[u/mrichter/AliRoot.git] / EMCAL / AliEMCALJetFinderPlots.cxx

/**************************************************************************
 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 *                                                                        *
 * Author: The ALICE Off-line Project.                                    *
 * Contributors are mentioned in the code where appropriate.              *
 *                                                                        *
 * Permission to use, copy, modify and distribute this software and its   *
 * documentation strictly for non-commercial purposes is hereby granted   *
 * without fee, provided that the above copyright notice appears in all   *
 * copies and that both the copyright notice and this permission notice   *
 * appear in the supporting documentation. The authors make no claims     *
 * about the suitability of this software for any purpose. It is          *
 * provided "as is" without express or implied warranty.                  *
 **************************************************************************/


/* $Id$ */


//_________________________________________________________________________
//  Class for Filling JetFinder Plots
// --
//*-- Author: Mark Horner (LBL/UCT)
// --
// --


#include "TMath.h"
#include "AliEMCALJetFinderPlots.h"

ClassImp(AliEMCALJetFinderPlots)
	
AliEMCALJetFinderPlots::AliEMCALJetFinderPlots()
{
	// Constructor to initialise variables
  fInitialised = kFALSE;
  fNominalEnergy = 0.0;
  fConeRadius = 0.3;
  fDebug = 0;
  fOutput=0;
    fhFragmFcn=0;// = new TH1F("hFragmFcn","Fragmentation Function",100,0,1);
    fhPartonFragmFcn=0;// = new TH1F("hPartonFragmFcn","Fragmentation Function",100,0,1);
   fhPartonJT=0;// = new TH1F("hPartonJT","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
    fhPartonPL=0;// = new TH1F("hPartonPL","Track Momentum Parallel to Parton Axis ",100,0.,100.);
    fhJetJT=0;// = new TH1F("hJetJT","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
    fhJetPL=0;// = new TH1F("hJetPL","Track Momentum Parallel to Jet Axis ",100,0.,100.);
    fhJetEt=0;// = new TH1F("hJetEt","E_{T}^{reco}",250,0.,250.);
    fhJetEta=0;// = new       TH1F("hJetEta","#eta_{jet}^{reco}",180,-0.9,0.9);
    fhJetPhi=0;// = new       TH1F("hJetPhi","#phi_{jet}^{reco}",62,0.,3.1);
    fhPartonEta=0;// = new    TH1F("hPartonEta","#eta_{Parton}",180,-0.9,0.9);
    fhPartonPhi=0;// = new    TH1F("hPartonPhi","#phi_{Parton}",62,0.,3.1);
    fhEtaDiff=0;// = new      TH1F("hEtaDiff","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
    fhPhiDiff=0;//  = new TH1F("hPhiDiff","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
    fhNJets=0;// = new        TH1F("hNJets","N Reconstructed jets",11,-0.5,10.5);
  fhEtaPhiSpread=0;	    

fhFragmFcn2=0;	// ("hFragmFcn2","Fragmentation Function",100,0,1);
fhPartonFragmFcn2=0;// ("hFragmFcn2","Parton Fragmentation Function",100,0,1);
fhPartonJT2=0;	// ("hPartonJT2","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
fhPartonPL2=0;	// ("hPartonPL2","Track Momentum Parallel to Parton Axis ",100,0.,100.);
fhJetJT2=0;	// ("hJetJT2","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
fhJetPL2=0;	// ("hJetPL2","Track Momentum Parallel to Jet Axis ",100,0.,100.);
fhJetEt2=0;	// ("hJetEt2","E_{T}^{reco}",250,0.,250.);
fhJetEta2=0;	// ("hJetEta2","#eta_{jet}^{reco}",180,-0.9,0.9);
fhJetPhi2=0;	// ("hJetPhi2","#phi_{jet}^{reco}",62,0.,3.1);
fhPartonEta2=0;	// ("hPartonEta2","#eta_{Parton}",180,-0.9,0.9);
fhPartonPhi2=0;	// ("hPartonPhi2","#phi_{Parton}",62,0.,3.1);
fhEtaDiff2=0;	// ("hEtaDiff2","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
fhPhiDiff2=0;	// ("hPhiDiff2","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
fhEtaPhiSpread2=0;	// ("hEtaPhiSpread2","#eta - #phi Distribution 
						//of Reconstructed Jets",192,-0.7,0.7,288,pi/3,pi);
fhNJets2=0;	// ("hNJets2","N Reconstructed jets",11,-0.5,10.5);
fhJetEtSecond2=0; //("hJetEtSecond2","E_{T}^{reco}",250,0.,250.); 
fhJetEtRatio2=0;  //("hJetEtRatio2","Ratio of Second Highest to Highest",100,0,1);
fhEtaPhiDist2=0;  //("hEtaPhiDist2","Angular Distance Between First and Second",100,0,3);

}

void AliEMCALJetFinderPlots::InitPlots()
{
//========================= CASE 1 =======================================	
    fhFragmFcn = new TH1F("hFragmFcn","Fragmentation Function",100,0,1);
    fhFragmFcn->Sumw2();
    fhPartonFragmFcn = new TH1F("hPartonFragmFcn","Parton Fragmentation Function",100,0,1);
    fhPartonFragmFcn->Sumw2();
    fhPartonJT = new TH1F("hPartonJT","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
    fhPartonJT->Sumw2();
    fhPartonPL = new TH1F("hPartonPL","Track Momentum Parallel to Parton Axis ",100,0.,100.);
    fhPartonPL->Sumw2();
    fhJetJT = new TH1F("hJetJT","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
    fhJetJT->Sumw2();
    fhJetPL = new TH1F("hJetPL","Track Momentum Parallel to Jet Axis ",100,0.,100.);
    fhJetPL->Sumw2();
    fhJetEt = new TH1F("hJetEt","E_{T}^{reco}",250,0.,250.);
    fhJetEt->Sumw2();
    fhJetEta = new	TH1F("hJetEta","#eta_{jet}^{reco}",180,-0.9,0.9);
    fhJetEta->Sumw2();
    fhJetPhi = new 	TH1F("hJetPhi","#phi_{jet}^{reco}",62,0.,3.1);
    fhJetPhi->Sumw2();
    fhPartonEta = new	TH1F("hPartonEta","#eta_{Parton}",180,-0.9,0.9);
    fhPartonEta->Sumw2();
    fhPartonPhi = new 	TH1F("hPartonPhi","#phi_{Parton}",62,0.,3.1);
    fhPartonPhi->Sumw2();
    fhEtaDiff = new	TH1F("hEtaDiff","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
    fhEtaDiff->Sumw2();
    fhPhiDiff  = new TH1F("hPhiDiff","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
    fhPhiDiff->Sumw2();
    fhNJets = new	TH1F("hNJets","N Reconstructed jets",11,-0.5,10.5);
    fhNJets->Sumw2();
    fhEtaPhiSpread = new TH2F("hEtaPhiSpread","#eta - #phi Distribution of Reconstructed Jets",100,-0.5,0.5,100,-0.5,0.5);
    fhEtaPhiSpread->Sumw2();    
  fhNJets->SetXTitle("N_{jets}^{reco}/event");
  fhNJets->SetYTitle("N_{events}");

  //Jet properties
  fhJetEt->SetFillColor(16);
  fhJetEt->SetXTitle("E_{T}^{reco}");
  
  fhJetEta->SetFillColor(16);
  fhJetEta->SetXTitle("#eta_{jet}^{reco}");
  
  fhJetPhi->SetFillColor(16);
  fhJetPhi->SetXTitle("#phi_{jet}^{reco}");
  
  fhPartonEta->SetFillColor(16);
  fhPartonEta->SetXTitle("#eta_{parton}");
  
  fhPartonPhi->SetFillColor(16);
  fhPartonPhi->SetXTitle("#phi_{parton}");

  fhPartonPL->SetXTitle("p (GeV/c)");
  fhPartonJT->SetXTitle("p (GeV/c)");

  fhPartonFragmFcn->SetXTitle("Z = p_{T}^{Chg}/E_{T}^{parton}");

  //Jet component properties

  fhJetPL->SetXTitle("p (GeV/c)");
  fhJetJT->SetXTitle("p (GeV/c)");
  fhFragmFcn->SetXTitle("Z = p_{T}^{Chg}/E_{T}^{reco}");
  fhPartonFragmFcn->SetXTitle("Z = p_{T}^{Chg}/E_{T}^{reco}");

  fhEtaDiff->SetXTitle("#eta_{jet}^{reco}-#eta_{jet}^{input}");
  fhPhiDiff->SetXTitle("#phi_{jet}^{reco}-#phi_{jet}^{input}");
  fhEtaPhiSpread->SetXTitle("#eta");
  fhEtaPhiSpread->SetYTitle("#phi");

//======================= CASE 2 ======================================
  

fhFragmFcn2 		= new TH1F("hFragmFcn2","Fragmentation Function",100,0,1);
fhFragmFcn2->Sumw2();
fhPartonFragmFcn2 	= new TH1F("hPartonFragmFcn2","Parton Fragmentation Function",100,0,1);
fhPartonFragmFcn2->Sumw2();
fhPartonJT2 		= new TH1F("hPartonJT2","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
fhPartonJT2->Sumw2();
fhPartonPL2		= new TH1F("hPartonPL2","Track Momentum Parallel to Parton Axis ",100,0.,100.);
fhPartonPL2->Sumw2();
fhJetJT2			= new TH1F("hJetJT2","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
fhJetJT2->Sumw2();
fhJetPL2			= new TH1F("hJetPL2","Track Momentum Parallel to Jet Axis ",100,0.,100.);
fhJetPL2->Sumw2();
fhJetEt2			= new TH1F("hJetEt2","E_{T}^{reco}",250,0.,250.);
fhJetEt2->Sumw2();
fhJetEta2		= new TH1F("hJetEta2","#eta_{jet}^{reco}",180,-0.9,0.9);
fhJetEta2->Sumw2();
fhJetPhi2		= new TH1F("hJetPhi2","#phi_{jet}^{reco}",62,0.,3.1);
fhJetPhi2->Sumw2();
fhPartonEta2		= new TH1F("hPartonEta2","#eta_{Parton}",180,-0.9,0.9);
fhPartonEta2->Sumw2();
fhPartonPhi2		= new TH1F("hPartonPhi2","#phi_{Parton}",62,0.,3.1);
fhPartonPhi2->Sumw2();
fhEtaDiff2		= new TH1F("hEtaDiff2","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
fhEtaDiff2->Sumw2();
fhPhiDiff2		= new TH1F("hPhiDiff2","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
fhPhiDiff2->Sumw2();
fhEtaPhiSpread2 = new TH2F("hEtaPhiSpread2","#eta - #phi Distribution of Reconstructed Jets",100,-0.5,0.5,100,-0.5,0.5);
fhEtaPhiSpread2->Sumw2();
fhNJets2			= new TH1F("hNJets2","N Reconstructed jets",11,-0.5,10.5);
fhNJets2->Sumw2();
fhJetEtSecond2		= new TH1F("hJetEtSecond2","E_{T}^{reco}",250,0.,250.); 
fhJetEtSecond2->Sumw2();
fhJetEtRatio2		= new TH1F("hJetEtRatio2","Ratio of Second Highest to Highest",100,0,1);
fhJetEtRatio2->Sumw2();
fhEtaPhiDist2		= new TH1F("hEtaPhiDist2","Angular Distance Between First and Second",100,0,3);
fhEtaPhiDist2->Sumw2();
  
  fInitialised = kTRUE;	
  
}

AliEMCALJetFinderPlots::~AliEMCALJetFinderPlots()
{
	// To ensure that all requested memory is returned
delete    fhFragmFcn;// = new TH1F("hFragmFcn","Fragmentation Function",100,0,1);
delete    fhPartonFragmFcn;// = new TH1F("hFragmFcn","Fragmentation Function",100,0,1);
delete   fhPartonJT;// = new TH1F("hPartonJT","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
delete    fhPartonPL;// = new TH1F("hPartonPL","Track Momentum Parallel to Parton Axis ",100,0.,100.);
delete    fhJetJT;// = new TH1F("hJetJT","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
delete    fhJetPL;// = new TH1F("hJetPL","Track Momentum Parallel to Jet Axis ",100,0.,100.);
delete    fhJetEt;// = new TH1F("hJetEt","E_{T}^{reco}",250,0.,250.);
delete    fhJetEta;// = new       TH1F("hJetEta","#eta_{jet}^{reco}",180,-0.9,0.9);
delete    fhJetPhi;// = new       TH1F("hJetPhi","#phi_{jet}^{reco}",62,0.,3.1);
delete    fhPartonEta;// = new    TH1F("hPartonEta","#eta_{Parton}",180,-0.9,0.9);
delete    fhPartonPhi;// = new    TH1F("hPartonPhi","#phi_{Parton}",62,0.,3.1);
delete    fhEtaDiff;// = new      TH1F("hEtaDiff","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
delete    fhPhiDiff;//  = new TH1F("hPhiDiff","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
delete    fhNJets;// = new        TH1F("hNJets","N Reconstructed jets",11,-0.5,10.5);
delete 	  fhEtaPhiSpread;	    

	delete				fhFragmFcn2;	// ("hFragmFcn2","Fragmentation Function",100,0,1);
	delete				fhPartonFragmFcn2;// ("hFragmFcn2","Parton Fragmentation Function",100,0,1);
	delete				fhPartonJT2;	// ("hPartonJT2","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
	delete				fhPartonPL2;	// ("hPartonPL2","Track Momentum Parallel to Parton Axis ",100,0.,100.);
	delete				fhJetJT2;	// ("hJetJT2","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
	delete				fhJetPL2;	// ("hJetPL2","Track Momentum Parallel to Jet Axis ",100,0.,100.);
	delete				fhJetEt2;	// ("hJetEt2","E_{T}^{reco}",250,0.,250.);
	delete				fhJetEta2;	// ("hJetEta2","#eta_{jet}^{reco}",180,-0.9,0.9);
	delete				fhJetPhi2;	// ("hJetPhi2","#phi_{jet}^{reco}",62,0.,3.1);
	delete				fhPartonEta2;	// ("hPartonEta2","#eta_{Parton}",180,-0.9,0.9);
	delete				fhPartonPhi2;	// ("hPartonPhi2","#phi_{Parton}",62,0.,3.1);
	delete				fhEtaDiff2;	// ("hEtaDiff2","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
	delete				fhPhiDiff2;	// ("hPhiDiff2","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
	delete				fhEtaPhiSpread2;	// ("hEtaPhiSpread2","#eta - #phi Distribution 
							//of Reconstructed Jets",192,-0.7,0.7,288,pi/3,pi);
	delete				fhNJets2;	// ("hNJets2","N Reconstructed jets",11,-0.5,10.5);
	delete				fhJetEtSecond2; //("hJetEtSecond2","E_{T}^{reco}",250,0.,250.); 
	delete				fhJetEtRatio2;  //("hJetEtRatio2","Ratio of Second Highest to Highest",100,0,1);
	delete 				fhEtaPhiDist2;  //("hEtaPhiDist2","Angular Distance Between First and Second",100,0,3);


}	

void AliEMCALJetFinderPlots::FillFromOutput(AliEMCALJetFinderOutput* output)
{
	// Fill histograms from an output object
if (!fInitialised) InitPlots();	
  fOutput = output;
  if (!fOutput) return;
  fhNJets->Fill(fOutput->GetNJets());
if (fOutput->GetNJets()>1)
{	
//========================= CASE 2 ===========================	
  Int_t nPartons = fOutput->GetNPartons();
  fhNJets2->Fill(fOutput->GetNJets());
  AliEMCALParton* parton;
  AliEMCALJet* jethighest=0; 
  AliEMCALJet* jetsecond=0; 
  //  Find Highest and Second Highest Jet
  for (Int_t counter = 0; counter<fOutput->GetNJets();counter++)
  {
	  if (counter==0){ 
		  jethighest = fOutput->GetJet(0);
		  jetsecond  = fOutput->GetJet(1);
	  }
	  if (counter>0)
	  {
		  Float_t energyhighest = jethighest->Energy();
		  Float_t energysecond = jetsecond->Energy();
		  
		  if ((fOutput->GetJet(counter))->Energy()>energyhighest) 
		  {
			  jetsecond=jethighest;
			  jethighest=fOutput->GetJet(counter);
		  }else if ((fOutput->GetJet(counter))->Energy()>energysecond) 
		  {
			  jetsecond=fOutput->GetJet(counter);
		  }
	  }
  }

  // End finding highest and second highest and continue
  fhJetEt2->Fill(jethighest->Energy());
  fhJetEta2->Fill(jethighest->Eta()  );
  fhJetPhi2->Fill(jethighest->Phi() );
  if (nPartons ==0) return;
  parton = fOutput->GetParton(0);
  
  fhPartonEta2->Fill( parton->Eta() );
  fhPartonPhi2->Fill( parton->Phi() );

  //hJetEtDiff->Fill( jet->Energy() - parton->Energy() );
  fhEtaDiff2->Fill( jethighest->Eta() - parton->Eta() );
  fhPhiDiff2->Fill( jethighest->Phi() - parton->Phi() );
  fhEtaPhiSpread2->Fill(jethighest->Eta()-parton->Eta(),jethighest->Phi() - parton->Phi());
  fhJetEtSecond2->Fill(jetsecond->Energy()); 
  fhJetEtRatio2->Fill(jetsecond->Energy()/jethighest->Energy()); 
  fhEtaPhiDist2->Fill( TMath::Sqrt((jethighest->Eta() - jetsecond->Eta())*(jethighest->Eta() - jetsecond->Eta())
		      + (jethighest->Phi() - jetsecond->Phi())*(jethighest->Phi() - jetsecond->Phi())	  ));  
  /* 
  Float_t *pt,*phi,*eta;
  Int_t *pdg;
  pt  = new Float_t[parton->GetNTracks()];
  eta = new Float_t[parton->GetNTracks()];
  phi = new Float_t[parton->GetNTracks()];
  pdg = new Int_t[parton->GetNTracks()];*/


 Float_t pt[2000];
 Float_t eta[2000];
 Float_t phi[2000];
 Int_t pdg[2000];
  
  parton->GetTrackList(pt,eta,phi,pdg);
  for(Int_t iT=0; iT< parton->GetNTracks() ; iT++ ) 
  {
      if ( (eta[iT]-parton->Eta())*(eta[iT]-parton->Eta())+
           (phi[iT]-parton->Phi())*(phi[iT]-parton->Phi()) >fConeRadius * fConeRadius ) continue; 
      Double_t tt = 2.0*atan(exp(-eta[iT])); // These names are short to make the equation manageable
      Double_t rt = 2.0*atan(exp(-parton->Eta()));
      Double_t ctt = cos(tt);
      Double_t crt = cos(rt);
      Double_t stt = sin(tt);
      Double_t srt = sin(rt);
      Double_t ctp = cos(phi[iT]);
      Double_t crp = cos(parton->Phi());
      Double_t stp = sin(phi[iT]);
      Double_t srp = sin(parton->Phi());
      Double_t alpha = acos(crp*ctp*srt*stt+srp*stp*srt*stt+crt*ctt);
      Double_t correctp = pt[iT]/stt; 	
      fhPartonPL2->Fill( correctp*cos(alpha));
      if ( (parton->Eta()-eta[iT])*(parton->Eta()-eta[iT]) +  
      (parton->Phi()-phi[iT])*(parton->Phi()-phi[iT]) < 0.2*0.2 ) 
    	      fhPartonJT2->Fill( correctp*sin(alpha));
      if (fNominalEnergy == 0.0) {
	      fhPartonFragmFcn2->Fill(  correctp*sin(tt)/parton->Energy()  );
      }else 
      {
              fhPartonFragmFcn2->Fill(correctp*sin(tt)/fNominalEnergy);
      }
  }// loop over tracks

/*
  pt  = new Float_t[jet->NTracks()];
  eta = new Float_t[jet->NTracks()];
  phi = new Float_t[jet->NTracks()];
  pdg = new Int_t[jet->NTracks()];*/
  jethighest->TrackList(pt,eta,phi,pdg);
  for(Int_t iT=0; iT< jethighest->NTracks() ; iT++ )
  {
      	  Double_t tt = 2.0*atan(exp(-eta[iT])); // These names are short to make the equation manageable
	  Double_t rt = 2.0*atan(exp(-jethighest->Eta()));
	  Double_t ctt = cos(tt);                   
	  Double_t crt = cos(rt);                         
	  Double_t stt = sin(tt);                               
	  Double_t srt = sin(rt);
	  Double_t ctp = cos(phi[iT]);
	  Double_t crp = cos(jethighest->Phi());
	  Double_t stp = sin(phi[iT]);
	  Double_t srp = sin(jethighest->Phi());
	  Double_t alpha = acos(crp*ctp*srt*stt+srp*stp*srt*stt+crt*ctt);   
	  Double_t correctp = pt[iT]/stt;
	  fhJetPL2->Fill( correctp*cos(alpha));      
	  if ( (jethighest->Eta()-eta[iT])*(jethighest->Eta()-eta[iT]) +  
			  (jethighest->Phi()-phi[iT])*(jethighest->Phi()-phi[iT]) < 0.2*0.2 )   
		  fhJetJT2->Fill( correctp*sin(alpha));
	  if (fNominalEnergy==0.0){
		  fhFragmFcn2->Fill(  correctp*sin(tt)/parton->Energy()  );
	  } else
	  {
                  fhFragmFcn2->Fill(  correctp*sin(tt)/fNominalEnergy );
	  }
  }// loop over tracks
  }

  if (fOutput->GetNJets()==1)
  {

//========================= CASE 1 ===========================	
  Int_t nPartons = fOutput->GetNPartons();
  if (fOutput->GetNJets()!=1) return;
  AliEMCALParton* parton;
  AliEMCALJet* jet; 
  jet = fOutput->GetJet(0);
  fhJetEt->Fill(jet->Energy());
  fhJetEta->Fill(jet->Eta()  );
  fhJetPhi->Fill(jet->Phi() );
  if (nPartons ==0) return;
  parton = fOutput->GetParton(0);
  
  fhPartonEta->Fill( parton->Eta() );
  fhPartonPhi->Fill( parton->Phi() );

  //hJetEtDiff->Fill( jet->Energy() - parton->Energy() );
  fhEtaDiff->Fill( jet->Eta() - parton->Eta() );
  fhPhiDiff->Fill( jet->Phi() - parton->Phi() );
  fhEtaPhiSpread->Fill(jet->Eta()-parton->Eta(),jet->Phi() - parton->Phi());
 /* 
  Float_t *pt,*phi,*eta;
  Int_t *pdg;
  pt  = new Float_t[parton->GetNTracks()];
  eta = new Float_t[parton->GetNTracks()];
  phi = new Float_t[parton->GetNTracks()];
  pdg = new Int_t[parton->GetNTracks()];*/


 Float_t pt[2000];
 Float_t eta[2000];
 Float_t phi[2000];
 Int_t pdg[2000];
  
  parton->GetTrackList(pt,eta,phi,pdg);
  for(Int_t iT=0; iT< parton->GetNTracks() ; iT++ ) 
  {
      if ( (eta[iT]-parton->Eta())*(eta[iT]-parton->Eta())+
           (phi[iT]-parton->Phi())*(phi[iT]-parton->Phi()) >fConeRadius * fConeRadius ) continue; 
      Double_t tt = 2.0*atan(exp(-eta[iT])); // These names are short to make the equation manageable
      Double_t rt = 2.0*atan(exp(-parton->Eta()));
      Double_t ctt = cos(tt);
      Double_t crt = cos(rt);
      Double_t stt = sin(tt);
      Double_t srt = sin(rt);
      Double_t ctp = cos(phi[iT]);
      Double_t crp = cos(parton->Phi());
      Double_t stp = sin(phi[iT]);
      Double_t srp = sin(parton->Phi());
      Double_t alpha = acos(crp*ctp*srt*stt+srp*stp*srt*stt+crt*ctt);
      Double_t correctp = pt[iT]/stt; 	
      fhPartonPL->Fill( correctp*cos(alpha));
      if ( (parton->Eta()-eta[iT])*(parton->Eta()-eta[iT]) +  
      (parton->Phi()-phi[iT])*(parton->Phi()-phi[iT]) < 0.2*0.2 ) 
    	      fhPartonJT->Fill( correctp*sin(alpha));
      if (fNominalEnergy == 0.0) {
	      fhPartonFragmFcn->Fill(  correctp*sin(tt)/parton->Energy()  );
      }else 
      {
              fhPartonFragmFcn->Fill(correctp*sin(tt)/fNominalEnergy);
      }
  }// loop over tracks

/*
  pt  = new Float_t[jet->NTracks()];
  eta = new Float_t[jet->NTracks()];
  phi = new Float_t[jet->NTracks()];
  pdg = new Int_t[jet->NTracks()];*/
  jet->TrackList(pt,eta,phi,pdg);
  for(Int_t iT=0; iT< jet->NTracks() ; iT++ )
  {
      	  Double_t tt = 2.0*atan(exp(-eta[iT])); // These names are short to make the equation manageable
	  Double_t rt = 2.0*atan(exp(-jet->Eta()));
	  Double_t ctt = cos(tt);                   
	  Double_t crt = cos(rt);                         
	  Double_t stt = sin(tt);                               
	  Double_t srt = sin(rt);
	  Double_t ctp = cos(phi[iT]);
	  Double_t crp = cos(jet->Phi());
	  Double_t stp = sin(phi[iT]);
	  Double_t srp = sin(jet->Phi());
	  Double_t alpha = acos(crp*ctp*srt*stt+srp*stp*srt*stt+crt*ctt);   
	  Double_t correctp = pt[iT]/stt;
	  fhJetPL->Fill( correctp*cos(alpha));      
	  if ( (jet->Eta()-eta[iT])*(jet->Eta()-eta[iT]) +  
			  (jet->Phi()-phi[iT])*(jet->Phi()-phi[iT]) < 0.2*0.2 )   
		  fhJetJT->Fill( correctp*sin(alpha));
	  if (fNominalEnergy==0.0){
		  fhFragmFcn->Fill(  correctp*sin(tt)/parton->Energy()  );
	  } else
	  {
                  fhFragmFcn->Fill(  correctp*sin(tt)/fNominalEnergy );
	  }
  }// loop over tracks
  }
}
Commit	Line	Data
	1	/**************************************************************************
	2	* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	3	* *
	4	* Author: The ALICE Off-line Project. *
	5	* Contributors are mentioned in the code where appropriate. *
	6	* *
	7	* Permission to use, copy, modify and distribute this software and its *
	8	* documentation strictly for non-commercial purposes is hereby granted *
	9	* without fee, provided that the above copyright notice appears in all *
	10	* copies and that both the copyright notice and this permission notice *
	11	* appear in the supporting documentation. The authors make no claims *
	12	* about the suitability of this software for any purpose. It is *
	13	* provided "as is" without express or implied warranty. *
	14	**************************************************************************/
	15
	16
	17	/* $Id$ */
	18
	19
	20	//_________________________________________________________________________
	21	// Class for Filling JetFinder Plots
	22	// --
	23	//*-- Author: Mark Horner (LBL/UCT)
	24	// --
	25	// --
	26
	27
	28	#include "TMath.h"
	29	#include "AliEMCALJetFinderPlots.h"
	30
	31	ClassImp(AliEMCALJetFinderPlots)
	32
	33	AliEMCALJetFinderPlots::AliEMCALJetFinderPlots()
	34	{
	35	// Constructor to initialise variables
	36	fInitialised = kFALSE;
	37	fNominalEnergy = 0.0;
	38	fConeRadius = 0.3;
	39	fDebug = 0;
	40	fOutput=0;
	41	fhFragmFcn=0;// = new TH1F("hFragmFcn","Fragmentation Function",100,0,1);
	42	fhPartonFragmFcn=0;// = new TH1F("hPartonFragmFcn","Fragmentation Function",100,0,1);
	43	fhPartonJT=0;// = new TH1F("hPartonJT","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
	44	fhPartonPL=0;// = new TH1F("hPartonPL","Track Momentum Parallel to Parton Axis ",100,0.,100.);
	45	fhJetJT=0;// = new TH1F("hJetJT","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
	46	fhJetPL=0;// = new TH1F("hJetPL","Track Momentum Parallel to Jet Axis ",100,0.,100.);
	47	fhJetEt=0;// = new TH1F("hJetEt","E_{T}^{reco}",250,0.,250.);
	48	fhJetEta=0;// = new TH1F("hJetEta","#eta_{jet}^{reco}",180,-0.9,0.9);
	49	fhJetPhi=0;// = new TH1F("hJetPhi","#phi_{jet}^{reco}",62,0.,3.1);
	50	fhPartonEta=0;// = new TH1F("hPartonEta","#eta_{Parton}",180,-0.9,0.9);
	51	fhPartonPhi=0;// = new TH1F("hPartonPhi","#phi_{Parton}",62,0.,3.1);
	52	fhEtaDiff=0;// = new TH1F("hEtaDiff","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
	53	fhPhiDiff=0;// = new TH1F("hPhiDiff","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
	54	fhNJets=0;// = new TH1F("hNJets","N Reconstructed jets",11,-0.5,10.5);
	55	fhEtaPhiSpread=0;
	56
	57	fhFragmFcn2=0; // ("hFragmFcn2","Fragmentation Function",100,0,1);
	58	fhPartonFragmFcn2=0;// ("hFragmFcn2","Parton Fragmentation Function",100,0,1);
	59	fhPartonJT2=0; // ("hPartonJT2","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
	60	fhPartonPL2=0; // ("hPartonPL2","Track Momentum Parallel to Parton Axis ",100,0.,100.);
	61	fhJetJT2=0; // ("hJetJT2","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
	62	fhJetPL2=0; // ("hJetPL2","Track Momentum Parallel to Jet Axis ",100,0.,100.);
	63	fhJetEt2=0; // ("hJetEt2","E_{T}^{reco}",250,0.,250.);
	64	fhJetEta2=0; // ("hJetEta2","#eta_{jet}^{reco}",180,-0.9,0.9);
	65	fhJetPhi2=0; // ("hJetPhi2","#phi_{jet}^{reco}",62,0.,3.1);
	66	fhPartonEta2=0; // ("hPartonEta2","#eta_{Parton}",180,-0.9,0.9);
	67	fhPartonPhi2=0; // ("hPartonPhi2","#phi_{Parton}",62,0.,3.1);
	68	fhEtaDiff2=0; // ("hEtaDiff2","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
	69	fhPhiDiff2=0; // ("hPhiDiff2","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
	70	fhEtaPhiSpread2=0; // ("hEtaPhiSpread2","#eta - #phi Distribution
	71	//of Reconstructed Jets",192,-0.7,0.7,288,pi/3,pi);
	72	fhNJets2=0; // ("hNJets2","N Reconstructed jets",11,-0.5,10.5);
	73	fhJetEtSecond2=0; //("hJetEtSecond2","E_{T}^{reco}",250,0.,250.);
	74	fhJetEtRatio2=0; //("hJetEtRatio2","Ratio of Second Highest to Highest",100,0,1);
	75	fhEtaPhiDist2=0; //("hEtaPhiDist2","Angular Distance Between First and Second",100,0,3);
	76
	77	}
	78
	79	void AliEMCALJetFinderPlots::InitPlots()
	80	{
	81	//========================= CASE 1 =======================================
	82	fhFragmFcn = new TH1F("hFragmFcn","Fragmentation Function",100,0,1);
	83	fhFragmFcn->Sumw2();
	84	fhPartonFragmFcn = new TH1F("hPartonFragmFcn","Parton Fragmentation Function",100,0,1);
	85	fhPartonFragmFcn->Sumw2();
	86	fhPartonJT = new TH1F("hPartonJT","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
	87	fhPartonJT->Sumw2();
	88	fhPartonPL = new TH1F("hPartonPL","Track Momentum Parallel to Parton Axis ",100,0.,100.);
	89	fhPartonPL->Sumw2();
	90	fhJetJT = new TH1F("hJetJT","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
	91	fhJetJT->Sumw2();
	92	fhJetPL = new TH1F("hJetPL","Track Momentum Parallel to Jet Axis ",100,0.,100.);
	93	fhJetPL->Sumw2();
	94	fhJetEt = new TH1F("hJetEt","E_{T}^{reco}",250,0.,250.);
	95	fhJetEt->Sumw2();
	96	fhJetEta = new TH1F("hJetEta","#eta_{jet}^{reco}",180,-0.9,0.9);
	97	fhJetEta->Sumw2();
	98	fhJetPhi = new TH1F("hJetPhi","#phi_{jet}^{reco}",62,0.,3.1);
	99	fhJetPhi->Sumw2();
	100	fhPartonEta = new TH1F("hPartonEta","#eta_{Parton}",180,-0.9,0.9);
	101	fhPartonEta->Sumw2();
	102	fhPartonPhi = new TH1F("hPartonPhi","#phi_{Parton}",62,0.,3.1);
	103	fhPartonPhi->Sumw2();
	104	fhEtaDiff = new TH1F("hEtaDiff","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
	105	fhEtaDiff->Sumw2();
	106	fhPhiDiff = new TH1F("hPhiDiff","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
	107	fhPhiDiff->Sumw2();
	108	fhNJets = new TH1F("hNJets","N Reconstructed jets",11,-0.5,10.5);
	109	fhNJets->Sumw2();
	110	fhEtaPhiSpread = new TH2F("hEtaPhiSpread","#eta - #phi Distribution of Reconstructed Jets",100,-0.5,0.5,100,-0.5,0.5);
	111	fhEtaPhiSpread->Sumw2();
	112	fhNJets->SetXTitle("N_{jets}^{reco}/event");
	113	fhNJets->SetYTitle("N_{events}");
	114
	115	//Jet properties
	116	fhJetEt->SetFillColor(16);
	117	fhJetEt->SetXTitle("E_{T}^{reco}");
	118
	119	fhJetEta->SetFillColor(16);
	120	fhJetEta->SetXTitle("#eta_{jet}^{reco}");
	121
	122	fhJetPhi->SetFillColor(16);
	123	fhJetPhi->SetXTitle("#phi_{jet}^{reco}");
	124
	125	fhPartonEta->SetFillColor(16);
	126	fhPartonEta->SetXTitle("#eta_{parton}");
	127
	128	fhPartonPhi->SetFillColor(16);
	129	fhPartonPhi->SetXTitle("#phi_{parton}");
	130
	131	fhPartonPL->SetXTitle("p (GeV/c)");
	132	fhPartonJT->SetXTitle("p (GeV/c)");
	133
	134	fhPartonFragmFcn->SetXTitle("Z = p_{T}^{Chg}/E_{T}^{parton}");
	135
	136	//Jet component properties
	137
	138	fhJetPL->SetXTitle("p (GeV/c)");
	139	fhJetJT->SetXTitle("p (GeV/c)");
	140	fhFragmFcn->SetXTitle("Z = p_{T}^{Chg}/E_{T}^{reco}");
	141	fhPartonFragmFcn->SetXTitle("Z = p_{T}^{Chg}/E_{T}^{reco}");
	142
	143	fhEtaDiff->SetXTitle("#eta_{jet}^{reco}-#eta_{jet}^{input}");
	144	fhPhiDiff->SetXTitle("#phi_{jet}^{reco}-#phi_{jet}^{input}");
	145	fhEtaPhiSpread->SetXTitle("#eta");
	146	fhEtaPhiSpread->SetYTitle("#phi");
	147
	148	//======================= CASE 2 ======================================
	149
	150
	151	fhFragmFcn2 = new TH1F("hFragmFcn2","Fragmentation Function",100,0,1);
	152	fhFragmFcn2->Sumw2();
	153	fhPartonFragmFcn2 = new TH1F("hPartonFragmFcn2","Parton Fragmentation Function",100,0,1);
	154	fhPartonFragmFcn2->Sumw2();
	155	fhPartonJT2 = new TH1F("hPartonJT2","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
	156	fhPartonJT2->Sumw2();
	157	fhPartonPL2 = new TH1F("hPartonPL2","Track Momentum Parallel to Parton Axis ",100,0.,100.);
	158	fhPartonPL2->Sumw2();
	159	fhJetJT2 = new TH1F("hJetJT2","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
	160	fhJetJT2->Sumw2();
	161	fhJetPL2 = new TH1F("hJetPL2","Track Momentum Parallel to Jet Axis ",100,0.,100.);
	162	fhJetPL2->Sumw2();
	163	fhJetEt2 = new TH1F("hJetEt2","E_{T}^{reco}",250,0.,250.);
	164	fhJetEt2->Sumw2();
	165	fhJetEta2 = new TH1F("hJetEta2","#eta_{jet}^{reco}",180,-0.9,0.9);
	166	fhJetEta2->Sumw2();
	167	fhJetPhi2 = new TH1F("hJetPhi2","#phi_{jet}^{reco}",62,0.,3.1);
	168	fhJetPhi2->Sumw2();
	169	fhPartonEta2 = new TH1F("hPartonEta2","#eta_{Parton}",180,-0.9,0.9);
	170	fhPartonEta2->Sumw2();
	171	fhPartonPhi2 = new TH1F("hPartonPhi2","#phi_{Parton}",62,0.,3.1);
	172	fhPartonPhi2->Sumw2();
	173	fhEtaDiff2 = new TH1F("hEtaDiff2","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
	174	fhEtaDiff2->Sumw2();
	175	fhPhiDiff2 = new TH1F("hPhiDiff2","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
	176	fhPhiDiff2->Sumw2();
	177	fhEtaPhiSpread2 = new TH2F("hEtaPhiSpread2","#eta - #phi Distribution of Reconstructed Jets",100,-0.5,0.5,100,-0.5,0.5);
	178	fhEtaPhiSpread2->Sumw2();
	179	fhNJets2 = new TH1F("hNJets2","N Reconstructed jets",11,-0.5,10.5);
	180	fhNJets2->Sumw2();
	181	fhJetEtSecond2 = new TH1F("hJetEtSecond2","E_{T}^{reco}",250,0.,250.);
	182	fhJetEtSecond2->Sumw2();
	183	fhJetEtRatio2 = new TH1F("hJetEtRatio2","Ratio of Second Highest to Highest",100,0,1);
	184	fhJetEtRatio2->Sumw2();
	185	fhEtaPhiDist2 = new TH1F("hEtaPhiDist2","Angular Distance Between First and Second",100,0,3);
	186	fhEtaPhiDist2->Sumw2();
	187
	188	fInitialised = kTRUE;
	189
	190	}
	191
	192	AliEMCALJetFinderPlots::~AliEMCALJetFinderPlots()
	193	{
	194	// To ensure that all requested memory is returned
	195	delete fhFragmFcn;// = new TH1F("hFragmFcn","Fragmentation Function",100,0,1);
	196	delete fhPartonFragmFcn;// = new TH1F("hFragmFcn","Fragmentation Function",100,0,1);
	197	delete fhPartonJT;// = new TH1F("hPartonJT","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
	198	delete fhPartonPL;// = new TH1F("hPartonPL","Track Momentum Parallel to Parton Axis ",100,0.,100.);
	199	delete fhJetJT;// = new TH1F("hJetJT","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
	200	delete fhJetPL;// = new TH1F("hJetPL","Track Momentum Parallel to Jet Axis ",100,0.,100.);
	201	delete fhJetEt;// = new TH1F("hJetEt","E_{T}^{reco}",250,0.,250.);
	202	delete fhJetEta;// = new TH1F("hJetEta","#eta_{jet}^{reco}",180,-0.9,0.9);
	203	delete fhJetPhi;// = new TH1F("hJetPhi","#phi_{jet}^{reco}",62,0.,3.1);
	204	delete fhPartonEta;// = new TH1F("hPartonEta","#eta_{Parton}",180,-0.9,0.9);
	205	delete fhPartonPhi;// = new TH1F("hPartonPhi","#phi_{Parton}",62,0.,3.1);
	206	delete fhEtaDiff;// = new TH1F("hEtaDiff","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
	207	delete fhPhiDiff;// = new TH1F("hPhiDiff","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
	208	delete fhNJets;// = new TH1F("hNJets","N Reconstructed jets",11,-0.5,10.5);
	209	delete fhEtaPhiSpread;
	210
	211	delete fhFragmFcn2; // ("hFragmFcn2","Fragmentation Function",100,0,1);
	212	delete fhPartonFragmFcn2;// ("hFragmFcn2","Parton Fragmentation Function",100,0,1);
	213	delete fhPartonJT2; // ("hPartonJT2","Track Momentum Perpendicular to Parton Axis",100,0.,10.);
	214	delete fhPartonPL2; // ("hPartonPL2","Track Momentum Parallel to Parton Axis ",100,0.,100.);
	215	delete fhJetJT2; // ("hJetJT2","Track Momentum Perpendicular to Jet Axis",100,0.,10.);
	216	delete fhJetPL2; // ("hJetPL2","Track Momentum Parallel to Jet Axis ",100,0.,100.);
	217	delete fhJetEt2; // ("hJetEt2","E_{T}^{reco}",250,0.,250.);
	218	delete fhJetEta2; // ("hJetEta2","#eta_{jet}^{reco}",180,-0.9,0.9);
	219	delete fhJetPhi2; // ("hJetPhi2","#phi_{jet}^{reco}",62,0.,3.1);
	220	delete fhPartonEta2; // ("hPartonEta2","#eta_{Parton}",180,-0.9,0.9);
	221	delete fhPartonPhi2; // ("hPartonPhi2","#phi_{Parton}",62,0.,3.1);
	222	delete fhEtaDiff2; // ("hEtaDiff2","#eta_{jet}^{reco}-#eta_{jet}^{input}",100,-0.5,0.5);
	223	delete fhPhiDiff2; // ("hPhiDiff2","#phi_{jet}^{reco}-#phi_{jet}^{input}",100,-0.5,0.5);
	224	delete fhEtaPhiSpread2; // ("hEtaPhiSpread2","#eta - #phi Distribution
	225	//of Reconstructed Jets",192,-0.7,0.7,288,pi/3,pi);
	226	delete fhNJets2; // ("hNJets2","N Reconstructed jets",11,-0.5,10.5);
	227	delete fhJetEtSecond2; //("hJetEtSecond2","E_{T}^{reco}",250,0.,250.);
	228	delete fhJetEtRatio2; //("hJetEtRatio2","Ratio of Second Highest to Highest",100,0,1);
	229	delete fhEtaPhiDist2; //("hEtaPhiDist2","Angular Distance Between First and Second",100,0,3);
	230
	231
	232
	233	}
	234
	235	void AliEMCALJetFinderPlots::FillFromOutput(AliEMCALJetFinderOutput* output)
	236	{
	237	// Fill histograms from an output object
	238	if (!fInitialised) InitPlots();
	239	fOutput = output;
	240	if (!fOutput) return;
	241	fhNJets->Fill(fOutput->GetNJets());
	242	if (fOutput->GetNJets()>1)
	243	{
	244	//========================= CASE 2 ===========================
	245	Int_t nPartons = fOutput->GetNPartons();
	246	fhNJets2->Fill(fOutput->GetNJets());
	247	AliEMCALParton* parton;
	248	AliEMCALJet* jethighest=0;
	249	AliEMCALJet* jetsecond=0;
	250	// Find Highest and Second Highest Jet
	251	for (Int_t counter = 0; counter<fOutput->GetNJets();counter++)
	252	{
	253	if (counter==0){
	254	jethighest = fOutput->GetJet(0);
	255	jetsecond = fOutput->GetJet(1);
	256	}
	257	if (counter>0)
	258	{
	259	Float_t energyhighest = jethighest->Energy();
	260	Float_t energysecond = jetsecond->Energy();
	261
	262	if ((fOutput->GetJet(counter))->Energy()>energyhighest)
	263	{
	264	jetsecond=jethighest;
	265	jethighest=fOutput->GetJet(counter);
	266	}else if ((fOutput->GetJet(counter))->Energy()>energysecond)
	267	{
	268	jetsecond=fOutput->GetJet(counter);
	269	}
	270	}
	271	}
	272
	273	// End finding highest and second highest and continue
	274	fhJetEt2->Fill(jethighest->Energy());
	275	fhJetEta2->Fill(jethighest->Eta() );
	276	fhJetPhi2->Fill(jethighest->Phi() );
	277	if (nPartons ==0) return;
	278	parton = fOutput->GetParton(0);
	279
	280	fhPartonEta2->Fill( parton->Eta() );
	281	fhPartonPhi2->Fill( parton->Phi() );
	282
	283	//hJetEtDiff->Fill( jet->Energy() - parton->Energy() );
	284	fhEtaDiff2->Fill( jethighest->Eta() - parton->Eta() );
	285	fhPhiDiff2->Fill( jethighest->Phi() - parton->Phi() );
	286	fhEtaPhiSpread2->Fill(jethighest->Eta()-parton->Eta(),jethighest->Phi() - parton->Phi());
	287	fhJetEtSecond2->Fill(jetsecond->Energy());
	288	fhJetEtRatio2->Fill(jetsecond->Energy()/jethighest->Energy());
	289	fhEtaPhiDist2->Fill( TMath::Sqrt((jethighest->Eta() - jetsecond->Eta())*(jethighest->Eta() - jetsecond->Eta())
	290	+ (jethighest->Phi() - jetsecond->Phi())*(jethighest->Phi() - jetsecond->Phi()) ));
	291	/*
	292	Float_t pt,phi,*eta;
	293	Int_t *pdg;
	294	pt = new Float_t[parton->GetNTracks()];
	295	eta = new Float_t[parton->GetNTracks()];
	296	phi = new Float_t[parton->GetNTracks()];
	297	pdg = new Int_t[parton->GetNTracks()];*/
	298
	299
	300
	301	Float_t pt[2000];
	302	Float_t eta[2000];
	303	Float_t phi[2000];
	304	Int_t pdg[2000];
	305
	306	parton->GetTrackList(pt,eta,phi,pdg);
	307	for(Int_t iT=0; iT< parton->GetNTracks() ; iT++ )
	308	{
	309	if ( (eta[iT]-parton->Eta())*(eta[iT]-parton->Eta())+
	310	(phi[iT]-parton->Phi())(phi[iT]-parton->Phi()) >fConeRadius fConeRadius ) continue;
	311	Double_t tt = 2.0*atan(exp(-eta[iT])); // These names are short to make the equation manageable
	312	Double_t rt = 2.0*atan(exp(-parton->Eta()));
	313	Double_t ctt = cos(tt);
	314	Double_t crt = cos(rt);
	315	Double_t stt = sin(tt);
	316	Double_t srt = sin(rt);
	317	Double_t ctp = cos(phi[iT]);
	318	Double_t crp = cos(parton->Phi());
	319	Double_t stp = sin(phi[iT]);
	320	Double_t srp = sin(parton->Phi());
	321	Double_t alpha = acos(crpctpsrtstt+srpstpsrtstt+crt*ctt);
	322	Double_t correctp = pt[iT]/stt;
	323	fhPartonPL2->Fill( correctp*cos(alpha));
	324	if ( (parton->Eta()-eta[iT])*(parton->Eta()-eta[iT]) +
	325	(parton->Phi()-phi[iT])(parton->Phi()-phi[iT]) < 0.20.2 )
	326	fhPartonJT2->Fill( correctp*sin(alpha));
	327	if (fNominalEnergy == 0.0) {
	328	fhPartonFragmFcn2->Fill( correctp*sin(tt)/parton->Energy() );
	329	}else
	330	{
	331	fhPartonFragmFcn2->Fill(correctp*sin(tt)/fNominalEnergy);
	332	}
	333	}// loop over tracks
	334
	335	/*
	336	pt = new Float_t[jet->NTracks()];
	337	eta = new Float_t[jet->NTracks()];
	338	phi = new Float_t[jet->NTracks()];
	339	pdg = new Int_t[jet->NTracks()];*/
	340	jethighest->TrackList(pt,eta,phi,pdg);
	341	for(Int_t iT=0; iT< jethighest->NTracks() ; iT++ )
	342	{
	343	Double_t tt = 2.0*atan(exp(-eta[iT])); // These names are short to make the equation manageable
	344	Double_t rt = 2.0*atan(exp(-jethighest->Eta()));
	345	Double_t ctt = cos(tt);
	346	Double_t crt = cos(rt);
	347	Double_t stt = sin(tt);
	348	Double_t srt = sin(rt);
	349	Double_t ctp = cos(phi[iT]);
	350	Double_t crp = cos(jethighest->Phi());
	351	Double_t stp = sin(phi[iT]);
	352	Double_t srp = sin(jethighest->Phi());
	353	Double_t alpha = acos(crpctpsrtstt+srpstpsrtstt+crt*ctt);
	354	Double_t correctp = pt[iT]/stt;
	355	fhJetPL2->Fill( correctp*cos(alpha));
	356	if ( (jethighest->Eta()-eta[iT])*(jethighest->Eta()-eta[iT]) +
	357	(jethighest->Phi()-phi[iT])(jethighest->Phi()-phi[iT]) < 0.20.2 )
	358	fhJetJT2->Fill( correctp*sin(alpha));
	359	if (fNominalEnergy==0.0){
	360	fhFragmFcn2->Fill( correctp*sin(tt)/parton->Energy() );
	361	} else
	362	{
	363	fhFragmFcn2->Fill( correctp*sin(tt)/fNominalEnergy );
	364	}
	365	}// loop over tracks
	366	}
	367
	368	if (fOutput->GetNJets()==1)
	369	{
	370
	371	//========================= CASE 1 ===========================
	372	Int_t nPartons = fOutput->GetNPartons();
	373	if (fOutput->GetNJets()!=1) return;
	374	AliEMCALParton* parton;
	375	AliEMCALJet* jet;
	376	jet = fOutput->GetJet(0);
	377	fhJetEt->Fill(jet->Energy());
	378	fhJetEta->Fill(jet->Eta() );
	379	fhJetPhi->Fill(jet->Phi() );
	380	if (nPartons ==0) return;
	381	parton = fOutput->GetParton(0);
	382
	383	fhPartonEta->Fill( parton->Eta() );
	384	fhPartonPhi->Fill( parton->Phi() );
	385
	386	//hJetEtDiff->Fill( jet->Energy() - parton->Energy() );
	387	fhEtaDiff->Fill( jet->Eta() - parton->Eta() );
	388	fhPhiDiff->Fill( jet->Phi() - parton->Phi() );
	389	fhEtaPhiSpread->Fill(jet->Eta()-parton->Eta(),jet->Phi() - parton->Phi());
	390	/*
	391	Float_t pt,phi,*eta;
	392	Int_t *pdg;
	393	pt = new Float_t[parton->GetNTracks()];
	394	eta = new Float_t[parton->GetNTracks()];
	395	phi = new Float_t[parton->GetNTracks()];
	396	pdg = new Int_t[parton->GetNTracks()];*/
	397
	398
	399
	400	Float_t pt[2000];
	401	Float_t eta[2000];
	402	Float_t phi[2000];
	403	Int_t pdg[2000];
	404
	405	parton->GetTrackList(pt,eta,phi,pdg);
	406	for(Int_t iT=0; iT< parton->GetNTracks() ; iT++ )
	407	{
	408	if ( (eta[iT]-parton->Eta())*(eta[iT]-parton->Eta())+
	409	(phi[iT]-parton->Phi())(phi[iT]-parton->Phi()) >fConeRadius fConeRadius ) continue;
	410	Double_t tt = 2.0*atan(exp(-eta[iT])); // These names are short to make the equation manageable
	411	Double_t rt = 2.0*atan(exp(-parton->Eta()));
	412	Double_t ctt = cos(tt);
	413	Double_t crt = cos(rt);
	414	Double_t stt = sin(tt);
	415	Double_t srt = sin(rt);
	416	Double_t ctp = cos(phi[iT]);
	417	Double_t crp = cos(parton->Phi());
	418	Double_t stp = sin(phi[iT]);
	419	Double_t srp = sin(parton->Phi());
	420	Double_t alpha = acos(crpctpsrtstt+srpstpsrtstt+crt*ctt);
	421	Double_t correctp = pt[iT]/stt;
	422	fhPartonPL->Fill( correctp*cos(alpha));
	423	if ( (parton->Eta()-eta[iT])*(parton->Eta()-eta[iT]) +
	424	(parton->Phi()-phi[iT])(parton->Phi()-phi[iT]) < 0.20.2 )
	425	fhPartonJT->Fill( correctp*sin(alpha));
	426	if (fNominalEnergy == 0.0) {
	427	fhPartonFragmFcn->Fill( correctp*sin(tt)/parton->Energy() );
	428	}else
	429	{
	430	fhPartonFragmFcn->Fill(correctp*sin(tt)/fNominalEnergy);
	431	}
	432	}// loop over tracks
	433
	434	/*
	435	pt = new Float_t[jet->NTracks()];
	436	eta = new Float_t[jet->NTracks()];
	437	phi = new Float_t[jet->NTracks()];
	438	pdg = new Int_t[jet->NTracks()];*/
	439	jet->TrackList(pt,eta,phi,pdg);
	440	for(Int_t iT=0; iT< jet->NTracks() ; iT++ )
	441	{
	442	Double_t tt = 2.0*atan(exp(-eta[iT])); // These names are short to make the equation manageable
	443	Double_t rt = 2.0*atan(exp(-jet->Eta()));
	444	Double_t ctt = cos(tt);
	445	Double_t crt = cos(rt);
	446	Double_t stt = sin(tt);
	447	Double_t srt = sin(rt);
	448	Double_t ctp = cos(phi[iT]);
	449	Double_t crp = cos(jet->Phi());
	450	Double_t stp = sin(phi[iT]);
	451	Double_t srp = sin(jet->Phi());
	452	Double_t alpha = acos(crpctpsrtstt+srpstpsrtstt+crt*ctt);
	453	Double_t correctp = pt[iT]/stt;
	454	fhJetPL->Fill( correctp*cos(alpha));
	455	if ( (jet->Eta()-eta[iT])*(jet->Eta()-eta[iT]) +
	456	(jet->Phi()-phi[iT])(jet->Phi()-phi[iT]) < 0.20.2 )
	457	fhJetJT->Fill( correctp*sin(alpha));
	458	if (fNominalEnergy==0.0){
	459	fhFragmFcn->Fill( correctp*sin(tt)/parton->Energy() );
	460	} else
	461	{
	462	fhFragmFcn->Fill( correctp*sin(tt)/fNominalEnergy );
	463	}
	464	}// loop over tracks
	465	}
	466	}
	467
	468