Exemplo n.º 1
0
void drawArrowPlot(TChain *mc, TString varU, TString deltaU, TString varV, TString deltaV, Int_t nbinU, Double_t minU, Double_t maxU, Int_t nbinV, Double_t minV, Double_t maxV){

  TString uvname = generateRandomName();
  TString uname = generateRandomName();
  TString vname = generateRandomName();
  TH2D * UV = new TH2D(uvname,uvname,10*nbinU,minU,maxU,10*nbinV,minV,maxV);
  TProfile2D * dU = new TProfile2D(uname,uname,nbinU,minU,maxU,nbinV,minV,maxV);
  TProfile2D * dV = new TProfile2D(vname,vname,nbinU,minU,maxU,nbinV,minV,maxV);

  mc->Draw(varV+":"+varU+">>"+uvname,"(isAssoc==1)","goff");
  mc->Draw(deltaU+":"+varV+":"+varU+">>"+uname,"(isAssoc==1)","goffprof");
  mc->Draw(deltaV+":"+varV+":"+varU+">>"+vname,"(isAssoc==1)","goffprof");
  
  SetFancyGrayscalePalette();
  UV->Draw("colsame");


  for (Int_t iU=1; iU<nbinU+1; iU++){
    for (Int_t iV=1; iV<nbinV+1; iV++){
      
      Double_t uu = dU->GetXaxis()->GetBinCenter(iU);
      Double_t vv = dU->GetYaxis()->GetBinCenter(iV);
      Double_t du = dU->GetBinContent(iU,iV);
      Double_t dv = dV->GetBinContent(iU,iV);
      Double_t due = dU->GetBinError(iU,iV);
      Double_t dve = dV->GetBinError(iU,iV);
      
      drawArrow(uu,vv,du,due,dv,dve);

    }
  }
}
int main (int argc, char **argv)
{
  /// Mc Ntuplas
  TString input = Form("/data1/rgerosa/NTUPLES_FINAL_CALIB/MC/WJetsToLNu_DYJetsToLL_7TeV-madgraph-tauola_Fall11_All.root"); 
  /// MC Calibration result E/p
  TString input2 = Form("/data1/rgerosa/L3_Weight/MC_WJets/EB_Z_recoFlag/WJetsToLNu_DYJetsToLL_7TeV-madgraph-tauola_Fall11_Z_noEP.root"); 

  TApplication* theApp = new TApplication("Application",&argc, argv);

  TFile *f = new TFile(input,"");
  TTree *inputTree = (TTree*)f->Get("ntu");

  TFile *f2 = new TFile(input2,"");
  TH2F *h_scale_EB = (TH2F*)f2->Get("h_scale_EB");
  TH2F *hcmap = (TH2F*) h_scale_EB->Clone("hcmap");
  
  hcmap -> Reset("ICEMS");
  hcmap -> ResetStats();
  
  /// Taking infos

  std::vector<float>* ele1_recHit_E=0;
  std::vector<float>* ele2_recHit_E=0;
  std::vector<int>* ele1_recHit_hashedIndex=0;
  std::vector<int>* ele2_recHit_hashedIndex=0;
  std::vector<int>* ele1_recHit_flag=0;
  std::vector<int>* ele2_recHit_flag=0;
  float ele1_E_true,ele2_E_true;
  float ele1_tkP,ele2_tkP;
  int ele1_isEB, ele2_isEB;
  float   ele1_fbrem,ele2_fbrem;
  int isW, isZ;
  
  inputTree->SetBranchAddress("ele1_recHit_E", &ele1_recHit_E);
  inputTree->SetBranchAddress("ele2_recHit_E", &ele2_recHit_E);
  inputTree->SetBranchAddress("ele1_recHit_hashedIndex", &ele1_recHit_hashedIndex);
  inputTree->SetBranchAddress("ele2_recHit_hashedIndex", &ele2_recHit_hashedIndex);
  inputTree->SetBranchAddress("ele1_recHit_flag", &ele1_recHit_flag);
  inputTree->SetBranchAddress("ele2_recHit_flag", &ele2_recHit_flag);
  inputTree->SetBranchAddress("ele1_E_true", &ele1_E_true);
  inputTree->SetBranchAddress("ele2_E_true", &ele2_E_true);
  inputTree->SetBranchAddress("ele1_tkP", &ele1_tkP);
  inputTree->SetBranchAddress("ele2_tkP", &ele2_tkP);
  inputTree->SetBranchAddress("ele1_isEB", &ele1_isEB);
  inputTree->SetBranchAddress("ele2_isEB", &ele2_isEB);
  inputTree->SetBranchAddress("ele1_fbrem", &ele1_fbrem);
  inputTree->SetBranchAddress("ele2_fbrem", &ele2_fbrem);
  inputTree->SetBranchAddress("isW", &isW);
  inputTree->SetBranchAddress("isZ", &isZ);
 
  TProfile2D* mapMomentum = new TProfile2D("mapMomentum","mapMomentum",360,0,360,170,-85,85);
  TProfile2D* mapfbrem = new TProfile2D("mapfbrem","mapfbrem",360,0,360,170,-85,85);

  /// Make fbrem and p/ptrue map cycling on MC --> all the events 

  for(Long64_t i=0; i< inputTree->GetEntries(); i++)
  {
   inputTree->GetEntry(i);
   if (!(i%100000))std::cerr<<i;
   if (!(i%10000)) std::cerr<<".";
       
   if (ele1_isEB == 1 && (isW==1 || isZ==1)) {
  
      double E_seed=0;
      int seed_hashedIndex, iseed;

      for (unsigned int iRecHit = 0; iRecHit < ele1_recHit_E->size(); iRecHit++ ) {
            
            if(ele1_recHit_E -> at(iRecHit) > E_seed &&  ele1_recHit_flag->at(iRecHit) < 4 ) /// control if this recHit is good
            {
              seed_hashedIndex=ele1_recHit_hashedIndex -> at(iRecHit);
              iseed=iRecHit;
              E_seed=ele1_recHit_E -> at(iRecHit);  ///! Seed search

            }
      }
    
   int eta_seed = GetIetaFromHashedIndex(seed_hashedIndex);
   int phi_seed = GetIphiFromHashedIndex(seed_hashedIndex);
   if(ele1_tkP>0 && ele1_E_true>0 && abs(ele1_tkP/ele1_E_true)<2. && abs(ele1_tkP/ele1_E_true)>0.5) mapMomentum->Fill(phi_seed,eta_seed,abs(ele1_tkP/ele1_E_true));
   mapfbrem->Fill(phi_seed,eta_seed,abs(ele1_fbrem)); 
   }
   
   if (ele2_isEB == 1 && isZ==1) {

      double E_seed=0;
      int seed_hashedIndex, iseed;

      for (unsigned int iRecHit = 0; iRecHit < ele2_recHit_E->size(); iRecHit++ ) {
            
            if(ele2_recHit_E -> at(iRecHit) > E_seed &&  ele2_recHit_flag->at(iRecHit) < 4 ) /// control if this recHit is good
            {
              seed_hashedIndex=ele2_recHit_hashedIndex -> at(iRecHit);
              iseed=iRecHit;
              E_seed=ele2_recHit_E -> at(iRecHit);  ///! Seed search

            }
      }
    
   int eta_seed = GetIetaFromHashedIndex(seed_hashedIndex);
   int phi_seed = GetIphiFromHashedIndex(seed_hashedIndex);
   if(ele2_tkP>0 && ele2_E_true>0 && abs(ele2_tkP/ele2_E_true)<2. && abs(ele2_tkP/ele2_E_true)>0.5) mapMomentum->Fill(phi_seed,eta_seed,abs(ele2_tkP/ele2_E_true));
   mapfbrem->Fill(phi_seed,eta_seed,abs(ele2_fbrem));

   }
 }

 /// Map of IC normalized in eta rings

 std::vector< std::pair<int,int> > TT_centre ;
 
 TT_centre.push_back(std::pair<int,int> (58,49));
 TT_centre.push_back(std::pair<int,int> (53,109));
 TT_centre.push_back(std::pair<int,int> (8,114));
 TT_centre.push_back(std::pair<int,int> (83,169));
 TT_centre.push_back(std::pair<int,int> (53,174));
 TT_centre.push_back(std::pair<int,int> (63,194));
 TT_centre.push_back(std::pair<int,int> (83,224));
 TT_centre.push_back(std::pair<int,int> (73,344));
 TT_centre.push_back(std::pair<int,int> (83,358));
 TT_centre.push_back(std::pair<int,int> (-13,18));
 TT_centre.push_back(std::pair<int,int> (-18,23));
 TT_centre.push_back(std::pair<int,int> (-8,53));
 TT_centre.push_back(std::pair<int,int> (-3,63));
 TT_centre.push_back(std::pair<int,int> (-53,128));
 TT_centre.push_back(std::pair<int,int> (-53,183));
 TT_centre.push_back(std::pair<int,int> (-83,193));
 TT_centre.push_back(std::pair<int,int> (-74,218));
 TT_centre.push_back(std::pair<int,int> (-8,223));
 TT_centre.push_back(std::pair<int,int> (-68,303));
 TT_centre.push_back(std::pair<int,int> (-43,328));
 
 /// Mean over phi corrected skipping dead channel 

 for (int iEta = 1 ; iEta < h_scale_EB->GetNbinsY()+1; iEta ++)
 {
   float SumIC = 0;
   int numIC = 0;
   
   for(int iPhi = 1 ; iPhi < h_scale_EB->GetNbinsX()+1 ; iPhi++)
   {
    bool isGood = CheckxtalIC(h_scale_EB,iPhi,iEta);
    bool isGoodTT = CheckxtalTT(iPhi,iEta,TT_centre);
 
     if(isGood && isGoodTT)
     {
      SumIC = SumIC + h_scale_EB->GetBinContent(iPhi,iEta);
      numIC ++ ;
     }
    }
   //fede: skip bad channels and bad TTs
   for (int iPhi = 1; iPhi< h_scale_EB->GetNbinsX()+1  ; iPhi++)
   { 
     if(numIC==0 || SumIC==0) continue;

     bool isGood = CheckxtalIC(h_scale_EB,iPhi,iEta);
     bool isGoodTT = CheckxtalTT(iPhi,iEta,TT_centre);
     if (!isGood || !isGoodTT) continue;

     hcmap->SetBinContent(iPhi,iEta,h_scale_EB->GetBinContent(iPhi,iEta)/(SumIC/numIC));
   }
  }

 /// ratio map

 TH2F* ratioMap = (TH2F*) hcmap -> Clone("ratioMap");
 ratioMap->Reset();

 for( int i =0 ; i<hcmap->GetNbinsX() ; i++){
  for( int j=0; j<hcmap->GetNbinsY() ; j++){
   if(hcmap->GetBinContent(i,j)!=0 && mapMomentum->GetBinContent(i,j)!=0)
    ratioMap->SetBinContent(i+1,j+1,mapMomentum->GetBinContent(i,j)/hcmap->GetBinContent(i,j));
  }
 }

 /// Profile along phi taking into account dead channels
 TGraphErrors *coeffEBp = new TGraphErrors();
 TGraphErrors *coeffEBm = new TGraphErrors();

 for (int iPhi =1; iPhi< hcmap->GetNbinsX()+1 ; iPhi++){
  double SumEBp =0, SumEBm=0;
  double iEBp=0, iEBm=0;
  for(int iEta = 1; iEta<hcmap->GetNbinsY()+1 ; iEta++){
     if(hcmap->GetBinContent(iPhi,iEta)==0)continue;
     if(iEta>85) {SumEBp=SumEBp+mapMomentum->GetBinContent(iPhi,iEta)/hcmap->GetBinContent(iPhi,iEta);
                  iEBp++;}
     else{ SumEBm=SumEBm+mapMomentum->GetBinContent(iPhi,iEta)/hcmap->GetBinContent(iPhi,iEta);
           iEBm++;}
     }
  coeffEBp->SetPoint(iPhi-1,iPhi-1,SumEBp/iEBp);
  coeffEBm->SetPoint(iPhi-1,iPhi-1,SumEBm/iEBm);

  }
     
 TFile* outputGraph = new TFile("output/GraphFor_P_Correction.root","RECREATE");
 outputGraph->cd();

 coeffEBp->Write("coeffEBp");
 coeffEBm->Write("coeffEBm");
 outputGraph->Close();
     
 gROOT->Reset();
 gROOT->SetStyle("Plain");

 gStyle->SetPadTickX(1);
 gStyle->SetPadTickY(1);
 gStyle->SetOptTitle(1); 
 gStyle->SetOptStat(0); 
 gStyle->SetOptFit(0); 
 gStyle->SetFitFormat("6.3g"); 
 gStyle->SetPalette(1); 
  
 gStyle->SetTextFont(42);
 gStyle->SetTextSize(0.05);
 gStyle->SetTitleFont(42,"xyz");
 gStyle->SetTitleSize(0.05);
 gStyle->SetLabelFont(42,"xyz");
 gStyle->SetLabelSize(0.05);
 gStyle->SetTitleXOffset(0.8);
 gStyle->SetTitleYOffset(1.1);
 gROOT->ForceStyle();
 
 TCanvas* c1 = new TCanvas("mapMomentum","mapMomentum",1);
 c1->cd();
 mapMomentum->GetXaxis()->SetTitle("#phi");
 mapMomentum->GetXaxis()->SetNdivisions(20);
 c1->SetGridx(); 
 mapMomentum->GetYaxis()->SetTitle("#eta");
 mapMomentum->GetZaxis()->SetRangeUser(0.7,1.3);
 mapMomentum->Draw("colz");

 TCanvas* c2 = new TCanvas("mapfbrem","mapfbrem",1);
 c2->cd();
 mapfbrem->GetXaxis()->SetTitle("#phi");
 mapfbrem->GetYaxis()->SetTitle("#eta");
 mapfbrem->GetXaxis()->SetNdivisions(20);
 c2->SetGridx(); 
 mapfbrem->GetZaxis()->SetRangeUser(0.,0.7);
 mapfbrem->Draw("colz");

 TCanvas* c3 = new TCanvas("ratioMap","ratioMap",1);
 c3->cd();
 ratioMap->GetXaxis()->SetTitle("#phi");
 ratioMap->GetYaxis()->SetTitle("#eta");
 ratioMap->GetXaxis()->SetNdivisions(20);
 c3->SetGridx(); 
 ratioMap->GetZaxis()->SetRangeUser(0.7,1.3);
 ratioMap->Draw("colz");

 TCanvas* c4 = new TCanvas("coeffEB","coeffEB",1);
 c4->cd();
 coeffEBp->GetXaxis()->SetTitle("#phi");
 coeffEBp->GetYaxis()->SetTitle("p/p_{true}");
 coeffEBp -> SetMarkerStyle(20);
 coeffEBp -> SetMarkerSize(1);
 coeffEBp -> SetMarkerColor(kRed+1); 
 coeffEBp -> SetLineColor(kRed+1); 
 c4->SetGridx(); 
 c4->SetGridy(); 
 ratioMap->Draw("ap");

 coeffEBm->GetXaxis()->SetTitle("#phi");
 coeffEBm->GetYaxis()->SetTitle("p/p_{true}");
 coeffEBm -> SetMarkerStyle(20);
 coeffEBm -> SetMarkerSize(1);
 coeffEBm -> SetMarkerColor(kBlue+1); 
 coeffEBm -> SetLineColor(kBlue+1); 
 coeffEBm->Draw("ap same");


 theApp->Run();
 return 0;
}
Exemplo n.º 3
0
//! main program
int main (int argc, char** argv)
{

  std::string outputRootName = "matchDistance.root" ;
  std::string fileName (argv[1]) ;
  boost::shared_ptr<edm::ProcessDesc> processDesc = edm::readConfigFile (fileName) ;
  boost::shared_ptr<edm::ParameterSet> parameterSet = processDesc->getProcessPSet () ;
  std::cout << parameterSet->dump () << std::endl ; //PG for testing
  
  edm::ParameterSet subPSetSelections =  parameterSet->getParameter<edm::ParameterSet> ("selections") ;
  //cuts on SC Energy
  double EnergyMaxSC = subPSetSelections.getParameter<double> ("EnergyMaxSC") ;
  double EnergyMinSC = subPSetSelections.getParameter<double> ("EnergyMinSC") ;
  
  //cuts on Angle Muon / SCdirection
  double angleMAX = subPSetSelections.getParameter<double> ("angleMAX") ;
  double angleMIN = subPSetSelections.getParameter<double> ("angleMIN") ;
 
  //cuts on Xtal Energy
  double XtalMaxEnergyMin = subPSetSelections.getParameter<double> ("XtalMaxEnergyMin") ;
  double XtalMaxEnergyMax = subPSetSelections.getParameter<double> ("XtalMaxEnergyMax") ;
  double XtalMinEnergy = subPSetSelections.getParameter<double> ("XtalMinEnergy") ;
  
  //cuts on Windows
  double phiWINDOW    = subPSetSelections.getParameter<double> ("phiWINDOW") ;
  double ietaMAX    = subPSetSelections.getUntrackedParameter<int> ("ietaMAX",85) ;

  edm::ParameterSet subPSetInput =  
    parameterSet->getParameter<edm::ParameterSet> ("inputNtuples") ;
  std::vector<std::string> inputFiles = 
   subPSetInput.getParameter<std::vector<std::string> > ("inputFiles") ;
  std::cout << "reading : " ;

  TChain *chain = new TChain ("EcalCosmicsAnalysis") ;
  EcalCosmicsTreeContent treeVars ; 
  setBranchAddresses (chain, treeVars) ;

  for (std::vector<std::string>::const_iterator listIt = inputFiles.begin () ;
       listIt != inputFiles.end () ;
       ++listIt)
    {   
      std::cout << *listIt << " " << std::endl ;
      chain->Add (listIt->c_str ()) ;
    }

  TProfile2D aveEoxMap ("aveEoxMap","aveEoxMap",360,1.,361.,172,-86.,86.); 

  int nEntries = chain->GetEntries () ;
  std::cout << "FOUND " << nEntries << " ENTRIES\n" ;    

  //PG loop over entries
  for (int entry = 0 ; entry < nEntries ; ++entry)
    {
      chain->GetEntry (entry) ;
      if (entry % 100000 == 0) std::cout << "reading entry " << entry << std::endl ;


      std::vector<ect::association> associations ;
      ect::fillAssocVector (associations, treeVars) ;
      ect::selectOnDR (associations, treeVars, 0.3) ;

      //PG loop on associations vector
      for (unsigned int i = 0 ; 
           i < associations.size () ; 
           ++i)
        {
          int MUindex = associations.at (i).first  ;
          int SCindex = associations.at (i).second ;

          TVector3 SC0_pos (treeVars.superClusterX[SCindex], 
                            treeVars.superClusterY[SCindex], 
                            treeVars.superClusterZ[SCindex]) ; 
	       
          TVector3 MuonDir (treeVars.muonPx[MUindex], 
                            treeVars.muonPy[MUindex], 
                            treeVars.muonPz[MUindex]) ;

          float dummyEmax = 0.;
          float dummyLmax = 0.;
          int numCrystalEMax = -1;
          int numCrystalLMax = -1;
          bool SclOk = false;
          double dummyLength = 0;
       
          for (int XTLindex = treeVars.xtalIndexInSuperCluster[SCindex] ;
               XTLindex < treeVars.xtalIndexInSuperCluster[SCindex] +
                          treeVars.nXtalsInSuperCluster[SCindex] ; 
               ++XTLindex)
            {
              if(treeVars.xtalTkLength[XTLindex] == -1) continue;
          
              dummyLength+= treeVars.xtalTkLength[XTLindex];
          
              //---- check the link Xtal with max energy  == Xtal with max length ----
              if (treeVars.xtalEnergy[XTLindex] > dummyEmax) numCrystalEMax = XTLindex;
              if(treeVars.xtalTkLength[XTLindex] > dummyLmax) numCrystalLMax = XTLindex;
            }
       
          //   if( abs(treeVars.muonTkLengthInEcalDetail[associations.at(i).first] - dummyLength) > 0.5) continue;
       
          if ( (numCrystalEMax != numCrystalLMax) && 
               (numCrystalEMax != -1) && 
               (numCrystalLMax != -1)) 
          {
            if ( 3.*treeVars.xtalEnergy[numCrystalLMax] < 
                 treeVars.xtalTkLength[numCrystalLMax] * 0.0125) SclOk = false;
          }
          else SclOk = true;
          if ((numCrystalEMax == -1) || (numCrystalLMax == -1)) SclOk = false;
          if(SclOk == false) continue;

          double SCphi = fabs(SC0_pos.Phi()) / 3.1415 * 180. ;
          if ( (SCphi < 90. - phiWINDOW/2) || (SCphi > 90. + phiWINDOW/2) ) continue;

          double SCieta = SC0_pos.Eta () / 0.0175 ;
          if (fabs (SCieta) > ietaMAX) continue ;
        
          double angle = MuonDir.Angle ( SC0_pos ) ;
          if( angle > 3.1415/2. ) angle = 3.1415 - angle; // angle belongs to [0:90]

          if ((angle < angleMIN) || (angle >= angleMAX)) continue ;

          if ((treeVars.superClusterRawEnergy[SCindex] >= EnergyMaxSC) || 
              (treeVars.superClusterRawEnergy[SCindex] < EnergyMinSC)) continue ; 

          std::pair <int,int> maxima = findMaxXtalsInSC (treeVars, SCindex) ;
          double XtalEnergyMax = treeVars.xtalEnergy[maxima.first] ;

          if ((XtalEnergyMax < XtalMaxEnergyMin) || 
              (XtalEnergyMax >= XtalMaxEnergyMax)) continue ;
          
          //loop su cristalli di Supercluster Associato
          for (int XTLindex = treeVars.xtalIndexInSuperCluster[SCindex] ;
                   XTLindex < treeVars.xtalIndexInSuperCluster[SCindex] +
                              treeVars.nXtalsInSuperCluster[SCindex] ;
                   ++XTLindex)
            {
              if (treeVars.xtalEnergy[XTLindex] < XtalMinEnergy) continue ;               
              if (treeVars.xtalTkLength[XTLindex] <= 0.) continue ;
              double eox = treeVars.xtalEnergy[XTLindex] / 
                           treeVars.xtalTkLength[XTLindex] ;
              EBDetId dummy = EBDetId::unhashIndex (treeVars.xtalHashedIndex[XTLindex]) ;
              aveEoxMap.Fill (dummy.iphi (), dummy.ieta (), eox) ;
            }
        }
    } //PG loop over entries

  TH1F aveEoxDistr ("aveEoxDistr","aveEoxDistr",500,0,0.5) ;
  for (int phiIndex = 1 ; phiIndex < 361 ; ++phiIndex)
    for (int etaIndex = 1 ; etaIndex < 173 ; ++etaIndex)
      aveEoxDistr.Fill (aveEoxMap.GetBinContent (phiIndex,etaIndex)) ;

  TFile saving ("singleXtalEox.root","recreate") ;
  saving.cd () ;  
  aveEoxMap.Write () ;
  aveEoxDistr.Write () ;
  saving.Close () ;

  return 0 ;
}