d7/d41/PFRecoTauEnergyAlgorithmPlugin_8cc_source.html

 /*

  * =============================================================================

  *       Filename:  RecoTauEnergyAlgorithmPlugin.cc

  *

  *    Description:  Determine best estimate for tau energy

  *                  for tau candidates reconstructed in different decay modes

  *

  *        Created:  04/09/2013 11:40:00

  *

  *         Authors:  Christian Veelken (LLR)

  *

  * =============================================================================

  */


 #include "FWCore/MessageLogger/interface/MessageLogger.h"


 #include "RecoTauTag/RecoTau/interface/RecoTauBuilderPlugins.h"

 #include "DataFormats/ParticleFlowCandidate/interface/PFCandidate.h"

 #include "DataFormats/ParticleFlowCandidate/interface/PFCandidateFwd.h"

 #include "DataFormats/JetReco/interface/PFJet.h"

 #include "DataFormats/TrackReco/interface/Track.h"

 #include "DataFormats/Common/interface/Ptr.h"

 #include "DataFormats/Common/interface/RefToPtr.h"

 #include "DataFormats/TauReco/interface/PFRecoTauChargedHadron.h"

 #include "DataFormats/TauReco/interface/PFRecoTauChargedHadronFwd.h"

 #include "RecoTauTag/RecoTau/interface/pfRecoTauChargedHadronAuxFunctions.h"


 #include "DataFormats/Math/interface/deltaR.h"

 #include "FWCore/Utilities/interface/isFinite.h"


 #include <vector>

 #include <cmath>


 namespace reco { namespace tau {


 class PFRecoTauEnergyAlgorithmPlugin : public RecoTauModifierPlugin

 {

  public:


   explicit PFRecoTauEnergyAlgorithmPlugin(const edm::ParameterSet&, edm::ConsumesCollector &&iC);

   virtual ~PFRecoTauEnergyAlgorithmPlugin();

   void operator()(PFTau&) const;

   virtual void beginEvent();

   virtual void endEvent();


  private:


   double dRaddNeutralHadron_;

   double minNeutralHadronEt_;

   double dRaddPhoton_;

   double minGammaEt_;


   int verbosity_;

 };


   PFRecoTauEnergyAlgorithmPlugin::PFRecoTauEnergyAlgorithmPlugin(const edm::ParameterSet& cfg, edm::ConsumesCollector &&iC)

     : RecoTauModifierPlugin(cfg, std::move(iC)),

     dRaddNeutralHadron_(cfg.getParameter<double>("dRaddNeutralHadron")),

     minNeutralHadronEt_(cfg.getParameter<double>("minNeutralHadronEt")),

     dRaddPhoton_(cfg.getParameter<double>("dRaddPhoton")),

     minGammaEt_(cfg.getParameter<double>("minGammaEt"))

 {

   verbosity_ = ( cfg.exists("verbosity") ) ?

     cfg.getParameter<int>("verbosity") : 0;

 }


 PFRecoTauEnergyAlgorithmPlugin::~PFRecoTauEnergyAlgorithmPlugin()

 {}


 void PFRecoTauEnergyAlgorithmPlugin::beginEvent()

 {}


 namespace

 {

   double getTrackPerr2(const reco::Track& track)

   {

     double trackPerr = track.p()*(track.ptError()/track.pt());

     return trackPerr*trackPerr;

   }


   void updateTauP4(PFTau& tau, double sf, const reco::Candidate::LorentzVector& addP4)

   {

     // preserve tau candidate mass when adding extra neutral energy

     double tauPx_modified = tau.px() + sf*addP4.px();

     double tauPy_modified = tau.py() + sf*addP4.py();

     double tauPz_modified = tau.pz() + sf*addP4.pz();

     double tauMass = tau.mass();

     double tauEn_modified = sqrt(tauPx_modified*tauPx_modified + tauPy_modified*tauPy_modified + tauPz_modified*tauPz_modified + tauMass*tauMass);

     reco::Candidate::LorentzVector tauP4_modified(tauPx_modified, tauPy_modified, tauPz_modified, tauEn_modified);

     tau.setP4(tauP4_modified);

   }


   void killTau(PFTau& tau)

   {

     reco::Candidate::LorentzVector tauP4_modified(0.,0.,0.,0.);

     tau.setP4(tauP4_modified);

     tau.setStatus(-1);

   }

 }


 void PFRecoTauEnergyAlgorithmPlugin::operator()(PFTau& tau) const

 {

   if ( verbosity_ ) {

     std::cout << "<PFRecoTauEnergyAlgorithmPlugin::operator()>:" << std::endl;

     std::cout << "tau: Pt = " << tau.pt() << ", eta = " << tau.eta() << ", phi = " << tau.phi() << " (En = " << tau.energy() << ", decayMode = " << tau.decayMode() << ")" << std::endl;

   }


   // Add high Pt PFNeutralHadrons and PFGammas that are not "used" by tau decay mode object

   std::vector<reco::PFCandidatePtr> addNeutrals;

   reco::Candidate::LorentzVector addNeutralsSumP4;

   std::vector<reco::PFCandidatePtr> jetConstituents = tau.jetRef()->getPFConstituents();

   for ( std::vector<reco::PFCandidatePtr>::const_iterator jetConstituent = jetConstituents.begin();

     jetConstituent != jetConstituents.end(); ++jetConstituent ) {

     reco::PFCandidate::ParticleType jetConstituentType = (*jetConstituent)->particleId();

     if ( !((jetConstituentType == reco::PFCandidate::h0    && (*jetConstituent)->et() > minNeutralHadronEt_) ||

        (jetConstituentType == reco::PFCandidate::gamma && (*jetConstituent)->et() > minGammaEt_        )) ) continue;


     bool isSignalPFCand = false;

     const std::vector<reco::PFCandidatePtr>& signalPFCands = tau.signalPFCands();

     for ( std::vector<reco::PFCandidatePtr>::const_iterator signalPFCand = signalPFCands.begin();

       signalPFCand != signalPFCands.end(); ++signalPFCand ) {

       if ( (*jetConstituent) == (*signalPFCand) ) isSignalPFCand = true;

     }

     if ( isSignalPFCand ) continue;


     double dR = deltaR((*jetConstituent)->p4(), tau.p4());

     double dRadd = -1.;

     if      ( jetConstituentType == reco::PFCandidate::h0    ) dRadd = dRaddNeutralHadron_;

     else if ( jetConstituentType == reco::PFCandidate::gamma ) dRadd = dRaddPhoton_;

     if ( dR < dRadd ) {

       addNeutrals.push_back(*jetConstituent);

       addNeutralsSumP4 += (*jetConstituent)->p4();

     }

   }

   if ( verbosity_ ) {

     std::cout << "addNeutralsSumP4: En = " << addNeutralsSumP4.energy() << std::endl;

   }


   unsigned numNonPFCandTracks = 0;

   double nonPFCandTracksSumP = 0.;

   double nonPFCandTracksSumPerr2 = 0.;

   const std::vector<PFRecoTauChargedHadron>& chargedHadrons = tau.signalTauChargedHadronCandidates();

   for ( std::vector<PFRecoTauChargedHadron>::const_iterator chargedHadron = chargedHadrons.begin();

     chargedHadron != chargedHadrons.end(); ++chargedHadron ) {

     if ( chargedHadron->algoIs(PFRecoTauChargedHadron::kTrack) ) {

       ++numNonPFCandTracks;

       const edm::Ptr<Track>& chargedHadronTrack = chargedHadron->getTrack();

       nonPFCandTracksSumP += chargedHadronTrack->p();

       nonPFCandTracksSumPerr2 += getTrackPerr2(*chargedHadronTrack);

     }

   }

   if ( verbosity_ ) {

     std::cout << "nonPFCandTracksSumP = " << nonPFCandTracksSumP << " +/- " << sqrt(nonPFCandTracksSumPerr2)

           << " (numNonPFCandTracks = " << numNonPFCandTracks << ")" << std::endl;

   }


   if ( numNonPFCandTracks == 0 ) {

     // This is the easy case:

     // All tau energy is taken from PFCandidates reconstructed by PFlow algorithm

     // and there is no issue with double-counting of energy.

     if ( verbosity_ ) {

       std::cout << "easy case: all tracks are associated to PFCandidates --> leaving tau momentum untouched." << std::endl;

     }

     updateTauP4(tau, 1., addNeutralsSumP4);

     return;

   } else {

     // This is the difficult case:

     // The tau energy needs to be computed for an arbitrary mix of charged and neutral PFCandidates plus reco::Tracks.

     // We need to make sure not to double-count energy deposited by reco::Track in ECAL and/or HCAL as neutral PFCandidates.


     // Check if we have enough energy in collection of PFNeutralHadrons and PFGammas that are not "used" by tau decay mode object

     // to balance track momenta:

     if ( nonPFCandTracksSumP < addNeutralsSumP4.energy() ) {

       double scaleFactor = 1. - nonPFCandTracksSumP/addNeutralsSumP4.energy();

       if ( !(scaleFactor >= 0. && scaleFactor <= 1.) ) {

     edm::LogWarning("PFRecoTauEnergyAlgorithmPlugin::operator()")

       << "Failed to compute tau energy --> killing tau candidate !!" << std::endl;

     killTau(tau);

     return;

       }

       if ( verbosity_ ) {

     std::cout << "case (2): addNeutralsSumEn > nonPFCandTracksSumP --> adjusting tau momentum." << std::endl;

       }

       updateTauP4(tau, scaleFactor, addNeutralsSumP4);

       return;

     }


     // Determine which neutral PFCandidates are close to PFChargedHadrons

     // and have been merged into ChargedHadrons

     std::vector<reco::PFCandidatePtr> mergedNeutrals;

     reco::Candidate::LorentzVector mergedNeutralsSumP4;

     for ( std::vector<PFRecoTauChargedHadron>::const_iterator chargedHadron = chargedHadrons.begin();

       chargedHadron != chargedHadrons.end(); ++chargedHadron ) {

       if ( chargedHadron->algoIs(PFRecoTauChargedHadron::kTrack) ) {

     const std::vector<reco::PFCandidatePtr>& neutralPFCands = chargedHadron->getNeutralPFCandidates();

     for ( std::vector<reco::PFCandidatePtr>::const_iterator neutralPFCand = neutralPFCands.begin();

           neutralPFCand != neutralPFCands.end(); ++neutralPFCand ) {

       mergedNeutrals.push_back(*neutralPFCand);

       mergedNeutralsSumP4 += (*neutralPFCand)->p4();

     }

       }

     }

     if ( verbosity_ ) {

       std::cout << "mergedNeutralsSumP4: En = " << mergedNeutralsSumP4.energy() << std::endl;

     }


     // Check if track momenta are balanced by sum of PFNeutralHadrons and PFGammas that are not "used" by tau decay mode object

     // plus neutral PFCandidates close to PFChargedHadrons:

     if ( nonPFCandTracksSumP < (addNeutralsSumP4.energy() + mergedNeutralsSumP4.energy()) ) {

       double scaleFactor = ((addNeutralsSumP4.energy() + mergedNeutralsSumP4.energy()) - nonPFCandTracksSumP)/mergedNeutralsSumP4.energy();

       if ( !(scaleFactor >= 0. && scaleFactor <= 1.) ) {

         edm::LogWarning("PFRecoTauEnergyAlgorithmPlugin::operator()")

       << "Failed to compute tau energy --> killing tau candidate !!" << std::endl;

     killTau(tau);

     return;

       }

       reco::Candidate::LorentzVector diffP4;

       size_t numChargedHadrons = chargedHadrons.size();

       for ( size_t iChargedHadron = 0; iChargedHadron < numChargedHadrons; ++iChargedHadron ) {

     const PFRecoTauChargedHadron& chargedHadron = chargedHadrons[iChargedHadron];

     if ( chargedHadron.getNeutralPFCandidates().size() >= 1 ) {

       PFRecoTauChargedHadron chargedHadron_modified = chargedHadron;

       setChargedHadronP4(chargedHadron_modified, scaleFactor);

       tau.signalTauChargedHadronCandidates_[iChargedHadron] = chargedHadron_modified;

       diffP4 += (chargedHadron.p4() - chargedHadron_modified.p4());

     }

       }

       if ( verbosity_ ) {

     std::cout << "case (3): (addNeutralsSumEn + mergedNeutralsSumEn) > nonPFCandTracksSumP --> adjusting tau momentum." << std::endl;

       }

       updateTauP4(tau, -1., diffP4);

       return;

     }


     // Determine energy sum of all PFNeutralHadrons interpreted as ChargedHadrons with missing track

     unsigned numChargedHadronNeutrals = 0;

     std::vector<reco::PFCandidatePtr> chargedHadronNeutrals;

     reco::Candidate::LorentzVector chargedHadronNeutralsSumP4;

     for ( std::vector<PFRecoTauChargedHadron>::const_iterator chargedHadron = chargedHadrons.begin();

       chargedHadron != chargedHadrons.end(); ++chargedHadron ) {

       if ( chargedHadron->algoIs(PFRecoTauChargedHadron::kPFNeutralHadron) ) {

     ++numChargedHadronNeutrals;

     chargedHadronNeutrals.push_back(chargedHadron->getChargedPFCandidate());

     chargedHadronNeutralsSumP4 += chargedHadron->getChargedPFCandidate()->p4();

       }

     }

     if ( verbosity_ ) {

       std::cout << "chargedHadronNeutralsSumP4: En = " << chargedHadronNeutralsSumP4.energy()

         << " (numChargedHadronNeutrals = " << numChargedHadronNeutrals << ")" << std::endl;

     }


     // Check if sum of PFNeutralHadrons and PFGammas that are not "used" by tau decay mode object

     // plus neutral PFCandidates close to PFChargedHadrons plus PFNeutralHadrons interpreted as ChargedHadrons with missing track balances track momenta

     if ( nonPFCandTracksSumP < (addNeutralsSumP4.energy() + mergedNeutralsSumP4.energy() + chargedHadronNeutralsSumP4.energy()) ) {

       double scaleFactor = ((addNeutralsSumP4.energy() + mergedNeutralsSumP4.energy() + chargedHadronNeutralsSumP4.energy()) - nonPFCandTracksSumP)/chargedHadronNeutralsSumP4.energy();

       if ( !(scaleFactor >= 0. && scaleFactor <= 1.) ) {

         edm::LogWarning("PFRecoTauEnergyAlgorithmPlugin::operator()")

       << "Failed to compute tau energy --> killing tau candidate !!" << std::endl;

     killTau(tau);

     return;

       }

       reco::Candidate::LorentzVector diffP4;

       size_t numChargedHadrons = chargedHadrons.size();

       for ( size_t iChargedHadron = 0; iChargedHadron < numChargedHadrons; ++iChargedHadron ) {

     const PFRecoTauChargedHadron& chargedHadron = chargedHadrons[iChargedHadron];

     if ( chargedHadron.algoIs(PFRecoTauChargedHadron::kPFNeutralHadron) ) {

       PFRecoTauChargedHadron chargedHadron_modified = chargedHadron;

       chargedHadron_modified.neutralPFCandidates_.clear();

       const PFCandidatePtr& chargedPFCand = chargedHadron.getChargedPFCandidate();

       double chargedHadronPx_modified = scaleFactor*chargedPFCand->px();

       double chargedHadronPy_modified = scaleFactor*chargedPFCand->py();

       double chargedHadronPz_modified = scaleFactor*chargedPFCand->pz();

       reco::Candidate::LorentzVector chargedHadronP4_modified = compChargedHadronP4fromPxPyPz(chargedHadronPx_modified, chargedHadronPy_modified, chargedHadronPz_modified);

       chargedHadron_modified.setP4(chargedHadronP4_modified);

       tau.signalTauChargedHadronCandidates_[iChargedHadron] = chargedHadron_modified;

       diffP4 += (chargedHadron.p4() - chargedHadron_modified.p4());

     }

       }

       if ( verbosity_ ) {

     std::cout << "case (4): (addNeutralsSumEn + mergedNeutralsSumEn + chargedHadronNeutralsSumEn) > nonPFCandTracksSumP --> adjusting momenta of tau and chargedHadrons." << std::endl;

       }

       updateTauP4(tau, -1., diffP4);

       return;

     } else {

       double allTracksSumP = 0.;

       double allTracksSumPerr2 = 0.;

       const std::vector<PFRecoTauChargedHadron> chargedHadrons = tau.signalTauChargedHadronCandidates();

       for ( std::vector<PFRecoTauChargedHadron>::const_iterator chargedHadron = chargedHadrons.begin();

         chargedHadron != chargedHadrons.end(); ++chargedHadron ) {

     if ( chargedHadron->algoIs(PFRecoTauChargedHadron::kChargedPFCandidate) || chargedHadron->algoIs(PFRecoTauChargedHadron::kTrack) ) {

           const edm::Ptr<Track>& chargedHadronTrack = chargedHadron->getTrack();

       if ( chargedHadronTrack.isNonnull() ) {

         allTracksSumP += chargedHadronTrack->p();

         allTracksSumPerr2 += getTrackPerr2(*chargedHadronTrack);

       } else {

         edm::LogWarning("PFRecoTauEnergyAlgorithmPlugin::operator()")

           << "PFRecoTauChargedHadron has no associated reco::Track !!" << std::endl;

         if ( verbosity_ ) {

           chargedHadron->print();

         }

       }

     }

       }

       if ( verbosity_ ) {

     std::cout << "allTracksSumP = " << allTracksSumP << " +/- " << sqrt(allTracksSumPerr2) << std::endl;

       }

       double allNeutralsSumEn = 0.;

       const std::vector<reco::PFCandidatePtr>& signalPFCands = tau.signalPFCands();

       for ( std::vector<reco::PFCandidatePtr>::const_iterator signalPFCand = signalPFCands.begin();

         signalPFCand != signalPFCands.end(); ++signalPFCand ) {

     if ( verbosity_ ) {

       std::cout << "PFCandidate #" << signalPFCand->id() << ":" << signalPFCand->key() << ":"

             << " Pt = " << (*signalPFCand)->pt() << ", eta = " << (*signalPFCand)->eta() << ", phi = " << (*signalPFCand)->phi() << std::endl;

       std::cout << "calorimeter energy:"

             << " ECAL = " << (*signalPFCand)->ecalEnergy() << ","

             << " HCAL = " << (*signalPFCand)->hcalEnergy() << ","

             << " HO = " << (*signalPFCand)->hoEnergy() << std::endl;

     }

     if ( edm::isFinite((*signalPFCand)->ecalEnergy()) ) allNeutralsSumEn += (*signalPFCand)->ecalEnergy();

     if ( edm::isFinite((*signalPFCand)->hcalEnergy()) ) allNeutralsSumEn += (*signalPFCand)->hcalEnergy();

     if ( edm::isFinite((*signalPFCand)->hoEnergy())   ) allNeutralsSumEn += (*signalPFCand)->hoEnergy();

       }

       allNeutralsSumEn += addNeutralsSumP4.energy();

       if ( allNeutralsSumEn < 0. ) allNeutralsSumEn = 0.;

       if ( verbosity_ ) {

     std::cout << "allNeutralsSumEn = " << allNeutralsSumEn << std::endl;

       }

       if ( allNeutralsSumEn > allTracksSumP ) {

     // Adjust momenta of neutral PFCandidates merged into ChargedHadrons

     size_t numChargedHadrons = chargedHadrons.size();

     for ( size_t iChargedHadron = 0; iChargedHadron < numChargedHadrons; ++iChargedHadron ) {

       const PFRecoTauChargedHadron& chargedHadron = chargedHadrons[iChargedHadron];

       if ( chargedHadron.algoIs(PFRecoTauChargedHadron::kChargedPFCandidate) ) {

         PFRecoTauChargedHadron chargedHadron_modified = chargedHadron;

         chargedHadron_modified.neutralPFCandidates_.clear();

         chargedHadron_modified.setP4(chargedHadron.getChargedPFCandidate()->p4());

         if ( verbosity_ ) {

           std::cout << "chargedHadron #" << iChargedHadron << ": changing En = " << chargedHadron.energy() << " to " << chargedHadron_modified.energy() << std::endl;

         }

         tau.signalTauChargedHadronCandidates_[iChargedHadron] = chargedHadron_modified;

       } else if ( chargedHadron.algoIs(PFRecoTauChargedHadron::kTrack) ) {

         PFRecoTauChargedHadron chargedHadron_modified = chargedHadron;

         chargedHadron_modified.neutralPFCandidates_.clear();

         reco::Candidate::LorentzVector chargedHadronP4_modified(0.,0.,0.,0.);

         if ( (chargedHadron.getTrack()).isNonnull() ) {

           const Track& chargedHadronTrack = *(chargedHadron.getTrack());

           double chargedHadronPx_modified     = chargedHadronTrack.px();

           double chargedHadronPy_modified = chargedHadronTrack.py();

           double chargedHadronPz_modified   = chargedHadronTrack.pz();

           chargedHadronP4_modified = compChargedHadronP4fromPxPyPz(chargedHadronPx_modified, chargedHadronPy_modified, chargedHadronPz_modified);

         } else {

           edm::LogWarning("PFRecoTauEnergyAlgorithmPlugin::operator()")

         << "PFRecoTauChargedHadron has no associated reco::Track !!" << std::endl;

           if ( verbosity_ ) {

         chargedHadron.print();

           }

         }

         chargedHadron_modified.setP4(chargedHadronP4_modified);

         if ( verbosity_ ) {

           std::cout << "chargedHadron #" << iChargedHadron << ": changing En = " << chargedHadron.energy() << " to " << chargedHadron_modified.energy() << std::endl;

         }

         tau.signalTauChargedHadronCandidates_[iChargedHadron] = chargedHadron_modified;

       }

     }

     double scaleFactor = allNeutralsSumEn/tau.energy();

     if ( verbosity_ ) {

       std::cout << "case (5): allNeutralsSumEn > allTracksSumP --> adjusting momenta of tau and chargedHadrons." << std::endl;

     }

     updateTauP4(tau, scaleFactor - 1., tau.p4());

     return;

       } else {

     if ( numChargedHadronNeutrals == 0 && tau.signalPiZeroCandidates().size() == 0 ) {

       // Adjust momenta of ChargedHadrons build from reco::Tracks to match sum of energy deposits in ECAL + HCAL + HO

       size_t numChargedHadrons = chargedHadrons.size();

       for ( size_t iChargedHadron = 0; iChargedHadron < numChargedHadrons; ++iChargedHadron ) {

         const PFRecoTauChargedHadron& chargedHadron = chargedHadrons[iChargedHadron];

         if ( chargedHadron.algoIs(PFRecoTauChargedHadron::kChargedPFCandidate) || chargedHadron.algoIs(PFRecoTauChargedHadron::kTrack) ) {

           PFRecoTauChargedHadron chargedHadron_modified = chargedHadron;

           chargedHadron_modified.neutralPFCandidates_.clear();

           reco::Candidate::LorentzVector chargedHadronP4_modified(0.,0.,0.,0.);

           const edm::Ptr<Track>& chargedHadronTrack = chargedHadron.getTrack();

           if ( chargedHadronTrack.isNonnull() ) {

         double trackP = chargedHadronTrack->p();

         double trackPerr2 = getTrackPerr2(*chargedHadronTrack);

         if ( verbosity_ ) {

           std::cout << "trackP = " << trackP << " +/- " << sqrt(trackPerr2) << std::endl;

         }

         // CV: adjust track momenta such that difference beeen (measuredTrackP - adjustedTrackP)/sigmaMeasuredTrackP is minimal

         //    (expression derived using Mathematica)

         double trackP_modified =

                   (trackP*(allTracksSumPerr2 - trackPerr2)

                  + trackPerr2*(allNeutralsSumEn - (allTracksSumP - trackP)))/

                   allTracksSumPerr2;

             // CV: trackP_modified may actually become negative in case sum of energy deposits in ECAL + HCAL + HO is small

         //     and one of the tracks has a significantly larger momentum uncertainty than the other tracks.

         //     In this case set track momentum to small positive value.

         if ( trackP_modified < 1.e-1 ) trackP_modified = 1.e-1;

         if ( verbosity_ ) {

           std::cout << "trackP (modified) = " << trackP_modified << std::endl;

         }

         double scaleFactor = trackP_modified/trackP;

         if ( !(scaleFactor >= 0. && scaleFactor <= 1.) ) {

           edm::LogWarning("PFRecoTauEnergyAlgorithmPlugin::operator()")

             << "Failed to compute tau energy --> killing tau candidate !!" << std::endl;

           killTau(tau);

           return;

         }

         double chargedHadronPx_modified = scaleFactor*chargedHadronTrack->px();

         double chargedHadronPy_modified = scaleFactor*chargedHadronTrack->py();

         double chargedHadronPz_modified = scaleFactor*chargedHadronTrack->pz();

         chargedHadronP4_modified = compChargedHadronP4fromPxPyPz(chargedHadronPx_modified, chargedHadronPy_modified, chargedHadronPz_modified);

           } else {

         edm::LogWarning("PFRecoTauEnergyAlgorithmPlugin::operator()")

           << "PFRecoTauChargedHadron has no associated reco::Track !!" << std::endl;

         if ( verbosity_ ) {

           chargedHadron.print();

         }

           }

           chargedHadron_modified.setP4(chargedHadronP4_modified);

           if ( verbosity_ ) {

         std::cout << "chargedHadron #" << iChargedHadron << ": changing En = " << chargedHadron.energy() << " to " << chargedHadron_modified.energy() << std::endl;

           }

           tau.signalTauChargedHadronCandidates_[iChargedHadron] = chargedHadron_modified;

         }

       }

       double scaleFactor = allNeutralsSumEn/tau.energy();

       if ( verbosity_ ) {

         std::cout << "case (6): allNeutralsSumEn < allTracksSumP --> adjusting momenta of tau and chargedHadrons." << std::endl;

       }

       updateTauP4(tau, scaleFactor - 1., tau.p4());

       return;

     } else {

       // Interpretation of PFNeutralHadrons as ChargedHadrons with missing track and/or reconstruction of extra PiZeros

       // is not compatible with the fact that sum of reco::Track momenta exceeds sum of energy deposits in ECAL + HCAL + HO:

       // kill tau candidate (by setting its four-vector to zero)

       if ( verbosity_ ) {

         std::cout << "case (7): allNeutralsSumEn < allTracksSumP not compatible with tau decay mode hypothesis --> killing tau candidate." << std::endl;

       }

       killTau(tau);

       return;

     }

       }

     }

   }


   // CV: You should never come here.

   if ( verbosity_ ) {

     std::cout << "undefined case: you should never come here !!" << std::endl;

   }

   assert(0);

 }


 void PFRecoTauEnergyAlgorithmPlugin::endEvent()

 {}


 }} // end namespace reco::tau


 #include "FWCore/Framework/interface/MakerMacros.h"


 DEFINE_EDM_PLUGIN(RecoTauModifierPluginFactory, reco::tau::PFRecoTauEnergyAlgorithmPlugin, "PFRecoTauEnergyAlgorithmPlugin");

reco::TrackBase::p
double p() const
momentum vector magnitude
Definition: TrackBase.h:663

edm::ParameterSet::getParameter
T getParameter(std::string const &) const

reco::tau::PFRecoTauEnergyAlgorithmPlugin::~PFRecoTauEnergyAlgorithmPlugin
virtual ~PFRecoTauEnergyAlgorithmPlugin()
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:67

isFinite.h

reco::tau::RecoTauModifierPlugin
Definition: RecoTauBuilderPlugins.h:100

pfRecoTauChargedHadronAuxFunctions.h

MessageLogger.h

reco::PFCandidate::ParticleType
ParticleType
particle types
Definition: PFCandidate.h:44

reco::PFTau::jetRef
const PFJetRef & jetRef() const
Definition: PFTau.cc:54

looper.cfg
tuple cfg
Definition: looper.py:259

reco::PFCandidate::gamma
Definition: PFCandidate.h:49

PFRecoTauChargedHadron.h

reco::PFTau::signalTauChargedHadronCandidates_
std::vector< reco::PFRecoTauChargedHadron > signalTauChargedHadronCandidates_
Definition: PFTau.h:259

reco::PFRecoTauChargedHadron::kChargedPFCandidate
Definition: PFRecoTauChargedHadron.h:28

RecoTauBuilderPlugins.h

assert
assert(m_qm.get())

MakerMacros.h

Ptr.h

edm::LogWarning
Definition: MessageLogger.h:140

edm::ParameterSet::exists
bool exists(std::string const &parameterName) const
checks if a parameter exists
Definition: ParameterSet.cc:758

reco::LeafCandidate::setP4
virtual void setP4(const LorentzVector &p4)
set 4-momentum
Definition: LeafCandidate.h:143

reco::PFRecoTauChargedHadron::kPFNeutralHadron
Definition: PFRecoTauChargedHadron.h:30

reco::deltaR
double deltaR(const T1 &t1, const T2 &t2)
Definition: deltaR.h:48

reco::TrackBase::px
double px() const
x coordinate of momentum vector
Definition: TrackBase.h:675

dt_dqm_sourceclient_common_cff.reco
tuple reco
Definition: dt_dqm_sourceclient_common_cff.py:107

reco::tau::PFRecoTauEnergyAlgorithmPlugin::minNeutralHadronEt_
double minNeutralHadronEt_
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:49

reco::PFTau::signalPFCands
const std::vector< reco::PFCandidatePtr > & signalPFCands() const
PFCandidates in signal region.
Definition: PFTau.cc:74

reco::LeafCandidate::eta
virtual double eta() const
momentum pseudorapidity
Definition: LeafCandidate.h:137

reco::LeafCandidate::pt
virtual double pt() const
transverse momentum
Definition: LeafCandidate.h:131

reco::PFCandidate::h0
Definition: PFCandidate.h:50

edm::isFinite
bool isFinite(T x)

reco::PFTau::decayMode
hadronicDecayMode decayMode() const
Definition: PFTau.cc:178

reco::PFRecoTauChargedHadron::print
void print(std::ostream &stream=std::cout) const
Definition: PFRecoTauChargedHadron.cc:88

reco::LeafCandidate::mass
virtual double mass() const
mass
Definition: LeafCandidate.h:116

reco::LeafCandidate::energy
virtual double energy() const
energy
Definition: LeafCandidate.h:110

tauMass
const double tauMass
Definition: ParticleReplacerParticleGun.cc:12

reco::tau::PFRecoTauEnergyAlgorithmPlugin::operator()
void operator()(PFTau &) const
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:101

PFCandidate.h

deltaR.h

edmplugin::PluginFactory
Definition: PluginFactory.h:31

reco::PFTau::signalPiZeroCandidates
const std::vector< RecoTauPiZero > & signalPiZeroCandidates() const
Retrieve the association of signal region gamma candidates into candidate PiZeros.
Definition: PFTau.cc:93

mathSSE::sqrt
T sqrt(T t)
Definition: SSEVec.h:48

reco::TrackBase::pt
double pt() const
track transverse momentum
Definition: TrackBase.h:669

reco::TrackBase::ptError
double ptError() const
error on Pt (set to 1000 TeV if charge==0 for safety)
Definition: TrackBase.h:811

reco::PFRecoTauChargedHadron
Definition: PFRecoTauChargedHadron.h:20

reco::PFTau
Definition: PFTau.h:33

metsig::tau
Definition: SignAlgoResolutions.h:40

edm::Ptr< Track >

RefToPtr.h

PFRecoTauDiscriminationAgainstElectronDeadECAL_cfi.dR
tuple dR
Definition: PFRecoTauDiscriminationAgainstElectronDeadECAL_cfi.py:19

reco::PFRecoTauChargedHadron::getTrack
const TrackPtr & getTrack() const
reference to reco::Track
Definition: PFRecoTauChargedHadron.cc:47

reco::tau::PFRecoTauEnergyAlgorithmPlugin
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:36

edm::Ptr::isNonnull
bool isNonnull() const
Checks for non-null.
Definition: Ptr.h:152

reco::TrackBase::pz
double pz() const
z coordinate of momentum vector
Definition: TrackBase.h:687

reco::tau::PFRecoTauEnergyAlgorithmPlugin::dRaddNeutralHadron_
double dRaddNeutralHadron_
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:48

reco::LeafCandidate::px
virtual double px() const
x coordinate of momentum vector
Definition: LeafCandidate.h:125

reco::PFRecoTauChargedHadron::getNeutralPFCandidates
const std::vector< PFCandidatePtr > & getNeutralPFCandidates() const
references to additional neutral PFCandidates
Definition: PFRecoTauChargedHadron.cc:52

reco::PFRecoTauChargedHadron::neutralPFCandidates_
std::vector< PFCandidatePtr > neutralPFCandidates_
Definition: PFRecoTauChargedHadron.h:80

reco::Track
Definition: Track.h:28

reco::LeafCandidate::pz
virtual double pz() const
z coordinate of momentum vector
Definition: LeafCandidate.h:129

reco::Candidate::LorentzVector
math::XYZTLorentzVector LorentzVector
Lorentz vector.
Definition: Candidate.h:37

alignCSCRings.e
list e
Definition: alignCSCRings.py:90

reco::tau::PFRecoTauEnergyAlgorithmPlugin::verbosity_
int verbosity_
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:53

reco::tau::PFRecoTauEnergyAlgorithmPlugin::beginEvent
virtual void beginEvent()
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:70

PFRecoTauChargedHadronFwd.h

reco::tau::PFRecoTauEnergyAlgorithmPlugin::PFRecoTauEnergyAlgorithmPlugin
PFRecoTauEnergyAlgorithmPlugin(const edm::ParameterSet &, edm::ConsumesCollector &&iC)
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:56

reco::PFRecoTauChargedHadron::algoIs
bool algoIs(PFRecoTauChargedHadronAlgorithm algo) const
Check whether a given algo produced this charged hadron.
Definition: PFRecoTauChargedHadron.cc:67

reco::PFTau::signalTauChargedHadronCandidates
const std::vector< PFRecoTauChargedHadron > & signalTauChargedHadronCandidates() const
Retrieve the association of signal region PF candidates into candidate PFRecoTauChargedHadrons.
Definition: PFTau.cc:140

edm::ParameterSet
Definition: ParameterSet.h:35

gather_cfg.cout
tuple cout
Definition: gather_cfg.py:121

DEFINE_EDM_PLUGIN
#define DEFINE_EDM_PLUGIN(factory, type, name)
Definition: PluginFactory.h:101

reco::tau::PFRecoTauEnergyAlgorithmPlugin::minGammaEt_
double minGammaEt_
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:51

Track.h

reco::tau::setChargedHadronP4
void setChargedHadronP4(reco::PFRecoTauChargedHadron &chargedHadron, double scaleFactor_neutralPFCands=1.0)
Definition: pfRecoTauChargedHadronAuxFunctions.cc:10

PFCandidateFwd.h

reco::LeafCandidate::phi
virtual double phi() const
momentum azimuthal angle
Definition: LeafCandidate.h:133

reco::LeafCandidate::p4
virtual const LorentzVector & p4() const
four-momentum Lorentz vector
Definition: LeafCandidate.h:99

reco::tau::PFRecoTauEnergyAlgorithmPlugin::endEvent
virtual void endEvent()
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:453

reco::PFRecoTauChargedHadron::kTrack
Definition: PFRecoTauChargedHadron.h:29

reco::LeafCandidate::py
virtual double py() const
y coordinate of momentum vector
Definition: LeafCandidate.h:127

RecoPFTauTag_cff.PFTau
tuple PFTau
Definition: RecoPFTauTag_cff.py:106

reco::TrackBase::py
double py() const
y coordinate of momentum vector
Definition: TrackBase.h:681

reco::PFRecoTauChargedHadron::getChargedPFCandidate
const PFCandidatePtr & getChargedPFCandidate() const
reference to &quot;charged&quot; PFCandidate (either charged PFCandidate or PFNeutralHadron) ...
Definition: PFRecoTauChargedHadron.cc:42

edm::ConsumesCollector
Definition: ConsumesCollector.h:32

PFJet.h

reco::tau::PFRecoTauEnergyAlgorithmPlugin::dRaddPhoton_
double dRaddPhoton_
Definition: PFRecoTauEnergyAlgorithmPlugin.cc:50

reco::tau::compChargedHadronP4fromPxPyPz
reco::Candidate::LorentzVector compChargedHadronP4fromPxPyPz(double, double, double)
Definition: pfRecoTauChargedHadronAuxFunctions.cc:50