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Public Member Functions | Protected Attributes | Private Member Functions | Private Attributes

GenericBenchmark Class Reference

#include <GenericBenchmark.h>

Inheritance diagram for GenericBenchmark:
GenericBenchmarkAnalyzer

List of all members.

Public Member Functions

template<typename C >
void fill (const C *RecoCollection, const C *GenCollection, bool startFromGen=false, bool PlotAgainstReco=true, bool onlyTwoJets=false, double recPt_cut=-1., double minEta_cut=-1., double maxEta_cut=-1., double deltaR_cut=-1.)
 GenericBenchmark ()
void setfile (TFile *file)
void setup (DQMStore *DQM=NULL, bool PlotAgainstReco_=true, float minDeltaEt=-100., float maxDeltaEt=50., float minDeltaPhi=-0.5, float maxDeltaPhi=0.5, bool doMetPlots=false)
void write (std::string Filename)
virtual ~GenericBenchmark ()

Protected Attributes

PFBenchmarkAlgoalgo_
DQMStoredbe_

Private Member Functions

bool accepted (const reco::Candidate *particle, double ptCut, double minEtaCut, double maxEtaCut) const
void fillHistos (const reco::Candidate *genParticle, const reco::Candidate *recParticle, double deltaR_cut, bool plotAgainstReco)

Private Attributes

bool doMetPlots_
TFile * file_
TH1F * hDeltaEt
TH1F * hDeltaEta
TH2F * hDeltaEtavsEt
TH2F * hDeltaEtavsEta
TH2F * hDeltaEtOverEtvsDeltaR
TH2F * hDeltaEtOverEtvsEt
TH2F * hDeltaEtOverEtvsEta
TH2F * hDeltaEtOverEtvsPhi
TH2F * hDeltaEtvsDeltaR
TH2F * hDeltaEtvsEt
TH2F * hDeltaEtvsEta
TH2F * hDeltaEtvsPhi
TH1F * hDeltaEx
TH1F * hDeltaEy
TH2F * hDeltaMexvsSet
TH1F * hDeltaPhi
TH2F * hDeltaPhivsEt
TH2F * hDeltaPhivsEta
TH1F * hDeltaR
TH2F * hDeltaRvsEt
TH2F * hDeltaRvsEta
TH2F * hDeltaSetOverSetvsSet
TH2F * hDeltaSetvsSet
TH1F * hEtaGen
TH1F * hEtaSeen
TH1F * hEtGen
TH1F * hEtRec
TH2F * hEtRecOverTrueEtvsTrueEt
TH2F * hEtRecvsEt
TH1F * hEtSeen
TH2F * hEtvsEtaGen
TH2F * hEtvsEtaSeen
TH2F * hEtvsPhiGen
TH2F * hEtvsPhiSeen
TH1F * hExRec
TH1F * hEyRec
TH1F * hNGen
TH1F * hNRec
TH1F * hPhiGen
TH1F * hPhiRec
TH1F * hPhiSeen
TH2F * hRecSetOverTrueSetvsTrueSet
TH2F * hRecSetvsTrueSet
TH1F * hSumEt
TH2F * hTrueMexvsTrueSet
TH1F * hTrueSumEt
BenchmarkTreetree_

Detailed Description

Definition at line 24 of file GenericBenchmark.h.


Constructor & Destructor Documentation

GenericBenchmark::GenericBenchmark ( )

Definition at line 37 of file GenericBenchmark.cc.

{}
GenericBenchmark::~GenericBenchmark ( ) [virtual]

Definition at line 39 of file GenericBenchmark.cc.

{}

Member Function Documentation

bool GenericBenchmark::accepted ( const reco::Candidate particle,
double  ptCut,
double  minEtaCut,
double  maxEtaCut 
) const [private]

Definition at line 288 of file GenericBenchmark.cc.

References reco::Candidate::eta(), and reco::Candidate::pt().

Referenced by fill().

                                                         {
 
  //skip reconstructed PFJets with p_t < recPt_cut
  if (particle->pt() < ptCut and ptCut != -1.)
    return false;

  if (fabs(particle->eta())>maxEtaCut and maxEtaCut > 0)
    return false;
  if (fabs(particle->eta())<minEtaCut and minEtaCut > 0)
    return false;

  //accepted!
  return true;
 
}
template<typename C >
void GenericBenchmark::fill ( const C *  RecoCollection,
const C *  GenCollection,
bool  startFromGen = false,
bool  PlotAgainstReco = true,
bool  onlyTwoJets = false,
double  recPt_cut = -1.,
double  minEta_cut = -1.,
double  maxEta_cut = -1.,
double  deltaR_cut = -1. 
)

Definition at line 137 of file GenericBenchmark.h.

References accepted(), algo_, deltaR(), PFBenchmarkAlgo::deltaR(), reco::Candidate::et(), reco::Candidate::eta(), fillHistos(), hEtaGen, hEtaSeen, hEtGen, hEtRec, hEtRecOverTrueEtvsTrueEt, hEtRecvsEt, hEtSeen, hEtvsEtaGen, hEtvsEtaSeen, hEtvsPhiGen, hEtvsPhiSeen, hExRec, hEyRec, hNGen, hNRec, hPhiGen, hPhiRec, hPhiSeen, i, j, PFBenchmarkAlgo::matchByDeltaR(), NULL, reco::Candidate::phi(), reco::Candidate::pt(), reco::Candidate::px(), and reco::Candidate::py().

                                               {

  //if (doMetPlots_)
  //{
  //  const reco::MET* met1=static_cast<const reco::MET*>(&((*RecoCollection)[0]));
  //  if (met1!=NULL) std::cout << "FL: met1.sumEt() = " << (*met1).sumEt() << std::endl;
  //}

  // loop over reco particles

  if( !startFromGen) {
    int nRec = 0;
    for (unsigned int i = 0; i < RecoCollection->size(); i++) {
      
      // generate histograms comparing the reco and truth candidate (truth = closest in delta-R)
      const reco::Candidate *particle = &(*RecoCollection)[i];
      
      assert( particle!=NULL ); 
      if( !accepted(particle, recPt_cut, 
                    minEta_cut, maxEta_cut)) continue;

    
      // Count the number of jets with a larger energy
      if( onlyTwoJets ) {
        unsigned highJets = 0;
        for(unsigned j=0; j<RecoCollection->size(); j++) { 
          const reco::Candidate *otherParticle = &(*RecoCollection)[j];
          if ( j != i && otherParticle->pt() > particle->pt() ) highJets++;
        }
        if ( highJets > 1 ) continue;
      }         
      nRec++;
      
      const reco::Candidate *gen_particle = algo_->matchByDeltaR(particle,
                                                                 GenCollection);
      if(gen_particle==NULL) continue; 



      // fill histograms
      fillHistos( gen_particle, particle, deltaR_cut, PlotAgainstReco);
    }

    hNRec->Fill(nRec);
  }

  // loop over gen particles
  
  //   std::cout<<"Reco size = "<<RecoCollection->size()<<", ";
  //   std::cout<<"Gen size = "<<GenCollection->size()<<std::endl;

  int nGen = 0;
  for (unsigned int i = 0; i < GenCollection->size(); i++) {

    const reco::Candidate *gen_particle = &(*GenCollection)[i]; 

    if( !accepted(gen_particle, recPt_cut, minEta_cut, maxEta_cut)) {
      continue;
    }

    hEtaGen->Fill(gen_particle->eta() );
    hPhiGen->Fill(gen_particle->phi() );
    hEtGen->Fill(gen_particle->et() );
    hEtvsEtaGen->Fill(gen_particle->eta(),gen_particle->et() );
    hEtvsPhiGen->Fill(gen_particle->phi(),gen_particle->et() );

    const reco::Candidate *rec_particle = algo_->matchByDeltaR(gen_particle,
                                                               RecoCollection);
    nGen++;
    if(! rec_particle) continue; // no match
    // must make a cut on delta R - so let's do the cut

    double deltaR = algo_->deltaR(rec_particle,gen_particle);
    if (deltaR>deltaR_cut && deltaR_cut != -1.)
      continue;
    
    hEtaSeen->Fill(gen_particle->eta() );
    hPhiSeen->Fill(gen_particle->phi() );
    hEtSeen->Fill(gen_particle->et() );
    hEtvsEtaSeen->Fill(gen_particle->eta(),gen_particle->et() );
    hEtvsPhiSeen->Fill(gen_particle->phi(),gen_particle->et() );

    hPhiRec->Fill(rec_particle->phi() );
    hEtRec->Fill(rec_particle->et() );
    hExRec->Fill(rec_particle->px() );
    hEyRec->Fill(rec_particle->py() );

    hEtRecvsEt->Fill(gen_particle->et(),rec_particle->et());
    if (gen_particle->et()!=0.0) hEtRecOverTrueEtvsTrueEt->Fill(gen_particle->et(),rec_particle->et()/gen_particle->et());

    if( startFromGen ) 
      fillHistos( gen_particle, rec_particle, deltaR_cut, PlotAgainstReco);

    
  }
  hNGen->Fill(nGen);

}
void GenericBenchmark::fillHistos ( const reco::Candidate genParticle,
const reco::Candidate recParticle,
double  deltaR_cut,
bool  plotAgainstReco 
) [private]

Definition at line 308 of file GenericBenchmark.cc.

References gather_cfg::cout, BenchmarkTreeEntry::deltaEt, BenchmarkTreeEntry::deltaEta, Geom::deltaPhi(), deltaR(), BenchmarkTreeEntry::et, reco::Candidate::et(), BenchmarkTreeEntry::eta, eta(), reco::Candidate::eta(), NULL, phi, reco::Candidate::phi(), reco::Candidate::px(), and reco::Candidate::py().

Referenced by fill().

                                                          {

  // get the quantities to place on the denominator and/or divide by
  double et = genParticle->et();
  double eta = genParticle->eta();
  double phi = genParticle->phi();
  //std::cout << "FL : et = " << et << std::endl;
  //std::cout << "FL : eta = " << eta << std::endl;
  //std::cout << "FL : phi = " << phi << std::endl;
  //std::cout << "FL : rec et = " << recParticle->et() << std::endl;
  //std::cout << "FL : rec eta = " << recParticle->eta() << std::endl;
  //std::cout << "FL : rec phi = " <<recParticle-> phi() << std::endl;

  if (plotAgainstReco) { 
    et = recParticle->et(); 
    eta = recParticle->eta(); 
    phi = recParticle->phi(); 
  }
  
    
  // get the delta quantities
  double deltaEt = algo_->deltaEt(recParticle,genParticle);
  double deltaR = algo_->deltaR(recParticle,genParticle);
  double deltaEta = algo_->deltaEta(recParticle,genParticle);
  double deltaPhi = algo_->deltaPhi(recParticle,genParticle);
   
  //std::cout << "FL :deltaR_cut = " << deltaR_cut << std::endl;
  //std::cout << "FL :deltaR = " << deltaR << std::endl;

  if (deltaR>deltaR_cut && deltaR_cut != -1.)
    return;  

  hDeltaEt->Fill(deltaEt);
  hDeltaEx->Fill(recParticle->px()-genParticle->px());
  hDeltaEy->Fill(recParticle->py()-genParticle->py());
  hDeltaEtvsEt->Fill(et,deltaEt);
  hDeltaEtOverEtvsEt->Fill(et,deltaEt/et);
  hDeltaEtvsEta->Fill(eta,deltaEt);
  hDeltaEtOverEtvsEta->Fill(eta,deltaEt/et);
  hDeltaEtvsPhi->Fill(phi,deltaEt);
  hDeltaEtOverEtvsPhi->Fill(phi,deltaEt/et);
  hDeltaEtvsDeltaR->Fill(deltaR,deltaEt);
  hDeltaEtOverEtvsDeltaR->Fill(deltaR,deltaEt/et);
    
  hDeltaEta->Fill(deltaEta);
  hDeltaEtavsEt->Fill(et,deltaEta);
  hDeltaEtavsEta->Fill(eta,deltaEta);
    
  hDeltaPhi->Fill(deltaPhi);
  hDeltaPhivsEt->Fill(et,deltaPhi);
  hDeltaPhivsEta->Fill(eta,deltaPhi);

  hDeltaR->Fill(deltaR);
  hDeltaRvsEt->Fill(et,deltaR);
  hDeltaRvsEta->Fill(eta,deltaR);

  BenchmarkTreeEntry entry;
  entry.deltaEt = deltaEt;
  entry.deltaEta = deltaEta;
  entry.et = et;
  entry.eta = eta;

  if (doMetPlots_)
  {
    const reco::MET* met1=static_cast<const reco::MET*>(genParticle);
    const reco::MET* met2=static_cast<const reco::MET*>(recParticle);
    if (met1!=NULL && met2!=NULL)
    {
      //std::cout << "FL: met1.sumEt() = " << (*met1).sumEt() << std::endl;
      hTrueSumEt->Fill((*met1).sumEt());
      hSumEt->Fill((*met2).sumEt());
      hDeltaSetvsSet->Fill((*met1).sumEt(),(*met2).sumEt()-(*met1).sumEt());
      hDeltaMexvsSet->Fill((*met1).sumEt(),recParticle->px()-genParticle->px());
      hDeltaMexvsSet->Fill((*met1).sumEt(),recParticle->py()-genParticle->py());
      if ((*met1).sumEt()>0.01) hDeltaSetOverSetvsSet->Fill((*met1).sumEt(),((*met2).sumEt()-(*met1).sumEt())/(*met1).sumEt());
      hRecSetvsTrueSet->Fill((*met1).sumEt(),(*met2).sumEt());
      hRecSetOverTrueSetvsTrueSet->Fill((*met1).sumEt(),(*met2).sumEt()/((*met1).sumEt()));
      hTrueMexvsTrueSet->Fill((*met1).sumEt(),(*met1).px());
      hTrueMexvsTrueSet->Fill((*met1).sumEt(),(*met1).py());
    }
    else
    {
      std::cout << "Warning : reco::MET* == NULL" << std::endl;
    }
  }

  //     tree_->Fill(entry);

}
void GenericBenchmark::setfile ( TFile *  file)

Definition at line 408 of file GenericBenchmark.cc.

References mergeVDriftHistosByStation::file.

Referenced by METManager::addGenBenchmark().

{
  file_=file;
}
void GenericBenchmark::setup ( DQMStore DQM = NULL,
bool  PlotAgainstReco_ = true,
float  minDeltaEt = -100.,
float  maxDeltaEt = 50.,
float  minDeltaPhi = -0.5,
float  maxDeltaPhi = 0.5,
bool  doMetPlots = false 
)

Definition at line 41 of file GenericBenchmark.cc.

References BOOK1D, BOOK2D, DQMStore::cd(), gather_cfg::cout, debug, benchmark_cfg::doMetPlots, ET, ETA, mergeVDriftHistosByStation::file, M_PI, CommPDSkim_cfg::maxDeltaEta, maxEta, benchmark_cfg::minEta, PHI, DQMStore::pwd(), and SETAXES.

Referenced by METManager::addGenBenchmark().

                                                                                    {

  //std::cout << "minDeltaPhi = " << minDeltaPhi << std::endl;

  // CMSSW_2_X_X
  // use bare Root if no DQM (FWLite applications)
  //if (!DQM)
  //{
  //  file_ = new TFile("pfmetBenchmark.root", "recreate");
  //  cout << "Info: DQM is not available to provide data storage service. Using TFile to save histograms. "<<endl;
  //}
  // Book Histograms

  //std::cout << "FL : pwd = ";
  //gDirectory->pwd();
  //std::cout << std::endl;

  int nbinsEt = 1000;
  float minEt = 0;
  float maxEt = 1000;

  //float minDeltaEt = -100;
  //float maxDeltaEt = 50;

  int nbinsEta = 200;
  float minEta = -5;
  float maxEta = 5;

  int nbinsDeltaEta = 1000;
  float minDeltaEta = -0.5;
  float maxDeltaEta = 0.5;

  int nbinsDeltaPhi = 1000;
  //float minDeltaPhi = -0.5;
  //float maxDeltaPhi = 0.5;


  // delta et quantities
  BOOK1D(DeltaEt,"#DeltaE_{T}", nbinsEt, minDeltaEt, maxDeltaEt);
  BOOK1D(DeltaEx,"#DeltaE_{X}", nbinsEt, minDeltaEt, maxDeltaEt);
  BOOK1D(DeltaEy,"#DeltaE_{Y}", nbinsEt, minDeltaEt, maxDeltaEt);
  BOOK2D(DeltaEtvsEt,"#DeltaE_{T} vs E_{T}",
         nbinsEt, minEt, maxEt,
         nbinsEt,minDeltaEt, maxDeltaEt);
  BOOK2D(DeltaEtOverEtvsEt,"#DeltaE_{T}/E_{T} vsE_{T}",
         nbinsEt, minEt, maxEt,
         nbinsEt,-1,1);
  BOOK2D(DeltaEtvsEta,"#DeltaE_{T} vs #eta",
         nbinsEta, minEta, maxEta,
         nbinsEt,minDeltaEt, maxDeltaEt);
  BOOK2D(DeltaEtOverEtvsEta,"#DeltaE_{T}/E_{T} vs #eta",
         nbinsEta, minEta, maxEta,
         100,-1,1);
  BOOK2D(DeltaEtvsPhi,"#DeltaE_{T} vs #phi",
         200,-M_PI,M_PI,
         nbinsEt,minDeltaEt, maxDeltaEt);
  BOOK2D(DeltaEtOverEtvsPhi,"#DeltaE_{T}/E_{T} vs #Phi",
         200,-M_PI,M_PI,
         100,-1,1);
  BOOK2D(DeltaEtvsDeltaR,"#DeltaE_{T} vs #DeltaR",
         100,0,1,
         nbinsEt,minDeltaEt, maxDeltaEt);
  BOOK2D(DeltaEtOverEtvsDeltaR,"#DeltaE_{T}/E_{T} vs #DeltaR",
         100,0,1,
         100,-1,1);

  // delta eta quantities
  BOOK1D(DeltaEta,"#Delta#eta",nbinsDeltaEta,minDeltaEta,maxDeltaEta);
  BOOK2D(DeltaEtavsEt,"#Delta#eta vs E_{T}",
         nbinsEt, minEt, maxEt,
         nbinsDeltaEta,minDeltaEta,maxDeltaEta);
  BOOK2D(DeltaEtavsEta,"#Delta#eta vs #eta",
         nbinsEta, minEta, maxEta,
         nbinsDeltaEta,minDeltaEta,maxDeltaEta);

  // delta phi quantities
  BOOK1D(DeltaPhi,"#Delta#phi",nbinsDeltaPhi,minDeltaPhi,maxDeltaPhi);
  BOOK2D(DeltaPhivsEt,"#Delta#phi vs E_{T}",
         nbinsEt, minEt, maxEt,
         nbinsDeltaPhi,minDeltaPhi,maxDeltaPhi);
  BOOK2D(DeltaPhivsEta,"#Delta#phi vs #eta",
         nbinsEta, minEta, maxEta,
         nbinsDeltaPhi,minDeltaPhi,maxDeltaPhi);

  // delta R quantities
  BOOK1D(DeltaR,"#DeltaR",100,0,1);
  BOOK2D(DeltaRvsEt,"#DeltaR vs E_{T}",
         nbinsEt, minEt, maxEt,
         100,0,1);
  BOOK2D(DeltaRvsEta,"#DeltaR vs #eta",
         nbinsEta, minEta, maxEta,
         100,0,1);

  BOOK1D(NRec,"Number of reconstructed objects",20,0,20);

  // seen and gen distributions, for efficiency computation
  BOOK1D(EtaSeen,"seen #eta",100,-5,5);
  BOOK1D(PhiSeen,"seen #phi",100,-3.5,3.5);
  BOOK1D(EtSeen,"seen E_{T}",nbinsEt, minEt, maxEt);
  BOOK2D(EtvsEtaSeen,"seen E_{T} vs eta",100,-5,5,200, 0, 200);
  BOOK2D(EtvsPhiSeen,"seen E_{T} vs seen #phi",100,-3.5,3.5,200, 0, 200);  

  BOOK1D(PhiRec,"Rec #phi",100,-3.5,3.5);
  BOOK1D(EtRec,"Rec E_{T}",nbinsEt, minEt, maxEt);
  BOOK1D(ExRec,"Rec E_{X}",nbinsEt, -maxEt, maxEt);
  BOOK1D(EyRec,"Rec E_{Y}",nbinsEt, -maxEt, maxEt);

  BOOK2D(EtRecvsEt,"Rec E_{T} vs E_{T}",
         nbinsEt, minEt, maxEt,
         nbinsEt, minEt, maxEt);
  BOOK2D(EtRecOverTrueEtvsTrueEt,"Rec E_{T} / E_{T} vs E_{T}",
         nbinsEt, minEt, maxEt,
         1000, 0., 100.);

  BOOK1D(EtaGen,"generated #eta",100,-5,5);
  BOOK1D(PhiGen,"generated #phi",100,-3.5,3.5);
  BOOK1D(EtGen,"generated E_{T}",nbinsEt, minEt, maxEt);
  BOOK2D(EtvsEtaGen,"generated E_{T} vs generated #eta",100,-5,5,200, 0, 200);  
  BOOK2D(EtvsPhiGen,"generated E_{T} vs generated #phi",100,-3.5,3.5, 200, 0, 200);  

  BOOK1D(NGen,"Number of generated objects",20,0,20);

  if (doMetPlots)
  {
    BOOK1D(SumEt,"SumEt", 1000, 0., 3000.);
    BOOK1D(TrueSumEt,"TrueSumEt", 1000, 0., 3000.);
    BOOK2D(DeltaSetvsSet,"#DeltaSEt vs trueSEt",
           3000, 0., 3000.,
           1000,-1000., 1000.);
    BOOK2D(DeltaMexvsSet,"#DeltaMEX vs trueSEt",
           3000, 0., 3000.,
           1000,-400., 400.);
    BOOK2D(DeltaSetOverSetvsSet,"#DeltaSetOverSet vs trueSet",
           3000, 0., 3000.,
           1000,-1., 1.);
    BOOK2D(RecSetvsTrueSet,"Set vs trueSet",
           3000, 0., 3000.,
           3000,0., 3000.);
    BOOK2D(RecSetOverTrueSetvsTrueSet,"Set/trueSet vs trueSet",
           3000, 0., 3000.,
           500,0., 2.);
    BOOK2D(TrueMexvsTrueSet,"trueMex vs trueSet",
           3000,0., 3000.,
           nbinsEt, -maxEt, maxEt);
  }
  // number of truth particles found within given cone radius of reco
  //BOOK2D(NumInConeVsConeSize,NumInConeVsConeSize,100,0,1,25,0,25);

  // Set Axis Titles
 
  // delta et quantities
  SETAXES(DeltaEt,"#DeltaE_{T} [GeV]","");
  SETAXES(DeltaEx,"#DeltaE_{X} [GeV]","");
  SETAXES(DeltaEy,"#DeltaE_{Y} [GeV]","");
  SETAXES(DeltaEtvsEt,ET,"#DeltaE_{T} [GeV]");
  SETAXES(DeltaEtOverEtvsEt,ET,"#DeltaE_{T}/E_{T}");
  SETAXES(DeltaEtvsEta,ETA,"#DeltaE_{T} [GeV]");
  SETAXES(DeltaEtOverEtvsEta,ETA,"#DeltaE_{T}/E_{T}");
  SETAXES(DeltaEtvsPhi,PHI,"#DeltaE_{T} [GeV]");
  SETAXES(DeltaEtOverEtvsPhi,PHI,"#DeltaE_{T}/E_{T}");
  SETAXES(DeltaEtvsDeltaR,"#DeltaR","#DeltaE_{T} [GeV]");
  SETAXES(DeltaEtOverEtvsDeltaR,"#DeltaR","#DeltaE_{T}/E_{T}");

  // delta eta quantities
  SETAXES(DeltaEta,"#Delta#eta","Events");
  SETAXES(DeltaEtavsEt,ET,"#Delta#eta");
  SETAXES(DeltaEtavsEta,ETA,"#Delta#eta");

  // delta phi quantities
  SETAXES(DeltaPhi,"#Delta#phi [rad]","Events");
  SETAXES(DeltaPhivsEt,ET,"#Delta#phi [rad]");
  SETAXES(DeltaPhivsEta,ETA,"#Delta#phi [rad]");

  // delta R quantities
  SETAXES(DeltaR,"#DeltaR","Events");
  SETAXES(DeltaRvsEt,ET,"#DeltaR");
  SETAXES(DeltaRvsEta,ETA,"#DeltaR");

  SETAXES(NRec,"Number of Rec Objects","");
  
  SETAXES(EtaSeen,"seen #eta","");
  SETAXES(PhiSeen,"seen #phi [rad]","");
  SETAXES(EtSeen,"seen E_{T} [GeV]","");
  SETAXES(EtvsEtaSeen,"seen #eta","seen E_{T}");
  SETAXES(EtvsPhiSeen,"seen #phi [rad]","seen E_{T}");

  SETAXES(PhiRec,"#phi [rad]","");
  SETAXES(EtRec,"E_{T} [GeV]","");
  SETAXES(ExRec,"E_{X} [GeV]","");
  SETAXES(EyRec,"E_{Y} [GeV]","");
  SETAXES(EtRecvsEt,ET,"Rec E_{T} [GeV]");
  SETAXES(EtRecOverTrueEtvsTrueEt,ET,"Rec E_{T} / E_{T} [GeV]");

  SETAXES(EtaGen,"generated #eta","");
  SETAXES(PhiGen,"generated #phi [rad]","");
  SETAXES(EtGen,"generated E_{T} [GeV]","");
  SETAXES(EtvsPhiGen,"generated #phi [rad]","generated E_{T} [GeV]");
  SETAXES(EtvsEtaGen,"generated #eta","generated E_{T} [GeV]");

  SETAXES(NGen,"Number of Gen Objects","");
  
  if (doMetPlots)
  {
    SETAXES(SumEt,"SumEt [GeV]","");
    SETAXES(TrueSumEt,"TrueSumEt [GeV]","");
    SETAXES(DeltaSetvsSet,"TrueSumEt","#DeltaSumEt [GeV]");
    SETAXES(DeltaMexvsSet,"TrueSumEt","#DeltaMEX [GeV]");
    SETAXES(DeltaSetOverSetvsSet,"TrueSumEt","#DeltaSumEt/trueSumEt");
    SETAXES(RecSetvsTrueSet,"TrueSumEt","SumEt");
    SETAXES(RecSetOverTrueSetvsTrueSet,"TrueSumEt","SumEt/trueSumEt");
    SETAXES(TrueMexvsTrueSet,"TrueSumEt","TrueMEX");
  }

  TDirectory* oldpwd = gDirectory;


  TIter next( gROOT->GetListOfFiles() );

  const bool debug=false;

  while ( TFile *file = (TFile *)next() )
  {
    if (debug) cout<<"file "<<file->GetName()<<endl;
  }
  if (DQM)
  {
    cout<<"DQM subdir"<<endl;
    cout<< DQM->pwd().c_str()<<endl;

    DQM->cd( DQM->pwd() );
  }

  if (debug)
  {
    cout<<"current dir"<<endl;
    gDirectory->pwd();
  }
  
  oldpwd->cd();
  //gDirectory->pwd();

  doMetPlots_=doMetPlots;

  //   tree_ = new BenchmarkTree("genericBenchmark", "Generic Benchmark TTree");
}
void GenericBenchmark::write ( std::string  Filename)

Definition at line 401 of file GenericBenchmark.cc.

                                               {

  if (Filename.size() != 0 && file_)
    file_->Write(Filename.c_str());

}

Member Data Documentation

Definition at line 132 of file GenericBenchmark.h.

Referenced by fill().

Definition at line 131 of file GenericBenchmark.h.

Reimplemented in GenericBenchmarkAnalyzer.

Definition at line 127 of file GenericBenchmark.h.

TFile* GenericBenchmark::file_ [private]

Definition at line 65 of file GenericBenchmark.h.

TH1F* GenericBenchmark::hDeltaEt [private]

Definition at line 67 of file GenericBenchmark.h.

TH1F* GenericBenchmark::hDeltaEta [private]

Definition at line 82 of file GenericBenchmark.h.

Definition at line 83 of file GenericBenchmark.h.

Definition at line 84 of file GenericBenchmark.h.

Definition at line 77 of file GenericBenchmark.h.

Definition at line 71 of file GenericBenchmark.h.

Definition at line 73 of file GenericBenchmark.h.

Definition at line 75 of file GenericBenchmark.h.

Definition at line 76 of file GenericBenchmark.h.

Definition at line 70 of file GenericBenchmark.h.

Definition at line 72 of file GenericBenchmark.h.

Definition at line 74 of file GenericBenchmark.h.

TH1F* GenericBenchmark::hDeltaEx [private]

Definition at line 68 of file GenericBenchmark.h.

TH1F* GenericBenchmark::hDeltaEy [private]

Definition at line 69 of file GenericBenchmark.h.

Definition at line 119 of file GenericBenchmark.h.

TH1F* GenericBenchmark::hDeltaPhi [private]

Definition at line 86 of file GenericBenchmark.h.

Definition at line 87 of file GenericBenchmark.h.

Definition at line 88 of file GenericBenchmark.h.

TH1F* GenericBenchmark::hDeltaR [private]

Definition at line 90 of file GenericBenchmark.h.

Definition at line 91 of file GenericBenchmark.h.

Definition at line 92 of file GenericBenchmark.h.

Definition at line 120 of file GenericBenchmark.h.

Definition at line 118 of file GenericBenchmark.h.

TH1F* GenericBenchmark::hEtaGen [private]

Definition at line 98 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hEtaSeen [private]

Definition at line 106 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hEtGen [private]

Definition at line 97 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hEtRec [private]

Definition at line 111 of file GenericBenchmark.h.

Referenced by fill().

Definition at line 80 of file GenericBenchmark.h.

Referenced by fill().

Definition at line 79 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hEtSeen [private]

Definition at line 105 of file GenericBenchmark.h.

Referenced by fill().

Definition at line 99 of file GenericBenchmark.h.

Referenced by fill().

Definition at line 108 of file GenericBenchmark.h.

Referenced by fill().

Definition at line 100 of file GenericBenchmark.h.

Referenced by fill().

Definition at line 109 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hExRec [private]

Definition at line 112 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hEyRec [private]

Definition at line 113 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hNGen [private]

Definition at line 103 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hNRec [private]

Definition at line 94 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hPhiGen [private]

Definition at line 101 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hPhiRec [private]

Definition at line 114 of file GenericBenchmark.h.

Referenced by fill().

TH1F* GenericBenchmark::hPhiSeen [private]

Definition at line 107 of file GenericBenchmark.h.

Referenced by fill().

Definition at line 122 of file GenericBenchmark.h.

Definition at line 121 of file GenericBenchmark.h.

TH1F* GenericBenchmark::hSumEt [private]

Definition at line 116 of file GenericBenchmark.h.

Definition at line 123 of file GenericBenchmark.h.

Definition at line 117 of file GenericBenchmark.h.

Definition at line 125 of file GenericBenchmark.h.