DataCertificationJetMET.cc

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// -*- C++ -*-
//
// Package:    DQMOffline/JetMET
// Class:      DataCertificationJetMET
//
// Original Author:  "Frank Chlebana"
//         Created:  Sun Oct  5 13:57:25 CDT 2008
//

#include "DQMOffline/JetMET/interface/DataCertificationJetMET.h"
#include "FWCore/Framework/interface/LuminosityBlock.h"
#include "FWCore/Framework/interface/Run.h"

// Some switches
//
// constructors and destructor
//
DataCertificationJetMET::DataCertificationJetMET(const edm::ParameterSet& iConfig) : conf_(iConfig) {
  // now do what ever initialization is needed
  inputMETLabelRECO_ = iConfig.getParameter<edm::InputTag>("METTypeRECO");
  inputMETLabelRECOUncleaned_ = iConfig.getParameter<edm::InputTag>("METTypeRECOUncleaned");
  inputMETLabelMiniAOD_ = iConfig.getParameter<edm::InputTag>("METTypeMiniAOD");
  inputJetLabelRECO_ = iConfig.getParameter<edm::InputTag>("JetTypeRECO");
  inputJetLabelMiniAOD_ = iConfig.getParameter<edm::InputTag>("JetTypeMiniAOD");

  nbinsPV_ = iConfig.getParameter<int>("pVBin");
  nPVMin_ = iConfig.getParameter<double>("pVMin");
  nPVMax_ = iConfig.getParameter<double>("pVMax");

  etaBin_ = iConfig.getParameter<int>("etaBin");
  etaMin_ = iConfig.getParameter<double>("etaMin");
  etaMax_ = iConfig.getParameter<double>("etaMax");

  ptBin_ = iConfig.getParameter<int>("ptBin");
  ptMin_ = iConfig.getParameter<double>("ptMin");
  ptMax_ = iConfig.getParameter<double>("ptMax");

  // -----------------------------------------
  // verbose_ 0: suppress printouts
  //          1: show printouts
  verbose_ = conf_.getUntrackedParameter<int>("Verbose", 0);
  metFolder = conf_.getUntrackedParameter<std::string>("metFolder");
  jetAlgo = conf_.getUntrackedParameter<std::string>("jetAlgo");
  folderName = conf_.getUntrackedParameter<std::string>("folderName");

  jetTests[0][0] = conf_.getUntrackedParameter<bool>("pfBarrelJetMeanTest", true);
  jetTests[0][1] = conf_.getUntrackedParameter<bool>("pfBarrelJetKSTest", false);
  jetTests[1][0] = conf_.getUntrackedParameter<bool>("pfEndcapJetMeanTest", true);
  jetTests[1][1] = conf_.getUntrackedParameter<bool>("pfEndcapJetKSTest", false);
  jetTests[2][0] = conf_.getUntrackedParameter<bool>("pfForwardJetMeanTest", true);
  jetTests[2][1] = conf_.getUntrackedParameter<bool>("pfForwardJetKSTest", false);
  jetTests[3][0] = conf_.getUntrackedParameter<bool>("caloJetMeanTest", true);
  jetTests[3][1] = conf_.getUntrackedParameter<bool>("caloJetKSTest", false);
  jetTests[4][0] = conf_.getUntrackedParameter<bool>("jptJetMeanTest", true);
  jetTests[4][1] = conf_.getUntrackedParameter<bool>("jptJetKSTest", false);

  metTests[0][0] = conf_.getUntrackedParameter<bool>("caloMETMeanTest", true);
  metTests[0][1] = conf_.getUntrackedParameter<bool>("caloMETKSTest", false);
  metTests[1][0] = conf_.getUntrackedParameter<bool>("pfMETMeanTest", true);
  metTests[1][1] = conf_.getUntrackedParameter<bool>("pfMETKSTest", false);
  metTests[2][0] = conf_.getUntrackedParameter<bool>("tcMETMeanTest", true);
  metTests[2][1] = conf_.getUntrackedParameter<bool>("tcMETKSTest", false);

  isHI = conf_.getUntrackedParameter<bool>("isHI", false);

  if (verbose_)
    std::cout << ">>> Constructor (DataCertificationJetMET) <<<" << std::endl;

  // -----------------------------------------
  //
}

DataCertificationJetMET::~DataCertificationJetMET() {
  // do anything here that needs to be done at desctruction time
  // (e.g. close files, deallocate resources etc.)
  if (verbose_)
    std::cout << ">>> Deconstructor (DataCertificationJetMET) <<<" << std::endl;
}

// ------------ method called right after a run ends ------------
void DataCertificationJetMET::dqmEndJob(DQMStore::IBooker& ibook_, DQMStore::IGetter& iget_) {
  //put RECO vs MiniAODDir first ->first MET
  std::vector<std::string> subDirVecMET;
  std::string RunDirMET = "JetMET/MET/";
  iget_.setCurrentFolder(RunDirMET);
  subDirVecMET = iget_.getSubdirs();
  bool found_METreco_dir = false;
  bool found_METminiaod_dir = false;
  //check if proper directories are inside the files
  for (int i = 0; i < int(subDirVecMET.size()); i++) {
    ibook_.setCurrentFolder(subDirVecMET[i]);
    if ((subDirVecMET[i] + "/Cleaned") == (RunDirMET + inputMETLabelRECO_.label() + "/Cleaned")) {
      found_METreco_dir = true;
    }
    if (((subDirVecMET[i] + "/Uncleaned") == (RunDirMET + inputMETLabelRECOUncleaned_.label() + "/Uncleaned")) ||
        ((subDirVecMET[i] + "/Uncleaned") == (RunDirMET + inputMETLabelMiniAOD_.label() + "/Uncleaned"))) {
      //check filters in uncleaned directory
      std::string rundirMET_reco = "";
      if ((subDirVecMET[i] + "/Uncleaned") == (RunDirMET + inputMETLabelRECOUncleaned_.label() + "/Uncleaned")) {
        rundirMET_reco = RunDirMET + inputMETLabelRECOUncleaned_.label() + "/Uncleaned";
      } else {
        rundirMET_reco = RunDirMET + inputMETLabelMiniAOD_.label() + "/Uncleaned";
      }
      MonitorElement* mMET_Reco = iget_.get(rundirMET_reco + "/" + "MET");
      MonitorElement* mMET_Reco_HBHENoiseFilter = iget_.get(rundirMET_reco + "/" + "MET_HBHENoiseFilter");
      MonitorElement* mMET_Reco_CSCTightHaloFilter = iget_.get(rundirMET_reco + "/" + "MET_CSCTightHaloFilter");
      MonitorElement* mMET_Reco_eeBadScFilter = iget_.get(rundirMET_reco + "/" + "MET_eeBadScFilter");
      MonitorElement* mMET_Reco_HBHEIsoNoiseFilter = iget_.get(rundirMET_reco + "/" + "MET_HBHEIsoNoiseFilter");
      MonitorElement* mMET_Reco_CSCTightHalo2015Filter = iget_.get(rundirMET_reco + "/" + "MET_CSCTightHalo2015Filter");
      MonitorElement* mMET_Reco_EcalDeadCellTriggerFilter =
          iget_.get(rundirMET_reco + "/" + "MET_EcalDeadCellTriggerFilter");
      MonitorElement* mMET_Reco_EcalDeadCellBoundaryFilter =
          iget_.get(rundirMET_reco + "/" + "MET_EcalDeadCellBoundaryFilter");
      MonitorElement* mMET_Reco_HcalStripHaloFilter = iget_.get(rundirMET_reco + "/" + "MET_HcalStripHaloFilter");
      ibook_.setCurrentFolder(rundirMET_reco);
      mMET_EffHBHENoiseFilter =
          ibook_.book1D("MET_EffHBHENoiseFilter", (TH1F*)mMET_Reco_HBHENoiseFilter->getRootObject());
      for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
        if (mMET_Reco->getBinContent(i) != 0) {
          mMET_EffHBHENoiseFilter->setBinContent(
              i, mMET_Reco_HBHENoiseFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
        } else {
          mMET_EffHBHENoiseFilter->setBinContent(i, 0);
        }
      }
      mMET_EffCSCTightHaloFilter =
          ibook_.book1D("MET_EffCSCTightHaloFilter", (TH1F*)mMET_Reco_CSCTightHaloFilter->getRootObject());
      for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
        if (mMET_Reco->getBinContent(i) != 0) {
          mMET_EffCSCTightHaloFilter->setBinContent(
              i, mMET_Reco_CSCTightHaloFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
        } else {
          mMET_EffCSCTightHaloFilter->setBinContent(i, 0);
        }
      }
      mMET_EffeeBadScFilter = ibook_.book1D("MET_EffeeBadScFilter", (TH1F*)mMET_Reco_eeBadScFilter->getRootObject());
      for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
        if (mMET_Reco->getBinContent(i) != 0) {
          mMET_EffeeBadScFilter->setBinContent(i,
                                               mMET_Reco_eeBadScFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
        } else {
          mMET_EffeeBadScFilter->setBinContent(i, 0);
        }
      }
      mMET_EffHBHEIsoNoiseFilter =
          ibook_.book1D("MET_EffHBHEIsoNoiseFilter", (TH1F*)mMET_Reco_HBHEIsoNoiseFilter->getRootObject());
      for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
        if (mMET_Reco->getBinContent(i) != 0) {
          mMET_EffHBHEIsoNoiseFilter->setBinContent(
              i, mMET_Reco_HBHEIsoNoiseFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
        } else {
          mMET_EffHBHEIsoNoiseFilter->setBinContent(i, 0);
        }
      }
      mMET_EffCSCTightHalo2015Filter =
          ibook_.book1D("MET_EffCSCTightHalo2015Filter", (TH1F*)mMET_Reco_CSCTightHalo2015Filter->getRootObject());
      for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
        if (mMET_Reco->getBinContent(i) != 0) {
          mMET_EffCSCTightHalo2015Filter->setBinContent(
              i, mMET_Reco_CSCTightHalo2015Filter->getBinContent(i) / mMET_Reco->getBinContent(i));
        } else {
          mMET_EffCSCTightHalo2015Filter->setBinContent(i, 0);
        }
      }
      mMET_EffEcalDeadCellTriggerFilter = ibook_.book1D("MET_EffEcalDeadCellTriggerFilter",
                                                        (TH1F*)mMET_Reco_EcalDeadCellTriggerFilter->getRootObject());
      for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
        if (mMET_Reco->getBinContent(i) != 0) {
          mMET_EffEcalDeadCellTriggerFilter->setBinContent(
              i, mMET_Reco_EcalDeadCellTriggerFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
        } else {
          mMET_EffEcalDeadCellTriggerFilter->setBinContent(i, 0);
        }
      }
      mMET_EffEcalDeadCellBoundaryFilter = ibook_.book1D("MET_EffEcalDeadCellBoundaryFilter",
                                                         (TH1F*)mMET_Reco_EcalDeadCellBoundaryFilter->getRootObject());
      for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
        if (mMET_Reco->getBinContent(i) != 0) {
          mMET_EffEcalDeadCellBoundaryFilter->setBinContent(
              i, mMET_Reco_EcalDeadCellBoundaryFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
        } else {
          mMET_EffEcalDeadCellBoundaryFilter->setBinContent(i, 0);
        }
      }
      mMET_EffHcalStripHaloFilter =
          ibook_.book1D("MET_EffHcalStripHaloFilter", (TH1F*)mMET_Reco_HcalStripHaloFilter->getRootObject());
      for (int i = 0; i <= (mMET_Reco->getNbinsX() + 1); i++) {
        if (mMET_Reco->getBinContent(i) != 0) {
          mMET_EffHcalStripHaloFilter->setBinContent(
              i, mMET_Reco_HcalStripHaloFilter->getBinContent(i) / mMET_Reco->getBinContent(i));
        } else {
          mMET_EffHcalStripHaloFilter->setBinContent(i, 0);
        }
      }
    }
    if ((subDirVecMET[i] + "/Cleaned") == (RunDirMET + inputMETLabelMiniAOD_.label() + "/Cleaned")) {
      found_METminiaod_dir = true;
    }
  }
  if (found_METreco_dir && found_METminiaod_dir) {
    std::string rundirMET_reco = RunDirMET + inputMETLabelRECO_.label() + "/Cleaned";
    std::string rundirMET_miniaod = RunDirMET + inputMETLabelMiniAOD_.label() + "/Cleaned";
    MonitorElement* mMET_Reco = iget_.get(rundirMET_reco + "/" + "MET");
    MonitorElement* mMEy_Reco = iget_.get(rundirMET_reco + "/" + "MEy");
    MonitorElement* mSumET_Reco = iget_.get(rundirMET_reco + "/" + "SumET");
    MonitorElement* mMETPhi_Reco = iget_.get(rundirMET_reco + "/" + "METPhi");
    MonitorElement* mMET_logx_Reco = iget_.get(rundirMET_reco + "/" + "MET_logx");
    MonitorElement* mSumET_logx_Reco = iget_.get(rundirMET_reco + "/" + "SumET_logx");
    MonitorElement* mChargedHadronEtFraction_Reco = iget_.get(rundirMET_reco + "/" + "PfChargedHadronEtFraction");
    MonitorElement* mNeutralHadronEtFraction_Reco = iget_.get(rundirMET_reco + "/" + "PfNeutralHadronEtFraction");
    MonitorElement* mPhotonEtFraction_Reco = iget_.get(rundirMET_reco + "/" + "PfPhotonEtFraction");
    MonitorElement* mHFHadronEtFraction_Reco = iget_.get(rundirMET_reco + "/" + "PfHFHadronEtFraction");
    MonitorElement* mHFEMEtFraction_Reco = iget_.get(rundirMET_reco + "/" + "PfHFEMEtFraction");
    MonitorElement* mMET_nVtx_profile_Reco = iget_.get(rundirMET_reco + "/" + "MET_profile");
    MonitorElement* mSumET_nVtx_profile_Reco = iget_.get(rundirMET_reco + "/" + "SumET_profile");
    MonitorElement* mChargedHadronEtFraction_nVtx_profile_Reco =
        iget_.get(rundirMET_reco + "/" + "PfChargedHadronEtFraction_profile");
    MonitorElement* mNeutralHadronEtFraction_nVtx_profile_Reco =
        iget_.get(rundirMET_reco + "/" + "PfNeutralHadronEtFraction_profile");
    MonitorElement* mPhotonEtFraction_nVtx_profile_Reco =
        iget_.get(rundirMET_reco + "/" + "PfPhotonEtFraction_profile");

    std::vector<MonitorElement*> me_MET_Reco;
    me_MET_Reco.push_back(mMET_Reco);
    me_MET_Reco.push_back(mMEy_Reco);
    me_MET_Reco.push_back(mSumET_Reco);
    me_MET_Reco.push_back(mMETPhi_Reco);
    me_MET_Reco.push_back(mMET_logx_Reco);
    me_MET_Reco.push_back(mSumET_logx_Reco);
    me_MET_Reco.push_back(mChargedHadronEtFraction_Reco);
    me_MET_Reco.push_back(mNeutralHadronEtFraction_Reco);
    me_MET_Reco.push_back(mPhotonEtFraction_Reco);
    me_MET_Reco.push_back(mHFHadronEtFraction_Reco);
    me_MET_Reco.push_back(mHFEMEtFraction_Reco);
    me_MET_Reco.push_back(mMET_nVtx_profile_Reco);
    me_MET_Reco.push_back(mSumET_nVtx_profile_Reco);
    me_MET_Reco.push_back(mChargedHadronEtFraction_nVtx_profile_Reco);
    me_MET_Reco.push_back(mNeutralHadronEtFraction_nVtx_profile_Reco);
    me_MET_Reco.push_back(mPhotonEtFraction_nVtx_profile_Reco);

    MonitorElement* mMET_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "MET");
    MonitorElement* mMEy_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "MEy");
    MonitorElement* mSumET_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "SumET");
    MonitorElement* mMETPhi_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "METPhi");
    MonitorElement* mMET_logx_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "MET_logx");
    MonitorElement* mSumET_logx_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "SumET_logx");
    MonitorElement* mChargedHadronEtFraction_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "PfChargedHadronEtFraction");
    MonitorElement* mNeutralHadronEtFraction_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "PfNeutralHadronEtFraction");
    MonitorElement* mPhotonEtFraction_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "PfPhotonEtFraction");
    MonitorElement* mHFHadronEtFraction_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "PfHFHadronEtFraction");
    MonitorElement* mHFEMEtFraction_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "PfHFEMEtFraction");
    MonitorElement* mMET_nVtx_profile_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "MET_profile");
    MonitorElement* mSumET_nVtx_profile_MiniAOD = iget_.get(rundirMET_miniaod + "/" + "SumET_profile");
    MonitorElement* mChargedHadronEtFraction_nVtx_profile_MiniAOD =
        iget_.get(rundirMET_miniaod + "/" + "PfChargedHadronEtFraction_profile");
    MonitorElement* mNeutralHadronEtFraction_nVtx_profile_MiniAOD =
        iget_.get(rundirMET_miniaod + "/" + "PfNeutralHadronEtFraction_profile");
    MonitorElement* mPhotonEtFraction_nVtx_profile_MiniAOD =
        iget_.get(rundirMET_miniaod + "/" + "PfPhotonEtFraction_profile");

    std::vector<MonitorElement*> me_MET_MiniAOD;
    me_MET_MiniAOD.push_back(mMET_MiniAOD);
    me_MET_MiniAOD.push_back(mMEy_MiniAOD);
    me_MET_MiniAOD.push_back(mSumET_MiniAOD);
    me_MET_MiniAOD.push_back(mMETPhi_MiniAOD);
    me_MET_MiniAOD.push_back(mMET_logx_MiniAOD);
    me_MET_MiniAOD.push_back(mSumET_logx_MiniAOD);
    me_MET_MiniAOD.push_back(mChargedHadronEtFraction_MiniAOD);
    me_MET_MiniAOD.push_back(mNeutralHadronEtFraction_MiniAOD);
    me_MET_MiniAOD.push_back(mPhotonEtFraction_MiniAOD);
    me_MET_MiniAOD.push_back(mHFHadronEtFraction_MiniAOD);
    me_MET_MiniAOD.push_back(mHFEMEtFraction_MiniAOD);
    me_MET_MiniAOD.push_back(mMET_nVtx_profile_MiniAOD);
    me_MET_MiniAOD.push_back(mSumET_nVtx_profile_MiniAOD);
    me_MET_MiniAOD.push_back(mChargedHadronEtFraction_nVtx_profile_MiniAOD);
    me_MET_MiniAOD.push_back(mNeutralHadronEtFraction_nVtx_profile_MiniAOD);
    me_MET_MiniAOD.push_back(mPhotonEtFraction_nVtx_profile_MiniAOD);

    ibook_.setCurrentFolder(RunDirMET + "MiniAOD_over_RECO");
    mMET_MiniAOD_over_Reco = ibook_.book1D("MET_MiniAOD_over_RECO", (TH1F*)mMET_Reco->getRootObject());
    mMEy_MiniAOD_over_Reco = ibook_.book1D("MEy_MiniAOD_over_RECO", (TH1F*)mMEy_Reco->getRootObject());
    mSumET_MiniAOD_over_Reco = ibook_.book1D("SumET_MiniAOD_over_RECO", (TH1F*)mSumET_Reco->getRootObject());
    mMETPhi_MiniAOD_over_Reco = ibook_.book1D("METPhi_MiniAOD_over_RECO", (TH1F*)mMETPhi_Reco->getRootObject());
    mMET_logx_MiniAOD_over_Reco = ibook_.book1D("MET_logx_MiniAOD_over_RECO", (TH1F*)mMET_logx_Reco->getRootObject());
    mSumET_logx_MiniAOD_over_Reco =
        ibook_.book1D("SumET_logx_MiniAOD_over_RECO", (TH1F*)mSumET_logx_Reco->getRootObject());
    mChargedHadronEtFraction_MiniAOD_over_Reco = ibook_.book1D("PfChargedHadronEtFraction_MiniAOD_over_RECO",
                                                               (TH1F*)mChargedHadronEtFraction_Reco->getRootObject());
    mNeutralHadronEtFraction_MiniAOD_over_Reco = ibook_.book1D("PfNeutralHadronEtFraction_MiniAOD_over_RECO",
                                                               (TH1F*)mNeutralHadronEtFraction_Reco->getRootObject());
    mPhotonEtFraction_MiniAOD_over_Reco =
        ibook_.book1D("PfPhotonEtFraction_MiniAOD_over_RECO", (TH1F*)mPhotonEtFraction_Reco->getRootObject());
    mHFHadronEtFraction_MiniAOD_over_Reco =
        ibook_.book1D("PfHFHadronEtFraction_MiniAOD_over_RECO", (TH1F*)mHFHadronEtFraction_Reco->getRootObject());
    mHFEMEtFraction_MiniAOD_over_Reco =
        ibook_.book1D("PfHFEMEtFraction_MiniAOD_over_RECO", (TH1F*)mHFEMEtFraction_Reco->getRootObject());
    //use same parameters defining X-Axis of the profiles
    mMET_nVtx_profile_MiniAOD_over_Reco =
        ibook_.book1D("MET_profile_MiniAOD_over_RECO", "MET_vs_nVtx", nbinsPV_, nPVMin_, nPVMax_);
    mSumET_nVtx_profile_MiniAOD_over_Reco =
        ibook_.book1D("SumET_profile_MiniAOD_over_RECO", "SumET_vs_nVtx", nbinsPV_, nPVMin_, nPVMax_);
    mChargedHadronEtFraction_nVtx_profile_MiniAOD_over_Reco =
        ibook_.book1D("PfChargedHadronEtFraction_profile_MiniAOD_over_RECO",
                      "PfChargedHadronEtFraction_vs_nVtx",
                      nbinsPV_,
                      nPVMin_,
                      nPVMax_);
    mNeutralHadronEtFraction_nVtx_profile_MiniAOD_over_Reco =
        ibook_.book1D("PfNeutralHadronEtFraction_profile_MiniAOD_over_RECO",
                      "PfNeutralHadronEtFraction_vs_nVtx",
                      nbinsPV_,
                      nPVMin_,
                      nPVMax_);
    mPhotonEtFraction_nVtx_profile_MiniAOD_over_Reco = ibook_.book1D(
        "PfPhotonEtFraction_profile_MiniAOD_over_RECO", "PfPhotonEtFraction_vs_nVtx", nbinsPV_, nPVMin_, nPVMax_);

    std::vector<MonitorElement*> me_MET_MiniAOD_over_Reco;
    me_MET_MiniAOD_over_Reco.push_back(mMET_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mMEy_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mSumET_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mMETPhi_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mMET_logx_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mSumET_logx_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mChargedHadronEtFraction_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mNeutralHadronEtFraction_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mPhotonEtFraction_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mHFHadronEtFraction_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mHFEMEtFraction_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mMET_nVtx_profile_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mSumET_nVtx_profile_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mChargedHadronEtFraction_nVtx_profile_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mNeutralHadronEtFraction_nVtx_profile_MiniAOD_over_Reco);
    me_MET_MiniAOD_over_Reco.push_back(mPhotonEtFraction_nVtx_profile_MiniAOD_over_Reco);

    for (unsigned int j = 0; j < me_MET_MiniAOD_over_Reco.size(); j++) {
      MonitorElement* monMETReco = me_MET_Reco[j];
      if (monMETReco && monMETReco->getRootObject()) {
        MonitorElement* monMETMiniAOD = me_MET_MiniAOD[j];
        if (monMETMiniAOD && monMETMiniAOD->getRootObject()) {
          MonitorElement* monMETMiniAOD_over_RECO = me_MET_MiniAOD_over_Reco[j];
          if (monMETMiniAOD_over_RECO && monMETMiniAOD_over_RECO->getRootObject()) {
            for (int i = 0; i <= (monMETMiniAOD_over_RECO->getNbinsX() + 1); i++) {
              if (monMETReco->getBinContent(i) != 0) {
                monMETMiniAOD_over_RECO->setBinContent(i,
                                                       monMETMiniAOD->getBinContent(i) / monMETReco->getBinContent(i));
              } else if (monMETMiniAOD->getBinContent(i) != 0) {
                monMETMiniAOD_over_RECO->setBinContent(i, -0.5);
              }
            }
          }
        }
      }
    }
  }  //check for RECO and MiniAOD directories

  //put RECO vs MiniAODDir first ->second Jets
  std::vector<std::string> subDirVecJet;
  //go only for cleaned directory
  std::string RunDirJet = "JetMET/Jet/";
  iget_.setCurrentFolder(RunDirJet);
  subDirVecJet = iget_.getSubdirs();
  bool found_Jetreco_dir = false;
  bool found_Jetminiaod_dir = false;
  for (int i = 0; i < int(subDirVecJet.size()); i++) {
    ibook_.setCurrentFolder(subDirVecJet[i]);
    if (subDirVecJet[i] == (RunDirJet + "Cleaned" + inputJetLabelRECO_.label())) {
      found_Jetreco_dir = true;
    }
    if (subDirVecJet[i] == (RunDirJet + "Cleaned" + inputJetLabelMiniAOD_.label())) {
      found_Jetminiaod_dir = true;
    }
  }
  if (found_Jetreco_dir && found_Jetminiaod_dir) {
    std::string rundirJet_reco = RunDirJet + "Cleaned" + inputJetLabelRECO_.label();
    std::string rundirJet_miniaod = RunDirJet + "Cleaned" + inputJetLabelMiniAOD_.label();

    MonitorElement* mPt_Reco = iget_.get(rundirJet_reco + "/" + "Pt");
    MonitorElement* mEta_Reco = iget_.get(rundirJet_reco + "/" + "Eta");
    MonitorElement* mPhi_Reco = iget_.get(rundirJet_reco + "/" + "Phi");
    MonitorElement* mNjets_Reco = iget_.get(rundirJet_reco + "/" + "NJets");
    MonitorElement* mPt_uncor_Reco = iget_.get(rundirJet_reco + "/" + "Pt_uncor");
    MonitorElement* mEta_uncor_Reco = iget_.get(rundirJet_reco + "/" + "Eta_uncor");
    MonitorElement* mPhi_uncor_Reco = iget_.get(rundirJet_reco + "/" + "Phi_uncor");
    MonitorElement* mJetEnergyCorr_Reco = iget_.get(rundirJet_reco + "/" + "JetEnergyCorr");
    MonitorElement* mJetEnergyCorrVSeta_Reco = iget_.get(rundirJet_reco + "/" + "JetEnergyCorrVSEta");
    MonitorElement* mDPhi_Reco = iget_.get(rundirJet_reco + "/" + "DPhi");
    MonitorElement* mLooseJIDPassFractionVSeta_Reco = iget_.get(rundirJet_reco + "/" + "JetIDPassFractionVSeta");
    MonitorElement* mPt_Barrel_Reco = iget_.get(rundirJet_reco + "/" + "Pt_Barrel");
    MonitorElement* mPt_EndCap_Reco = iget_.get(rundirJet_reco + "/" + "Pt_EndCap");
    MonitorElement* mPt_Forward_Reco = iget_.get(rundirJet_reco + "/" + "Pt_Forward");
    MonitorElement* mMVAPUJIDDiscriminant_lowPt_Barrel_Reco =
        iget_.get(rundirJet_reco + "/" + "MVAPUJIDDiscriminant_lowPt_Barrel");
    MonitorElement* mMVAPUJIDDiscriminant_lowPt_EndCap_Reco =
        iget_.get(rundirJet_reco + "/" + "MVAPUJIDDiscriminant_lowPt_EndCap");
    MonitorElement* mMVAPUJIDDiscriminant_lowPt_Forward_Reco =
        iget_.get(rundirJet_reco + "/" + "MVAPUJIDDiscriminant_lowPt_Forward");
    MonitorElement* mMVAPUJIDDiscriminant_mediumPt_EndCap_Reco =
        iget_.get(rundirJet_reco + "/" + "MVAPUJIDDiscriminant_mediumPt_EndCap");
    MonitorElement* mMVAPUJIDDiscriminant_highPt_Barrel_Reco =
        iget_.get(rundirJet_reco + "/" + "MVAPUJIDDiscriminant_highPt_Barrel");
    MonitorElement* mCHFracVSpT_Barrel_Reco = iget_.get(rundirJet_reco + "/" + "CHFracVSpT_Barrel");
    MonitorElement* mNHFracVSpT_EndCap_Reco = iget_.get(rundirJet_reco + "/" + "NHFracVSpT_EndCap");
    MonitorElement* mPhFracVSpT_Barrel_Reco = iget_.get(rundirJet_reco + "/" + "PhFracVSpT_Barrel");
    MonitorElement* mHFHFracVSpT_Forward_Reco = iget_.get(rundirJet_reco + "/" + "HFHFracVSpT_Forward");
    MonitorElement* mHFEFracVSpT_Forward_Reco = iget_.get(rundirJet_reco + "/" + "HFEFracVSpT_Forward");
    MonitorElement* mCHFrac_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "CHFrac");
    MonitorElement* mNHFrac_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "NHFrac");
    MonitorElement* mPhFrac_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "PhFrac");
    MonitorElement* mChargedMultiplicity_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "ChargedMultiplicity");
    MonitorElement* mNeutralMultiplicity_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "NeutralMultiplicity");
    MonitorElement* mMuonMultiplicity_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "MuonMultiplicity");
    MonitorElement* mNeutralFraction_Reco = iget_.get(rundirJet_reco + "/DiJet/" + "NeutralConstituentsFraction");

    std::vector<MonitorElement*> me_Jet_Reco;
    me_Jet_Reco.push_back(mPt_Reco);
    me_Jet_Reco.push_back(mEta_Reco);
    me_Jet_Reco.push_back(mPhi_Reco);
    me_Jet_Reco.push_back(mNjets_Reco);
    me_Jet_Reco.push_back(mPt_uncor_Reco);
    me_Jet_Reco.push_back(mEta_uncor_Reco);
    me_Jet_Reco.push_back(mPhi_uncor_Reco);
    me_Jet_Reco.push_back(mJetEnergyCorr_Reco);
    me_Jet_Reco.push_back(mJetEnergyCorrVSeta_Reco);
    me_Jet_Reco.push_back(mDPhi_Reco);
    me_Jet_Reco.push_back(mLooseJIDPassFractionVSeta_Reco);
    me_Jet_Reco.push_back(mPt_Barrel_Reco);
    me_Jet_Reco.push_back(mPt_EndCap_Reco);
    me_Jet_Reco.push_back(mPt_Forward_Reco);
    me_Jet_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_Barrel_Reco);
    me_Jet_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_EndCap_Reco);
    me_Jet_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_Forward_Reco);
    me_Jet_Reco.push_back(mMVAPUJIDDiscriminant_mediumPt_EndCap_Reco);
    me_Jet_Reco.push_back(mMVAPUJIDDiscriminant_highPt_Barrel_Reco);
    me_Jet_Reco.push_back(mCHFracVSpT_Barrel_Reco);
    me_Jet_Reco.push_back(mNHFracVSpT_EndCap_Reco);
    me_Jet_Reco.push_back(mPhFracVSpT_Barrel_Reco);
    me_Jet_Reco.push_back(mHFHFracVSpT_Forward_Reco);
    me_Jet_Reco.push_back(mHFEFracVSpT_Forward_Reco);
    me_Jet_Reco.push_back(mCHFrac_Reco);
    me_Jet_Reco.push_back(mNHFrac_Reco);
    me_Jet_Reco.push_back(mPhFrac_Reco);
    me_Jet_Reco.push_back(mChargedMultiplicity_Reco);
    me_Jet_Reco.push_back(mNeutralMultiplicity_Reco);
    me_Jet_Reco.push_back(mMuonMultiplicity_Reco);
    me_Jet_Reco.push_back(mNeutralFraction_Reco);

    MonitorElement* mPt_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Pt");
    MonitorElement* mEta_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Eta");
    MonitorElement* mPhi_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Phi");
    MonitorElement* mNjets_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "NJets");
    MonitorElement* mPt_uncor_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Pt_uncor");
    MonitorElement* mEta_uncor_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Eta_uncor");
    MonitorElement* mPhi_uncor_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Phi_uncor");
    MonitorElement* mJetEnergyCorr_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "JetEnergyCorr");
    MonitorElement* mJetEnergyCorrVSeta_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "JetEnergyCorrVSEta");
    MonitorElement* mDPhi_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "DPhi");
    MonitorElement* mLooseJIDPassFractionVSeta_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "JetIDPassFractionVSeta");
    MonitorElement* mPt_Barrel_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Pt_Barrel");
    MonitorElement* mPt_EndCap_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Pt_EndCap");
    MonitorElement* mPt_Forward_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "Pt_Forward");
    MonitorElement* mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD =
        iget_.get(rundirJet_miniaod + "/" + "MVAPUJIDDiscriminant_lowPt_Barrel");
    MonitorElement* mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD =
        iget_.get(rundirJet_miniaod + "/" + "MVAPUJIDDiscriminant_lowPt_EndCap");
    MonitorElement* mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD =
        iget_.get(rundirJet_miniaod + "/" + "MVAPUJIDDiscriminant_lowPt_Forward");
    MonitorElement* mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD =
        iget_.get(rundirJet_miniaod + "/" + "MVAPUJIDDiscriminant_mediumPt_EndCap");
    MonitorElement* mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD =
        iget_.get(rundirJet_miniaod + "/" + "MVAPUJIDDiscriminant_highPt_Barrel");
    MonitorElement* mCHFracVSpT_Barrel_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "CHFracVSpT_Barrel");
    MonitorElement* mNHFracVSpT_EndCap_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "NHFracVSpT_EndCap");
    MonitorElement* mPhFracVSpT_Barrel_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "PhFracVSpT_Barrel");
    MonitorElement* mHFHFracVSpT_Forward_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "HFHFracVSpT_Forward");
    MonitorElement* mHFEFracVSpT_Forward_MiniAOD = iget_.get(rundirJet_miniaod + "/" + "HFEFracVSpT_Forward");
    MonitorElement* mCHFrac_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "CHFrac");
    MonitorElement* mNHFrac_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "NHFrac");
    MonitorElement* mPhFrac_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "PhFrac");
    MonitorElement* mChargedMultiplicity_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "ChargedMultiplicity");
    MonitorElement* mNeutralMultiplicity_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "NeutralMultiplicity");
    MonitorElement* mMuonMultiplicity_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "MuonMultiplicity");
    MonitorElement* mNeutralFraction_MiniAOD = iget_.get(rundirJet_miniaod + "/DiJet/" + "NeutralConstituentsFraction");

    std::vector<MonitorElement*> me_Jet_MiniAOD;
    me_Jet_MiniAOD.push_back(mPt_MiniAOD);
    me_Jet_MiniAOD.push_back(mEta_MiniAOD);
    me_Jet_MiniAOD.push_back(mPhi_MiniAOD);
    me_Jet_MiniAOD.push_back(mNjets_MiniAOD);
    me_Jet_MiniAOD.push_back(mPt_uncor_MiniAOD);
    me_Jet_MiniAOD.push_back(mEta_uncor_MiniAOD);
    me_Jet_MiniAOD.push_back(mPhi_uncor_MiniAOD);
    me_Jet_MiniAOD.push_back(mJetEnergyCorr_MiniAOD);
    me_Jet_MiniAOD.push_back(mJetEnergyCorrVSeta_MiniAOD);
    me_Jet_MiniAOD.push_back(mDPhi_MiniAOD);
    me_Jet_MiniAOD.push_back(mLooseJIDPassFractionVSeta_MiniAOD);
    me_Jet_MiniAOD.push_back(mPt_Barrel_MiniAOD);
    me_Jet_MiniAOD.push_back(mPt_EndCap_MiniAOD);
    me_Jet_MiniAOD.push_back(mPt_Forward_MiniAOD);
    me_Jet_MiniAOD.push_back(mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD);
    me_Jet_MiniAOD.push_back(mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD);
    me_Jet_MiniAOD.push_back(mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD);
    me_Jet_MiniAOD.push_back(mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD);
    me_Jet_MiniAOD.push_back(mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD);
    me_Jet_MiniAOD.push_back(mCHFracVSpT_Barrel_MiniAOD);
    me_Jet_MiniAOD.push_back(mNHFracVSpT_EndCap_MiniAOD);
    me_Jet_MiniAOD.push_back(mPhFracVSpT_Barrel_MiniAOD);
    me_Jet_MiniAOD.push_back(mHFHFracVSpT_Forward_MiniAOD);
    me_Jet_MiniAOD.push_back(mHFEFracVSpT_Forward_MiniAOD);
    me_Jet_MiniAOD.push_back(mCHFrac_MiniAOD);
    me_Jet_MiniAOD.push_back(mNHFrac_MiniAOD);
    me_Jet_MiniAOD.push_back(mPhFrac_MiniAOD);
    me_Jet_MiniAOD.push_back(mChargedMultiplicity_MiniAOD);
    me_Jet_MiniAOD.push_back(mNeutralMultiplicity_MiniAOD);
    me_Jet_MiniAOD.push_back(mMuonMultiplicity_MiniAOD);
    me_Jet_MiniAOD.push_back(mNeutralFraction_MiniAOD);

    ibook_.setCurrentFolder(RunDirJet + "MiniAOD_over_RECO");
    mPt_MiniAOD_over_Reco = ibook_.book1D("Pt_MiniAOD_over_RECO", (TH1F*)mPt_Reco->getRootObject());
    mEta_MiniAOD_over_Reco = ibook_.book1D("Eta_MiniAOD_over_RECO", (TH1F*)mEta_Reco->getRootObject());
    mPhi_MiniAOD_over_Reco = ibook_.book1D("Phi_MiniAOD_over_RECO", (TH1F*)mPhi_Reco->getRootObject());
    mNjets_MiniAOD_over_Reco = ibook_.book1D("NJets_MiniAOD_over_RECO", (TH1F*)mNjets_Reco->getRootObject());
    mPt_uncor_MiniAOD_over_Reco = ibook_.book1D("Pt_uncor_MiniAOD_over_RECO", (TH1F*)mPt_uncor_Reco->getRootObject());
    mEta_uncor_MiniAOD_over_Reco =
        ibook_.book1D("Eta_uncor_MiniAOD_over_RECO", (TH1F*)mEta_uncor_Reco->getRootObject());
    mPhi_uncor_MiniAOD_over_Reco =
        ibook_.book1D("Phi_uncor_MiniAOD_over_RECO", (TH1F*)mPhi_uncor_Reco->getRootObject());
    mJetEnergyCorr_MiniAOD_over_Reco =
        ibook_.book1D("JetEnergyCorr_MiniAOD_over_RECO", (TH1F*)mJetEnergyCorr_Reco->getRootObject());
    mJetEnergyCorrVSeta_MiniAOD_over_Reco = ibook_.book1D(
        "JetEnergyCorrVSEta_MiniAOD_over_RECO", "jet energy correction factor VS eta", etaBin_, etaMin_, etaMax_);
    mDPhi_MiniAOD_over_Reco = ibook_.book1D("DPhi_MiniAOD_over_RECO", (TH1F*)mDPhi_Reco->getRootObject());
    mLooseJIDPassFractionVSeta_MiniAOD_over_Reco =
        ibook_.book1D("JetIDPassFractionVSeta_MiniAOD_over_RECO", "JetIDPassFractionVSeta", etaBin_, etaMin_, etaMax_);
    mPt_Barrel_MiniAOD_over_Reco =
        ibook_.book1D("Pt_Barrel_MiniAOD_over_RECO", (TH1F*)mPt_Barrel_Reco->getRootObject());
    mPt_EndCap_MiniAOD_over_Reco =
        ibook_.book1D("Pt_EndCap_MiniAOD_over_RECO", (TH1F*)mPt_EndCap_Reco->getRootObject());
    mPt_Forward_MiniAOD_over_Reco =
        ibook_.book1D("Pt_Forward_MiniAOD_over_RECO", (TH1F*)mPt_Forward_Reco->getRootObject());
    mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD_over_Reco =
        ibook_.book1D("MVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD_over_RECO",
                      (TH1F*)mMVAPUJIDDiscriminant_lowPt_Barrel_Reco->getRootObject());
    mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD_over_Reco =
        ibook_.book1D("MVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD_over_RECO",
                      (TH1F*)mMVAPUJIDDiscriminant_lowPt_EndCap_Reco->getRootObject());
    mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD_over_Reco =
        ibook_.book1D("MVAPUJIDDiscriminant_lowPt_Forward_MiniAOD_over_RECO",
                      (TH1F*)mMVAPUJIDDiscriminant_lowPt_Forward_Reco->getRootObject());
    mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD_over_Reco =
        ibook_.book1D("MVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD_over_RECO",
                      (TH1F*)mMVAPUJIDDiscriminant_mediumPt_EndCap_Reco->getRootObject());
    mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD_over_Reco =
        ibook_.book1D("MVAPUJIDDiscriminant_highPt_Barrel_MiniAOD_over_RECO",
                      (TH1F*)mMVAPUJIDDiscriminant_highPt_Barrel_Reco->getRootObject());
    mCHFracVSpT_Barrel_MiniAOD_over_Reco =
        ibook_.book1D("CHFracVSpT_Barrel_MiniAOD_over_RECO", "CHFracVSpT_Barrel", ptBin_, ptMin_, ptMax_);
    mNHFracVSpT_EndCap_MiniAOD_over_Reco =
        ibook_.book1D("NHFracVSpT_EndCap_MiniAOD_over_RECO", "NHFracVSpT_EndCap", ptBin_, ptMin_, ptMax_);
    mPhFracVSpT_Barrel_MiniAOD_over_Reco =
        ibook_.book1D("PhFracVSpT_Barrel_MiniAOD_over_RECO", "PhFracVSpT_Barrel", ptBin_, ptMin_, ptMax_);
    mHFHFracVSpT_Forward_MiniAOD_over_Reco =
        ibook_.book1D("HFHFracVSpT_Forward_MiniAOD_over_RECO", "HFHFracVSpT_Forward", ptBin_, ptMin_, ptMax_);
    mHFEFracVSpT_Forward_MiniAOD_over_Reco =
        ibook_.book1D("HFEFracVSpT_Forward_MiniAOD_over_RECO", "HFEFracVSpT_Forward", ptBin_, ptMin_, ptMax_);
    ibook_.setCurrentFolder(RunDirJet + "MiniAOD_over_RECO" + "/" + "DiJet");
    mCHFrac_MiniAOD_over_Reco = ibook_.book1D("CHFrac_MiniAOD_over_RECO", (TH1F*)mCHFrac_Reco->getRootObject());
    mNHFrac_MiniAOD_over_Reco = ibook_.book1D("NHFrac_MiniAOD_over_RECO", (TH1F*)mNHFrac_Reco->getRootObject());
    mPhFrac_MiniAOD_over_Reco = ibook_.book1D("PhFrac_MiniAOD_over_RECO", (TH1F*)mPhFrac_Reco->getRootObject());
    mChargedMultiplicity_MiniAOD_over_Reco =
        ibook_.book1D("ChargedMultiplicity_MiniAOD_over_RECO", (TH1F*)mChargedMultiplicity_Reco->getRootObject());
    mNeutralMultiplicity_MiniAOD_over_Reco =
        ibook_.book1D("NeutralMultiplicity_MiniAOD_over_RECO", (TH1F*)mNeutralMultiplicity_Reco->getRootObject());
    mMuonMultiplicity_MiniAOD_over_Reco =
        ibook_.book1D("MuonMultiplicity_MiniAOD_over_RECO", (TH1F*)mMuonMultiplicity_Reco->getRootObject());
    mNeutralFraction_MiniAOD_over_Reco =
        ibook_.book1D("NeutralConstituentsFraction_MiniAOD_over_RECO", (TH1F*)mNeutralFraction_Reco->getRootObject());

    std::vector<MonitorElement*> me_Jet_MiniAOD_over_Reco;
    me_Jet_MiniAOD_over_Reco.push_back(mPt_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mEta_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mPhi_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mNjets_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mPt_uncor_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mEta_uncor_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mPhi_uncor_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mJetEnergyCorr_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mJetEnergyCorrVSeta_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mDPhi_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mLooseJIDPassFractionVSeta_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mPt_Barrel_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mPt_EndCap_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mPt_Forward_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_Barrel_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_EndCap_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mMVAPUJIDDiscriminant_lowPt_Forward_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mMVAPUJIDDiscriminant_mediumPt_EndCap_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mMVAPUJIDDiscriminant_highPt_Barrel_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mCHFracVSpT_Barrel_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mNHFracVSpT_EndCap_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mPhFracVSpT_Barrel_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mHFHFracVSpT_Forward_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mHFEFracVSpT_Forward_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mCHFrac_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mNHFrac_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mPhFrac_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mChargedMultiplicity_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mNeutralMultiplicity_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mMuonMultiplicity_MiniAOD_over_Reco);
    me_Jet_MiniAOD_over_Reco.push_back(mNeutralFraction_MiniAOD_over_Reco);

    for (unsigned int j = 0; j < me_Jet_MiniAOD_over_Reco.size(); j++) {
      MonitorElement* monJetReco = me_Jet_Reco[j];
      if (monJetReco && monJetReco->getRootObject()) {
        MonitorElement* monJetMiniAOD = me_Jet_MiniAOD[j];
        if (monJetMiniAOD && monJetMiniAOD->getRootObject()) {
          MonitorElement* monJetMiniAOD_over_RECO = me_Jet_MiniAOD_over_Reco[j];
          if (monJetMiniAOD_over_RECO && monJetMiniAOD_over_RECO->getRootObject()) {
            for (int i = 0; i <= (monJetMiniAOD_over_RECO->getNbinsX() + 1); i++) {
              if (monJetReco->getBinContent(i) != 0) {
                monJetMiniAOD_over_RECO->setBinContent(i,
                                                       monJetMiniAOD->getBinContent(i) / monJetReco->getBinContent(i));
              } else if (monJetMiniAOD->getBinContent(i) != 0) {
                monJetMiniAOD_over_RECO->setBinContent(i, -0.5);
              }
            }
          }
        }
      }
    }
  }  //check for RECO and MiniAOD directories

  if (verbose_)
    std::cout << ">>> EndRun (DataCertificationJetMET) <<<" << std::endl;

  std::vector<std::string> subDirVec;
  std::string RunDir;

  if (verbose_)
    std::cout << "InMemory_           = " << InMemory_ << std::endl;

  ibook_.setCurrentFolder(folderName);
  reportSummary = ibook_.bookFloat("reportSummary");
  CertificationSummary = ibook_.bookFloat("CertificationSummary");

  reportSummaryMap = ibook_.book2D("reportSummaryMap", "reportSummaryMap", 3, 0, 3, 5, 0, 5);
  CertificationSummaryMap = ibook_.book2D("CertificationSummaryMap", "CertificationSummaryMap", 3, 0, 3, 5, 0, 5);

  reportSummary = iget_.get(folderName + "/" + "reportSummary");
  CertificationSummary = iget_.get(folderName + "/" + "CertificationSummary");
  reportSummaryMap = iget_.get(folderName + "/" + "reportSummaryMap");
  CertificationSummaryMap = iget_.get(folderName + "/" + "CertificationSummaryMap");

  if (reportSummaryMap && reportSummaryMap->getRootObject()) {
    reportSummaryMap->getTH2F()->SetStats(kFALSE);
    reportSummaryMap->setOption("colz");
    reportSummaryMap->setBinLabel(1, "CaloTower");
    reportSummaryMap->setBinLabel(2, "MET");
    reportSummaryMap->setBinLabel(3, "Jet");
  }
  if (CertificationSummaryMap && CertificationSummaryMap->getRootObject()) {
    CertificationSummaryMap->getTH2F()->SetStats(kFALSE);
    CertificationSummaryMap->setOption("colz");
    CertificationSummaryMap->setBinLabel(1, "CaloTower");
    CertificationSummaryMap->setBinLabel(2, "MET");
    CertificationSummaryMap->setBinLabel(3, "Jet");
  }

  reportSummary->Fill(1.);
  CertificationSummary->Fill(1.);

  if (RunDir == "Reference")
    RunDir = "";
  if (verbose_)
    std::cout << RunDir << std::endl;
  ibook_.setCurrentFolder("JetMET/EventInfo/CertificationSummaryContents/");

  std::string refHistoName;
  std::string newHistoName;

  //-----------------------------
  // Jet DQM Data Certification
  //-----------------------------
  //we have 4 types anymore: PF (barrel,endcap,forward) and calojets
  MonitorElement* meJetPt[4];
  MonitorElement* meJetEta[4];
  MonitorElement* meJetPhi[4];
  MonitorElement* meJetEMFrac[4];
  MonitorElement* meJetConstituents[4];
  RunDir = "";
  if (RunDir.empty())
    newHistoName = "JetMET/Jet/";
  else
    newHistoName = RunDir + "/JetMET/Runsummary/Jet/";
  std::string cleaningdir = "";
  cleaningdir = "Cleaned";

  // Read different histograms for PbPb and pp collisions

  if (isHI) {  // Histograms for heavy ions

    newHistoName = "JetMET/HIJetValidation/";
    cleaningdir = "";

    //Jet Phi histos
    meJetPhi[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Cs4PFJets/Phi");
    meJetPhi[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu3PFJets/Phi");
    meJetPhi[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4PFJets/Phi");
    meJetPhi[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4CaloJets/Phi");

    //Jet Eta histos
    meJetEta[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Cs4PFJets/Eta");
    meJetEta[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu3PFJets/Eta");
    meJetEta[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4PFJets/Eta");
    meJetEta[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4CaloJets/Eta");

    //Jet Pt histos
    meJetPt[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Cs4PFJets/Pt");
    meJetPt[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu3PFJets/Pt");
    meJetPt[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4PFJets/Pt");
    meJetPt[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4CaloJets/Pt");

    //Jet Constituents histos
    meJetConstituents[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Cs4PFJets/Constituents");
    meJetConstituents[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu3PFJets/Constituents");
    meJetConstituents[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4PFJets/Constituents");
    meJetConstituents[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "Pu4CaloJets/Constituents");

    //There are no jet EMFrac histograms for HI. Dummy paths will pass the tests by default
    meJetEMFrac[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "dummy/dummy");
    meJetEMFrac[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "dummy/dummy");
    meJetEMFrac[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "dummy/dummy");
    meJetEMFrac[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "dummy/dummy");

  } else {  // Histograms for protons

    //Jet Phi histos
    meJetPhi[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Phi_Barrel");
    meJetPhi[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Phi_EndCap");
    meJetPhi[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Phi_Forward");
    meJetPhi[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "CaloJets/Phi");
    //meJetPhi[4] = iget_.get(newHistoName+cleaningdir+"JetPlusTrackZSPCorJetAntiKt5/Phi");

    //Jet Eta histos
    meJetEta[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Eta");
    meJetEta[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Eta");
    meJetEta[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/EtaFirst");
    meJetEta[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "CaloJets/Eta");
    //meJetEta[4] = iget_.get(newHistoName+cleaningdir+"JetPlusTrackZSPCorJetAntiKt5/Eta");

    //Jet Pt histos
    meJetPt[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Pt_Barrel");
    meJetPt[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Pt_EndCap");
    meJetPt[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Pt_Forward");
    meJetPt[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "CaloJets/Pt_2");

    //Jet Constituents histos
    meJetConstituents[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Constituents_Barrel");
    meJetConstituents[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Constituents_EndCap");
    meJetConstituents[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/Constituents_Forward");
    meJetConstituents[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "CaloJets/Constituents");

    //Jet EMFrac histos
    meJetEMFrac[0] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/EFrac_Barrel");
    meJetEMFrac[1] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/EFrac_EndCap");
    meJetEMFrac[2] = iget_.get(newHistoName + cleaningdir + jetAlgo + "PFJets/EFrac_Forward");
    meJetEMFrac[3] = iget_.get(newHistoName + cleaningdir + jetAlgo + "CaloJets/EFrac");
  }

  //------------------------------------------------------------------------------
  //--- Extract quality test results and fill data certification results for Jets
  //--- Tests for Calo Barrel, EndCap and Forward, as well as PF and JPT jets
  //--- For Calo and PF jets:
  //--- Look at mean of Constituents, EM Frac and Pt
  //--- Look at Kolmogorov result for Eta, Phi, and Pt
  //--- For JPT jets:
  //--- Look at mean of Pt, AllPionsTrackNHits?, nTracks,
  //--- Look at Kolmogorov result for Eta, Phi, and Pt
  //------------------------------------------------------------------------------

  // Four types of jets {AK5 Barrel, AK5 EndCap, AK5 Forward, PF}, removed JPT which is 5th type of jets
  //----------------------------------------------------------------------------
  // Kolmogorov (KS) tests
  const QReport* QReport_JetEta[4] = {nullptr};
  const QReport* QReport_JetPhi[4] = {nullptr};
  // Mean and KS tests for Calo and PF jets
  const QReport* QReport_JetConstituents[4][2] = {{nullptr}};
  const QReport* QReport_JetEFrac[4][2] = {{nullptr}};
  const QReport* QReport_JetPt[4][2] = {{nullptr}};

  // Mean and KS tests for JPT jets
  //const QReport* QReport_JetNTracks[2] = {0, 0};
  float qr_Jet_Eta[4] = {-1};
  float qr_Jet_Phi[4] = {-1};
  float dc_Jet[4] = {-1};

  float qr_Jet_Constituents[4][2] = {{-1}};
  float qr_Jet_EFrac[4][2] = {{-1}};
  float qr_Jet_Pt[4][2] = {{-1}};

  // Loop
  //----------------------------------------------------------------------------
  for (int jtyp = 0; jtyp < 4; ++jtyp) {
    // Mean test results

    if (meJetConstituents[jtyp] && meJetConstituents[jtyp]->getRootObject()) {
      QReport_JetConstituents[jtyp][0] = meJetConstituents[jtyp]->getQReport("meanJetConstituentsTest");
      QReport_JetConstituents[jtyp][1] = meJetConstituents[jtyp]->getQReport("KolmogorovTest");
    }
    if (meJetEMFrac[jtyp] && meJetEMFrac[jtyp]->getRootObject()) {
      QReport_JetEFrac[jtyp][0] = meJetEMFrac[jtyp]->getQReport("meanEMFractionTest");
      QReport_JetEFrac[jtyp][1] = meJetEMFrac[jtyp]->getQReport("KolmogorovTest");
    }
    if (meJetPt[jtyp] && meJetPt[jtyp]->getRootObject()) {
      QReport_JetPt[jtyp][0] = meJetPt[jtyp]->getQReport("meanJetPtTest");
      QReport_JetPt[jtyp][1] = meJetPt[jtyp]->getQReport("KolmogorovTest");
    }
    if (meJetPhi[jtyp] && meJetPhi[jtyp]->getRootObject()) {
      QReport_JetPhi[jtyp] = meJetPhi[jtyp]->getQReport("KolmogorovTest");
    }
    if (meJetEta[jtyp] && meJetEta[jtyp]->getRootObject()) {
      QReport_JetEta[jtyp] = meJetEta[jtyp]->getQReport("KolmogorovTest");
    }

    //Jet Pt test
    if (QReport_JetPt[jtyp][0]) {
      //std::cout<<"jet type test pt "<<jtyp<<"/"<<QReport_JetPt[jtyp][0]->getStatus()<<std::endl;
      if (QReport_JetPt[jtyp][0]->getStatus() == 100 || QReport_JetPt[jtyp][0]->getStatus() == 200)
        qr_Jet_Pt[jtyp][0] = 1;
      else if (QReport_JetPt[jtyp][0]->getStatus() == 300)
        qr_Jet_Pt[jtyp][0] = 0;
      else
        qr_Jet_Pt[jtyp][0] = -1;
    } else {
      qr_Jet_Pt[jtyp][0] = -2;
      //std::cout<<"qreport is REALLY NULL type test pt "<<jtyp<<" 0 "<<std::endl;
    }
    if (QReport_JetPt[jtyp][1]) {
      if (QReport_JetPt[jtyp][1]->getStatus() == 100 || QReport_JetPt[jtyp][1]->getStatus() == 200)
        qr_Jet_Pt[jtyp][1] = 1;
      else if (QReport_JetPt[jtyp][1]->getStatus() == 300)
        qr_Jet_Pt[jtyp][1] = 0;
      else
        qr_Jet_Pt[jtyp][1] = -1;
    } else {
      qr_Jet_Pt[jtyp][1] = -2;
    }

    //Jet Phi test
    if (QReport_JetPhi[jtyp]) {
      if (QReport_JetPhi[jtyp]->getStatus() == 100 || QReport_JetPhi[jtyp]->getStatus() == 200)
        qr_Jet_Phi[jtyp] = 1;
      else if (QReport_JetPhi[jtyp]->getStatus() == 300)
        qr_Jet_Phi[jtyp] = 0;
      else
        qr_Jet_Phi[jtyp] = -1;
    } else {
      qr_Jet_Phi[jtyp] = -2;
    }
    //Jet Eta test
    if (QReport_JetEta[jtyp]) {
      if (QReport_JetEta[jtyp]->getStatus() == 100 || QReport_JetEta[jtyp]->getStatus() == 200)
        qr_Jet_Eta[jtyp] = 1;
      else if (QReport_JetEta[jtyp]->getStatus() == 300)
        qr_Jet_Eta[jtyp] = 0;
      else
        qr_Jet_Eta[jtyp] = -1;
    } else {
      qr_Jet_Eta[jtyp] = -2;
    }
    //Jet Constituents test
    if (QReport_JetConstituents[jtyp][0]) {
      if (QReport_JetConstituents[jtyp][0]->getStatus() == 100 || QReport_JetConstituents[jtyp][0]->getStatus() == 200)
        qr_Jet_Constituents[jtyp][0] = 1;
      else if (QReport_JetConstituents[jtyp][0]->getStatus() == 300)
        qr_Jet_Constituents[jtyp][0] = 0;
      else
        qr_Jet_Constituents[jtyp][0] = -1;
    } else {
      qr_Jet_Constituents[jtyp][0] = -2;
    }

    if (QReport_JetConstituents[jtyp][1]) {
      if (QReport_JetConstituents[jtyp][1]->getStatus() == 100 || QReport_JetConstituents[jtyp][1]->getStatus() == 200)
        qr_Jet_Constituents[jtyp][1] = 1;
      else if (QReport_JetConstituents[jtyp][1]->getStatus() == 300)
        qr_Jet_Constituents[jtyp][1] = 0;
      else
        qr_Jet_Constituents[jtyp][1] = -1;
    } else {
      qr_Jet_Constituents[jtyp][1] = -2;
    }
    //Jet EMFrac test
    if (QReport_JetEFrac[jtyp][0]) {
      if (QReport_JetEFrac[jtyp][0]->getStatus() == 100 || QReport_JetEFrac[jtyp][0]->getStatus() == 200)
        qr_Jet_EFrac[jtyp][0] = 1;
      else if (QReport_JetEFrac[jtyp][0]->getStatus() == 300)
        qr_Jet_EFrac[jtyp][0] = 0;
      else
        qr_Jet_EFrac[jtyp][0] = -1;
    } else {
      qr_Jet_EFrac[jtyp][0] = -2;
    }

    if (QReport_JetEFrac[jtyp][1]) {
      if (QReport_JetEFrac[jtyp][1]->getStatus() == 100 || QReport_JetEFrac[jtyp][1]->getStatus() == 200)
        qr_Jet_EFrac[jtyp][1] = 1;
      else if (QReport_JetEFrac[jtyp][1]->getStatus() == 300)
        qr_Jet_EFrac[jtyp][1] = 0;
      else
        qr_Jet_EFrac[jtyp][1] = -1;
    } else {
      qr_Jet_EFrac[jtyp][1] = -2;
    }

    if (verbose_) {
      printf("====================Jet Type %d QTest Report Summary========================\n", jtyp);
      printf("Eta:    Phi:   Pt 1:    2:    Const/Ntracks 1:    2:    EFrac/tracknhits 1:    2:\n");

      printf("%2.2f    %2.2f    %2.2f    %2.2f    %2.2f    %2.2f    %2.2f    %2.2f\n",
             qr_Jet_Eta[jtyp],
             qr_Jet_Phi[jtyp],
             qr_Jet_Pt[jtyp][0],
             qr_Jet_Pt[jtyp][1],
             qr_Jet_Constituents[jtyp][0],
             qr_Jet_Constituents[jtyp][1],
             qr_Jet_EFrac[jtyp][0],
             qr_Jet_EFrac[jtyp][1]);
    }
    //certification result for Jet

    //Only apply certain tests, as defined in the config
    for (int ttyp = 0; ttyp < 2; ++ttyp) {
      if (!jetTests[jtyp][ttyp]) {
        qr_Jet_Pt[jtyp][ttyp] = 1;
        if (ttyp == 1) {
          qr_Jet_Eta[jtyp] = 1;
          qr_Jet_Phi[jtyp] = 1;
        }
        qr_Jet_EFrac[jtyp][ttyp] = 1;
        qr_Jet_Constituents[jtyp][ttyp] = 1;
      }
    }

    if ((qr_Jet_EFrac[jtyp][0] == 0) || (qr_Jet_EFrac[jtyp][1] == 0) || (qr_Jet_Constituents[jtyp][1] == 0) ||
        (qr_Jet_Constituents[jtyp][0] == 0) || (qr_Jet_Eta[jtyp] == 0) || (qr_Jet_Phi[jtyp] == 0) ||
        (qr_Jet_Pt[jtyp][0] == 0) || (qr_Jet_Pt[jtyp][1] == 0))
      dc_Jet[jtyp] = 0;
    else if ((qr_Jet_EFrac[jtyp][0] == -1) && (qr_Jet_EFrac[jtyp][1] == -1) && (qr_Jet_Constituents[jtyp][1] == -1) &&
             (qr_Jet_Constituents[jtyp][0] == -1) && (qr_Jet_Eta[jtyp] == -1) && (qr_Jet_Phi[jtyp] == -1) &&
             (qr_Jet_Pt[jtyp][0] == -1) && (qr_Jet_Pt[jtyp][1] == -1))
      dc_Jet[jtyp] = -1;
    else if ((qr_Jet_EFrac[jtyp][0] == -2) && (qr_Jet_EFrac[jtyp][1] == -2) && (qr_Jet_Constituents[jtyp][1] == -2) &&
             (qr_Jet_Constituents[jtyp][0] == -2) && (qr_Jet_Eta[jtyp] == -2) && (qr_Jet_Phi[jtyp] == -2) &&
             (qr_Jet_Pt[jtyp][0] == -2) && (qr_Jet_Pt[jtyp][1] == -2))
      dc_Jet[jtyp] = -2;
    else
      dc_Jet[jtyp] = 1;

    if (verbose_)
      std::cout << "Certifying Jet algo: " << jtyp << " with value: " << dc_Jet[jtyp] << std::endl;

    CertificationSummaryMap->Fill(2, 4 - jtyp, dc_Jet[jtyp]);
    reportSummaryMap->Fill(2, 4 - jtyp, dc_Jet[jtyp]);
  }

  // There is nothing on the first row for HI, so mark the unfilled
  if (isHI) {
    CertificationSummaryMap->Fill(2, 0, -2);
    reportSummaryMap->Fill(2, 0, -2);
  }

  //-----------------------------
  // MET DQM Data Certification
  //-----------------------------
  //
  // Prepare test histograms
  //
  MonitorElement* meMExy[2][2];
  MonitorElement* meMEt[2];
  MonitorElement* meSumEt[2];
  MonitorElement* meMETPhi[2];

  RunDir = "";
  if (RunDir.empty())
    newHistoName = "JetMET/MET/";
  else
    newHistoName = RunDir + "/JetMET/Runsummary/MET/";

  metFolder = "Cleaned";

  //MEx/MEy monitor elements
  meMExy[0][0] = iget_.get(newHistoName + "met/" + metFolder + "/MEx");
  meMExy[0][1] = iget_.get(newHistoName + "met/" + metFolder + "/MEy");
  meMExy[1][0] = iget_.get(newHistoName + "pfMet/" + metFolder + "/MEx");
  meMExy[1][1] = iget_.get(newHistoName + "pfMet/" + metFolder + "/MEy");

  //MET Phi monitor elements
  meMETPhi[0] = iget_.get(newHistoName + "met/" + metFolder + "/METPhi");
  meMETPhi[1] = iget_.get(newHistoName + "pfMet/" + metFolder + "/METPhi");
  //MET monitor elements
  meMEt[0] = iget_.get(newHistoName + "met/" + metFolder + "/MET");
  meMEt[1] = iget_.get(newHistoName + "pfMet/" + metFolder + "/MET");
  //SumET monitor elements
  meSumEt[0] = iget_.get(newHistoName + "met/" + metFolder + "/SumET");
  meSumEt[1] = iget_.get(newHistoName + "pfMet/" + metFolder + "/SumET");

  //----------------------------------------------------------------------------
  //--- Extract quality test results and fill data certification results for MET
  //----------------------------------------------------------------------------

  // 2 types of MET {CaloMET, PfMET}  // It is 5 if CaloMETNoHF is included, 4 for MuonCorMET
  // removed 3rd type of TcMET
  // 2 types of tests Mean test/Kolmogorov test
  const QReport* QReport_MExy[2][2][2] = {{{nullptr}}};
  const QReport* QReport_MEt[2][2] = {{nullptr}};
  const QReport* QReport_SumEt[2][2] = {{nullptr}};
  //2 types of tests phiQTest and Kolmogorov test
  const QReport* QReport_METPhi[2][2] = {{nullptr}};

  float qr_MET_MExy[2][2][2] = {{{-999.}}};
  float qr_MET_MEt[2][2] = {{-999.}};
  float qr_MET_SumEt[2][2] = {{-999.}};
  float qr_MET_METPhi[2][2] = {{-999.}};
  float dc_MET[2] = {-999.};

  // J.Piedra, 27/02/212
  // removed MuCorrMET & TcMET --> loop up to 2 instead of 4, remove already from definition
  for (int mtyp = 0; mtyp < 2; ++mtyp) {
    //Mean test results
    if (meMExy[mtyp][0] && meMExy[mtyp][0]->getRootObject()) {
      QReport_MExy[mtyp][0][0] = meMExy[mtyp][0]->getQReport("meanMExyTest");
      QReport_MExy[mtyp][1][0] = meMExy[mtyp][0]->getQReport("KolmogorovTest");
    }
    if (meMExy[mtyp][1] && meMExy[mtyp][1]->getRootObject()) {
      QReport_MExy[mtyp][0][1] = meMExy[mtyp][1]->getQReport("meanMExyTest");
      QReport_MExy[mtyp][1][1] = meMExy[mtyp][1]->getQReport("KolmogorovTest");
    }
    if (meMEt[mtyp] && meMEt[mtyp]->getRootObject()) {
      QReport_MEt[mtyp][0] = meMEt[mtyp]->getQReport("meanMETTest");
      QReport_MEt[mtyp][1] = meMEt[mtyp]->getQReport("KolmogorovTest");
    }

    if (meSumEt[mtyp] && meSumEt[mtyp]->getRootObject()) {
      QReport_SumEt[mtyp][0] = meSumEt[mtyp]->getQReport("meanSumETTest");
      QReport_SumEt[mtyp][1] = meSumEt[mtyp]->getQReport("KolmogorovTest");
    }

    if (meMETPhi[mtyp] && meMETPhi[mtyp]->getRootObject()) {
      QReport_METPhi[mtyp][0] = meMETPhi[mtyp]->getQReport("phiQTest");
      QReport_METPhi[mtyp][1] = meMETPhi[mtyp]->getQReport("KolmogorovTest");
    }
    for (int testtyp = 0; testtyp < 2; ++testtyp) {
      //MEx test
      if (QReport_MExy[mtyp][testtyp][0]) {
        if (QReport_MExy[mtyp][testtyp][0]->getStatus() == 100 || QReport_MExy[mtyp][testtyp][0]->getStatus() == 200)
          qr_MET_MExy[mtyp][testtyp][0] = 1;
        else if (QReport_MExy[mtyp][testtyp][0]->getStatus() == 300)
          qr_MET_MExy[mtyp][testtyp][0] = 0;
        else
          qr_MET_MExy[mtyp][testtyp][0] = -1;
      } else
        qr_MET_MExy[mtyp][testtyp][0] = -2;
      //MEy test
      if (QReport_MExy[mtyp][testtyp][1]) {
        if (QReport_MExy[mtyp][testtyp][1]->getStatus() == 100 || QReport_MExy[mtyp][testtyp][1]->getStatus() == 200)
          qr_MET_MExy[mtyp][testtyp][1] = 1;
        else if (QReport_MExy[mtyp][testtyp][1]->getStatus() == 300)
          qr_MET_MExy[mtyp][testtyp][1] = 0;
        else
          qr_MET_MExy[mtyp][testtyp][1] = -1;
      } else
        qr_MET_MExy[mtyp][testtyp][1] = -2;

      //MEt test
      if (QReport_MEt[mtyp][testtyp]) {
        if (QReport_MEt[mtyp][testtyp]->getStatus() == 100 || QReport_MEt[mtyp][testtyp]->getStatus() == 200)
          qr_MET_MEt[mtyp][testtyp] = 1;
        else if (QReport_MEt[mtyp][testtyp]->getStatus() == 300)
          qr_MET_MEt[mtyp][testtyp] = 0;
        else
          qr_MET_MEt[mtyp][testtyp] = -1;
      } else {
        qr_MET_MEt[mtyp][testtyp] = -2;
      }
      //SumEt test
      if (QReport_SumEt[mtyp][testtyp]) {
        if (QReport_SumEt[mtyp][testtyp]->getStatus() == 100 || QReport_SumEt[mtyp][testtyp]->getStatus() == 200)
          qr_MET_SumEt[mtyp][testtyp] = 1;
        else if (QReport_SumEt[mtyp][testtyp]->getStatus() == 300)
          qr_MET_SumEt[mtyp][testtyp] = 0;
        else
          qr_MET_SumEt[mtyp][testtyp] = -1;
      } else {
        qr_MET_SumEt[mtyp][testtyp] = -2;
      }
      //METPhi test
      if (QReport_METPhi[mtyp][testtyp]) {
        if (QReport_METPhi[mtyp][testtyp]->getStatus() == 100 || QReport_METPhi[mtyp][testtyp]->getStatus() == 200)
          qr_MET_METPhi[mtyp][testtyp] = 1;
        else if (QReport_METPhi[mtyp][testtyp]->getStatus() == 300)
          qr_MET_METPhi[mtyp][testtyp] = 0;
        else
          qr_MET_METPhi[mtyp][testtyp] = -1;
      } else {
        qr_MET_METPhi[mtyp][testtyp] = -2;
      }
    }

    if (verbose_) {
      //certification result for MET
      printf("====================MET Type %d QTest Report Summary========================\n", mtyp);
      printf("MEx test    MEy test    MEt test:    SumEt test:    METPhi test:\n");
      for (int tt = 0; tt < 2; ++tt) {
        printf("%2.2f    %2.2f    %2.2f    %2.2f    %2.2f\n",
               qr_MET_MExy[mtyp][tt][0],
               qr_MET_MExy[mtyp][tt][1],
               qr_MET_MEt[mtyp][tt],
               qr_MET_SumEt[mtyp][tt],
               qr_MET_METPhi[mtyp][tt]);
      }
      printf("===========================================================================\n");
    }

    //Only apply certain tests, as defined in the config
    for (int ttyp = 0; ttyp < 2; ++ttyp) {
      if (!metTests[mtyp][ttyp]) {
        qr_MET_MExy[mtyp][ttyp][0] = 1;
        qr_MET_MExy[mtyp][ttyp][1] = 1;
        qr_MET_MEt[mtyp][ttyp] = 1;
        qr_MET_SumEt[mtyp][ttyp] = 1;
        qr_MET_METPhi[mtyp][ttyp] = 1;
      }
    }

    if ((qr_MET_MExy[mtyp][0][0] == 0) || (qr_MET_MExy[mtyp][0][1] == 0) || (qr_MET_MEt[mtyp][0] == 0) ||
        (qr_MET_SumEt[mtyp][0] == 0) || (qr_MET_METPhi[mtyp][0] == 0) || (qr_MET_MExy[mtyp][1][0] == 0) ||
        (qr_MET_MExy[mtyp][1][1] == 0) || (qr_MET_MEt[mtyp][1] == 0) || (qr_MET_SumEt[mtyp][1] == 0) ||
        (qr_MET_METPhi[mtyp][1] == 0))
      dc_MET[mtyp] = 0;
    else if ((qr_MET_MExy[mtyp][0][0] == -1) && (qr_MET_MExy[mtyp][0][1] == -1) && (qr_MET_MEt[mtyp][0] == -1) &&
             (qr_MET_SumEt[mtyp][0] == -1) && (qr_MET_METPhi[mtyp][0] == -1) && (qr_MET_MExy[mtyp][1][0] == -1) &&
             (qr_MET_MExy[mtyp][1][1] == -1) && (qr_MET_MEt[mtyp][1] == -1) && (qr_MET_SumEt[mtyp][1] == -1) &&
             (qr_MET_METPhi[mtyp][1] == -1))
      dc_MET[mtyp] = -1;
    else if ((qr_MET_MExy[mtyp][0][0] == -2) && (qr_MET_MExy[mtyp][0][1] == -2) && (qr_MET_MEt[mtyp][0] == -2) &&
             (qr_MET_SumEt[mtyp][0] == -2) && (qr_MET_METPhi[mtyp][0] == -2) && (qr_MET_MExy[mtyp][1][0] == -2) &&
             (qr_MET_MExy[mtyp][1][1] == -2) && (qr_MET_MEt[mtyp][1] == -2) && (qr_MET_SumEt[mtyp][1] == -2) &&
             (qr_MET_METPhi[mtyp][1] == -2))
      dc_MET[mtyp] = -2;
    else
      dc_MET[mtyp] = 1;

    if (verbose_)
      std::cout << "Certifying MET algo: " << mtyp << " with value: " << dc_MET[mtyp] << std::endl;
    CertificationSummaryMap->Fill(1, 4 - mtyp, dc_MET[mtyp]);
    reportSummaryMap->Fill(1, 4 - mtyp, dc_MET[mtyp]);
  }

  // There is nothing on the first three rows for HI, so mark them unfilled
  if (isHI) {
    for (int i = 0; i < 3; i++) {
      CertificationSummaryMap->Fill(1, i, -2);
      reportSummaryMap->Fill(1, i, -2);
    }
  }

  //----------------------------------------------------------------------------
  //--- Extract quality test results and fill data certification results for MET
  //----------------------------------------------------------------------------
  // Commenting out unused but initialized variables. [Suchandra Dutta]
  float dc_CT[3] = {-2.};
  dc_CT[0] = -2.;
  dc_CT[1] = -2.;
  dc_CT[2] = -2.;

  for (int cttyp = 0; cttyp < 3; ++cttyp) {
    if (verbose_)
      std::cout << "Certifying CaloTowers with value: " << dc_CT[cttyp] << std::endl;
    CertificationSummaryMap->Fill(0, 4 - cttyp, dc_CT[cttyp]);
    reportSummaryMap->Fill(0, 4 - cttyp, dc_CT[cttyp]);
  }
  ibook_.setCurrentFolder("");
}

//define this as a plug-in
//DEFINE_FWK_MODULE(DataCertificationJetMET);