_ && isFired ) return kContinue; else if( !(negateTrigger_) && !isFired ) return kContinue; #ifdef USE_CALLGRIND CALLGRIND_START_INSTRUMENTATION; #endif if (debug_>0) { std::cout << "[MuScleFit-duringLoop]: loopCounter = " << loopCounter << " Run: " << event.id().run() << " Event: " << event.id().event() << std::endl; } // On the first iteration we read the bank, otherwise we fetch the information from the muon tree // ------------------------------------ Important Note --------------------------------------- // // The fillMuonCollection method applies any smearing or bias to the muons, so we NEVER use // unbiased muons. // ---------------------------------------------------------------------------------------------- if( loopCounter == 0 ) { if( !fastLoop || inputRootTreeFileName_.empty() ) { if( debug_ > 0 ) std::cout << "Reading from edm event" << std::endl; selectMuons(event); duringFastLoop(); ++totalEvents_; } } return kContinue; #ifdef USE_CALLGRIND CALLGRIND_STOP_INSTRUMENTATION; CALLGRIND_DUMP_STATS; #endif }
void MuScleFit::endOfFastLoop | ( | const unsigned int | iLoop | ) | [virtual] |
Definition at line 712 of file MuScleFit.cc.
References MuScleFitBase::clearHistoMap(), gather_cfg::cout, loopCounter, MuScleFitUtils::minimizeLikelihood(), plotter, MuScleFitBase::theFiles_, and MuScleFitBase::writeHistoMap().
Referenced by endOfLoop().
{ // std::cout<< "Inside endOfFastLoop, iLoop = " << iLoop << " and loopCounter = " << loopCounter << std::endl; if( loopCounter == 0 ) { // plotter->writeHistoMap(); // The destructor will call the writeHistoMap after the cd to the output file delete plotter; } std::cout << "Ending loop # " << iLoop << std::endl; // Write the histos to file // ------------------------ // theFiles_[iLoop]->cd(); writeHistoMap(iLoop); // Likelihood minimization to compute corrections // ---------------------------------------------- // theFiles_[iLoop]->cd(); TDirectory * likelihoodDir = theFiles_[iLoop]->mkdir("likelihood"); likelihoodDir->cd(); MuScleFitUtils::minimizeLikelihood(); // ATTENTION, this was put BEFORE the minimizeLikelihood. Check for problems. theFiles_[iLoop]->Close(); // ATTENTION: Check that this delete does not give any problem delete theFiles_[iLoop]; // Clear the histos // ---------------- clearHistoMap(); }
virtual void MuScleFit::endOfFastLoop | ( | const unsigned int | iLoop | ) | [virtual] |
virtual void MuScleFit::endOfJob | ( | ) | [virtual] |
Reimplemented from edm::EDLooperBase.
void MuScleFit::endOfJob | ( | ) | [virtual] |
Reimplemented from edm::EDLooperBase.
Definition at line 632 of file MuScleFit.cc.
References gather_cfg::cout, and MuScleFitBase::debug_.
edm::EDLooper::Status MuScleFit::endOfLoop | ( | const edm::EventSetup & | , |
unsigned int | iCounter | ||
) | [virtual] |
Called after the system has finished one loop over the events. Thar argument is a count of how many loops have been processed before this loo. For the first time through the events the argument will be 0.
Implements edm::EDLooperBase.
Definition at line 665 of file MuScleFit.cc.
References gather_cfg::cout, duringFastLoop(), endOfFastLoop(), fastLoop, iev, inputRootTreeFileName_, edm::EDLooperBase::kContinue, edm::EDLooperBase::kStop, maxEventsFromRootTree_, maxLoopNumber, MuScleFitUtils::SavedPair, selectMuons(), startingNewLoop(), and totalEvents_.
{ unsigned int iFastLoop = 1; // Read the events from the root tree if requested if( !(inputRootTreeFileName_.empty()) ) { selectMuons(maxEventsFromRootTree_, inputRootTreeFileName_); // When reading from local file all the loops are done here totalEvents_ = MuScleFitUtils::SavedPair.size(); iFastLoop = 0; } else { endOfFastLoop(iLoop); } // If a fastLoop is required we do all the remaining iterations here if( fastLoop == true ) { for( ; iFastLoop<maxLoopNumber; ++iFastLoop ) { std::cout << "Starting fast loop number " << iFastLoop << std::endl; // In the first loop is called by the framework // if( iFastLoop > 0 ) { startingNewLoop(iFastLoop); // } // std::vector<std::pair<lorentzVector,lorentzVector> >::const_iterator it = MuScleFitUtils::SavedPair.begin(); // for( ; it != SavedPair.end(); ++it ) { while( iev<totalEvents_ ) { if( iev%50000 == 0 ) { std::cout << "Fast looping on event number " << iev << std::endl; } // This reads muons from SavedPair using iev to keep track of the event duringFastLoop(); } std::cout << "End of fast loop number " << iFastLoop << ". Ran on " << iev << " events" << std::endl; endOfFastLoop(iFastLoop); } } if (iFastLoop>=maxLoopNumber-1) { return kStop; } else { return kContinue; } }
virtual edm::EDLooper::Status MuScleFit::endOfLoop | ( | const edm::EventSetup & | , |
unsigned int | iCounter | ||
) | [virtual] |
Called after the system has finished one loop over the events. Thar argument is a count of how many loops have been processed before this loo. For the first time through the events the argument will be 0.
Implements edm::EDLooperBase.
void MuScleFit::fillComparisonHistograms | ( | const reco::Particle::LorentzVector & | genMu, |
const reco::Particle::LorentzVector & | recoMu, | ||
const std::string & | inputName, | ||
const int | charge | ||
) | [protected] |
Fill the reco vs gen and reco vs sim comparison histograms.
void MuScleFit::fillComparisonHistograms | ( | const reco::Particle::LorentzVector & | genMu, |
const reco::Particle::LorentzVector & | recoMu, | ||
const std::string & | inputName, | ||
const int | charge | ||
) | [protected] |
Fill the reco vs gen and reco vs sim comparison histograms.
Definition at line 1234 of file MuScleFit.cc.
References DeDxDiscriminatorTools::charge(), funct::cos(), MuScleFitUtils::deltaPhiNoFabs(), MuScleFitBase::mapHisto_, mergeVDriftHistosByStation::name, funct::sin(), and AlCaHLTBitMon_QueryRunRegistry::string.
Referenced by duringFastLoop().
{ std::string name(inputName + "VSMu"); mapHisto_["hResolPt"+name]->Fill(recMu, (-genMu.Pt()+recMu.Pt())/genMu.Pt(), charge); mapHisto_["hResolTheta"+name]->Fill(recMu, (-genMu.Theta()+recMu.Theta()), charge); mapHisto_["hResolCotgTheta"+name]->Fill(recMu,(-cos(genMu.Theta())/sin(genMu.Theta()) +cos(recMu.Theta())/sin(recMu.Theta())), charge); mapHisto_["hResolEta"+name]->Fill(recMu, (-genMu.Eta()+recMu.Eta()),charge); mapHisto_["hResolPhi"+name]->Fill(recMu, MuScleFitUtils::deltaPhiNoFabs(recMu.Phi(), genMu.Phi()), charge); // Fill only if it was matched to a genMu and this muon is valid if( (genMu.Pt() != 0) && (recMu.Pt() != 0) ) { mapHisto_["hPtRecoVsPt"+inputName]->Fill(genMu.Pt(), recMu.Pt()); } }
std::vector< reco::LeafCandidate > MuScleFit::fillMuonCollection | ( | const std::vector< T > & | tracks | ) |
Definition at line 309 of file MuScleFit.cc.
References applyBias(), applySmearing(), gather_cfg::cout, MuScleFitBase::debug_, MuScleFitUtils::goodmuon, MuScleFitUtils::mMu2, RPCpg::mu, metsig::muon, patZpeak::muons, and mathSSE::sqrt().
{ std::vector<reco::LeafCandidate> muons; typename std::vector<T>::const_iterator track; for( track = tracks.begin(); track != tracks.end(); ++track ) { reco::Particle::LorentzVector mu; mu = reco::Particle::LorentzVector(track->px(),track->py(),track->pz(), sqrt(track->p()*track->p() + MuScleFitUtils::mMu2)); // Apply smearing if needed, and then bias // --------------------------------------- MuScleFitUtils::goodmuon++; if (debug_>0) std::cout <<std::setprecision(9)<< "Muon #" << MuScleFitUtils::goodmuon << ": initial value Pt = " << mu.Pt() << std::endl; applySmearing(mu); applyBias(mu, track->charge()); reco::LeafCandidate muon(track->charge(),mu); // Store modified muon // ------------------- muons.push_back (muon); } return muons; }
std::vector<reco::LeafCandidate> MuScleFit::fillMuonCollection | ( | const std::vector< T > & | tracks | ) |
void MuScleFit::selectMuons | ( | const int | maxEvents, |
const TString & | treeFileName | ||
) | [protected] |
Selects the muon pairs and fills the SavedPair and (if needed) the genPair vector. This version reads the events from a tree in the file specified in the cfg. The tree only contains one muon pair per event. This means that no selection is performed and we use preselected muons.
void MuScleFit::selectMuons | ( | const edm::Event & | event | ) | [protected] |
Selects the muon pairs and fills the SavedPair and (if needed) the genPair vector. This version reads the events from the edm root file and performs a selection of the muons according to the parameters in the cfg.
Definition at line 825 of file MuScleFit.cc.
References prof2calltree::back, gather_cfg::cout, MuScleFitBase::debug_, MuScleFitUtils::findBestRecoRes(), first, MuScleFitBase::genMuonPairs_, MuScleFitUtils::genPair, MuScleFitBase::muonPairs_, patZpeak::muons, muonSelector_, plotter, reco::tau::disc::Pt(), recMu1, recMu2, MuScleFitUtils::ResFound, edm::Event::run(), MuScleFitUtils::SavedPair, edm::second(), MuScleFitUtils::simPair, and MuScleFitUtils::speedup.
Referenced by duringLoop(), and endOfLoop().
{ recMu1 = reco::Particle::LorentzVector(0,0,0,0); recMu2 = reco::Particle::LorentzVector(0,0,0,0); std::vector<reco::LeafCandidate> muons; muonSelector_->selectMuons(event, muons, genMuonPairs_, MuScleFitUtils::simPair, plotter); // plotter->fillRec(muons); // @EM method already invoked inside MuScleFitMuonSelector::selectMuons() // Find the two muons from the resonance, and set ResFound bool // ------------------------------------------------------------ std::pair<reco::Particle::LorentzVector, reco::Particle::LorentzVector> recMuFromBestRes = MuScleFitUtils::findBestRecoRes(muons); if (MuScleFitUtils::ResFound) { if (debug_>0) { std::cout <<std::setprecision(9)<< "Pt after findbestrecores: " << (recMuFromBestRes.first).Pt() << " " << (recMuFromBestRes.second).Pt() << std::endl; std::cout << "recMu1 = " << recMu1 << std::endl; std::cout << "recMu2 = " << recMu2 << std::endl; } recMu1 = recMuFromBestRes.first; recMu2 = recMuFromBestRes.second; if (debug_>0) { std::cout << "after recMu1 = " << recMu1 << std::endl; std::cout << "after recMu2 = " << recMu2 << std::endl; std::cout << "mu1.pt = " << recMu1.Pt() << std::endl; std::cout << "mu2.pt = " << recMu2.Pt() << std::endl; } MuScleFitUtils::SavedPair.push_back( std::make_pair( recMu1, recMu2 ) ); } else { MuScleFitUtils::SavedPair.push_back( std::make_pair( lorentzVector(0.,0.,0.,0.), lorentzVector(0.,0.,0.,0.) ) ); } // Save the events also in the external tree so that it can be saved late // std::cout << "SavedPair->size() " << MuScleFitUtils::SavedPair.size() << std::endl; muonPairs_.push_back(MuonPair(MuScleFitUtils::SavedPair.back().first, MuScleFitUtils::SavedPair.back().second, event.run(), event.id().event())); // Fill the internal genPair tree from the external one if( MuScleFitUtils::speedup == false ) { MuScleFitUtils::genPair.push_back(std::make_pair( genMuonPairs_.back().mu1, genMuonPairs_.back().mu2 )); } }
void MuScleFit::selectMuons | ( | const int | maxEvents, |
const TString & | treeFileName | ||
) | [protected] |
Selects the muon pairs and fills the SavedPair and (if needed) the genPair vector. This version reads the events from a tree in the file specified in the cfg. The tree only contains one muon pair per event. This means that no selection is performed and we use preselected muons.
Definition at line 870 of file MuScleFit.cc.
References applyBias(), applySmearing(), MuScleFitUtils::BiasType, gather_cfg::cout, SiPixelRawToDigiRegional_cfi::deltaPhi, MuScleFitUtils::deltaPhiMaxCut_, MuScleFitUtils::deltaPhiMinCut_, MuScleFitPlotter::fillTreeGen(), MuScleFitPlotter::fillTreeRec(), MuScleFitBase::genMuonPairs_, MuScleFitUtils::genPair, inputRootTreeFileName_, MuScleFitUtils::maxMuonEtaFirstRange_, MuScleFitUtils::maxMuonEtaSecondRange_, MuScleFitUtils::maxMuonPt_, MuScleFitUtils::minMuonEtaFirstRange_, MuScleFitUtils::minMuonEtaSecondRange_, MuScleFitUtils::minMuonPt_, MuScleFitBase::muonPairs_, plotter, RootTreeHandler::readTree(), MuScleFitUtils::SavedPair, MuScleFitUtils::separateRanges_, MuScleFitUtils::SmearType, MuScleFitUtils::speedup, and MuScleFitBase::theMuonType_.
{ std::cout << "Reading muon pairs from Root Tree in " << treeFileName << std::endl; RootTreeHandler rootTreeHandler; std::vector<std::pair<int, int> > evtRun; if( MuScleFitUtils::speedup ) { rootTreeHandler.readTree(maxEvents, inputRootTreeFileName_, &(MuScleFitUtils::SavedPair), theMuonType_, &evtRun); } else { rootTreeHandler.readTree(maxEvents, inputRootTreeFileName_, &(MuScleFitUtils::SavedPair), theMuonType_, &evtRun, &(MuScleFitUtils::genPair)); } // Now loop on all the pairs and apply any smearing and bias if needed std::vector<std::pair<int, int> >::iterator evtRunIt = evtRun.begin(); std::vector<std::pair<lorentzVector,lorentzVector> >::iterator it = MuScleFitUtils::SavedPair.begin(); std::vector<std::pair<lorentzVector,lorentzVector> >::iterator genIt; if(MuScleFitUtils::speedup == false) genIt = MuScleFitUtils::genPair.begin(); for( ; it != MuScleFitUtils::SavedPair.end(); ++it, ++evtRunIt ) { // Apply any cut if requested // Note that cuts here are only applied to already selected muons. They should not be used unless // you are sure that the difference is negligible (e.g. the number of events with > 2 muons is negligible). double pt1 = it->first.pt(); // std::cout << "pt1 = " << pt1 << std::endl; double pt2 = it->second.pt(); // std::cout << "pt2 = " << pt2 << std::endl; double eta1 = it->first.eta(); // std::cout << "eta1 = " << eta1 << std::endl; double eta2 = it->second.eta(); // std::cout << "eta2 = " << eta2 << std::endl; // If they don't pass the cuts set to null vectors bool dontPass = false; bool eta1InFirstRange; bool eta2InFirstRange; bool eta1InSecondRange; bool eta2InSecondRange; if( MuScleFitUtils::separateRanges_ ) { eta1InFirstRange = eta1 >= MuScleFitUtils::minMuonEtaFirstRange_ && eta1 < MuScleFitUtils::maxMuonEtaFirstRange_; eta2InFirstRange = eta2 >= MuScleFitUtils::minMuonEtaFirstRange_ && eta2 < MuScleFitUtils::maxMuonEtaFirstRange_; eta1InSecondRange = eta1 >= MuScleFitUtils::minMuonEtaSecondRange_ && eta1 < MuScleFitUtils::maxMuonEtaSecondRange_; eta2InSecondRange = eta2 >= MuScleFitUtils::minMuonEtaSecondRange_ && eta2 < MuScleFitUtils::maxMuonEtaSecondRange_; // This is my logic, which should be erroneous, but certainly simpler... if( !(pt1 >= MuScleFitUtils::minMuonPt_ && pt1 < MuScleFitUtils::maxMuonPt_ && pt2 >= MuScleFitUtils::minMuonPt_ && pt2 < MuScleFitUtils::maxMuonPt_ && eta1InFirstRange && eta2InSecondRange ) ) { dontPass = true; } } else { eta1 = fabs(eta1); eta2 = fabs(eta2); eta1InFirstRange = eta1 >= MuScleFitUtils::minMuonEtaFirstRange_ && eta1 < MuScleFitUtils::maxMuonEtaFirstRange_; eta2InFirstRange = eta2 >= MuScleFitUtils::minMuonEtaFirstRange_ && eta2 < MuScleFitUtils::maxMuonEtaFirstRange_; eta1InSecondRange = eta1 >= MuScleFitUtils::minMuonEtaSecondRange_ && eta1 < MuScleFitUtils::maxMuonEtaSecondRange_; eta2InSecondRange = eta2 >= MuScleFitUtils::minMuonEtaSecondRange_ && eta2 < MuScleFitUtils::maxMuonEtaSecondRange_; if( !(pt1 >= MuScleFitUtils::minMuonPt_ && pt1 < MuScleFitUtils::maxMuonPt_ && pt2 >= MuScleFitUtils::minMuonPt_ && pt2 < MuScleFitUtils::maxMuonPt_ && ( ((eta1InFirstRange && !eta2InFirstRange) && (eta2InSecondRange && !eta1InSecondRange)) || ((eta2InFirstRange && !eta1InFirstRange) && (eta1InSecondRange && !eta2InSecondRange)) )) ) { dontPass = true; } } // Additional check on deltaPhi double deltaPhi = MuScleFitUtils::deltaPhi(it->first.phi(), it->second.phi()); if( (deltaPhi <= MuScleFitUtils::deltaPhiMinCut_) || (deltaPhi >= MuScleFitUtils::deltaPhiMaxCut_) ) dontPass = true; if( dontPass ) { // std::cout << "removing muons not passing cuts" << std::endl; it->first = reco::Particle::LorentzVector(0,0,0,0); it->second = reco::Particle::LorentzVector(0,0,0,0); } // First is always mu-, second mu+ if( (MuScleFitUtils::SmearType != 0) || (MuScleFitUtils::BiasType != 0) ) { applySmearing(it->first); applyBias(it->first, -1); applySmearing(it->second); applyBias(it->second, 1); } muonPairs_.push_back(MuonPair(it->first, it->second, evtRunIt->second, evtRunIt->first)); // Fill the internal genPair tree from the external one if( MuScleFitUtils::speedup == false ) { genMuonPairs_.push_back(GenMuonPair(genIt->first, genIt->second, 0)); ++genIt; } } plotter->fillTreeRec(MuScleFitUtils::SavedPair); if( !(MuScleFitUtils::speedup) ) { plotter->fillTreeGen(MuScleFitUtils::genPair); } }
void MuScleFit::selectMuons | ( | const edm::Event & | event | ) | [protected] |
Selects the muon pairs and fills the SavedPair and (if needed) the genPair vector. This version reads the events from the edm root file and performs a selection of the muons according to the parameters in the cfg.
bool MuScleFit::selGlobalMuon | ( | const pat::Muon * | aMuon | ) | [protected] |
Function for onia selections.
Definition at line 1358 of file MuScleFit.cc.
References pat::Muon::globalTrack(), pat::Muon::innerTrack(), pat::Muon::muonID(), reco::HitPattern::numberOfValidMuonHits(), AlCaHLTBitMon_ParallelJobs::p, reco::HitPattern::pixelLayersWithMeasurement(), and lumiQueryAPI::q.
{ reco::TrackRef iTrack = aMuon->innerTrack(); const reco::HitPattern& p = iTrack->hitPattern(); reco::TrackRef gTrack = aMuon->globalTrack(); const reco::HitPattern& q = gTrack->hitPattern(); return (//isMuonInAccept(aMuon) &&// no acceptance cuts! iTrack->found() > 11 && gTrack->chi2()/gTrack->ndof() < 20.0 && q.numberOfValidMuonHits() > 0 && iTrack->chi2()/iTrack->ndof() < 4.0 && aMuon->muonID("TrackerMuonArbitrated") && aMuon->muonID("TMLastStationAngTight") && p.pixelLayersWithMeasurement() > 1 && fabs(iTrack->dxy()) < 3.0 && //should be done w.r.t. PV! fabs(iTrack->dz()) < 15.0 );//should be done w.r.t. PV! }
bool MuScleFit::selGlobalMuon | ( | const pat::Muon * | aMuon | ) | [protected] |
Function for onia selections.
bool MuScleFit::selTrackerMuon | ( | const pat::Muon * | aMuon | ) | [protected] |
Definition at line 1379 of file MuScleFit.cc.
References pat::Muon::innerTrack(), pat::Muon::muonID(), AlCaHLTBitMon_ParallelJobs::p, and reco::HitPattern::pixelLayersWithMeasurement().
{ reco::TrackRef iTrack = aMuon->innerTrack(); const reco::HitPattern& p = iTrack->hitPattern(); return (//isMuonInAccept(aMuon) // no acceptance cuts! iTrack->found() > 11 && iTrack->chi2()/iTrack->ndof() < 4.0 && aMuon->muonID("TrackerMuonArbitrated") && aMuon->muonID("TMLastStationAngTight") && p.pixelLayersWithMeasurement() > 1 && fabs(iTrack->dxy()) < 3.0 && //should be done w.r.t. PV! fabs(iTrack->dz()) < 15.0 );//should be done w.r.t. PV! }
bool MuScleFit::selTrackerMuon | ( | const pat::Muon * | aMuon | ) | [protected] |
virtual void MuScleFit::startingNewLoop | ( | unsigned int | int | ) | [virtual] |
Called before system starts to loop over the events. The argument is a count of how many loops have been processed. For the first time through the events the argument will be 0.
Implements edm::EDLooperBase.
void MuScleFit::startingNewLoop | ( | unsigned int | int | ) | [virtual] |
Called before system starts to loop over the events. The argument is a count of how many loops have been processed. For the first time through the events the argument will be 0.
Implements edm::EDLooperBase.
Definition at line 638 of file MuScleFit.cc.
References MuScleFitUtils::counter_resprob, gather_cfg::cout, MuScleFitBase::debug_, MuScleFitBase::fillHistoMap(), MuScleFitUtils::goodmuon, iev, MuScleFitUtils::iev_, loopCounter, MuScleFitUtils::loopCounter, MuScleFitUtils::oldNormalization_, and MuScleFitBase::theFiles_.
Referenced by endOfLoop().
{ if (debug_>0) std::cout << "[MuScleFit]: Starting loop # " << iLoop << std::endl; // Number of muons used // -------------------- MuScleFitUtils::goodmuon = 0; // Counters for problem std::cout-ing // ----------------------------- MuScleFitUtils::counter_resprob = 0; // Create the root file // -------------------- fillHistoMap(theFiles_[iLoop], iLoop); loopCounter = iLoop; MuScleFitUtils::loopCounter = loopCounter; iev = 0; MuScleFitUtils::iev_ = 0; MuScleFitUtils::oldNormalization_ = 0; }
void MuScleFit::takeSelectedMuonType | ( | const T & | muon, |
std::vector< reco::Track > & | tracks | ||
) | [protected] |
Template method used to fill the track collection starting from reco::muons or pat::muons.
void MuScleFit::takeSelectedMuonType | ( | const T & | muon, |
std::vector< reco::Track > & | tracks | ||
) | [protected] |
Template method used to fill the track collection starting from reco::muons or pat::muons.
Definition at line 336 of file MuScleFit.cc.
References MuScleFitBase::theMuonType_.
{ // std::cout<<"muon "<<muon->isGlobalMuon()<<muon->isStandAloneMuon()<<muon->isTrackerMuon()<<std::endl; //NNBB: one muon can be of many kinds at once but with the theMuonType_ we are sure // to avoid double counting of the same muon if(muon->isGlobalMuon() && theMuonType_==1) tracks.push_back(*(muon->globalTrack())); else if(muon->isStandAloneMuon() && theMuonType_==2) tracks.push_back(*(muon->outerTrack())); else if(muon->isTrackerMuon() && theMuonType_==3) tracks.push_back(*(muon->innerTrack())); else if( theMuonType_ == 10 && !(muon->isStandAloneMuon()) ) //particular case!! tracks.push_back(*(muon->innerTrack())); else if( theMuonType_ == 11 && muon->isGlobalMuon() ) tracks.push_back(*(muon->innerTrack())); else if( theMuonType_ == 13 && muon->isTrackerMuon() ) tracks.push_back(*(muon->innerTrack())); }
bool MuScleFit::compareToSimTracks_ [protected] |
Definition at line 287 of file MuScleFit.cc.
Referenced by duringFastLoop(), and MuScleFit().
bool MuScleFit::fastLoop [protected] |
Definition at line 277 of file MuScleFit.cc.
Referenced by duringLoop(), endOfLoop(), and MuScleFit().
std::string MuScleFit::genParticlesName_ [protected] |
Definition at line 290 of file MuScleFit.cc.
Referenced by MuScleFit().
int MuScleFit::iev [protected] |
Definition at line 284 of file MuScleFit.cc.
Referenced by duringFastLoop(), endOfLoop(), and startingNewLoop().
bool MuScleFit::ifGenPart [protected] |
Definition at line 265 of file MuScleFit.cc.
bool MuScleFit::ifHepMC [protected] |
Definition at line 264 of file MuScleFit.cc.
std::string MuScleFit::inputRootTreeFileName_ [protected] |
Definition at line 293 of file MuScleFit.cc.
Referenced by duringLoop(), endOfLoop(), MuScleFit(), selectMuons(), and ~MuScleFit().
unsigned int MuScleFit::loopCounter [protected] |
Definition at line 275 of file MuScleFit.cc.
Referenced by duringFastLoop(), duringLoop(), endOfFastLoop(), MuScleFit(), and startingNewLoop().
int MuScleFit::maxEventsFromRootTree_ [protected] |
Definition at line 297 of file MuScleFit.cc.
Referenced by endOfLoop(), and MuScleFit().
unsigned int MuScleFit::maxLoopNumber [protected] |
Definition at line 274 of file MuScleFit.cc.
Referenced by beginOfJobInConstructor(), checkParameters(), endOfLoop(), and MuScleFit().
double MuScleFit::maxResMass_hwindow [protected] |
Definition at line 270 of file MuScleFit.cc.
Referenced by MuScleFit().
double MuScleFit::minResMass_hwindow [protected] |
Definition at line 269 of file MuScleFit.cc.
Referenced by MuScleFit().
std::auto_ptr< MuScleFitMuonSelector > MuScleFit::muonSelector_ [protected] |
Definition at line 305 of file MuScleFit.cc.
Referenced by MuScleFit(), and selectMuons().
bool MuScleFit::negateTrigger_ [protected] |
Definition at line 302 of file MuScleFit.cc.
Referenced by duringLoop(), and MuScleFit().
int MuScleFit::numberOfEwkZ [protected] |
Definition at line 262 of file MuScleFit.cc.
int MuScleFit::numberOfSimMuons [protected] |
Definition at line 260 of file MuScleFit.cc.
int MuScleFit::numberOfSimTracks [protected] |
Definition at line 259 of file MuScleFit.cc.
int MuScleFit::numberOfSimVertices [protected] |
Definition at line 261 of file MuScleFit.cc.
std::string MuScleFit::outputRootTreeFileName_ [protected] |
Definition at line 295 of file MuScleFit.cc.
Referenced by MuScleFit(), and ~MuScleFit().
bool MuScleFit::PATmuons_ [protected] |
Definition at line 289 of file MuScleFit.cc.
Referenced by MuScleFit().
MuScleFitPlotter * MuScleFit::plotter [protected] |
Definition at line 279 of file MuScleFit.cc.
Referenced by beginOfJobInConstructor(), endOfFastLoop(), and selectMuons().
reco::Particle::LorentzVector MuScleFit::recMu1 [protected] |
Definition at line 283 of file MuScleFit.cc.
Referenced by duringFastLoop(), and selectMuons().
reco::Particle::LorentzVector MuScleFit::recMu2 [protected] |
Definition at line 283 of file MuScleFit.cc.
Referenced by duringFastLoop(), and selectMuons().
bool MuScleFit::saveAllToTree_ [protected] |
Definition at line 303 of file MuScleFit.cc.
Referenced by MuScleFit(), and ~MuScleFit().
edm::InputTag MuScleFit::simTracksCollection_ [protected] |
Definition at line 288 of file MuScleFit.cc.
Referenced by MuScleFit().
MuonServiceProxy * MuScleFit::theService [protected] |
Definition at line 255 of file MuScleFit.cc.
int MuScleFit::totalEvents_ [protected] |
Definition at line 285 of file MuScleFit.cc.
Referenced by duringLoop(), endOfLoop(), and ~MuScleFit().
std::string MuScleFit::triggerPath_ [protected] |
Definition at line 166 of file MuScleFit.h.
std::vector<std::string> MuScleFit::triggerPath_ [protected] |
Definition at line 301 of file MuScleFit.cc.
Referenced by duringLoop(), and MuScleFit().
std::string MuScleFit::triggerResultsLabel_ [protected] |
Definition at line 299 of file MuScleFit.cc.
Referenced by duringLoop(), and MuScleFit().
std::string MuScleFit::triggerResultsProcess_ [protected] |
Definition at line 300 of file MuScleFit.cc.
Referenced by duringLoop(), and MuScleFit().