AdHocNTupler.h

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#include "DataFormats/PatCandidates/interface/Electron.h"
#include "DataFormats/PatCandidates/interface/Photon.h"
#include "DataFormats/PatCandidates/interface/TriggerPath.h"
#include "DataFormats/PatCandidates/interface/TriggerEvent.h"
#include "DataFormats/PatCandidates/interface/TriggerAlgorithm.h"
#include "RecoEgamma/EgammaTools/interface/ConversionFinder.h"
#include "MagneticField/Records/interface/IdealMagneticFieldRecord.h"
#include "MagneticField/Engine/interface/MagneticField.h"
#include "DataFormats/TrackReco/interface/Track.h"
#include "DataFormats/TrackReco/interface/TrackExtra.h"
#include "DataFormats/Scalers/interface/DcsStatus.h"
#include "FWCore/Framework/interface/ESHandle.h"
#include "FWCore/Utilities/interface/Exception.h"

#include "DataFormats/Common/interface/ConditionsInEdm.h"
#include "FWCore/Framework/interface/Run.h"
#include "CondFormats/JetMETObjects/interface/JetCorrectorParameters.h"
#include "CondFormats/JetMETObjects/interface/FactorizedJetCorrector.h"
#include "CondFormats/JetMETObjects/interface/JetCorrectionUncertainty.h"

#include "SimDataFormats/PileupSummaryInfo/interface/PileupSummaryInfo.h" 
#include "DataFormats/Common/interface/TriggerResults.h"
#include "FWCore/Common/interface/TriggerNames.h"
#include "DataFormats/HcalRecHit/interface/HBHERecHit.h"

#include "DataFormats/RecoCandidate/interface/IsoDeposit.h"
#include "DataFormats/Common/interface/ValueMap.h"
#include "RecoEgamma/EgammaTools/interface/ConversionTools.h"

#include "DataFormats/PatCandidates/interface/MET.h"
#include "DataFormats/PatCandidates/interface/Jet.h"

#include "SimDataFormats/GeneratorProducts/interface/LHEEventProduct.h"

#include "EGamma/EGammaAnalysisTools/src/PFIsolationEstimator.cc"
#include "DataFormats/VertexReco/interface/Vertex.h"

//for conversion safe electron veto
#include "RecoEgamma/EgammaTools/interface/ConversionTools.h"

#include "CMGTools/External/interface/PileupJetIdentifier.h"

class AdHocNTupler : public NTupler {
 public:

  typedef std::vector< edm::Handle< edm::ValueMap<double> > > IsoDepositVals;

  AdHocNTupler (const edm::ParameterSet& iConfig){
    edm::ParameterSet adHocPSet = iConfig.getParameter<edm::ParameterSet>("AdHocNPSet");

    if (adHocPSet.exists("useTFileService"))
      useTFileService_=adHocPSet.getParameter<bool>("useTFileService");         
    else
      useTFileService_=iConfig.getParameter<bool>("useTFileService");

    if (useTFileService_){
      if (adHocPSet.exists("treeName")){
    treeName_=adHocPSet.getParameter<std::string>("treeName");
    ownTheTree_=true;
      }
      else{
    treeName_=iConfig.getParameter<std::string>("treeName");
    ownTheTree_=false;
      }
    }
    

    trigger_prescalevalue = new std::vector<float>;
    trigger_name = new std::vector<std::string>;
    trigger_decision = new std::vector<float>;
    trigger_lastfiltername = new std::vector<std::string>;
    triggerobject_pt = new std::vector<std::vector<float> >;
    triggerobject_px = new std::vector<std::vector<float> >;
    triggerobject_py = new std::vector<std::vector<float> >;
    triggerobject_pz = new std::vector<std::vector<float> >;
    triggerobject_et = new std::vector<std::vector<float> >;
    triggerobject_energy = new std::vector<std::vector<float> >;
    triggerobject_phi = new std::vector<std::vector<float> >;
    triggerobject_eta = new std::vector<std::vector<float> >;
    triggerobject_collectionname = new std::vector<std::vector<std::string> >;
    standalone_triggerobject_pt = new std::vector<float>;
    standalone_triggerobject_px = new std::vector<float>;
    standalone_triggerobject_py = new std::vector<float>;
    standalone_triggerobject_pz = new std::vector<float>;
    standalone_triggerobject_et = new std::vector<float>;
    standalone_triggerobject_energy = new std::vector<float>;
    standalone_triggerobject_phi = new std::vector<float>;
    standalone_triggerobject_eta = new std::vector<float>;
    standalone_triggerobject_collectionname = new std::vector<std::string>;
    L1trigger_bit = new std::vector<float>;
    L1trigger_techTrigger = new std::vector<float>;
    L1trigger_prescalevalue = new std::vector<float>;
    L1trigger_name = new std::vector<std::string>;
    L1trigger_alias = new std::vector<std::string>;
    L1trigger_decision = new std::vector<float>;
    L1trigger_decision_nomask = new std::vector<float>;
    els_conversion_dist = new std::vector<float>;
    els_conversion_dcot = new std::vector<float>;
    els_PFchargedHadronIsoR03 = new std::vector<float>;
    els_PFphotonIsoR03 = new std::vector<float>;
    els_PFneutralHadronIsoR03 = new std::vector<float>;
    els_hasMatchedConversion = new std::vector<bool>;
    pf_els_PFchargedHadronIsoR03 = new std::vector<float>;
    pf_els_PFphotonIsoR03 = new std::vector<float>;
    pf_els_PFneutralHadronIsoR03 = new std::vector<float>;
    pf_els_hasMatchedConversion = new std::vector<bool>;
    trk_nTOBTEC = new int;
    trk_ratioAllTOBTEC = new float;
    trk_ratioJetTOBTEC = new float;
    hbhefilter_decision_ = new int;
    cschalofilter_decision_ = new int;
    ecalTPfilter_decision_ = new int;
    ecalBEfilter_decision_ = new int;
    scrapingVeto_decision_ = new int;
    trackingfailurefilter_decision_ = new int;
    greedymuonfilter_decision_ = new int;
    inconsistentPFmuonfilter_decision_ = new int;
    hcallaserfilter_decision_ = new int;
    ecallaserfilter_decision_ = new int;
    eenoisefilter_decision_ = new int;
    eebadscfilter_decision_ = new int;
    trackercoherentnoisefilter1_decision_ = new int;  
    trackercoherentnoisefilter2_decision_ = new int;  
    trackertoomanyclustersfilter_decision_ = new int; 
    trackertoomanytripletsfilter_decision_ = new int; 
    trackertoomanyseedsfilter_decision_ = new int;    
    passprescalePFHT350filter_decision_ = new int;
    passprescaleHT250filter_decision_ = new int;
    passprescaleHT300filter_decision_ = new int;
    passprescaleHT350filter_decision_ = new int;
    passprescaleHT400filter_decision_ = new int;
    passprescaleHT450filter_decision_ = new int;
    MPT_ = new float;
    genHT_ = new float;
    jets_AK5PFclean_corrL2L3_ = new std::vector<float>; 
    jets_AK5PFclean_corrL2L3Residual_ = new std::vector<float>;
    jets_AK5PFclean_corrL1FastL2L3_ = new std::vector<float>;
    jets_AK5PFclean_corrL1L2L3_ = new std::vector<float>;
    jets_AK5PFclean_corrL1FastL2L3Residual_ = new std::vector<float>;
    jets_AK5PFclean_corrL1L2L3Residual_ = new std::vector<float>;
    jets_AK5PFclean_Uncert_ = new std::vector<float>;
    PU_zpositions_ = new std::vector<std::vector<float> >;
    PU_sumpT_lowpT_ = new std::vector<std::vector<float> >;
    PU_sumpT_highpT_ = new std::vector<std::vector<float> >;
    PU_ntrks_lowpT_ = new std::vector<std::vector<int> >;
    PU_ntrks_highpT_ = new std::vector<std::vector<int> >;
    PU_NumInteractions_ = new std::vector<int>;
    PU_bunchCrossing_ = new std::vector<int>;
    PU_TrueNumInteractions_ = new std::vector<float>;
    rho_kt6PFJetsForIsolation2011_ = new float;
    rho_kt6PFJetsForIsolation2012_ = new float;
    pfmets_fullSignif_ = new float;
    pfmets_fullSignifCov00_ = new float;
    pfmets_fullSignifCov10_ = new float;
    pfmets_fullSignifCov11_ = new float;
    softjetUp_dMEx_ = new float;
    softjetUp_dMEy_ = new float;
    pdfweights_cteq_ = new std::vector<float>;
    pdfweights_mstw_ = new std::vector<float>;
    pdfweights_nnpdf_ = new std::vector<float>;
     photon_chIsoValues = new std::vector<float>;
     photon_phIsoValues = new std::vector<float>;
     photon_nhIsoValues = new std::vector<float>;
     photon_passElectronVeto = new std::vector<bool>;
    //PU Jet ID vars
    puJet_rejectionBeta = new std::vector<std::vector<float> >;
    puJet_rejectionMVA  = new std::vector<std::vector<float> >;
    pfmets_fullSignif_2012_ = new float;
    pfmets_fullSignifCov00_2012_ = new float;
    pfmets_fullSignifCov10_2012_ = new float;
    pfmets_fullSignifCov11_2012_ = new float;

  }

  ~AdHocNTupler(){
    delete trigger_prescalevalue;
    delete trigger_name;
    delete trigger_decision;
    delete trigger_lastfiltername;
    delete triggerobject_pt;
    delete triggerobject_px;
    delete triggerobject_py;
    delete triggerobject_pz;
    delete triggerobject_et;
    delete triggerobject_energy;
    delete triggerobject_phi;
    delete triggerobject_eta;
    delete triggerobject_collectionname;
    delete standalone_triggerobject_pt;
    delete standalone_triggerobject_px;
    delete standalone_triggerobject_py;
    delete standalone_triggerobject_pz;
    delete standalone_triggerobject_et;
    delete standalone_triggerobject_energy;
    delete standalone_triggerobject_phi;
    delete standalone_triggerobject_eta;
    delete standalone_triggerobject_collectionname;
    delete L1trigger_bit;
    delete L1trigger_techTrigger;
    delete L1trigger_prescalevalue;
    delete L1trigger_name;
    delete L1trigger_alias;
    delete L1trigger_decision;
    delete L1trigger_decision_nomask;
    delete els_conversion_dist;
    delete els_conversion_dcot;
    delete els_PFchargedHadronIsoR03;
    delete els_PFphotonIsoR03;
    delete els_PFneutralHadronIsoR03;
    delete els_hasMatchedConversion;
    delete pf_els_PFchargedHadronIsoR03;
    delete pf_els_PFphotonIsoR03;
    delete pf_els_PFneutralHadronIsoR03;
    delete pf_els_hasMatchedConversion;
    delete trk_nTOBTEC;
    delete trk_ratioAllTOBTEC;
    delete trk_ratioJetTOBTEC;
    delete hbhefilter_decision_;
    delete cschalofilter_decision_;
    delete ecalTPfilter_decision_;
    delete ecalBEfilter_decision_;
    delete scrapingVeto_decision_;
    delete trackingfailurefilter_decision_;
    delete greedymuonfilter_decision_;
    delete inconsistentPFmuonfilter_decision_;
    delete hcallaserfilter_decision_;
    delete ecallaserfilter_decision_;
    delete eenoisefilter_decision_;
    delete eebadscfilter_decision_;
    delete trackercoherentnoisefilter1_decision_;
    delete trackercoherentnoisefilter2_decision_;
    delete trackertoomanyclustersfilter_decision_;
    delete trackertoomanytripletsfilter_decision_;
    delete trackertoomanyseedsfilter_decision_; 
    delete passprescalePFHT350filter_decision_;
    delete passprescaleHT250filter_decision_;
    delete passprescaleHT300filter_decision_;
    delete passprescaleHT350filter_decision_;
    delete passprescaleHT400filter_decision_;
    delete passprescaleHT450filter_decision_;
    delete MPT_;
    delete genHT_;
    delete jets_AK5PFclean_corrL2L3_;
    delete jets_AK5PFclean_corrL2L3Residual_;
    delete jets_AK5PFclean_corrL1FastL2L3_;
    delete jets_AK5PFclean_corrL1L2L3_;
    delete jets_AK5PFclean_corrL1FastL2L3Residual_;
    delete jets_AK5PFclean_corrL1L2L3Residual_;
    delete jets_AK5PFclean_Uncert_;
    delete PU_zpositions_;
    delete PU_sumpT_lowpT_;
    delete PU_sumpT_highpT_;
    delete PU_ntrks_lowpT_;
    delete PU_ntrks_highpT_;
    delete PU_NumInteractions_;
    delete PU_bunchCrossing_;
    delete PU_TrueNumInteractions_;
    delete rho_kt6PFJetsForIsolation2011_;
    delete rho_kt6PFJetsForIsolation2012_;
    delete  pfmets_fullSignif_;
    delete  pfmets_fullSignifCov00_;
    delete  pfmets_fullSignifCov10_;
    delete  pfmets_fullSignifCov11_;
    delete softjetUp_dMEx_;
    delete softjetUp_dMEy_;
    delete pdfweights_cteq_;
    delete pdfweights_mstw_;
    delete pdfweights_nnpdf_;
     delete photon_chIsoValues;
     delete photon_phIsoValues;
     delete photon_nhIsoValues;
     delete photon_passElectronVeto;
    delete puJet_rejectionBeta;
    delete puJet_rejectionMVA;
    delete  pfmets_fullSignif_2012_;
    delete  pfmets_fullSignifCov00_2012_;
    delete  pfmets_fullSignifCov10_2012_;
    delete  pfmets_fullSignifCov11_2012_;

  }

  uint registerleaves(edm::ProducerBase * producer){
    uint nLeaves=0;
    if (useTFileService_){
      edm::Service<TFileService> fs;      
      if (ownTheTree_){
    ownTheTree_=true;
    tree_=fs->make<TTree>(treeName_.c_str(),"StringBasedNTupler tree");
      }else{
    TObject * object = fs->file().Get(treeName_.c_str());
    if (!object){
      ownTheTree_=true;
      tree_=fs->make<TTree>(treeName_.c_str(),"StringBasedNTupler tree");
    }
    tree_=dynamic_cast<TTree*>(object);
    if (!tree_){
      ownTheTree_=true;
      tree_=fs->make<TTree>(treeName_.c_str(),"StringBasedNTupler tree");
    }
      }
      
      //register the leaves by hand
      tree_->Branch("trigger_prescalevalue",&trigger_prescalevalue);
      tree_->Branch("trigger_name",&trigger_name);
      tree_->Branch("trigger_decision",&trigger_decision);
      tree_->Branch("trigger_lastfiltername",&trigger_lastfiltername);
      tree_->Branch("triggerobject_pt",&triggerobject_pt);
      tree_->Branch("triggerobject_px",&triggerobject_px);
      tree_->Branch("triggerobject_py",&triggerobject_py);
      tree_->Branch("triggerobject_pz",&triggerobject_pz);
      tree_->Branch("triggerobject_et",&triggerobject_et);
      tree_->Branch("triggerobject_energy",&triggerobject_energy);
      tree_->Branch("triggerobject_phi",&triggerobject_phi);
      tree_->Branch("triggerobject_eta",&triggerobject_eta);
      tree_->Branch("triggerobject_collectionname",&triggerobject_collectionname);
      tree_->Branch("standalone_triggerobject_pt",&standalone_triggerobject_pt);
      tree_->Branch("standalone_triggerobject_px",&standalone_triggerobject_px);
      tree_->Branch("standalone_triggerobject_py",&standalone_triggerobject_py);
      tree_->Branch("standalone_triggerobject_pz",&standalone_triggerobject_pz);
      tree_->Branch("standalone_triggerobject_et",&standalone_triggerobject_et);
      tree_->Branch("standalone_triggerobject_energy",&standalone_triggerobject_energy);
      tree_->Branch("standalone_triggerobject_phi",&standalone_triggerobject_phi);
      tree_->Branch("standalone_triggerobject_eta",&standalone_triggerobject_eta);
      tree_->Branch("standalone_triggerobject_collectionname",&standalone_triggerobject_collectionname);
      tree_->Branch("L1trigger_bit",&L1trigger_bit);
      tree_->Branch("L1trigger_techTrigger",&L1trigger_techTrigger);
      tree_->Branch("L1trigger_prescalevalue",&L1trigger_prescalevalue);
      tree_->Branch("L1trigger_name",&L1trigger_name);
      tree_->Branch("L1trigger_alias",&L1trigger_alias);
      tree_->Branch("L1trigger_decision",&L1trigger_decision);
      tree_->Branch("L1trigger_decision_nomask",&L1trigger_decision_nomask);
      tree_->Branch("els_conversion_dist",&els_conversion_dist);
      tree_->Branch("els_conversion_dcot",&els_conversion_dcot);
      tree_->Branch("els_PFchargedHadronIsoR03",&els_PFchargedHadronIsoR03);
      tree_->Branch("els_PFphotonIsoR03",&els_PFphotonIsoR03);
      tree_->Branch("els_PFneutralHadronIsoR03",&els_PFneutralHadronIsoR03);
      tree_->Branch("els_hasMatchedConversion",&els_hasMatchedConversion);
      tree_->Branch("pf_els_PFchargedHadronIsoR03",&pf_els_PFchargedHadronIsoR03);
      tree_->Branch("pf_els_PFphotonIsoR03",&pf_els_PFphotonIsoR03);
      tree_->Branch("pf_els_PFneutralHadronIsoR03",&pf_els_PFneutralHadronIsoR03);
      tree_->Branch("pf_els_hasMatchedConversion",&pf_els_hasMatchedConversion);
      tree_->Branch("trk_nTOBTEC",trk_nTOBTEC,"Ctrk_nTOBTEC/I");    
      tree_->Branch("trk_ratioAllTOBTEC",trk_ratioAllTOBTEC,"trk_ratioAllTOBTEC/F");
      tree_->Branch("trk_ratioJetTOBTEC",trk_ratioJetTOBTEC,"trk_ratioJetTOBTEC/F");
      tree_->Branch("hbhefilter_decision",hbhefilter_decision_,"hbhefilter_decision/I");
      tree_->Branch("trackingfailurefilter_decision",trackingfailurefilter_decision_,"trackingfailurefilter_decision/I");
      tree_->Branch("cschalofilter_decision",cschalofilter_decision_,"cschalofilter_decision/I");          
      tree_->Branch("ecalTPfilter_decision",ecalTPfilter_decision_,"ecalTPfilter_decision/I");             
      tree_->Branch("ecalBEfilter_decision",ecalBEfilter_decision_,"ecalBEfilter_decision/I");             
      tree_->Branch("scrapingVeto_decision",scrapingVeto_decision_,"scrapingVeto_decision/I");             
      tree_->Branch("greedymuonfilter_decision",greedymuonfilter_decision_,"greedymuonfilter_decision/I");
      tree_->Branch("inconsistentPFmuonfilter_decision",inconsistentPFmuonfilter_decision_,"inconsistentPFmuonfilter_decision/I");
      tree_->Branch("hcallaserfilter_decision",hcallaserfilter_decision_,"hcallaserfilter_decision/I");
      tree_->Branch("ecallaserfilter_decision",ecallaserfilter_decision_,"ecallaserfilter_decision/I");
      tree_->Branch("eenoisefilter_decision",eenoisefilter_decision_,"eenoisefilter_decision/I");
      tree_->Branch("eebadscfilter_decision",eebadscfilter_decision_,"eebadscfilter_decision/I");
      tree_->Branch("trackercoherentnoisefilter1_decision", trackercoherentnoisefilter1_decision_, "trackercoherentnoisefilter1 /I");
      tree_->Branch("trackercoherentnoisefilter2_decision", trackercoherentnoisefilter2_decision_, "trackercoherentnoisefilter2 /I");
      tree_->Branch("trackertoomanyclustersfilter_decision", trackertoomanyclustersfilter_decision_, "trackertoomanyclustersfilter/I");
      tree_->Branch("trackertoomanytripletsfilter_decision", trackertoomanytripletsfilter_decision_, "trackertoomanytripletsfilter/I");
      tree_->Branch("trackertoomanyseedsfilter_decision", trackertoomanyseedsfilter_decision_, "trackertoomanyseedsfilter /I");
      tree_->Branch("passprescalePFHT350filter_decision",passprescalePFHT350filter_decision_,"passprescalePFHT350filter_decision/I");
      tree_->Branch("passprescaleHT250filter_decision",passprescaleHT250filter_decision_,"passprescaleHT250filter_decision/I");
      tree_->Branch("passprescaleHT300filter_decision",passprescaleHT300filter_decision_,"passprescaleHT300filter_decision/I");
      tree_->Branch("passprescaleHT350filter_decision",passprescaleHT350filter_decision_,"passprescaleHT350filter_decision/I");
      tree_->Branch("passprescaleHT400filter_decision",passprescaleHT400filter_decision_,"passprescaleHT400filter_decision/I");
      tree_->Branch("passprescaleHT450filter_decision",passprescaleHT450filter_decision_,"passprescaleHT450filter_decision/I");
      tree_->Branch("MPT",MPT_,"MPT/F");
      tree_->Branch("genHT",genHT_,"genHT/F");
      tree_->Branch("jets_AK5PFclean_corrL2L3",&jets_AK5PFclean_corrL2L3_);
      tree_->Branch("jets_AK5PFclean_corrL2L3Residual",&jets_AK5PFclean_corrL2L3Residual_);
      tree_->Branch("jets_AK5PFclean_corrL1FastL2L3",&jets_AK5PFclean_corrL1FastL2L3_);
      tree_->Branch("jets_AK5PFclean_corrL1L2L3",&jets_AK5PFclean_corrL1L2L3_);
      tree_->Branch("jets_AK5PFclean_corrL1FastL2L3Residual",&jets_AK5PFclean_corrL1FastL2L3Residual_);
      tree_->Branch("jets_AK5PFclean_corrL1L2L3Residual",&jets_AK5PFclean_corrL1L2L3Residual_);
      tree_->Branch("jets_AK5PFclean_Uncert",&jets_AK5PFclean_Uncert_);
      tree_->Branch("PU_zpositions",&PU_zpositions_);
      tree_->Branch("PU_sumpT_lowpT",&PU_sumpT_lowpT_);
      tree_->Branch("PU_sumpT_highpT",&PU_sumpT_highpT_);
      tree_->Branch("PU_ntrks_lowpT",&PU_ntrks_lowpT_);
      tree_->Branch("PU_ntrks_highpT",&PU_ntrks_highpT_);
      tree_->Branch("PU_NumInteractions",&PU_NumInteractions_);
      tree_->Branch("PU_bunchCrossing",&PU_bunchCrossing_);
      tree_->Branch("PU_TrueNumInteractions",&PU_TrueNumInteractions_);
      tree_->Branch("rho_kt6PFJetsForIsolation2011",rho_kt6PFJetsForIsolation2011_,"rho_kt6PFJetsForIsolation2011/F");
      tree_->Branch("rho_kt6PFJetsForIsolation2012",rho_kt6PFJetsForIsolation2012_,"rho_kt6PFJetsForIsolation2012/F");
      tree_->Branch("pfmets_fullSignif",pfmets_fullSignif_,"pfmets_fullSignif/F");
      tree_->Branch("pfmets_fullSignifCov00",pfmets_fullSignifCov00_,"pfmets_fullSignifCov00/F");
      tree_->Branch("pfmets_fullSignifCov10",pfmets_fullSignifCov10_,"pfmets_fullSignifCov10/F");
      tree_->Branch("pfmets_fullSignifCov11",pfmets_fullSignifCov11_,"pfmets_fullSignifCov11/F");
      tree_->Branch("softjetUp_dMEx",softjetUp_dMEx_,"softjetUp_dMEx/F");
      tree_->Branch("softjetUp_dMEy",softjetUp_dMEy_,"softjetUp_dMEy/F");
      tree_->Branch("pdfweights_cteq",&pdfweights_cteq_);
      tree_->Branch("pdfweights_mstw",&pdfweights_mstw_);
      tree_->Branch("pdfweights_nnpdf",&pdfweights_nnpdf_);
      tree_->Branch("photon_chIsoValues",&photon_chIsoValues);
      tree_->Branch("photon_phIsoValues",&photon_phIsoValues);
      tree_->Branch("photon_nhIsoValues",&photon_nhIsoValues);
      tree_->Branch("photon_passElectronVeto",&photon_passElectronVeto);
      tree_->Branch("puJet_rejectionBeta",&puJet_rejectionBeta);
      tree_->Branch("puJet_rejectionMVA",&puJet_rejectionMVA);
      tree_->Branch("pfmets_fullSignif_2012",pfmets_fullSignif_2012_,"pfmets_fullSignif_2012/F");
      tree_->Branch("pfmets_fullSignifCov00_2012",pfmets_fullSignifCov00_2012_,"pfmets_fullSignifCov00_2012/F");
      tree_->Branch("pfmets_fullSignifCov10_2012",pfmets_fullSignifCov10_2012_,"pfmets_fullSignifCov10_2012/F");
      tree_->Branch("pfmets_fullSignifCov11_2012",pfmets_fullSignifCov11_2012_,"pfmets_fullSignifCov11_2012/F");

    }

    else{
      //EDM COMPLIANT PART
      //      producer->produce<ACertainCollection>(ACertainInstanceName);
    }


    return nLeaves;
  }

  void fill(edm::Event& iEvent){
    //open the collection that you want
    //retrieve the objects
    //fill the variable for tree filling 


    edm::Handle< pat::TriggerEvent > triggerevent;
    iEvent.getByLabel("patTriggerEvent",triggerevent);  
    //    std::cout<<"The trigger HLT table is"<<triggerevent->nameHltTable()<<std::endl;


        edm::Handle<edm::TriggerResults> hltresults;
        edm::InputTag myPatTrig("TriggerResults","","PAT");
        iEvent.getByLabel(myPatTrig,hltresults);
    //  iEvent.getByLabel("TriggerResults","","PAT",hltresults);
        int ntrigs=hltresults->size();

        // get hold of trigger names - based on TriggerResults object!
        const edm::TriggerNames & triggerNames_ = iEvent.triggerNames(*hltresults);
        int cschalofilterResult =1, trackingfailturefilterResult=1, ecaltpfilterResult=1, ecalbefilterResult=1, scrapingVetoResult=1;
        int greedymuonfilterResult=1, inconsistentPFmuonfilterResult=1, hcallaserfilterResult=1, ecallaserfilterResult=1,  eenoisefilterResult=1;
        int eebadscfilterResult=1, passprescalePFHT350filterResult=1, passprescaleHT250filterResult=1, passprescaleHT300filterResult=1;
        int passprescaleHT350filterResult=1, passprescaleHT400filterResult=1, passprescaleHT450filterResult=1;
        int trackercoherentnoisefilter1Result=1, trackercoherentnoisefilter2Result=1, trackertoomanyclustersfilterResult=1, trackertoomanytripletsfilterResult=1, trackertoomanyseedsfilterResult=1;
        for (int itrig=0; itrig< ntrigs; itrig++) {
            std::string trigName = triggerNames_.triggerName(itrig);
                int hltflag = (*hltresults)[itrig].accept();
            if (trigName=="csctighthalofilter") cschalofilterResult = hltflag;
            if (trigName=="trackingfailturefilter") trackingfailturefilterResult = hltflag;
            if (trigName=="ecaltpfilter") ecaltpfilterResult = hltflag;
                        if (trigName=="ecalbefilter") ecalbefilterResult = hltflag;
            if (trigName=="scrapingveto") scrapingVetoResult = hltflag;
            if (trigName=="greedymuonfilter") greedymuonfilterResult = hltflag;
                        if (trigName=="inconsistentPFmuonfilter") inconsistentPFmuonfilterResult = hltflag;
                        if (trigName=="hcallaserfilter") hcallaserfilterResult = hltflag;
                        if (trigName=="ecallaserfilter") ecallaserfilterResult = hltflag;
                        if (trigName=="eenoisefilter") eenoisefilterResult = hltflag;
                        if (trigName=="eebadscfilter") eebadscfilterResult = hltflag;
            if (trigName=="trackercoherentnoisefilter1") trackercoherentnoisefilter1Result = hltflag; 
                        if (trigName=="trackercoherentnoisefilter2") trackercoherentnoisefilter2Result = hltflag;
                        if (trigName=="trackertoomanyclustersfilter") trackertoomanyclustersfilterResult = hltflag;
                        if (trigName=="trackertoomanytripletsfilter") trackertoomanytripletsfilterResult = hltflag;
                        if (trigName=="trackertoomanyseedsfilter") trackertoomanyseedsfilterResult = hltflag;
                        if (trigName=="passprescalePFHT350filter") passprescalePFHT350filterResult = hltflag;
            if (trigName=="passprescaleHT250filter") passprescaleHT250filterResult = hltflag;
                        if (trigName=="passprescaleHT300filter") passprescaleHT300filterResult = hltflag;
                        if (trigName=="passprescaleHT350filter") passprescaleHT350filterResult = hltflag;
                        if (trigName=="passprescaleHT400filter") passprescaleHT400filterResult = hltflag;
                        if (trigName=="passprescaleHT450filter") passprescaleHT450filterResult = hltflag;

        }
        
    *cschalofilter_decision_ = cschalofilterResult;
    *trackingfailurefilter_decision_ = trackingfailturefilterResult;
    *ecalTPfilter_decision_ = ecaltpfilterResult;
    *ecalBEfilter_decision_ = ecalbefilterResult;
    *scrapingVeto_decision_ = scrapingVetoResult;
    *greedymuonfilter_decision_ = greedymuonfilterResult;
    *inconsistentPFmuonfilter_decision_ = inconsistentPFmuonfilterResult;
    *hcallaserfilter_decision_ = hcallaserfilterResult;
    *ecallaserfilter_decision_ = ecallaserfilterResult;
    *eenoisefilter_decision_ = eenoisefilterResult;
    *eebadscfilter_decision_ = eebadscfilterResult;
    *trackercoherentnoisefilter1_decision_ = trackercoherentnoisefilter1Result;
    *trackercoherentnoisefilter2_decision_ = trackercoherentnoisefilter2Result;
    *trackertoomanyclustersfilter_decision_ = trackertoomanyclustersfilterResult;
    *trackertoomanytripletsfilter_decision_ = trackertoomanytripletsfilterResult;
    *trackertoomanyseedsfilter_decision_ = trackertoomanyseedsfilterResult;
    *passprescalePFHT350filter_decision_ = passprescalePFHT350filterResult; 
    *passprescaleHT250filter_decision_ = passprescaleHT250filterResult;
    *passprescaleHT300filter_decision_ = passprescaleHT300filterResult;
    *passprescaleHT350filter_decision_ = passprescaleHT350filterResult;
    *passprescaleHT400filter_decision_ = passprescaleHT400filterResult;
    *passprescaleHT450filter_decision_ = passprescaleHT450filterResult;

    
    edm::Handle< std::vector<pat::TriggerPath> > triggerpaths;
    iEvent.getByLabel("patTrigger",triggerpaths);  
    for( std::vector<pat::TriggerPath>::const_iterator tp=triggerpaths->begin(); tp!=triggerpaths->end(); ++tp ){
      double prescalevalue = tp->prescale(); 
      std::string name = tp->name();
      float decision = tp->wasAccept();
      (*trigger_prescalevalue).push_back(prescalevalue);
      (*trigger_name).push_back(name);
      (*trigger_decision).push_back(decision);

      std::vector<std::string> collection_names;
      std::vector<float> pt_vector;
      std::vector<float> px_vector;
      std::vector<float> py_vector;
      std::vector<float> pz_vector;
      std::vector<float> et_vector;
      std::vector<float> energy_vector;
      std::vector<float> phi_vector;
      std::vector<float> eta_vector;

      /*
      cout<<""<<endl;
      cout<<"Trigger names is: "<<name<<endl;
      cout<<"Trigger decision is: "<<decision<<endl;
      */

      edm::RefVector< pat::TriggerFilterCollection> toFilt = triggerevent->pathFilters(name);
      edm::RefVector<pat::TriggerFilterCollection>::const_iterator toFilt_it=toFilt.end();
       if(toFilt.size()>0){
    const pat::TriggerFilter *triggerfilter = (*(--toFilt_it)).get();
    (*trigger_lastfiltername).push_back(triggerfilter->label());
    //cout<<"The trigger filter is: "<<triggerfilter->label()<<endl;
    edm::RefVector< pat::TriggerObjectCollection > tocoll = triggerevent->filterObjects(triggerfilter->label());
      
    for( edm::RefVector<pat::TriggerObjectCollection>::const_iterator to=tocoll.begin(); to!=tocoll.end(); ++to ){
      const pat::TriggerObject *triggerObject = (*to).get();
      double pt = triggerObject->pt(); 
      double px = triggerObject->px(); 
      double py = triggerObject->py(); 
      double pz = triggerObject->pz(); 
          double et = triggerObject->et();
      double energy = triggerObject->energy(); 
          double phi = triggerObject->phi();
          double eta = triggerObject->eta();
      std::string collname(triggerObject->collection());
      //cout<<"The trigger collname is: "<<collname<<endl;
      //cout<<"The trigger objectpt is: "<<pt<<endl;
      collection_names.push_back(collname);
      pt_vector.push_back(pt);
      px_vector.push_back(px);
      py_vector.push_back(py);
      pz_vector.push_back(pz);
          et_vector.push_back(et);
      energy_vector.push_back(energy);
          phi_vector.push_back(phi);
          eta_vector.push_back(eta);
    }
    
    (*triggerobject_collectionname).push_back(collection_names);
    (*triggerobject_pt).push_back(pt_vector);
    (*triggerobject_px).push_back(px_vector);
    (*triggerobject_py).push_back(py_vector);
    (*triggerobject_pz).push_back(pz_vector);
        (*triggerobject_et).push_back(et_vector);
    (*triggerobject_energy).push_back(energy_vector);
        (*triggerobject_phi).push_back(phi_vector);
        (*triggerobject_eta).push_back(eta_vector);
       }//end of if statement requiring that reVector be greater than 0
       else{
     (*trigger_lastfiltername).push_back("none");
     (*triggerobject_collectionname).push_back(collection_names);
     (*triggerobject_pt).push_back(pt_vector);
     (*triggerobject_px).push_back(px_vector);
     (*triggerobject_py).push_back(py_vector);
     (*triggerobject_pz).push_back(pz_vector);
         (*triggerobject_et).push_back(et_vector);
     (*triggerobject_energy).push_back(energy_vector);
         (*triggerobject_phi).push_back(phi_vector);
         (*triggerobject_eta).push_back(eta_vector);
       }
      collection_names.clear();
      pt_vector.clear();
      px_vector.clear();
      py_vector.clear();
      pz_vector.clear();
      et_vector.clear();
      energy_vector.clear();
      phi_vector.clear();
      eta_vector.clear();
    }
    

    //Get all trigger objects
    edm::Handle< std::vector<pat::TriggerObject> > triggerobjects;
    iEvent.getByLabel("patTrigger",triggerobjects);
    for( std::vector<pat::TriggerObject>::const_iterator to=triggerobjects->begin(); to!=triggerobjects->end(); ++to ){
      double pt = to->pt();
      double px = to->px();
      double py = to->py();
      double pz = to->pz();
      double et = to->et();
      double energy = to->energy();
      double phi = to->phi();
      double eta = to->eta();
      std::string collname = to->collection();
      //cout<<"The trigger collname is: "<<collname<<endl;
      //cout<<"The trigger objectpt is: "<<pt<<endl;
      (*standalone_triggerobject_collectionname).push_back(collname);
      (*standalone_triggerobject_pt).push_back(pt);
      (*standalone_triggerobject_px).push_back(px);
      (*standalone_triggerobject_py).push_back(py);
      (*standalone_triggerobject_pz).push_back(pz);
      (*standalone_triggerobject_et).push_back(et);
      (*standalone_triggerobject_energy).push_back(energy);
      (*standalone_triggerobject_phi).push_back(phi);
      (*standalone_triggerobject_eta).push_back(eta);
    }


    edm::Handle< std::vector<pat::TriggerAlgorithm> > triggeralgos;
    iEvent.getByLabel("patTrigger",triggeralgos);
    for( std::vector<pat::TriggerAlgorithm>::const_iterator ta=triggeralgos->begin(); ta!=triggeralgos->end(); ++ta ){
      float prescalevalue = ta->prescale();
      std::string name = ta->name();
      std::string alias = ta->alias();
      float bit = ta->bit();
      float techTrig = ta->techTrigger();
      float decision = ta->decision();
      float decision_nomask = ta->decisionBeforeMask();
      (*L1trigger_prescalevalue).push_back(prescalevalue);
      (*L1trigger_name).push_back(name);
      (*L1trigger_alias).push_back(alias);
      (*L1trigger_bit).push_back(bit);
      (*L1trigger_techTrigger).push_back(techTrig);
      (*L1trigger_decision).push_back(decision);
      (*L1trigger_decision_nomask).push_back(decision_nomask);
    }
    edm::Handle<bool> filter_h;
    if(iEvent.getByLabel("HBHENoiseFilterResultProducer","HBHENoiseFilterResult",filter_h)) { 
      
      iEvent.getByLabel("HBHENoiseFilterResultProducer","HBHENoiseFilterResult", filter_h);
      //      cout<<"The filter decision is :"<<*filter_h<<endl;
      if(*filter_h){*hbhefilter_decision_ = 1;}
      if(!(*filter_h)){*hbhefilter_decision_ = 0;}
    }
    else{
      *hbhefilter_decision_ = -1;
      //      cout<<"The hbheflag is not present, is this FastSim?"<<endl;
    }
   
    *MPT_ = -1; 

    edm::Handle< std::vector<pat::Electron> > electrons;
    iEvent.getByLabel("cleanPatElectrons",electrons);

    edm::Handle< std::vector<pat::Electron> > PFelectrons;
    iEvent.getByLabel("selectedPatElectronsPF",PFelectrons);

     edm::Handle< std::vector<pat::Photon> > photons;
     iEvent.getByLabel("cleanPatPhotons", photons);

     edm::Handle< reco::VertexCollection> vertexCollection;
     iEvent.getByLabel("offlinePrimaryVertices", vertexCollection);

     edm::Handle< reco::PFCandidateCollection> pfCandidatesH;
     iEvent.getByLabel("particleFlow", pfCandidatesH);
     const PFCandidateCollection thePfColl = *(pfCandidatesH.product());

    edm::Handle<reco::TrackCollection> tracks_h;
    iEvent.getByLabel("generalTracks", tracks_h);

    edm::Handle<reco::BeamSpot> bsHandle;
    iEvent.getByLabel("offlineBeamSpot", bsHandle);
    const reco::BeamSpot &beamspot = *bsHandle.product();

    edm::Handle<reco::ConversionCollection> hConversions;
    iEvent.getByLabel("allConversions", hConversions);

    edm::Handle<DcsStatusCollection> dcsHandle;
    iEvent.getByLabel("scalersRawToDigi", dcsHandle);
    //iEvent.getByLabel(dcsTag_, dcsHandle);

    const edm::Run& iRun = iEvent.getRun();
    // get ConditionsInRunBlock
    edm::Handle<edm::ConditionsInRunBlock> condInRunBlock;
    iRun.getByLabel("conditionsInEdm", condInRunBlock);


    //       edm::Handle<BFieldCollection> bfield_;
    edm::Handle< std::vector<double> > bfield_;
    iEvent.getByLabel("BFieldColl","BField", bfield_);
    //iEvent.getByLabel(dcsTag_, dcsHandle);

    
    double evt_bField;
    // need the magnetic field
    //
    // if isData then derive bfield using the
    // magnet current from DcsStatus
    // otherwise take it from the IdealMagneticFieldRecord
    if (iEvent.isRealData()) {
         // scale factor = 3.801/18166.0 which are
         // average values taken over a stable two
         // week period
         float currentToBFieldScaleFactor = 2.09237036221512717e-04;
         float current;
         if(dcsHandle->size()>0) current = (*dcsHandle)[0].magnetCurrent();
     else current = condInRunBlock->BAvgCurrent;
         evt_bField = current*currentToBFieldScaleFactor;
         //cout<<"\n"<<evt_bField;
        }
    else {
        
        //edm::ESHandle<MagneticField> magneticField;
        //iSetup.get<IdealMagneticFieldRecord>().get(magneticField);        
        //evt_bField = magneticField->inTesla(GlobalPoint(0.,0.,0.)).z();
       
      evt_bField = (*bfield_)[0];

    }


    //electron PFiso variables
    IsoDepositVals electronIsoValPFId(3);
    const IsoDepositVals * electronIsoVals = &electronIsoValPFId;
    iEvent.getByLabel("elPFIsoValueCharged03PFIdPFIso", electronIsoValPFId[0]);
    iEvent.getByLabel("elPFIsoValueGamma03PFIdPFIso", electronIsoValPFId[1]);
    iEvent.getByLabel("elPFIsoValueNeutral03PFIdPFIso", electronIsoValPFId[2]);


    for(std::vector<pat::Electron>::const_iterator elec=electrons->begin(); elec!=electrons->end(); ++elec) {

        //Get Gsf electron
        reco::GsfElectron* el = (reco::GsfElectron*) elec->originalObject(); 
    if(el == NULL) {    
    throw cms::Exception("GsfElectron")<<"No GsfElectron matched to pat::Electron.\n";
        }

        //cout << "Found and electron" << endl;
    //if(!el->closestCtfTrackRef().isNonnull())
    //cout<< "Could not find an electron ctf track" << endl;             

        ConversionInfo convInfo = egammaTools::getConversionInfo(*el, tracks_h, evt_bField);
   
        (*els_conversion_dist).push_back(convInfo.dist());
        (*els_conversion_dcot).push_back(convInfo.dcot());
        //double convradius = convInfo.radiusOfConversion();
        //math::XYZPoint convPoint = convInfo.pointOfConversion();

    bool hasMatchedConversion = ConversionTools::hasMatchedConversion(*el,hConversions,beamspot.position());
    (*els_hasMatchedConversion).push_back(hasMatchedConversion);

    //get PF isolation
        edm::Ptr< reco::GsfElectron > gsfel = (edm::Ptr< reco::GsfElectron >) elec->originalObjectRef();
        double charged =  (*(*electronIsoVals)[0])[gsfel];
        double photon = (*(*electronIsoVals)[1])[gsfel];
        double neutral = (*(*electronIsoVals)[2])[gsfel];
        //cout<<charged<<" "<<photon<<" "<<neutral<<endl;
        (*els_PFchargedHadronIsoR03).push_back(charged);
        (*els_PFphotonIsoR03).push_back(photon);
        (*els_PFneutralHadronIsoR03).push_back(neutral);

    }


    //get PFelectron variables
    for(std::vector<pat::Electron>::const_iterator elec=PFelectrons->begin(); elec!=PFelectrons->end(); ++elec) {

        //Get Gsf electron
        reco::GsfElectron* el = (reco::GsfElectron*) elec->originalObject();
        if(el == NULL) {
        throw cms::Exception("GsfElectron")<<"No GsfElectron matched to pat::Electron.\n";
        }

        bool hasMatchedConversion = ConversionTools::hasMatchedConversion(*el,hConversions,beamspot.position());
        (*pf_els_hasMatchedConversion).push_back(hasMatchedConversion);

        //get PF isolation
        edm::Ptr< reco::GsfElectron > gsfel = (edm::Ptr< reco::GsfElectron >) elec->originalObjectRef();
        double charged =  (*(*electronIsoVals)[0])[gsfel];
        double photon = (*(*electronIsoVals)[1])[gsfel];
        double neutral = (*(*electronIsoVals)[2])[gsfel];
        (*pf_els_PFchargedHadronIsoR03).push_back(charged);
        (*pf_els_PFphotonIsoR03).push_back(photon);
        (*pf_els_PFneutralHadronIsoR03).push_back(neutral);

    }

    //-- Prepare safe electron conversion variables
    edm::Handle<reco::ConversionCollection> hVetoConversions;
    iEvent.getByLabel("allConversions", hVetoConversions);

    edm::Handle<reco::GsfElectronCollection> hVetoElectrons;
    iEvent.getByLabel("gsfElectrons", hVetoElectrons);  

    //-- Get Photon iso variables
    PFIsolationEstimator isolator;
    isolator.initializePhotonIsolation(kTRUE);
    isolator.setConeSize(0.3);

    unsigned int ivtx = 0;
    VertexRef myVtxRef(vertexCollection, ivtx);

    bool passelectronveto = false;

    for(std::vector<pat::Photon>::const_iterator ph=photons->begin(); ph!=photons->end(); ++ph) {
        //isolator.fGetIsolation((*ph),&candColl, myVtxRef, Vertices);
    
        isolator.fGetIsolation(&*ph,
                                        &thePfColl,
                                    myVtxRef,
                                    vertexCollection);

    //  std::cout << " ChargedIso " << isolator.getIsolationCharged() << std::endl;
   //   std::cout << " PhotonIso " << isolator.getIsolationPhoton() << std::endl;
   //   std::cout << " NeutralHadron Iso " << isolator.getIsolationNeutral()  << std::endl;
    
      (*photon_chIsoValues).push_back(isolator.getIsolationCharged());  
      (*photon_phIsoValues).push_back(isolator.getIsolationPhoton());   
      (*photon_nhIsoValues).push_back(isolator.getIsolationNeutral());

        passelectronveto = !ConversionTools::hasMatchedPromptElectron(ph->superCluster(), hVetoElectrons, hVetoConversions, beamspot.position());

        (*photon_passElectronVeto).push_back(passelectronveto);

    }

   //Get PF jets---------------------------
    edm::Handle< std::vector<pat::Jet> > jets;
    //iEvent.getByLabel("selectedPatJetsPF",jets);
    iEvent.getByLabel("cleanPatJetsAK5PF",jets);

    edm::Handle< std::vector<double> > ak5PFL2L3_;
    iEvent.getByLabel("JetCorrColl","ak5PFL2L3", ak5PFL2L3_);
    edm::Handle< std::vector<double> > ak5PFL2L3Residual_;
    iEvent.getByLabel("JetCorrColl","ak5PFL2L3Residual", ak5PFL2L3Residual_);
    edm::Handle< std::vector<double> > ak5PFL1FastL2L3_;
    iEvent.getByLabel("JetCorrColl","ak5PFL1FastL2L3", ak5PFL1FastL2L3_);
    edm::Handle< std::vector<double> > ak5PFL1L2L3_;
    iEvent.getByLabel("JetCorrColl","ak5PFL1L2L3", ak5PFL1L2L3_);
    edm::Handle< std::vector<double> > ak5PFL1FastL2L3Residual_;
    iEvent.getByLabel("JetCorrColl","ak5PFL1FastL2L3Residual", ak5PFL1FastL2L3Residual_);
    edm::Handle< std::vector<double> > ak5PFL1L2L3Residual_;
    iEvent.getByLabel("JetCorrColl","ak5PFL1L2L3Residual", ak5PFL1L2L3Residual_);
    edm::Handle< std::vector<double> > ak5PFUncert_;
    iEvent.getByLabel("JetCorrColl","ak5PFUncert", ak5PFUncert_);

    if(jets->size() != (*ak5PFL2L3_).size()) {
      throw cms::Exception("JetCorrProblem")
         << "cleanPatJetsAK5PF collection different size than JetCorrColl.\n";
    }

    *softjetUp_dMEx_ = 0;
    *softjetUp_dMEy_ = 0;

    for(uint it=0; it<(*ak5PFL2L3_).size(); it++){
      if((jets->at(it)).pt()>10) { //only save jets with pT>10 GeV
        (*jets_AK5PFclean_corrL2L3_).push_back((*ak5PFL2L3_)[it]);
        (*jets_AK5PFclean_corrL2L3Residual_).push_back((*ak5PFL2L3Residual_)[it]);
        (*jets_AK5PFclean_corrL1FastL2L3_).push_back((*ak5PFL1FastL2L3_)[it]);
        (*jets_AK5PFclean_corrL1L2L3_).push_back((*ak5PFL1L2L3_)[it]);
        (*jets_AK5PFclean_corrL1FastL2L3Residual_).push_back((*ak5PFL1FastL2L3Residual_)[it]);
        (*jets_AK5PFclean_corrL1L2L3Residual_).push_back((*ak5PFL1L2L3Residual_)[it]);
        (*jets_AK5PFclean_Uncert_).push_back((*ak5PFUncert_)[it]);
      }
      else { //save change in MET when soft jet energy increased by 10%
    //subtract because MET opposite the extra jet energy 
    *softjetUp_dMEx_ -= 0.1*(jets->at(it)).px();
    *softjetUp_dMEy_ -= 0.1*(jets->at(it)).py();
      }
    }


  if(!iEvent.isRealData()) { //Access PU info in MC
    edm::Handle<std::vector< PileupSummaryInfo > >  PupInfo;
    iEvent.getByLabel("addPileupInfo", PupInfo);
    std::vector<PileupSummaryInfo>::const_iterator PVI;

    for(PVI = PupInfo->begin(); PVI != PupInfo->end(); ++PVI) {
  //    std::cout << " Pileup Information: bunchXing, nvtx: " << PVI->getBunchCrossing() << " " << PVI->getPU_NumInteractions() <<"   "<< iEvent.id().event() << std::endl;
      (*PU_NumInteractions_).push_back(PVI->getPU_NumInteractions());
      (*PU_bunchCrossing_).push_back(PVI->getBunchCrossing());
      (*PU_TrueNumInteractions_).push_back(PVI->getTrueNumInteractions());
      (*PU_zpositions_).push_back(PVI->getPU_zpositions());
      (*PU_sumpT_lowpT_).push_back(PVI->getPU_sumpT_lowpT());
      (*PU_sumpT_highpT_).push_back(PVI->getPU_sumpT_highpT());
      (*PU_ntrks_lowpT_).push_back(PVI->getPU_ntrks_lowpT());
      (*PU_ntrks_highpT_).push_back(PVI->getPU_ntrks_highpT());
    }
  }


   edm::Handle< double > rho_;
   iEvent.getByLabel("kt6PFJetsForIsolation2011","rho", rho_);
   *rho_kt6PFJetsForIsolation2011_ = (*rho_);

   if(iEvent.getByLabel(edm::InputTag("kt6PFJets:rho:RECO"), rho_)){
     iEvent.getByLabel(edm::InputTag("kt6PFJets:rho:RECO"), rho_);
     *rho_kt6PFJetsForIsolation2012_ = (*rho_);
   }
   else if(iEvent.getByLabel("kt6PFJetsForIsolation2012","rho", rho_)){ //in case kt6PFJets:rho:RECO isn't present, as in FastSim
     iEvent.getByLabel("kt6PFJetsForIsolation2012","rho", rho_);
     *rho_kt6PFJetsForIsolation2012_ = (*rho_);
   }
   else *rho_kt6PFJetsForIsolation2012_ = -999;


   double htEvent = 0.0;
   edm::Handle<LHEEventProduct> product;
   if(iEvent.getByLabel("source", product)){
     iEvent.getByLabel("source", product);
     const lhef::HEPEUP hepeup_ = product->hepeup();
     const std::vector<lhef::HEPEUP::FiveVector> pup_ = hepeup_.PUP;

     size_t iMax = hepeup_.NUP;
     for(size_t i = 2; i < iMax; ++i) {
        if( hepeup_.ISTUP[i] != 1 ) continue;
        int idabs = abs( hepeup_.IDUP[i] );
        if( idabs != 21 && (idabs<1 || idabs>6) ) continue;
        double ptPart = sqrt( pow(hepeup_.PUP[i][0],2) + pow(hepeup_.PUP[i][1],2) );
        //std::cout << ptPart << std::endl;
        htEvent += ptPart;
     } 
     //std::cout <<"Total: " << htEvent << std::endl;
   }
   *genHT_ = htEvent;

   //met significance
   edm::Handle< edm::View<pat::MET> > pfMEThandle;
   iEvent.getByLabel("patMETsPF", pfMEThandle);
   double sigmaX2= (pfMEThandle->front() ).getSignificanceMatrix()(0,0);
   double sigmaY2= (pfMEThandle->front() ).getSignificanceMatrix()(1,1);
   float significance = -1;
   //required sanity check according to https://twiki.cern.ch/twiki/bin/view/CMSPublic/SWGuideMETSignificance?rev=5#Known_Issues
   try {
     if(sigmaX2<1.e10 && sigmaY2<1.e10) significance = (pfMEThandle->front() ).significance();
   }
   catch (cms::Exception &e) {
     std::cout << "Caught exception in MET significance calculation:\n" 
           << e.what() 
           << "Setting MET significance to -1.0\n" 
           << std::endl;
     significance = -1.;
   }
   *pfmets_fullSignif_ = significance;
   *pfmets_fullSignifCov00_ = (float) sigmaX2;
   *pfmets_fullSignifCov10_ = (pfMEThandle->front() ).getSignificanceMatrix()(1,0);
   *pfmets_fullSignifCov11_ = (float) sigmaY2;

   //this is slightly dangerous in the sense that if the inputtag is missing but
   //the user intends it to be there, the code will silently continue
   //But it provides a smooth mechanism to disable the pdf weights in the python...
   //just don't run the PdfWeightProducer
   edm::InputTag pdfWeightTag("pdfWeights:cteq66"); // or any other PDF set
   edm::Handle<std::vector<double> > weightHandle;
   iEvent.getByLabel(pdfWeightTag, weightHandle);

   if (!weightHandle.failedToGet()) {
     std::vector<double> weights = (*weightHandle);
     unsigned int nmembers = weights.size();
     for (unsigned int j=0; j<nmembers; j++)   pdfweights_cteq_->push_back(weights[j]);
   }

   edm::InputTag pdfWeightTag2("pdfWeights:MSTW2008nlo68cl"); // or any other PDF set
   edm::Handle<std::vector<double> > weightHandle2;
   iEvent.getByLabel(pdfWeightTag2, weightHandle2);

   if (!weightHandle2.failedToGet()) {
     std::vector<double> weights2 = (*weightHandle2);
     unsigned int nmembers2 = weights2.size();
     for (unsigned int j2=0; j2<nmembers2; j2++) pdfweights_mstw_->push_back(weights2[j2]);
   }
   
   edm::InputTag pdfWeightTag3("pdfWeights:NNPDF20"); // or any other PDF set
   edm::Handle<std::vector<double> > weightHandle3;
   iEvent.getByLabel(pdfWeightTag3, weightHandle3);

   if (!weightHandle3.failedToGet()) {
     std::vector<double> weights3 = (*weightHandle3);
     unsigned int nmembers3 = weights3.size();
     for (unsigned int j3=0; j3<nmembers3; j3++) pdfweights_nnpdf_->push_back(weights3[j3]);
   }

   //get tracking TOBTEC filter variables
   // code copied from http://cmssw.cvs.cern.ch/cgi-bin/cmssw.cgi/UserCode/KStenson/TrackingFilters/plugins/TobTecFakesFilter.cc?view=markup
   const double piconst = 3.141592653589793;
   const double twopiconst = 2.0*piconst;
   const int phibins = 100;
   const double phibinsize = twopiconst/static_cast<double>(phibins);
   Handle<reco::TrackCollection> trks;
   iEvent.getByLabel("generalTracks",trks);
  
   int phiIterPixelTrks[phibins][2] = { {0} };
   int phiIterTobTecTrks[phibins][2] = { {0} };
   double n_iterPixelTrks = 0;
   double n_iterTobTecTrks = 0;

   int i_trkphi;
   double trkabseta;
   int trkalgo;

   // Count up pixel seeded tracks (n_iterPixelTrks) and TOBTEC seeded tracks (n_iterTobTecTrks)
   // Also count up pixel seeded and TOBTEC seeded tracks in bins of phi in the transition region
   for (reco::TrackCollection::const_iterator trk=trks->begin(); trk!=trks->end(); ++trk){
     trkalgo = trk->algo();
     switch(trkalgo) {
     case reco::TrackBase::initialStep:
     case reco::TrackBase::highPtTripletStep:
     case reco::TrackBase::lowPtQuadStep:
     case reco::TrackBase::lowPtTripletStep:
     case reco::TrackBase::pixelPairStep:
       ++n_iterPixelTrks;
         break;
     case reco::TrackBase::tobTecStep:
       ++n_iterTobTecTrks;
       break;
     default:
       break;
     }

     trkabseta = fabs(trk->eta());
     int zside = 0;
     if (trk->eta() > 0) zside = 1;
     if (trkabseta < 1.6 && trkabseta > 0.9) { // hardcode eta range from 0.9 to 1.6
       i_trkphi = std::max(0,std::min(phibins-1,(int) ((trk->phi()+piconst)/phibinsize)));
       switch(trkalgo) {
       case reco::TrackBase::initialStep:
       case reco::TrackBase::highPtTripletStep:
       case reco::TrackBase::lowPtQuadStep:
       case reco::TrackBase::lowPtTripletStep:
       case reco::TrackBase::pixelPairStep:
         ++phiIterPixelTrks[i_trkphi][zside];
           break;
       case reco::TrackBase::tobTecStep:
         ++phiIterTobTecTrks[i_trkphi][zside];
         break;
       default:
         break;
       }
     }
   }
   if (n_iterPixelTrks < 0.5) n_iterPixelTrks = 1.0; // avoid divide by zero
   double ritertobtec = n_iterTobTecTrks / n_iterPixelTrks; // ratio of TOBTEC seeded to pixel seeded tracks

   // Simple jet finder for TOBTEC seeded tracks.  Find the value of phi that maximizes
   // the number of tracks inside a phi window of windowRange (only for tracks in the 
   // transition region.
   int windowRange = std::max(1,static_cast<int>(0.7/phibinsize+0.5));
   int runPhiIterTobTec[phibins][2] = { {0} };
   int lowindx;
   int maxIterTobTecPhiTrks = -1;
   int maxIterTobTecPhiTrksBin = -1;
   int maxIterTobTecPhiTrksZBin = -1;
   for (int zside = 0; zside < 2; ++zside) {
     for (int iphi = phibins-windowRange+1; iphi < phibins; ++iphi) {
       runPhiIterTobTec[0][zside] += phiIterTobTecTrks[iphi][zside];
     }
     runPhiIterTobTec[0][zside] += phiIterTobTecTrks[0][zside];
     for (int iphi = 1; iphi < phibins; ++iphi) {
       lowindx = iphi-windowRange;
       if (lowindx < 0) lowindx += phibins;
       runPhiIterTobTec[iphi][zside] = runPhiIterTobTec[iphi-1][zside] + phiIterTobTecTrks[iphi][zside] - phiIterTobTecTrks[lowindx][zside];
       if (runPhiIterTobTec[iphi][zside] > maxIterTobTecPhiTrks) {
     maxIterTobTecPhiTrks = runPhiIterTobTec[iphi][zside];
     maxIterTobTecPhiTrksBin = iphi;
     maxIterTobTecPhiTrksZBin = zside;
       }
     }
   }
   double n_iterTobTecTrksInIterTobTecJet = static_cast<double>(maxIterTobTecPhiTrks);
   double n_iterPixelTrksInIterTobTecJet = 0.0;

   // Find the number of pixel seeded tracks in the same region that maximizes the number
   // of TOBTEC seeded tracks.
   int indx;
   for (int iphi = maxIterTobTecPhiTrksBin-windowRange+1; iphi < maxIterTobTecPhiTrksBin+1; ++iphi) {
     indx = iphi < 0 ? phibins+iphi : iphi;
     n_iterPixelTrksInIterTobTecJet += phiIterPixelTrks[indx][maxIterTobTecPhiTrksZBin];
   }
   if (n_iterPixelTrksInIterTobTecJet < 0.5) n_iterPixelTrksInIterTobTecJet = 1.0; // avoid divide by zero
   // Calculate ratio of TOBTEC seeded tracks in "jet" to pixel seeded tracks in same region
   double ritertobtecjet = n_iterTobTecTrksInIterTobTecJet / n_iterPixelTrksInIterTobTecJet;

   *trk_nTOBTEC = n_iterTobTecTrksInIterTobTecJet;
   *trk_ratioAllTOBTEC = ritertobtec;
   *trk_ratioJetTOBTEC = ritertobtecjet;


  // PU Jet Rejection Variables

  edm::Handle<edm::View<pat::Jet> > pujets;
  iEvent.getByLabel("selectedPatJetsPF",pujets);
  const View<pat::Jet> & jetss = *pujets;

  Handle<ValueMap<StoredPileupJetIdentifier> > puJetId;
  iEvent.getByLabel("puJetIdChs",puJetId);
  //const edm::ValueMap<StoredPileupJetIdentifier> * puId = puJetId.product();

  edm::Handle<ValueMap<float> > puJetIdMVA_full;
  iEvent.getByLabel("puJetMvaChs","fullDiscriminant",puJetIdMVA_full);
  edm::Handle<ValueMap<int> > puJetIdFlag_full;
  iEvent.getByLabel("puJetMvaChs","fullId",puJetIdFlag_full);

  //For some reason the simpleDiscriminant isn't produced... 

  edm::Handle<ValueMap<float> > puJetIdMVA_cutbased;
  iEvent.getByLabel("puJetMvaChs","cutbasedDiscriminant",puJetIdMVA_cutbased);
  edm::Handle<ValueMap<int> > puJetIdFlag_cutbased;
  iEvent.getByLabel("puJetMvaChs","cutbasedId",puJetIdFlag_cutbased);

  std::vector<float> betavector;
  std::vector<float> mvavector;

  //Fill the vector of vectors. They need to be done separately..      
      
  //Store for each jet: pT, eta, beta, betaStar, betaClassic, betaStarClassic
  for ( unsigned int i=0; i<jetss.size(); ++i ) {
    const pat::Jet & patjet = jetss.at(i);
    float jec = patjet.jecFactor(0);
    float jpt = patjet.pt();
    
    //Apply the same jet pt cut as is done for eventB jet collection
    if ( jpt*jec>10.0 || jpt>20.0 ) {   
    
      float pt =  (*puJetId)[jetss.refAt(i)].jetPt() ;
      float eta =  (*puJetId)[jetss.refAt(i)].jetEta() ;
      float beta =  (*puJetId)[jetss.refAt(i)].beta() ;
      float betaStar =  (*puJetId)[jetss.refAt(i)].betaStar() ;
      float betaClassic =  (*puJetId)[jetss.refAt(i)].betaClassic() ;
      float betaStarClassic =  (*puJetId)[jetss.refAt(i)].betaStarClassic() ;

    //cout << "pt=" << pt << " jpt=" << jpt << " jec=" << jec << " rawpt=" << jpt*jec <<  endl;
      betavector.push_back(pt);
      betavector.push_back(eta);
      betavector.push_back(beta);
      betavector.push_back(betaStar);
      betavector.push_back(betaClassic);
      betavector.push_back(betaStarClassic);
 
      (*puJet_rejectionBeta).push_back(betavector);
    } // jet pt cut
    betavector.clear();
  }//end

  //Store for each jet: pT, eta, MVA Full Discrim, MVA Full ID, MVA Cut Discrim, MVA Cut ID     
  for ( unsigned int jeti = 0; jeti != jetss.size(); jeti++) {
    const pat::Jet & patjet = jetss.at(jeti);
    float pt = patjet.pt() ;
    float eta = patjet.eta();
    float jec = patjet.jecFactor(0);
    
    //Apply the same jet pt cut as is done for eventB jet collection
    if ( pt*jec>10.0 || pt>20.0 ) {     

      float mvaF    = (*puJetIdMVA_full)[jetss.refAt(jeti)];
      int   idflagF = (*puJetIdFlag_full)[jetss.refAt(jeti)];
      float mvaC    = (*puJetIdMVA_cutbased)[jetss.refAt(jeti)];
      int   idflagC = (*puJetIdFlag_cutbased)[jetss.refAt(jeti)];

      mvavector.push_back(pt);
      mvavector.push_back(eta);
      mvavector.push_back(mvaF);
      mvavector.push_back(idflagF);
      mvavector.push_back(mvaC);
      mvavector.push_back(idflagC);
    
      (*puJet_rejectionMVA).push_back(mvavector);
    } // jet pt cut
    mvavector.clear();
  }

   // Met Significance

   edm::Handle<double> metsigHandle;
   iEvent.getByLabel("pfMetSig","METSignificance", metsigHandle);
   edm::Handle<double> metsigm00Handle;
   iEvent.getByLabel("pfMetSig","CovarianceMatrix00", metsigm00Handle);
   edm::Handle<double> metsigm10Handle;
   iEvent.getByLabel("pfMetSig","CovarianceMatrix10", metsigm10Handle);
   edm::Handle<double> metsigm11Handle;
   iEvent.getByLabel("pfMetSig","CovarianceMatrix11", metsigm11Handle);
   *pfmets_fullSignif_2012_ = *(metsigHandle.product());
   *pfmets_fullSignifCov00_2012_ = *(metsigm00Handle.product());
   *pfmets_fullSignifCov10_2012_ = *(metsigm10Handle.product());
   *pfmets_fullSignifCov11_2012_ = *(metsigm11Handle.product());



   //fill the tree    
    if (ownTheTree_){ tree_->Fill(); }
    (*trigger_prescalevalue).clear();
    (*trigger_name).clear();
    (*trigger_decision).clear();
    (*trigger_lastfiltername).clear();
    (*triggerobject_pt).clear();
    (*triggerobject_px).clear();
    (*triggerobject_py).clear();
    (*triggerobject_pz).clear();
    (*triggerobject_et).clear();
    (*triggerobject_energy).clear();
    (*triggerobject_phi).clear();
    (*triggerobject_eta).clear();
    (*triggerobject_collectionname).clear();
    (*standalone_triggerobject_pt).clear();
    (*standalone_triggerobject_px).clear();
    (*standalone_triggerobject_py).clear();
    (*standalone_triggerobject_pz).clear();
    (*standalone_triggerobject_et).clear();
    (*standalone_triggerobject_energy).clear();
    (*standalone_triggerobject_phi).clear();
    (*standalone_triggerobject_eta).clear();
    (*standalone_triggerobject_collectionname).clear();
    (*L1trigger_bit).clear();
    (*L1trigger_techTrigger).clear();
    (*L1trigger_prescalevalue).clear();
    (*L1trigger_name).clear();
    (*L1trigger_alias).clear();
    (*L1trigger_decision).clear();
    (*L1trigger_decision_nomask).clear();
    (*els_conversion_dist).clear();
    (*els_conversion_dcot).clear();
    (*els_PFchargedHadronIsoR03).clear();
    (*els_PFphotonIsoR03).clear();
    (*els_PFneutralHadronIsoR03).clear();
    (*els_hasMatchedConversion).clear();
    (*pf_els_PFchargedHadronIsoR03).clear();
    (*pf_els_PFphotonIsoR03).clear();
    (*pf_els_PFneutralHadronIsoR03).clear();
    (*pf_els_hasMatchedConversion).clear();
    (*jets_AK5PFclean_corrL2L3_).clear();
    (*jets_AK5PFclean_corrL2L3Residual_).clear();
    (*jets_AK5PFclean_corrL1FastL2L3_).clear();
    (*jets_AK5PFclean_corrL1L2L3_).clear();
    (*jets_AK5PFclean_corrL1FastL2L3Residual_).clear();
    (*jets_AK5PFclean_corrL1L2L3Residual_).clear();
    (*jets_AK5PFclean_Uncert_).clear();
    (*PU_zpositions_).clear();
    (*PU_sumpT_lowpT_).clear();
    (*PU_sumpT_highpT_).clear();
    (*PU_ntrks_lowpT_).clear();
    (*PU_ntrks_highpT_).clear();
    (*PU_NumInteractions_).clear();
    (*PU_bunchCrossing_).clear();
    (*PU_TrueNumInteractions_).clear();
    (*pdfweights_cteq_).clear();
    (*pdfweights_mstw_).clear();
    (*pdfweights_nnpdf_).clear();
    (*photon_chIsoValues).clear();
    (*photon_phIsoValues).clear();
    (*photon_nhIsoValues).clear();
    (*photon_passElectronVeto).clear();
    (*puJet_rejectionBeta).clear();
    (*puJet_rejectionMVA).clear();

  }

  void callBack(){
    //clean up whatever memory was allocated
  }

 private:
  bool ownTheTree_;
  std::string treeName_;
  bool useTFileService_;

  std::vector<float> * trigger_prescalevalue;
  std::vector<std::string> * trigger_name;
  std::vector<float> * trigger_decision;
  std::vector<std::string> * trigger_lastfiltername;
  std::vector<std::vector<float> > * triggerobject_pt;
  std::vector<std::vector<float> > * triggerobject_px;
  std::vector<std::vector<float> > * triggerobject_py;
  std::vector<std::vector<float> > * triggerobject_pz;
  std::vector<std::vector<float> > * triggerobject_et;
  std::vector<std::vector<float> > * triggerobject_energy;
  std::vector<std::vector<float> > * triggerobject_phi;
  std::vector<std::vector<float> > * triggerobject_eta;
  std::vector<std::vector<std::string> > * triggerobject_collectionname;
  std::vector<float> * standalone_triggerobject_pt;
  std::vector<float> * standalone_triggerobject_px;
  std::vector<float> * standalone_triggerobject_py;
  std::vector<float> * standalone_triggerobject_pz;
  std::vector<float> * standalone_triggerobject_et;
  std::vector<float> * standalone_triggerobject_energy;
  std::vector<float> * standalone_triggerobject_phi;
  std::vector<float> * standalone_triggerobject_eta;
  std::vector<std::string> * standalone_triggerobject_collectionname;
  std::vector<float> * L1trigger_bit;
  std::vector<float> * L1trigger_techTrigger;
  std::vector<float> * L1trigger_prescalevalue;
  std::vector<std::string> * L1trigger_name;
  std::vector<std::string> * L1trigger_alias;
  std::vector<float> * L1trigger_decision;
  std::vector<float> * L1trigger_decision_nomask;
  std::vector<float> * els_conversion_dist;
  std::vector<float> * els_conversion_dcot;
  std::vector<float> * els_PFchargedHadronIsoR03;
  std::vector<float> * els_PFphotonIsoR03;
  std::vector<float> * els_PFneutralHadronIsoR03;
  std::vector<bool> * els_hasMatchedConversion;
  std::vector<float> * pf_els_PFchargedHadronIsoR03;
  std::vector<float> * pf_els_PFphotonIsoR03;
  std::vector<float> * pf_els_PFneutralHadronIsoR03;
  std::vector<bool> * pf_els_hasMatchedConversion;
  int * trk_nTOBTEC;
  float * trk_ratioAllTOBTEC;
  float * trk_ratioJetTOBTEC;
  int * hbhefilter_decision_;
  int * cschalofilter_decision_;
  int * ecalTPfilter_decision_;
  int * ecalBEfilter_decision_;
  int * scrapingVeto_decision_;
  int * trackingfailurefilter_decision_;
  int * greedymuonfilter_decision_;
  int * inconsistentPFmuonfilter_decision_;
  int * hcallaserfilter_decision_;
  int * ecallaserfilter_decision_;
  int * eenoisefilter_decision_;
  int * eebadscfilter_decision_;
  int * trackercoherentnoisefilter1_decision_; 
  int * trackercoherentnoisefilter2_decision_;  
  int * trackertoomanyclustersfilter_decision_; 
  int * trackertoomanytripletsfilter_decision_; 
  int * trackertoomanyseedsfilter_decision_;
  int * passprescalePFHT350filter_decision_;
  int * passprescaleHT250filter_decision_;
  int * passprescaleHT300filter_decision_;
  int * passprescaleHT350filter_decision_;
  int * passprescaleHT400filter_decision_;
  int * passprescaleHT450filter_decision_;
  float * MPT_;
  float * genHT_;
  std::vector<float> * jets_AK5PFclean_corrL2L3_;
  std::vector<float> * jets_AK5PFclean_corrL2L3Residual_;
  std::vector<float> * jets_AK5PFclean_corrL1FastL2L3_;
  std::vector<float> * jets_AK5PFclean_corrL1L2L3_;
  std::vector<float> * jets_AK5PFclean_corrL1FastL2L3Residual_;
  std::vector<float> * jets_AK5PFclean_corrL1L2L3Residual_;
  std::vector<float> * jets_AK5PFclean_Uncert_;
  std::vector<std::vector<float> > * PU_zpositions_;
  std::vector<std::vector<float> > * PU_sumpT_lowpT_;
  std::vector<std::vector<float> > * PU_sumpT_highpT_;
  std::vector<std::vector<int> > * PU_ntrks_lowpT_;
  std::vector<std::vector<int> > * PU_ntrks_highpT_;
  std::vector<int> * PU_NumInteractions_;
  std::vector<int> * PU_bunchCrossing_;
  std::vector<float> * PU_TrueNumInteractions_;
  float * rho_kt6PFJetsForIsolation2011_;
  float * rho_kt6PFJetsForIsolation2012_;
  float *  pfmets_fullSignif_;
  float *  pfmets_fullSignifCov00_;
  float *  pfmets_fullSignifCov10_;
  float *  pfmets_fullSignifCov11_;
  float *  softjetUp_dMEx_;
  float *  softjetUp_dMEy_;
  std::vector<float> * pdfweights_cteq_;
  std::vector<float> * pdfweights_mstw_;
  std::vector<float> * pdfweights_nnpdf_;
  std::vector<float> * photon_chIsoValues;
  std::vector<float> * photon_phIsoValues;
  std::vector<float> * photon_nhIsoValues;
  std::vector<bool> * photon_passElectronVeto;
  std::vector<std::vector<float> > * puJet_rejectionBeta;
  std::vector<std::vector<float> > * puJet_rejectionMVA;
  float *  pfmets_fullSignif_2012_;
  float *  pfmets_fullSignifCov00_2012_;
  float *  pfmets_fullSignifCov10_2012_;
  float *  pfmets_fullSignifCov11_2012_;

};