AliAnalysisTaskSubJetFraction.cxx

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//
// Subjet fraction analysis task.
//
//Nima Zardoshti

#include <TClonesArray.h>
#include <TH1F.h>
#include <TH2F.h>
#include <TH3F.h>
#include <TCanvas.h>
#include <THnSparse.h>
#include <TTree.h>
#include <TList.h>
#include <TLorentzVector.h>
#include <TProfile.h>
#include <TChain.h>
#include <TSystem.h>
#include <TFile.h>
#include <TKey.h>
#include <AliAnalysisDataSlot.h>
#include <AliAnalysisDataContainer.h>
#include "TMatrixD.h"
#include "TMatrixDSym.h"
#include "TMatrixDSymEigen.h"
#include "TVector3.h"
#include "TVector2.h"
#include "AliVCluster.h"
#include "AliVTrack.h"
#include "AliEmcalJet.h"
#include "AliRhoParameter.h"
#include "AliLog.h"
#include "AliEmcalParticle.h"
#include "AliMCEvent.h"
#include "AliGenPythiaEventHeader.h"
#include "AliAODMCHeader.h"
#include "AliMCEvent.h"
#include "AliAnalysisManager.h"
#include "AliJetContainer.h"
#include "AliParticleContainer.h"
//#include "AliPythiaInfo.h"
#include "TRandom3.h"
#include "AliPicoTrack.h"
#include "AliEmcalJetFinder.h"
#include "AliAODEvent.h"
#include "AliAnalysisTaskSubJetFraction.h"

//Globals


Double_t XBinsPt[66]={0.15,0.20,0.25,0.30,0.35,0.40,0.45,0.50,0.55,0.60,0.65,0.70,0.75,0.80,0.85,0.9,0.95,1.00,1.10,1.20,1.30,1.40,1.50,1.60,1.70,1.80,1.90,2.00,2.20,2.40,2.60,2.80,3.00,3.20,3.40,3.60,3.80,4.00,4.50,5.00,5.50,6.00,6.50,7.00,8.00,9.00,10.00,11.00,12.00,13.00,14.00,15.00,16.00,18.00,20.00,22.00,24.00,26.00,28.00,30.00,32.00,34.00,36.00,40.00,45.00,50.00}; //Lower edges of new bins for rebbing purposes for track pt                                                                                                           
Double_t XBinsPtSize=66;
Double_t XBinsJetPt[35]={0,0.50,1.00,2.00,3.00,4.00,5.00,6.00,7.00,8.00,9.00,10.00,12.00,14.00,16.00,18.00,20.00,25.00,30.00,35.00,40.00,45.00,50.00,60.00,70.00,80.00,90.00,100.00,120.00,140.00,160.00,180.00,200.00,250.00,300.00}; //for jet pt
Int_t XBinsJetPtSize=35;
Double_t XBinsJetMass[28]={0,0.50,1.00,2.00,3.00,4.00,5.00,6.00,7.00,8.00,9.00,10.00,12.00,14.00,16.00,18.00,20.00,25.00,30.00,35.00,40.00,45.00,50.00,60.00,70.00,80.00,90.00,100.00}; //for jet mass
Int_t XBinsJetMassSize=28;
Double_t Eta_Up=1.00;
Double_t Eta_Low=-1.00;
Int_t Eta_Bins=100;
Double_t Phi_Up=2*(TMath::Pi());
Double_t Phi_Low=(-1*(TMath::Pi()));
Int_t Phi_Bins=100;





using std::cout;
using std::endl;

ClassImp(AliAnalysisTaskSubJetFraction)

//________________________________________________________________________
AliAnalysisTaskSubJetFraction::AliAnalysisTaskSubJetFraction() : 
  AliAnalysisTaskEmcalJet("AliAnalysisTaskSubJetFraction", kTRUE),
  fContainer(0),
  fMinFractionShared(0),
  fJetShapeType(kData),
  fJetShapeSub(kNoSub),
  fJetSelection(kInclusive),
  fPtThreshold(-9999.),
  fRMatching(0.2),
  fPtMinTriggerHadron(20.),
  fPtMaxTriggerHadron(50.),
  fRecoilAngularWindow(0.6),
  fSemigoodCorrect(0),
  fHolePos(0),
  fHoleWidth(0), 
  fCentSelectOn(kTRUE),
  fCentMin(0),
  fCentMax(10),
  fSubJetAlgorithm(0),
  fSubJetRadius(0.1),
  fSubJetMinPt(1),
  fJetRadius(0.4),
  fRMatched(0.2),
  fSharedFractionPtMin(0.5),
  fDerivSubtrOrder(0),
  fFullTree(kFALSE),
  fBeta_SD(0),
  fZCut(0.1),
  fReclusteringAlgorithm(0),
  fNsubMeasure(kFALSE),
  fhPtTriggerHadron(0x0),
  fhJetPt(0x0),
  fhJetPt_1(0x0),
  fhJetPt_2(0x0),
  fhJetPhi(0x0),
  fhJetPhi_1(0x0),
  fhJetPhi_2(0x0),
  fhJetEta(0x0),
  fhJetEta_1(0x0),
  fhJetEta_2(0x0),
  fhJetMass(0x0),
  fhJetMass_1(0x0),
  fhJetMass_2(0x0),
  fhJetRadius(0x0),
  fhJetRadius_1(0x0),
  fhJetRadius_2(0x0),
  fhJetCounter(0x0),
  fhJetCounter_1(0x0),
  fhJetCounter_2(0x0),
  fhNumberOfJetTracks(0x0),
  fhNumberOfJetTracks_1(0x0),
  fhNumberOfJetTracks_2(0x0),
  fhSubJetPt(0x0),
  fhSubJetPt_1(0x0),
  fhSubJetPt_2(0x0),
  fhSubJetMass(0x0),
  fhSubJetMass_1(0x0),
  fhSubJetMass_2(0x0),
  fhSubJetRadius(0x0),
  fhSubJetRadius_1(0x0),
  fhSubJetRadius_2(0x0),
  fhSubJetCounter(0x0),
  fhSubJetCounter_1(0x0),
  fhSubJetCounter_2(0x0),
  fhNumberOfSubJetTracks(0x0),
  fhNumberOfSubJetTracks_1(0x0),
  fhNumberOfSubJetTracks_2(0x0),
  fh2PtTriggerHadronJet(0x0),
  fhPhiTriggerHadronJet(0x0),
  fhPhiTriggerHadronEventPlane(0x0),
  fhPhiTriggerHadronEventPlaneTPC(0x0),
  fh2PtRatio(0x0),
  fhEventCounter(0x0),
  fhEventCounter_1(0x0),
  fhEventCounter_2(0x0),
  fhSubJettiness1CheckRatio_FJ_AKT(0x0),
  fhSubJettiness1CheckRatio_FJ_KT(0x0),
  fhSubJettiness1CheckRatio_FJ_CA(0x0),
  fhSubJettiness1CheckRatio_FJ_WTA_KT(0x0),
  fhSubJettiness1CheckRatio_FJ_WTA_CA(0x0),
  fhSubJettiness1CheckRatio_FJ_OP_AKT(0x0),
  fhSubJettiness1CheckRatio_FJ_OP_KT(0x0),
  fhSubJettiness1CheckRatio_FJ_OP_CA(0x0),
  fhSubJettiness1CheckRatio_FJ_OP_WTA_KT(0x0),
  fhSubJettiness1CheckRatio_FJ_OP_WTA_CA(0x0),
  fhSubJettiness1CheckRatio_FJ_MIN(0x0),
  fhSubJettiness2CheckRatio_FJ_AKT(0x0),
  fhSubJettiness2CheckRatio_FJ_KT(0x0),
  fhSubJettiness2CheckRatio_FJ_CA(0x0),
  fhSubJettiness2CheckRatio_FJ_WTA_KT(0x0),
  fhSubJettiness2CheckRatio_FJ_WTA_CA(0x0),
  fhSubJettiness2CheckRatio_FJ_OP_AKT(0x0),
  fhSubJettiness2CheckRatio_FJ_OP_KT(0x0),
  fhSubJettiness2CheckRatio_FJ_OP_CA(0x0),
  fhSubJettiness2CheckRatio_FJ_OP_WTA_KT(0x0),
  fhSubJettiness2CheckRatio_FJ_OP_WTA_CA(0x0),
  fhSubJettiness2CheckRatio_FJ_MIN(0x0),
  fhSubJettiness2to1CheckRatio_FJ_AKT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_KT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_CA(0x0),
  fhSubJettiness2to1CheckRatio_FJ_WTA_KT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_WTA_CA(0x0),
  fhSubJettiness2to1CheckRatio_FJ_OP_AKT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_OP_KT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_OP_CA(0x0),
  fhSubJettiness2to1CheckRatio_FJ_OP_WTA_KT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_OP_WTA_CA(0x0),
  fhSubJettiness2to1CheckRatio_FJ_MIN(0x0),
  fhSubJettiness1_FJ_AKT(0x0),
  fhSubJettiness1_FJ_KT(0x0),
  fhSubJettiness1_FJ_CA(0x0),
  fhSubJettiness1_FJ_WTA_KT(0x0),
  fhSubJettiness1_FJ_WTA_CA(0x0),
  fhSubJettiness1_FJ_OP_AKT(0x0),
  fhSubJettiness1_FJ_OP_KT(0x0),
  fhSubJettiness1_FJ_OP_CA(0x0),
  fhSubJettiness1_FJ_OP_WTA_KT(0x0),
  fhSubJettiness1_FJ_OP_WTA_CA(0x0),
  fhSubJettiness1_FJ_MIN(0x0),
  fhSubJettiness2_FJ_AKT(0x0),
  fhSubJettiness2_FJ_KT(0x0),
  fhSubJettiness2_FJ_CA(0x0),
  fhSubJettiness2_FJ_WTA_KT(0x0),
  fhSubJettiness2_FJ_WTA_CA(0x0),
  fhSubJettiness2_FJ_OP_AKT(0x0),
  fhSubJettiness2_FJ_OP_KT(0x0),
  fhSubJettiness2_FJ_OP_CA(0x0),
  fhSubJettiness2_FJ_OP_WTA_KT(0x0),
  fhSubJettiness2_FJ_OP_WTA_CA(0x0),
  fhSubJettiness2_FJ_MIN(0x0),
  fhSubJettiness2to1_FJ_AKT(0x0),
  fhSubJettiness2to1_FJ_KT(0x0),
  fhSubJettiness2to1_FJ_CA(0x0),
  fhSubJettiness2to1_FJ_WTA_KT(0x0),
  fhSubJettiness2to1_FJ_WTA_CA(0x0),
  fhSubJettiness2to1_FJ_OP_AKT(0x0),
  fhSubJettiness2to1_FJ_OP_KT(0x0),
  fhSubJettiness2to1_FJ_OP_CA(0x0),
  fhSubJettiness2to1_FJ_OP_WTA_KT(0x0),
  fhSubJettiness2to1_FJ_OP_WTA_CA(0x0),
  fhSubJettiness2to1_FJ_MIN(0x0),
  fTreeResponseMatrixAxis(0)

{
  for(Int_t i=0;i<nVar;i++){
    fShapesVar[i]=0;
  }
  SetMakeGeneralHistograms(kTRUE);
  DefineOutput(1, TList::Class());
  DefineOutput(2, TTree::Class());
}

//________________________________________________________________________
AliAnalysisTaskSubJetFraction::AliAnalysisTaskSubJetFraction(const char *name) : 
  AliAnalysisTaskEmcalJet(name, kTRUE),
  fContainer(0),
  fMinFractionShared(0),
  fJetShapeType(kData),
  fJetShapeSub(kNoSub),
  fJetSelection(kInclusive),
  fPtThreshold(-9999.),
  fRMatching(0.2),
  fPtMinTriggerHadron(20.),
  fPtMaxTriggerHadron(50.),
  fRecoilAngularWindow(0.6),
  fSemigoodCorrect(0),
  fHolePos(0),
  fHoleWidth(0), 
  fCentSelectOn(kTRUE),
  fCentMin(0),
  fCentMax(10),
  fSubJetAlgorithm(0),
  fSubJetRadius(0.1),
  fSubJetMinPt(1),
  fJetRadius(0.4),
  fRMatched(0.2),
  fSharedFractionPtMin(0.5),
  fDerivSubtrOrder(0),
  fFullTree(kFALSE),
  fBeta_SD(0),
  fZCut(0.1),
  fReclusteringAlgorithm(0),
  fNsubMeasure(kFALSE),
  fhPtTriggerHadron(0x0),
  fhJetPt(0x0),
  fhJetPt_1(0x0),
  fhJetPt_2(0x0),
  fhJetPhi(0x0),
  fhJetPhi_1(0x0),
  fhJetPhi_2(0x0),
  fhJetEta(0x0),
  fhJetEta_1(0x0),
  fhJetEta_2(0x0),
  fhJetMass(0x0),
  fhJetMass_1(0x0),
  fhJetMass_2(0x0),
  fhJetRadius(0x0),
  fhJetRadius_1(0x0),
  fhJetRadius_2(0x0),
  fhJetCounter(0x0),
  fhJetCounter_1(0x0),
  fhJetCounter_2(0x0),
  fhNumberOfJetTracks(0x0),
  fhNumberOfJetTracks_1(0x0),
  fhNumberOfJetTracks_2(0x0),
  fhSubJetPt(0x0),
  fhSubJetPt_1(0x0),
  fhSubJetPt_2(0x0),
  fhSubJetMass(0x0),
  fhSubJetMass_1(0x0),
  fhSubJetMass_2(0x0),
  fhSubJetRadius(0x0),
  fhSubJetRadius_1(0x0),
  fhSubJetRadius_2(0x0),
  fhSubJetCounter(0x0),
  fhSubJetCounter_1(0x0),
  fhSubJetCounter_2(0x0),
  fhNumberOfSubJetTracks(0x0),
  fhNumberOfSubJetTracks_1(0x0),
  fhNumberOfSubJetTracks_2(0x0),
  fh2PtTriggerHadronJet(0x0),
  fhPhiTriggerHadronJet(0x0),
  fhPhiTriggerHadronEventPlane(0x0),
  fhPhiTriggerHadronEventPlaneTPC(0x0),
  fh2PtRatio(0x0),
  fhEventCounter(0x0),
  fhEventCounter_1(0x0),
  fhEventCounter_2(0x0),
  fhSubJettiness1CheckRatio_FJ_AKT(0x0),
  fhSubJettiness1CheckRatio_FJ_KT(0x0),
  fhSubJettiness1CheckRatio_FJ_CA(0x0),
  fhSubJettiness1CheckRatio_FJ_WTA_KT(0x0),
  fhSubJettiness1CheckRatio_FJ_WTA_CA(0x0),
  fhSubJettiness1CheckRatio_FJ_OP_AKT(0x0),
  fhSubJettiness1CheckRatio_FJ_OP_KT(0x0),
  fhSubJettiness1CheckRatio_FJ_OP_CA(0x0),
  fhSubJettiness1CheckRatio_FJ_OP_WTA_KT(0x0),
  fhSubJettiness1CheckRatio_FJ_OP_WTA_CA(0x0),
  fhSubJettiness1CheckRatio_FJ_MIN(0x0),
  fhSubJettiness2CheckRatio_FJ_AKT(0x0),
  fhSubJettiness2CheckRatio_FJ_KT(0x0),
  fhSubJettiness2CheckRatio_FJ_CA(0x0),
  fhSubJettiness2CheckRatio_FJ_WTA_KT(0x0),
  fhSubJettiness2CheckRatio_FJ_WTA_CA(0x0),
  fhSubJettiness2CheckRatio_FJ_OP_AKT(0x0),
  fhSubJettiness2CheckRatio_FJ_OP_KT(0x0),
  fhSubJettiness2CheckRatio_FJ_OP_CA(0x0),
  fhSubJettiness2CheckRatio_FJ_OP_WTA_KT(0x0),
  fhSubJettiness2CheckRatio_FJ_OP_WTA_CA(0x0),
  fhSubJettiness2CheckRatio_FJ_MIN(0x0),
  fhSubJettiness2to1CheckRatio_FJ_AKT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_KT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_CA(0x0),
  fhSubJettiness2to1CheckRatio_FJ_WTA_KT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_WTA_CA(0x0),
  fhSubJettiness2to1CheckRatio_FJ_OP_AKT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_OP_KT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_OP_CA(0x0),
  fhSubJettiness2to1CheckRatio_FJ_OP_WTA_KT(0x0),
  fhSubJettiness2to1CheckRatio_FJ_OP_WTA_CA(0x0),
  fhSubJettiness2to1CheckRatio_FJ_MIN(0x0),
  fhSubJettiness1_FJ_AKT(0x0),
  fhSubJettiness1_FJ_KT(0x0),
  fhSubJettiness1_FJ_CA(0x0),
  fhSubJettiness1_FJ_WTA_KT(0x0),
  fhSubJettiness1_FJ_WTA_CA(0x0),
  fhSubJettiness1_FJ_OP_AKT(0x0),
  fhSubJettiness1_FJ_OP_KT(0x0),
  fhSubJettiness1_FJ_OP_CA(0x0),
  fhSubJettiness1_FJ_OP_WTA_KT(0x0),
  fhSubJettiness1_FJ_OP_WTA_CA(0x0),
  fhSubJettiness1_FJ_MIN(0x0),
  fhSubJettiness2_FJ_AKT(0x0),
  fhSubJettiness2_FJ_KT(0x0),
  fhSubJettiness2_FJ_CA(0x0),
  fhSubJettiness2_FJ_WTA_KT(0x0),
  fhSubJettiness2_FJ_WTA_CA(0x0),
  fhSubJettiness2_FJ_OP_AKT(0x0),
  fhSubJettiness2_FJ_OP_KT(0x0),
  fhSubJettiness2_FJ_OP_CA(0x0),
  fhSubJettiness2_FJ_OP_WTA_KT(0x0),
  fhSubJettiness2_FJ_OP_WTA_CA(0x0),
  fhSubJettiness2_FJ_MIN(0x0),
  fhSubJettiness2to1_FJ_AKT(0x0),
  fhSubJettiness2to1_FJ_KT(0x0),
  fhSubJettiness2to1_FJ_CA(0x0),
  fhSubJettiness2to1_FJ_WTA_KT(0x0),
  fhSubJettiness2to1_FJ_WTA_CA(0x0),
  fhSubJettiness2to1_FJ_OP_AKT(0x0),
  fhSubJettiness2to1_FJ_OP_KT(0x0),
  fhSubJettiness2to1_FJ_OP_CA(0x0),
  fhSubJettiness2to1_FJ_OP_WTA_KT(0x0),
  fhSubJettiness2to1_FJ_OP_WTA_CA(0x0),
  fhSubJettiness2to1_FJ_MIN(0x0),
  fTreeResponseMatrixAxis(0)
  
{
  // Standard constructor.
  for(Int_t i=0;i<nVar;i++){
    fShapesVar[i]=0;
  }
  SetMakeGeneralHistograms(kTRUE);
  DefineOutput(1, TList::Class());
  DefineOutput(2, TTree::Class());
}

//________________________________________________________________________
AliAnalysisTaskSubJetFraction::~AliAnalysisTaskSubJetFraction()
{
  // Destructor.
}

//________________________________________________________________________
 void AliAnalysisTaskSubJetFraction::UserCreateOutputObjects()
{
  // Create user output.

  AliAnalysisTaskEmcalJet::UserCreateOutputObjects();

  Bool_t oldStatus = TH1::AddDirectoryStatus();
  TH1::AddDirectory(kFALSE);
  TH1::AddDirectory(oldStatus);
  //create a tree used for the MC data and making a 4D response matrix
  const char* nameoutput = GetOutputSlot(2)->GetContainer()->GetName();
  fTreeResponseMatrixAxis = new TTree(nameoutput, nameoutput);
  if (fFullTree){
    TString *fShapesVarNames = new TString [nVar];
  
    fShapesVarNames[0] = "Pt";
    fShapesVarNames[1] = "Pt_Truth";
    fShapesVarNames[2] = "Tau1";
    fShapesVarNames[3] = "Tau1_Truth";
    fShapesVarNames[4] = "Tau2";
    fShapesVarNames[5] = "Tau2_Truth";
    fShapesVarNames[6] = "Tau3";
    fShapesVarNames[7] = "Tau3_Truth";
    fShapesVarNames[8] = "OpeningAngle";
    fShapesVarNames[9] = "OpeningAngle_Truth";
    fShapesVarNames[10] = "JetMultiplicity";
    fShapesVarNames[11] = "JetMultiplicity_Truth";
    fShapesVarNames[12] = "OpeningAngleSD";
    fShapesVarNames[13] = "OpeningAngleSD_Truth";
    fShapesVarNames[14] = "Zg";
    fShapesVarNames[15] = "Zg_Truth";
    fShapesVarNames[16] = "LeadingTrackPt";
    fShapesVarNames[17] = "LeadingTrackPt_Truth";
    fShapesVarNames[18] = "EventPlaneTriggerHadron";
    fShapesVarNames[19] = "EventPlaneTriggerHadron_Truth";
    fShapesVarNames[20] = "EventPlaneTPCTriggerHadron";
    fShapesVarNames[21] = "EventPlaneTPCTriggerHadron_Truth";
    fShapesVarNames[22] = "DeltaR";
    fShapesVarNames[23] = "DeltaR_Truth";
    fShapesVarNames[24] = "Frac1";
    fShapesVarNames[25] = "Frac1_Truth";
    fShapesVarNames[26] = "Frac2";
    fShapesVarNames[27] = "Frac2_Truth";
    for(Int_t ivar=0; ivar < nVar; ivar++){
      cout<<"looping over variables"<<endl;
      fTreeResponseMatrixAxis->Branch(fShapesVarNames[ivar].Data(), &fShapesVar[ivar], Form("%s/D", fShapesVarNames[ivar].Data()));
    }
  }
  
  if (!fFullTree){
    const Int_t nVarMin = 22; 
    TString *fShapesVarNames = new TString [nVarMin];
  
    fShapesVarNames[0] = "Pt";
    fShapesVarNames[1] = "Pt_Truth";
    fShapesVarNames[2] = "Tau1";
    fShapesVarNames[3] = "Tau1_Truth";
    fShapesVarNames[4] = "Tau2";
    fShapesVarNames[5] = "Tau2_Truth";
    fShapesVarNames[6] = "SubJet1LeadingTrackPt";
    fShapesVarNames[7] = "SubJet1LeadingTrackPt_Truth";
    fShapesVarNames[8] = "OpeningAngle";
    fShapesVarNames[9] = "OpeningAngle_Truth";
    fShapesVarNames[10] = "SubJet2LeadingTrackPt";
    fShapesVarNames[11] = "SubJet2LeadingTrackPt_Truth";
    fShapesVarNames[12] = "OpeningAngleSD";
    fShapesVarNames[13] = "OpeningAngleSD_Truth";
    fShapesVarNames[14] = "SubJet1Pt";
    fShapesVarNames[15] = "SubJet1Pt_Truth";
    fShapesVarNames[16] = "LeadingTrackPt";
    fShapesVarNames[17] = "LeadingTrackPt_Truth";
    fShapesVarNames[18] = "EventPlaneTriggerHadron";
    fShapesVarNames[19] = "EventPlaneTriggerHadron_Truth";
    fShapesVarNames[20] = "SubJet2Pt";
    fShapesVarNames[21] = "SubJet2Pt_Truth";
    
    for(Int_t ivar=0; ivar < nVarMin; ivar++){
      cout<<"looping over variables"<<endl;
      fTreeResponseMatrixAxis->Branch(fShapesVarNames[ivar].Data(), &fShapesVar[ivar], Form("%s/D", fShapesVarNames[ivar].Data()));
    }
  }
  
  if (fJetSelection == AliAnalysisTaskSubJetFraction::kRecoil){
    fhPtTriggerHadron= new TH1F("fhPtTriggerHadron", "fhPtTriggerHadron",1500,-0.5,149.5);  
    fOutput->Add(fhPtTriggerHadron);
    fh2PtTriggerHadronJet= new TH2F("fh2PtTriggerHadronJet", "fh2PtTriggerHadronJet",1500,-0.5,149.5,1500,-0.5,149.5);  
    fOutput->Add(fh2PtTriggerHadronJet);
    fhPhiTriggerHadronJet= new TH1F("fhPhiTriggerHadronJet", "fhPhiTriggerHadronJet",360 , -1.5*(TMath::Pi()), 1.5*(TMath::Pi()));  
    fOutput->Add(fhPhiTriggerHadronJet);
    fhPhiTriggerHadronEventPlane= new TH1F("fhPhiTriggerHadronEventPlane", "fhPhiTriggerHadronEventPlane",360 , -1.5*(TMath::Pi()), 1.5*(TMath::Pi()));  
    fOutput->Add(fhPhiTriggerHadronEventPlane);
    fhPhiTriggerHadronEventPlaneTPC= new TH1F("fhPhiTriggerHadronEventPlaneTPC", "fhPhiTriggerHadronEventPlaneTPC",360 , -1.5*(TMath::Pi()), 1.5*(TMath::Pi()));  
    fOutput->Add(fhPhiTriggerHadronEventPlaneTPC);
  }
  if (fJetShapeType==AliAnalysisTaskSubJetFraction::kData || fJetShapeType==AliAnalysisTaskSubJetFraction::kSim || fJetShapeType==AliAnalysisTaskSubJetFraction::kGenOnTheFly){
    
    //  fhJetPt= new TH1F("fhJetPt", "Jet Pt", (XBinsJetPtSize)-1, XBinsJetPt);
    fhJetPt= new TH1F("fhJetPt", "Jet Pt",1500,-0.5,149.5 );   
    fOutput->Add(fhJetPt);
    //fhJetPhi= new TH1F("fhJetPhi", "Jet Phi", Phi_Bins, Phi_Low, Phi_Up);
    fhJetPhi= new TH1F("fhJetPhi", "Jet Phi",360 , -1.5*(TMath::Pi()), 1.5*(TMath::Pi()));
    fOutput->Add(fhJetPhi);
    fhJetEta= new TH1F("fhJetEta", "Jet Eta", Eta_Bins, Eta_Low, Eta_Up);
    fOutput->Add(fhJetEta);
    fhJetMass= new TH1F("fhJetMass", "Jet Mass", 4000,-0.5, 39.5);
    fOutput->Add(fhJetMass);
    fhJetRadius= new TH1F("fhJetRadius", "Jet Radius", 100, -0.05,0.995);
    fOutput->Add(fhJetRadius);
    fhNumberOfJetTracks= new TH1F("fhNumberOfJetTracks", "Number of Tracks within a Jet", 300, -0.5,299.5);
    fOutput->Add(fhNumberOfJetTracks);
    fhSubJetRadius= new TH1F("fhSubJetRadius", "SubJet Radius", 100, -0.05,0.995);
    fOutput->Add(fhSubJetRadius);
    fhSubJetPt= new TH1F("fhSubJetPt", "SubJet Pt", 1500, -0.5,149.5);
    fOutput->Add(fhSubJetPt);
    fhSubJetMass= new TH1F("fhSubJetMass", "Sub Jet Mass", 4000,-0.5, 39.5);
    fOutput->Add(fhSubJetMass);
    fhNumberOfSubJetTracks= new TH1F("fhNumberOfSubJetTracks", "Number of Tracks within a Sub Jet", 300, -0.5,299.5);
    fOutput->Add(fhNumberOfSubJetTracks);
    fhJetCounter= new TH1F("fhJetCounter", "Jet Counter", 150, -0.5, 149.5);
    fOutput->Add(fhJetCounter);
    fhSubJetCounter = new TH1F("fhSubJetCounter", "SubJet Counter",50, -0.5,49.5);
    fOutput->Add(fhSubJetCounter);
    fhEventCounter= new TH1F("fhEventCounter", "Event Counter", 15,0.5,15.5);
    fOutput->Add(fhEventCounter);
  }
  if(fJetShapeType==AliAnalysisTaskSubJetFraction::kSim || fJetShapeType==AliAnalysisTaskSubJetFraction::kGenOnTheFly){
    fhSubJettiness1_FJ_KT= new TH1D("fhSubJettiness1_FJ_KT","fhSubJettiness1_FJ_KT",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_KT);
    fhSubJettiness1_FJ_MIN= new TH1D("fhSubJettiness1_FJ_MIN","fhSubJettiness1_FJ_MIN",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_MIN);
    fhSubJettiness2_FJ_KT= new TH1D("fhSubJettiness2_FJ_KT","fhSubJettiness2_FJ_KT",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_KT);
    fhSubJettiness2_FJ_MIN= new TH1D("fhSubJettiness2_FJ_MIN","fhSubJettiness2_FJ_MIN",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_MIN);
    fhSubJettiness1CheckRatio_FJ_AKT = new TH2D("fhSubJettiness1CheckRatio_FJ_AKT","fhSubJettiness1CheckRatio_FJ_AKT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_AKT);
    fhSubJettiness1CheckRatio_FJ_KT= new TH2D("fhSubJettiness1CheckRatio_FJ_KT","fhSubJettiness1CheckRatio_FJ_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_KT);
    fhSubJettiness1CheckRatio_FJ_CA= new TH2D("fhSubJettiness1CheckRatio_FJ_CA","fhSubJettiness1CheckRatio_FJ_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_CA);
    fhSubJettiness1CheckRatio_FJ_WTA_KT= new TH2D("fhSubJettiness1CheckRatio_FJ_WTA_KT","fhSubJettiness1CheckRatio_FJ_WTA_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_WTA_KT);
    fhSubJettiness1CheckRatio_FJ_WTA_CA= new TH2D("fhSubJettiness1CheckRatio_FJ_WTA_CA","fhSubJettiness1CheckRatio_FJ_WTA_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_WTA_CA);
    fhSubJettiness1CheckRatio_FJ_OP_AKT= new TH2D("fhSubJettiness1CheckRatio_FJ_OP_AKT","fhSubJettiness1CheckRatio_FJ_OP_AKT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_OP_AKT);
    fhSubJettiness1CheckRatio_FJ_OP_KT= new TH2D("fhSubJettiness1CheckRatio_FJ_OP_KT","fhSubJettiness1CheckRatio_FJ_OP_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_OP_KT);
    fhSubJettiness1CheckRatio_FJ_OP_CA= new TH2D("fhSubJettiness1CheckRatio_FJ_OP_CA","fhSubJettiness1CheckRatio_FJ_OP_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_OP_CA);
    fhSubJettiness1CheckRatio_FJ_OP_WTA_KT= new TH2D("fhSubJettiness1CheckRatio_FJ_OP_WTA_KT","fhSubJettiness1CheckRatio_FJ_OP_WTA_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_OP_WTA_KT);
    fhSubJettiness1CheckRatio_FJ_OP_WTA_CA= new TH2D("fhSubJettiness1CheckRatio_FJ_OP_WTA_CA","fhSubJettiness1CheckRatio_FJ_OP_WTA_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_OP_WTA_CA);
    fhSubJettiness1CheckRatio_FJ_MIN= new TH2D("fhSubJettiness1CheckRatio_FJ_MIN","fhSubJettiness1CheckRatio_FJ_MIN",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness1CheckRatio_FJ_MIN);
    fhSubJettiness2CheckRatio_FJ_AKT = new TH2D("fhSubJettiness2CheckRatio_FJ_AKT","fhSubJettiness2CheckRatio_FJ_AKT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_AKT);
    fhSubJettiness2CheckRatio_FJ_KT= new TH2D("fhSubJettiness2CheckRatio_FJ_KT","fhSubJettiness2CheckRatio_FJ_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_KT);
    fhSubJettiness2CheckRatio_FJ_CA= new TH2D("fhSubJettiness2CheckRatio_FJ_CA","fhSubJettiness2CheckRatio_FJ_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_CA);
    fhSubJettiness2CheckRatio_FJ_WTA_KT= new TH2D("fhSubJettiness2CheckRatio_FJ_WTA_KT","fhSubJettiness2CheckRatio_FJ_WTA_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_WTA_KT);
    fhSubJettiness2CheckRatio_FJ_WTA_CA= new TH2D("fhSubJettiness2CheckRatio_FJ_WTA_CA","fhSubJettiness2CheckRatio_FJ_WTA_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_WTA_CA);
    fhSubJettiness2CheckRatio_FJ_OP_AKT= new TH2D("fhSubJettiness2CheckRatio_FJ_OP_AKT","fhSubJettiness2CheckRatio_FJ_OP_AKT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_OP_AKT);
    fhSubJettiness2CheckRatio_FJ_OP_KT= new TH2D("fhSubJettiness2CheckRatio_FJ_OP_KT","fhSubJettiness2CheckRatio_FJ_OP_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_OP_KT);
    fhSubJettiness2CheckRatio_FJ_OP_CA= new TH2D("fhSubJettiness2CheckRatio_FJ_OP_CA","fhSubJettiness2CheckRatio_FJ_OP_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_OP_CA);
    fhSubJettiness2CheckRatio_FJ_OP_WTA_KT= new TH2D("fhSubJettiness2CheckRatio_FJ_OP_WTA_KT","fhSubJettiness2CheckRatio_FJ_OP_WTA_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_OP_WTA_KT);
    fhSubJettiness2CheckRatio_FJ_OP_WTA_CA= new TH2D("fhSubJettiness2CheckRatio_FJ_OP_WTA_CA","fhSubJettiness2CheckRatio_FJ_OP_WTA_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_OP_WTA_CA);
    fhSubJettiness2CheckRatio_FJ_MIN= new TH2D("fhSubJettiness2CheckRatio_FJ_MIN","fhSubJettiness2CheckRatio_FJ_MIN",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2CheckRatio_FJ_MIN);
    fhSubJettiness2to1CheckRatio_FJ_AKT = new TH2D("fhSubJettiness2to1CheckRatio_FJ_AKT","fhSubJettiness2to1CheckRatio_FJ_AKT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_AKT);
    fhSubJettiness2to1CheckRatio_FJ_KT= new TH2D("fhSubJettiness2to1CheckRatio_FJ_KT","fhSubJettiness2to1CheckRatio_FJ_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_KT);
    fhSubJettiness2to1CheckRatio_FJ_CA= new TH2D("fhSubJettiness2to1CheckRatio_FJ_CA","fhSubJettiness2to1CheckRatio_FJ_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_CA);
    fhSubJettiness2to1CheckRatio_FJ_WTA_KT= new TH2D("fhSubJettiness2to1CheckRatio_FJ_WTA_KT","fhSubJettiness2to1CheckRatio_FJ_WTA_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_WTA_KT);
    fhSubJettiness2to1CheckRatio_FJ_WTA_CA= new TH2D("fhSubJettiness2to1CheckRatio_FJ_WTA_CA","fhSubJettiness2to1CheckRatio_FJ_WTA_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_WTA_CA);
    fhSubJettiness2to1CheckRatio_FJ_OP_AKT= new TH2D("fhSubJettiness2to1CheckRatio_FJ_OP_AKT","fhSubJettiness2to1CheckRatio_FJ_OP_AKT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_OP_AKT);
    fhSubJettiness2to1CheckRatio_FJ_OP_KT= new TH2D("fhSubJettiness2to1CheckRatio_FJ_OP_KT","fhSubJettiness2to1CheckRatio_FJ_OP_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_OP_KT);
    fhSubJettiness2to1CheckRatio_FJ_OP_CA= new TH2D("fhSubJettiness2to1CheckRatio_FJ_OP_CA","fhSubJettiness2to1CheckRatio_FJ_OP_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_OP_CA);
    fhSubJettiness2to1CheckRatio_FJ_OP_WTA_KT= new TH2D("fhSubJettiness2to1CheckRatio_FJ_OP_WTA_KT","fhSubJettiness2to1CheckRatio_FJ_OP_WTA_KT",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_OP_WTA_KT);
    fhSubJettiness2to1CheckRatio_FJ_OP_WTA_CA= new TH2D("fhSubJettiness2to1CheckRatio_FJ_OP_WTA_CA","fhSubJettiness2to1CheckRatio_FJ_OP_WTA_CA",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_OP_WTA_CA);
    fhSubJettiness2to1CheckRatio_FJ_MIN= new TH2D("fhSubJettiness2to1CheckRatio_FJ_MIN","fhSubJettiness2to1CheckRatio_FJ_MIN",400,-2,2,300,-1,2);
    fOutput->Add(fhSubJettiness2to1CheckRatio_FJ_MIN);
    fhSubJettiness1_FJ_AKT= new TH1D("fhSubJettiness1_FJ_AKT","fhSubJettiness1_FJ_AKT",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_AKT);
    fhSubJettiness1_FJ_CA= new TH1D("fhSubJettiness1_FJ_CA","fhSubJettiness1_FJ_CA",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_CA);
    fhSubJettiness1_FJ_WTA_KT= new TH1D("fhSubJettiness1_FJ_WTA_KT","fhSubJettiness1_FJ_WTA_KT",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_WTA_KT);
    fhSubJettiness1_FJ_WTA_CA= new TH1D("fhSubJettiness1_FJ_WTA_CA","fhSubJettiness1_FJ_WTA_CA",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_WTA_CA);
    fhSubJettiness1_FJ_OP_AKT= new TH1D("fhSubJettiness1_FJ_OP_AKT","fhSubJettiness1_FJ_OP_AKT",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_OP_AKT);
    fhSubJettiness1_FJ_OP_KT= new TH1D("fhSubJettiness1_FJ_OP_KT","fhSubJettiness1_FJ_OP_KT",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_OP_KT);
    fhSubJettiness1_FJ_OP_CA= new TH1D("fhSubJettiness1_FJ_OP_CA","fhSubJettiness1_FJ_OP_CA",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_OP_CA);
    fhSubJettiness1_FJ_OP_WTA_KT= new TH1D("fhSubJettiness1_FJ_OP_WTA_KT","fhSubJettiness1_FJ_OP_WTA_KT",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_OP_WTA_KT);
    fhSubJettiness1_FJ_OP_WTA_CA= new TH1D("fhSubJettiness1_FJ_OP_WTA_CA","fhSubJettiness1_FJ_OP_WTA_CA",400,-2,2);
    fOutput->Add(fhSubJettiness1_FJ_OP_WTA_CA);
    fhSubJettiness2_FJ_AKT= new TH1D("fhSubJettiness2_FJ_AKT","fhSubJettiness2_FJ_AKT",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_AKT);
    fhSubJettiness2_FJ_CA= new TH1D("fhSubJettiness2_FJ_CA","fhSubJettiness2_FJ_CA",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_CA);
    fhSubJettiness2_FJ_WTA_KT= new TH1D("fhSubJettiness2_FJ_WTA_KT","fhSubJettiness2_FJ_WTA_KT",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_WTA_KT);
    fhSubJettiness2_FJ_WTA_CA= new TH1D("fhSubJettiness2_FJ_WTA_CA","fhSubJettiness2_FJ_WTA_CA",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_WTA_CA);
    fhSubJettiness2_FJ_OP_AKT= new TH1D("fhSubJettiness2_FJ_OP_AKT","fhSubJettiness2_FJ_OP_AKT",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_OP_AKT);
    fhSubJettiness2_FJ_OP_KT= new TH1D("fhSubJettiness2_FJ_OP_KT","fhSubJettiness2_FJ_OP_KT",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_OP_KT);
    fhSubJettiness2_FJ_OP_CA= new TH1D("fhSubJettiness2_FJ_OP_CA","fhSubJettiness2_FJ_OP_CA",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_OP_CA);
    fhSubJettiness2_FJ_OP_WTA_KT= new TH1D("fhSubJettiness2_FJ_OP_WTA_KT","fhSubJettiness2_FJ_OP_WTA_KT",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_OP_WTA_KT);
    fhSubJettiness2_FJ_OP_WTA_CA= new TH1D("fhSubJettiness2_FJ_OP_WTA_CA","fhSubJettiness2_FJ_OP_WTA_CA",400,-2,2);
    fOutput->Add(fhSubJettiness2_FJ_OP_WTA_CA);
    fhSubJettiness2to1_FJ_KT= new TH1D("fhSubJettiness2to1_FJ_KT","fhSubJettiness2to1_FJ_KT",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_KT);
    fhSubJettiness2to1_FJ_AKT= new TH1D("fhSubJettiness2to1_FJ_AKT","fhSubJettiness2to1_FJ_AKT",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_AKT);
    fhSubJettiness2to1_FJ_CA= new TH1D("fhSubJettiness2to1_FJ_CA","fhSubJettiness2to1_FJ_CA",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_CA);
    fhSubJettiness2to1_FJ_WTA_KT= new TH1D("fhSubJettiness2to1_FJ_WTA_KT","fhSubJettiness2to1_FJ_WTA_KT",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_WTA_KT);
    fhSubJettiness2to1_FJ_WTA_CA= new TH1D("fhSubJettiness2to1_FJ_WTA_CA","fhSubJettiness2to1_FJ_WTA_CA",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_WTA_CA);
    fhSubJettiness2to1_FJ_OP_AKT= new TH1D("fhSubJettiness2to1_FJ_OP_AKT","fhSubJettiness2to1_FJ_OP_AKT",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_OP_AKT);
    fhSubJettiness2to1_FJ_OP_KT= new TH1D("fhSubJettiness2to1_FJ_OP_KT","fhSubJettiness2to1_FJ_OP_KT",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_OP_KT);
    fhSubJettiness2to1_FJ_OP_CA= new TH1D("fhSubJettiness2to1_FJ_OP_CA","fhSubJettiness2to1_FJ_OP_CA",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_OP_CA);
    fhSubJettiness2to1_FJ_OP_WTA_KT= new TH1D("fhSubJettiness2to1_FJ_OP_WTA_KT","fhSubJettiness2to1_FJ_OP_WTA_KT",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_OP_WTA_KT);
    fhSubJettiness2to1_FJ_OP_WTA_CA= new TH1D("fhSubJettiness2to1_FJ_OP_WTA_CA","fhSubJettiness2to1_FJ_OP_WTA_CA",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_OP_WTA_CA);
    fhSubJettiness2to1_FJ_MIN= new TH1D("fhSubJettiness2to1_FJ_MIN","fhSubJettiness2to1_FJ_MIN",400,-2,2);
    fOutput->Add(fhSubJettiness2to1_FJ_MIN);
  }
  if(fJetShapeType==AliAnalysisTaskSubJetFraction::kTrueDet){
    fhJetPt_1= new TH1F("fhJetPt_1", "Jet Pt Detector Level",1500,-0.5,149.5 );
    fOutput->Add(fhJetPt_1);
    fhJetPt_2= new TH1F("fhJetPt_2", "Jet Pt Particle Level",1500,-0.5,149.5 );
    fOutput->Add(fhJetPt_2);
    fhJetPhi_1= new TH1F("fhJetPhi_1", "Jet Phi Detector Level",360 , -1.5*(TMath::Pi()), 1.5*(TMath::Pi()));
    fOutput->Add(fhJetPhi_1);
    fhJetPhi_2= new TH1F("fhJetPhi_2", "Jet Phi Particle Level",360 , -1.5*(TMath::Pi()), 1.5*(TMath::Pi()));
    fOutput->Add(fhJetPhi_2);
    fhJetEta_1= new TH1F("fhJetEta_1", "Jet Eta Detector Level", Eta_Bins, Eta_Low, Eta_Up);
    fOutput->Add(fhJetEta_1);
    fhJetEta_2= new TH1F("fhJetEta_2", "Jet Eta Particle Level", Eta_Bins, Eta_Low, Eta_Up);
    fOutput->Add(fhJetEta_2);
    fhJetMass_1= new TH1F("fhJetMass_1", "Jet Mass Detector Level", 4000,-0.5, 39.5);
    fOutput->Add(fhJetMass_1);
    fhJetMass_2= new TH1F("fhJetMass_2", "Jet Mass Particle Level", 4000,-0.5, 39.5);
    fOutput->Add(fhJetMass_2);
    fhJetRadius_1= new TH1F("fhJetRadius_1", "Jet Radius Detector Level", 100, -0.05,0.995);
    fOutput->Add(fhJetRadius_1);
    fhJetRadius_2= new TH1F("fhJetRadius_2", "Jet Radius Particle Level", 100, -0.05,0.995);
    fOutput->Add(fhJetRadius_2);
    fhNumberOfJetTracks_1= new TH1F("fhNumberOfJetTracks_1", "Number of Tracks within a Jet Detector Level", 300, -0.5,299.5);
    fOutput->Add(fhNumberOfJetTracks_1);
    fhNumberOfJetTracks_2= new TH1F("fhNumberOfJetTracks_2", "Number of Tracks within a Jet Particle Level", 300, -0.5,299.5);
    fOutput->Add(fhNumberOfJetTracks_2);
    fhSubJetRadius_1= new TH1F("fhSubJetRadius_1", "SubJet Radius Detector Level", 100, -0.05,0.995);
    fOutput->Add(fhSubJetRadius_1);
    fhSubJetRadius_2= new TH1F("fhSubJetRadius_2", "SubJet Radius Particle Level", 100, -0.05,0.995);
    fOutput->Add(fhSubJetRadius_2);
    fhSubJetPt_1= new TH1F("fhSubJetPt_1", "SubJet Pt Detector Level", 1500, -0.5,149.5);
    fOutput->Add(fhSubJetPt_1);
    fhSubJetPt_2= new TH1F("fhSubJetPt_2", "SubJet Pt Particle Level", 1500, -0.5,149.5);
    fOutput->Add(fhSubJetPt_2);
    fhSubJetMass_1= new TH1F("fhSubJetMass_1", "Sub Jet Mass Detector Level", 4000,-0.5, 39.5);
    fOutput->Add(fhSubJetMass_1);
    fhSubJetMass_2= new TH1F("fhSubJetMass_2", "Sub Jet Mass Particle Level", 4000,-0.5, 39.5);
    fOutput->Add(fhSubJetMass_2);
    fhNumberOfSubJetTracks_1= new TH1F("fhNumberOfSubJetTracks_1", "Number of Tracks within a Sub Jet Detector Level", 300, -0.5,299.5);
    fOutput->Add(fhNumberOfSubJetTracks_1);
    fhNumberOfSubJetTracks_2= new TH1F("fhNumberOfSubJetTracks_2", "Number of Tracks within a Sub Jet Particle Level", 300, -0.5,299.5);
    fOutput->Add(fhNumberOfSubJetTracks_2);
    fhJetCounter_1= new TH1F("fhJetCounter_1", "Jet Counter Detector Level", 150, -0.5, 149.5);
    fOutput->Add(fhJetCounter_1);
    fhJetCounter_2= new TH1F("fhJetCounter_2", "Jet Counter Particle Level", 150, -0.5, 149.5);
    fOutput->Add(fhJetCounter_2);
    fhSubJetCounter_1 = new TH1F("fhSubJetCounter_1", "SubJet Counter Detector Level",50, -0.5,49.5);
    fOutput->Add(fhSubJetCounter_1);
    fhSubJetCounter_2 = new TH1F("fhSubJetCounter_2", "SubJet Counter Particle Level",50, -0.5,49.5);
    fOutput->Add(fhSubJetCounter_2);
    fh2PtRatio= new TH2F("fhPtRatio", "MC pt for detector level vs particle level jets",1500,-0.5,149.5,1500,-0.5,149.5);
    fOutput->Add(fh2PtRatio);
    fhEventCounter_1= new TH1F("fhEventCounter_1", "Event Counter Detector Level", 15,0.5,15.5);
    fOutput->Add(fhEventCounter_1);
    fhEventCounter_2= new TH1F("fhEventCounter_2", "Event Counter Particle Level", 15,0.5,15.5);
    fOutput->Add(fhEventCounter_2);
  }
  if (fJetShapeType == AliAnalysisTaskSubJetFraction::kDetEmbPart){
    fhEventCounter= new TH1F("fhEventCounter", "Event Counter", 15,0.5,15.5);
    fOutput->Add(fhEventCounter);
  }
  
  PostData(1,fOutput);
  PostData(2,fTreeResponseMatrixAxis);
  // delete [] fShapesVarNames;
}

//________________________________________________________________________
Bool_t AliAnalysisTaskSubJetFraction::Run()
{
  // Run analysis code here, if needed. It will be executed before FillHistograms().


  return kTRUE;
}

//________________________________________________________________________
Bool_t AliAnalysisTaskSubJetFraction::FillHistograms()
{

  //fhEventCounter Key:
  // 1: Number of events with a Jet Container 
  // 2: Number of Jets without a Jet Container
  // 3:
  // 4: Number of Jets found in all events
  // 5: Number of Jets that were reclustered in all events
  // 6: Number of SubJets found in all events 
  // 7: Number of events were primary vertext was found
  // 8: Number of Jets with more than one SubJet
  // 9:Number of Jets with more than two SubJets
  // 12:Number of SubJetinessEvents in kData


  //  const AliVVertex *vert = InputEvent()->GetPrimaryVertex();
  //  Double_t dVtx[3]={vert->GetX(),vert->GetY(),vert->GetZ()};
  // if(vert) fhEventCounter->Fill(7);

  //cout << ((AliVAODHeader*)(InputEvent()->GetHeader()))->GetEventplane()<< "    "<<fEPV0<<endl;
  // cout << InputEvent()->GetEventplane()->GetEventplane("Q")<< "    "<<fEPV0<<endl;   
  if (fCentSelectOn){
    if ((fCent>fCentMax) || (fCent<fCentMin)) return 0;
  }

  AliAODTrack *TriggerHadron = 0x0;
  if (fJetSelection == kRecoil) {
    //you have to set a flag and the limits of the pT interval for your trigger
    Int_t TriggerHadronLabel = SelectTriggerHadron(fPtMinTriggerHadron, fPtMaxTriggerHadron);    
    if (TriggerHadronLabel==-99999) return 0;  //Trigger Hadron Not Found
    AliTrackContainer *PartCont =NULL;
    AliParticleContainer *PartContMC=NULL;
    if (fJetShapeSub==kConstSub){
      if (fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly) PartContMC = GetParticleContainer(1);
      else PartCont = GetTrackContainer(1);
    }
    else{
      if (fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly) PartContMC = GetParticleContainer(0);
      else PartCont = GetTrackContainer(0);
    }
    TClonesArray *TrackArray = NULL;
    TClonesArray *TrackArrayMC = NULL;
    if (fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly) TrackArrayMC = PartContMC->GetArray();
    else TrackArray = PartCont->GetArray();    
    if (fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly) TriggerHadron = static_cast<AliAODTrack*>(TrackArrayMC->At(TriggerHadronLabel));
    else TriggerHadron = static_cast<AliAODTrack*>(TrackArray->At(TriggerHadronLabel));
    if (!TriggerHadron) return 0;//No trigger hadron with label found   
    if(fSemigoodCorrect){
      Double_t HoleDistance=RelativePhi(TriggerHadron->Phi(),fHolePos);
      if(TMath::Abs(HoleDistance)+fHoleWidth+fJetRadius>TMath::Pi()-fRecoilAngularWindow) return 0;
    }
    fhPtTriggerHadron->Fill(TriggerHadron->Pt()); //Needed for per trigger Normalisation
    if (fJetShapeType != AliAnalysisTaskSubJetFraction::kGenOnTheFly) fhPhiTriggerHadronEventPlane->Fill(TMath::Abs(RelativePhiEventPlane(fEPV0,TriggerHadron->Phi()))); //fEPV0 is the event plane from AliAnalysisTaskEmcal
    if (fJetShapeType != AliAnalysisTaskSubJetFraction::kGenOnTheFly) fhPhiTriggerHadronEventPlaneTPC->Fill(TMath::Abs(RelativePhiEventPlane(((AliVAODHeader*)(InputEvent()->GetHeader()))->GetEventplane(),TriggerHadron->Phi()))); //TPC event plane 
  }

  
  if (fJetShapeType == AliAnalysisTaskSubJetFraction::kDetEmbPart){
    AliEmcalJet *Jet1 = NULL; //Subtracted hybrid Jet  
    AliEmcalJet *Jet2 = NULL; //Unsubtracted Hybrid Jet                                                                                                                     
    AliEmcalJet *Jet3 = NULL; //Detector Level Pythia Jet
    AliEmcalJet *Jet4 = NULL; //Particle Level Pyhtia Jet
    AliJetContainer *JetCont1= GetJetContainer(0); //Jet Container for Subtracted Hybrid Jets 
    AliJetContainer *JetCont2= GetJetContainer(1); //Jet Container for Unsubtracted Hybrid Jets                                                                                  
    AliJetContainer *JetCont3= GetJetContainer(2); //Jet Container for Detector Level Pyhtia Jets 
    AliJetContainer *JetCont4= GetJetContainer(3); //Jet Container for Particle Level Pythia Jets
    AliEmcalJetFinder *Reclusterer1; //Object containg Subjets from Subtracted Hybrid Jets     
    AliEmcalJetFinder *Reclusterer4; //Object containg Subjets from Particle Level Pythia Jets  
    Bool_t JetsMatched=kFALSE;
    Bool_t EventCounter=kFALSE;
    Int_t JetNumber=-1;
    Double_t JetPtThreshold=-2;
    fhEventCounter->Fill(1);
    if(JetCont1) {
      fhEventCounter->Fill(2);
      JetCont1->ResetCurrentID();
      while((Jet1=JetCont1->GetNextAcceptJet())) {
  if (fJetShapeSub==kConstSub) JetPtThreshold=Jet1->Pt();
  else JetPtThreshold=Jet1->Pt()-(GetRhoVal(0)*Jet1->Area());
        if ( (!Jet1) || (JetPtThreshold<fPtThreshold)) continue;
        else {
    /*  if(fSemigoodCorrect){
      Double_t HoleDistance=RelativePhi(Jet1->Phi(),fHolePos);
      if(TMath::Abs(HoleDistance)<fHoleWidth) continue;
      }*/
    Float_t RecoilDeltaPhi = 0.;
    if (fJetSelection == kRecoil){
      RecoilDeltaPhi = RelativePhi(TriggerHadron->Phi(), Jet1->Phi());
      if (TMath::Abs(RecoilDeltaPhi) < (TMath::Pi() - fRecoilAngularWindow)) continue;  //accept the jet only if it overlaps with the recoil phi area of the trigger
      fh2PtTriggerHadronJet->Fill(TriggerHadron->Pt(), Jet1->Pt());
      fhPhiTriggerHadronJet->Fill(RelativePhi(TriggerHadron->Phi(), Jet1->Phi()));
    }
      if (!EventCounter){
      fhEventCounter->Fill(3);
      EventCounter=kTRUE;
    }
    if(fJetShapeSub==kConstSub){
      JetNumber=-1;
      for(Int_t i = 0; i<JetCont2->GetNJets(); i++) {
        Jet2 = JetCont2->GetJet(i);
        if(Jet2->GetLabel()==Jet1->GetLabel()) {
    JetNumber=i;
        }
      }
      if(JetNumber==-1) continue;
      Jet2=JetCont2->GetJet(JetNumber);
      if (JetCont2->AliJetContainer::GetFractionSharedPt(Jet2)<fSharedFractionPtMin) continue;
      Jet3=Jet2->ClosestJet();
    }
    if(!(fJetShapeSub==kConstSub)){
      if (JetCont1->AliJetContainer::GetFractionSharedPt(Jet1)<fSharedFractionPtMin) continue;
      Jet3 = Jet1->ClosestJet();   //Note for NoSub and Deriv Sub cases you must fill both the Unsubtracted and Subtracted Hybrid jet containers with the same jet branch
    }
    if (!Jet3) continue;
    Jet4=Jet3->ClosestJet();
    if(!Jet4) continue;
    JetsMatched=kTRUE;  
    if (fJetShapeSub==kConstSub) fShapesVar[0]=Jet1->Pt();
    else fShapesVar[0]=Jet1->Pt()-(GetRhoVal(0)*Jet1->Area());
    fShapesVar[2]=fjNSubJettiness(Jet1,0,1,0,1,0);
    fShapesVar[4]=fjNSubJettiness(Jet1,0,2,0,1,0);
    fShapesVar[6]=fjNSubJettiness(Jet1,0,2,0,1,8);
    fShapesVar[8]=fjNSubJettiness(Jet1,0,2,0,1,1);
    // fShapesVar[10]=Jet1->GetNumberOfTracks();
    fShapesVar[10]=fjNSubJettiness(Jet1,0,2,0,1,9);
    fShapesVar[12]=fjNSubJettiness(Jet1,0,2,0,1,3,fBeta_SD,fZCut);
    fShapesVar[14]=fjNSubJettiness(Jet1,0,2,0,1,5,fBeta_SD,fZCut);
    fShapesVar[16]=Jet1->GetLeadingTrack(JetCont1->GetParticleContainer()->GetArray())->Pt();
    fShapesVar[18]=RelativePhiEventPlane(fEPV0,Jet1->Phi());
    //fShapesVar[20]=RelativePhiEventPlane(((AliVAODHeader*)(InputEvent()->GetHeader()))->GetEventplane(),Jet1->Phi());
    fShapesVar[20]=fjNSubJettiness(Jet1,0,2,0,1,6,fBeta_SD,fZCut);
    if (fFullTree){
      fShapesVar[22]=fjNSubJettiness(Jet1,0,2,0,1,2);
      Reclusterer1 = Recluster(Jet1, 0, fSubJetRadius, fSubJetMinPt, fSubJetAlgorithm, "SubJetFinder_1");
      fShapesVar[24]=SubJetFraction(Jet1, Reclusterer1, 1, 0, kTRUE, kFALSE);
      fShapesVar[26]=SubJetFraction(Jet1, Reclusterer1, 2, 0, kTRUE, kFALSE);
    }
    if (JetsMatched){ //even needed? Not now but might be if you want to fill trees when jets aren't matched too
      fShapesVar[1]=Jet4->Pt();
      fShapesVar[3]=fjNSubJettiness(Jet4,3,1,0,1,0);
      fShapesVar[5]=fjNSubJettiness(Jet4,3,2,0,1,0);
      fShapesVar[7]=fjNSubJettiness(Jet4,3,2,0,1,8);
      fShapesVar[9]=fjNSubJettiness(Jet4,3,2,0,1,1);
      //fShapesVar[11]=Jet4->GetNumberOfTracks();
      fShapesVar[11]=fjNSubJettiness(Jet4,3,2,0,1,9);
      fShapesVar[13]=fjNSubJettiness(Jet4,3,2,0,1,3,fBeta_SD,fZCut);
      fShapesVar[15]=fjNSubJettiness(Jet4,3,2,0,1,5,fBeta_SD,fZCut);
      fShapesVar[17]=Jet4->GetLeadingTrack(JetCont4->GetParticleContainer()->GetArray())->Pt();
      fShapesVar[19]=RelativePhiEventPlane(fEPV0,Jet4->Phi());
      //fShapesVar[21]=RelativePhiEventPlane(((AliVAODHeader*)(InputEvent()->GetHeader()))->GetEventplane(),Jet4->Phi());
      fShapesVar[21]=fjNSubJettiness(Jet4,3,2,0,1,6,fBeta_SD,fZCut);
      if (fFullTree){
        fShapesVar[23]=fjNSubJettiness(Jet4,3,2,0,1,2);
        Reclusterer4=Recluster(Jet4, 3, fSubJetRadius, 0, fSubJetAlgorithm, "SubJetFinder_4");
        fShapesVar[25]=SubJetFraction(Jet4, Reclusterer4, 1, 0, kTRUE, kFALSE);
        fShapesVar[27]=SubJetFraction(Jet4, Reclusterer4, 2, 0, kTRUE, kFALSE);
      } 
    }
    else{
      fShapesVar[1]=-2;
      fShapesVar[3]=-2;
      fShapesVar[5]=-2;
      fShapesVar[7]=-2;
      fShapesVar[9]=-2;
      fShapesVar[11]=-2;
      fShapesVar[13]=-2;
      fShapesVar[15]=-2;
      fShapesVar[17]=-2;
      fShapesVar[19]=-2;
      fShapesVar[21]=-2;
      if (fFullTree){
        fShapesVar[23]=-2;
        fShapesVar[25]=-2;
        fShapesVar[27]=-2;
      }
    }
    fTreeResponseMatrixAxis->Fill();
    JetsMatched=kFALSE;
  }
      }
    }
  }
  
  if (fJetShapeType == AliAnalysisTaskSubJetFraction::kTrueDet){          
    AliEmcalJet *Jet1 = NULL; //Detector Level Jet                                                                                                                  
    AliEmcalJet *Jet2 = NULL; //Particle Level Jet  
    AliJetContainer *JetCont1= GetJetContainer(0); //Jet Container for Detector Level Pythia
    AliJetContainer *JetCont2= GetJetContainer(1); //Jet Container for Particle Level Pythia
    AliEmcalJetFinder *Reclusterer1; //Object containg Subjets Detector Level 
    AliEmcalJetFinder *Reclusterer2; //Object containg Subjets Particle Level 
    Int_t JetCounter1=0; //Counts number of jets in event
    Int_t JetCounter2=0; //Counts number of jets in event                                                                                                      
    Double_t JetPhi1=0;
    Double_t JetPhi2=0;
    Bool_t JetsMatched=kFALSE;
    Double_t Pythia_Event_Weight=1;
    Bool_t EventCounter=kFALSE;
    fhEventCounter_1->Fill(1);
    if(JetCont1) {
      fhEventCounter_1->Fill(2); //Number of events with a jet container                                                                                               
      JetCont1->ResetCurrentID();
      while((Jet1=JetCont1->GetNextAcceptJet())) {
  if( (!Jet1) || ((Jet1->Pt())<fPtThreshold)) {
    // fhEventCounter_1->Fill(3); //events where the jet had a problem                                                                                   
    continue;
  }
  else {
    /* if(fSemigoodCorrect){
      Double_t HoleDistance=RelativePhi(Jet1->Phi(),fHolePos);
      if(TMath::Abs(HoleDistance)<fHoleWidth) continue;
      }*/
    Float_t RecoilDeltaPhi = 0.;
    if (fJetSelection == kRecoil){
      RecoilDeltaPhi = RelativePhi(TriggerHadron->Phi(), Jet1->Phi());
      if (TMath::Abs(RecoilDeltaPhi) < (TMath::Pi() - fRecoilAngularWindow)) continue;  //accept the jet only if it overlaps with the recoil phi area of the trigger
      fh2PtTriggerHadronJet->Fill(TriggerHadron->Pt(), Jet1->Pt());
      fhPhiTriggerHadronJet->Fill(RelativePhi(TriggerHadron->Phi(), Jet1->Phi()));
    }
    if (!EventCounter){
      fhEventCounter_1->Fill(3);
      EventCounter=kTRUE;
    }
    if((Jet1->GetNumberOfTracks())==0){
      fhEventCounter_1->Fill(10); //zero track jets                                                                                                         
    }
    if((Jet1->GetNumberOfTracks())==1){
      fhEventCounter_1->Fill(11); //one track jets                                                                                                              
    }
    fhEventCounter_1->Fill(4); //Number of Jets found in all events                                                                                         
    JetCounter1++;
    fhJetPt_1->Fill(Jet1->Pt());
    JetPhi1=Jet1->Phi();
    if(JetPhi1 < -1*TMath::Pi()) JetPhi1 += (2*TMath::Pi());
    else if (JetPhi1 > TMath::Pi()) JetPhi1 -= (2*TMath::Pi());
    fhJetPhi_1->Fill(JetPhi1);
    fhJetEta_1->Fill(Jet1->Eta());
    fhJetMass_1->Fill(Jet1->M());
    fhJetRadius_1->Fill(TMath::Sqrt((Jet1->Area()/TMath::Pi()))); //Radius of Jets per event                                                            
    fhNumberOfJetTracks_1->Fill(Jet1->GetNumberOfTracks());
    if((Jet2 = Jet1->ClosestJet())){
      JetsMatched=kTRUE;
      if((Jet2->GetNumberOfTracks())==0){
        fhEventCounter_2->Fill(10); //zero track jets                                                                                              
      }
      if((Jet2->GetNumberOfTracks())==1){
        fhEventCounter_2->Fill(11); //one track jets                                                                                              
      }
      fhEventCounter_2->Fill(4); //Number of Jets found in all events                                                                                                  
      JetCounter2++;
      fhJetPt_2->Fill(Jet2->Pt());
      JetPhi2=Jet2->Phi();
      if(JetPhi2 < -1*TMath::Pi()) JetPhi2 += (2*TMath::Pi());
      else if (JetPhi2 > TMath::Pi()) JetPhi2 -= (2*TMath::Pi());
      fhJetPhi_2->Fill(JetPhi2);
      fhJetEta_2->Fill(Jet2->Eta());
      fhJetMass_2->Fill(Jet2->M());
      fhJetRadius_2->Fill(TMath::Sqrt((Jet2->Area()/TMath::Pi()))); //Radius of Jets per event                                                                         
      fhNumberOfJetTracks_2->Fill(Jet2->GetNumberOfTracks());
      fh2PtRatio->Fill(Jet1->Pt(),Jet2->Pt(),Pythia_Event_Weight);
    }
          else {
            fhEventCounter_2->Fill(1);
      //continue;
          }
    

    fShapesVar[0]=Jet1->Pt();
    fShapesVar[2]=fjNSubJettiness(Jet1,0,1,0,1,0);
    fShapesVar[4]=fjNSubJettiness(Jet1,0,2,0,1,0);
    fShapesVar[6]=fjNSubJettiness(Jet1,0,2,0,1,8);
    fShapesVar[8]=fjNSubJettiness(Jet1,0,2,0,1,1);
    // fShapesVar[10]=Jet1->GetNumberOfTracks();
    fShapesVar[10]=fjNSubJettiness(Jet1,0,2,0,1,9);
    fShapesVar[12]=fjNSubJettiness(Jet1,0,2,0,1,3,fBeta_SD,fZCut);
    fShapesVar[14]=fjNSubJettiness(Jet1,0,2,0,1,5,fBeta_SD,fZCut);
    fShapesVar[16]=Jet1->GetLeadingTrack(JetCont1->GetParticleContainer()->GetArray())->Pt();
    fShapesVar[18]=-2; //event plane calculation only needed for PbPb recoils
    fShapesVar[20]=fjNSubJettiness(Jet1,0,2,0,1,6,fBeta_SD,fZCut);
    Reclusterer1 = Recluster(Jet1, 0, fSubJetRadius, fSubJetMinPt, fSubJetAlgorithm, "SubJetFinder_1");
    if (fFullTree){
      fShapesVar[22]=fjNSubJettiness(Jet1,0,2,0,1,2);
      fShapesVar[24]=SubJetFraction(Jet1, Reclusterer1, 1, 0, kTRUE, kFALSE);
      fShapesVar[26]=SubJetFraction(Jet1, Reclusterer1, 2, 0, kTRUE, kFALSE);
    }
    if (JetsMatched){ //even needed? Not now but might be if you want to fill trees when jets aren't matched too
      fShapesVar[1]=Jet2->Pt();
      fShapesVar[3]=fjNSubJettiness(Jet2,1,1,0,1,0);
      fShapesVar[5]=fjNSubJettiness(Jet2,1,2,0,1,0);
      fShapesVar[7]=fjNSubJettiness(Jet2,1,2,0,1,8);
      fShapesVar[9]=fjNSubJettiness(Jet2,1,2,0,1,1);
      // fShapesVar[11]=Jet2->GetNumberOfTracks();
      fShapesVar[11]=fjNSubJettiness(Jet2,1,2,0,1,9);
      fShapesVar[13]=fjNSubJettiness(Jet2,1,2,0,1,3,fBeta_SD,fZCut);
      fShapesVar[15]=fjNSubJettiness(Jet2,1,2,0,1,5,fBeta_SD,fZCut);
      fShapesVar[17]=Jet2->GetLeadingTrack(JetCont2->GetParticleContainer()->GetArray())->Pt();
      fShapesVar[19]=-2;
      fShapesVar[21]=fjNSubJettiness(Jet2,1,2,0,1,6,fBeta_SD,fZCut);
      Reclusterer2 = Recluster(Jet2, 1, fSubJetRadius, 0, fSubJetAlgorithm, "SubJetFinder_2");
      if (fFullTree){
        fShapesVar[23]=fjNSubJettiness(Jet2,1,2,0,1,2);
        fShapesVar[25]=SubJetFraction(Jet2, Reclusterer2, 1, 0, kTRUE, kFALSE);
        fShapesVar[27]=SubJetFraction(Jet2, Reclusterer2, 2, 0, kTRUE, kFALSE);
      } 
    }
    else{
      fShapesVar[1]=-2;
      fShapesVar[3]=-2;
      fShapesVar[5]=-2;
      fShapesVar[7]=-2;
      fShapesVar[9]=-2;
      fShapesVar[11]=-2;
      fShapesVar[13]=-2;
      fShapesVar[15]=-2;
      fShapesVar[17]=-2;
      fShapesVar[19]=-2;
      fShapesVar[21]=-2;
      if (fFullTree){
        fShapesVar[23]=-2;
        fShapesVar[25]=-2;
        fShapesVar[27]=-2;
      }
    }
    fTreeResponseMatrixAxis->Fill();

    fhSubJetCounter_1->Fill(Reclusterer1->GetNumberOfJets());
    for (Int_t i= 0; i<Reclusterer1->GetNumberOfJets(); i++){
      fhEventCounter_1->Fill(6); //Number of overall subjets in all events                                                                                           
      fhSubJetPt_1->Fill(Reclusterer1->GetJet(i)->Pt());
      fhSubJetMass_1->Fill(Reclusterer1->GetJet(i)->M());
      fhNumberOfSubJetTracks_1->Fill(Reclusterer1->GetJet(i)->GetNumberOfTracks());
      fhSubJetRadius_1->Fill(TMath::Sqrt((Reclusterer1->GetJet(i)->Area()/TMath::Pi()))); //Radius of SubJets per event                                                 
    }
    if(JetsMatched){
      fhSubJetCounter_2->Fill(Reclusterer2->GetNumberOfJets());
      for (Int_t i= 0; i<Reclusterer2->GetNumberOfJets(); i++){
        fhEventCounter_2->Fill(6); //Number of overall subjets in all events                                                                                          
        fhSubJetPt_2->Fill(Reclusterer2->GetJet(i)->Pt());
        fhSubJetMass_2->Fill(Reclusterer2->GetJet(i)->M());
        fhNumberOfSubJetTracks_2->Fill(Reclusterer2->GetJet(i)->GetNumberOfTracks());
        fhSubJetRadius_2->Fill(TMath::Sqrt((Reclusterer2->GetJet(i)->Area()/TMath::Pi()))); //Radius of SubJets per event                                            
      }
    }
    JetsMatched=kFALSE;
  }
      }
      fhJetCounter_1->Fill(JetCounter1); //Number of Jets in Each Event Particle Level                                                                 
      fhJetCounter_2->Fill(JetCounter2); //Number of Jets in Each Event Detector Level        
    }
    //else {fhEventCounter_1->Fill(3);} //Events with no jet container 
  }


  
  if (fJetShapeType == AliAnalysisTaskSubJetFraction::kData){
    AliEmcalJet *Jet1 = NULL; //Original Jet in the event                                                                                                                
    AliJetContainer *JetCont= GetJetContainer(0); //Jet Container for event 
    Int_t JetCounter=0; //Counts number of jets in event  
    Double_t JetPhi=0;
    Bool_t EventCounter=kFALSE;
    Double_t JetPt_ForThreshold=0;
    fhEventCounter->Fill(1);
    if(JetCont) {
      fhEventCounter->Fill(2); //Number of events with a jet container
      JetCont->ResetCurrentID();
      while((Jet1=JetCont->GetNextAcceptJet())) {
  if(!Jet1) continue;
  if (fJetShapeSub==kNoSub || fJetShapeSub==kDerivSub) JetPt_ForThreshold = Jet1->Pt()-(GetRhoVal(0)*Jet1->Area());
  else JetPt_ForThreshold = Jet1->Pt();
  if(JetPt_ForThreshold<fPtThreshold) {
    //fhEventCounter->Fill(3); //events where the jet had a problem
    continue;
  }
  else {
    /* if(fSemigoodCorrect){
      Double_t HoleDistance=RelativePhi(Jet1->Phi(),fHolePos);
      if(TMath::Abs(HoleDistance)<fHoleWidth) continue;
    }*/
    Float_t RecoilDeltaPhi = 0.;
    if (fJetSelection == kRecoil){
      RecoilDeltaPhi = RelativePhi(TriggerHadron->Phi(), Jet1->Phi());
      if (TMath::Abs(RecoilDeltaPhi) < (TMath::Pi() - fRecoilAngularWindow)) continue;  //accept the jet only if it overlaps with the recoil phi area of the trigger
      fh2PtTriggerHadronJet->Fill(TriggerHadron->Pt(), Jet1->Pt());
      fhPhiTriggerHadronJet->Fill(RelativePhi(TriggerHadron->Phi(), Jet1->Phi()));
    }
          if (!EventCounter){
            fhEventCounter->Fill(3);
            EventCounter=kTRUE;
          }
    if((Jet1->GetNumberOfTracks())==0){
      fhEventCounter->Fill(10); //zero track jets
    }
    if((Jet1->GetNumberOfTracks())==1){
      fhEventCounter->Fill(11); //one track jets
    }
          fhEventCounter->Fill(4); //Number of Jets found in all events  
    JetCounter++;
    fhJetPt->Fill(Jet1->Pt());    
    JetPhi=Jet1->Phi();
    if(JetPhi < -1*TMath::Pi()) JetPhi += (2*TMath::Pi());
    else if (JetPhi > TMath::Pi()) JetPhi -= (2*TMath::Pi());
    fhJetPhi->Fill(JetPhi);
    fhJetEta->Fill(Jet1->Eta());
    fhJetMass->Fill(Jet1->M());
    fhJetRadius->Fill(TMath::Sqrt((Jet1->Area()/TMath::Pi()))); //Radius of Jets per event
          fhNumberOfJetTracks->Fill(Jet1->GetNumberOfTracks());   
    if(fJetShapeSub==kNoSub || fJetShapeSub==kDerivSub) fShapesVar[0]= Jet1->Pt()-(GetRhoVal(0)*Jet1->Area());
    else fShapesVar[0]=Jet1->Pt();
    fShapesVar[2]=fjNSubJettiness(Jet1,0,1,0,1,0);
    fShapesVar[4]=fjNSubJettiness(Jet1,0,2,0,1,0);
    fShapesVar[6]=fjNSubJettiness(Jet1,0,2,0,1,8);
    fShapesVar[8]=fjNSubJettiness(Jet1,0,2,0,1,1);
    //fShapesVar[10]=Jet1->GetNumberOfTracks();
    fShapesVar[10]=fjNSubJettiness(Jet1,0,2,0,1,9);
    fShapesVar[12]=fjNSubJettiness(Jet1,0,2,0,1,3,fBeta_SD,fZCut);
    fShapesVar[14]=fjNSubJettiness(Jet1,0,2,0,1,5,fBeta_SD,fZCut);
    fShapesVar[16]=Jet1->GetLeadingTrack(JetCont->GetParticleContainer()->GetArray())->Pt();
    fShapesVar[18]=-2; //event plane calculation not needed for data
    fShapesVar[20]=fjNSubJettiness(Jet1,0,2,0,1,6,fBeta_SD,fZCut);
    AliEmcalJetFinder *Reclusterer1 = Recluster(Jet1, 0, fSubJetRadius, fSubJetMinPt, fSubJetAlgorithm, "SubJetFinder");
    if (fFullTree){
      fShapesVar[22]=fjNSubJettiness(Jet1,0,2,0,1,2);
      fShapesVar[24]=SubJetFraction(Jet1, Reclusterer1, 1, 0, kTRUE, kFALSE);
      fShapesVar[26]=SubJetFraction(Jet1, Reclusterer1, 2, 0, kTRUE, kFALSE);
    }
    fShapesVar[1]=-2;
    fShapesVar[3]=-2;
    fShapesVar[5]=-2;
    fShapesVar[7]=-2;
    fShapesVar[9]=-2;
    fShapesVar[11]=-2;
    fShapesVar[13]=-2;
    fShapesVar[15]=-2;
    fShapesVar[17]=-2;
    fShapesVar[19]=-2;
    fShapesVar[21]=-2;
    if (fFullTree){
      fShapesVar[23]=-2;
      fShapesVar[25]=-2;
      fShapesVar[27]=-2;
    }
    fTreeResponseMatrixAxis->Fill();
    fhSubJetCounter->Fill(Reclusterer1->GetNumberOfJets());
    for (Int_t i= 0; i<Reclusterer1->GetNumberOfJets(); i++){
      fhEventCounter->Fill(6); //Number of overall subjets in all events
      fhSubJetPt->Fill(Reclusterer1->GetJet(i)->Pt());
      fhSubJetMass->Fill(Reclusterer1->GetJet(i)->M());
      fhNumberOfSubJetTracks->Fill(Reclusterer1->GetJet(i)->GetNumberOfTracks());
      fhSubJetRadius->Fill(TMath::Sqrt((Reclusterer1->GetJet(i)->Area()/TMath::Pi()))); //Radius of SubJets per event
    }
  }
      }
      fhJetCounter->Fill(JetCounter); //Number of Jets in Each Event
    }
    //else {fhEventCounter->Fill(2);} //Events with no jet container
  }

  
  if (fJetShapeType==AliAnalysisTaskSubJetFraction::kSim || fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly){
    
    AliEmcalJet *Jet1 = NULL; //Original Jet in the event                                                                                                                
    AliJetContainer *JetCont= GetJetContainer(0); //Jet Container for event 
    Int_t JetCounter=0; //Counts number of jets in event  
    Double_t JetPhi=0;
    Bool_t EventCounter=kFALSE;
    Double_t JetPt_ForThreshold=0;
    fhEventCounter->Fill(1);
    if(JetCont) {
      fhEventCounter->Fill(2); //Number of events with a jet container
      JetCont->ResetCurrentID();
      while((Jet1=JetCont->GetNextAcceptJet())) {
  //  if (((Jet1=JetCont->GetLeadingJet("rho")) && (fPtThreshold<=Jet1->Pt()-(GetRhoVal(0)*Jet1->Area())))){ 
  if(!Jet1) continue;
  if(fJetShapeSub==kNoSub || fJetShapeSub==kDerivSub) JetPt_ForThreshold = Jet1->Pt()-(GetRhoVal(0)*Jet1->Area());
  else JetPt_ForThreshold = Jet1->Pt(); 
  if(JetPt_ForThreshold<fPtThreshold) {
    //fhEventCounter->Fill(3); //events where the jet had a problem
    continue;
  }
  else {
    /* if(fSemigoodCorrect){
      Double_t HoleDistance=RelativePhi(Jet1->Phi(),fHolePos);
      if(TMath::Abs(HoleDistance)<fHoleWidth) continue;
    }*/
    Float_t RecoilDeltaPhi = 0.;
    if (fJetSelection == kRecoil){
      RecoilDeltaPhi = RelativePhi(TriggerHadron->Phi(), Jet1->Phi());
      if (TMath::Abs(RecoilDeltaPhi) < (TMath::Pi() - fRecoilAngularWindow)) continue;  //accept the jet only if it overlaps with the recoil phi area of the trigger
      fh2PtTriggerHadronJet->Fill(TriggerHadron->Pt(), Jet1->Pt());
      fhPhiTriggerHadronJet->Fill(RelativePhi(TriggerHadron->Phi(), Jet1->Phi()));
    }
          if (!EventCounter){
            fhEventCounter->Fill(3);
            EventCounter=kTRUE;
          }
    if((Jet1->GetNumberOfTracks())==0){
      fhEventCounter->Fill(10); //zero track jets
    }
    if((Jet1->GetNumberOfTracks())==1){
      fhEventCounter->Fill(11); //one track jets
    }
          fhEventCounter->Fill(4); //Number of Jets found in all events  
    JetCounter++;
    fhJetPt->Fill(Jet1->Pt());    
    JetPhi=Jet1->Phi();
    if(JetPhi < -1*TMath::Pi()) JetPhi += (2*TMath::Pi());
    else if (JetPhi > TMath::Pi()) JetPhi -= (2*TMath::Pi());
    fhJetPhi->Fill(JetPhi);
    fhJetEta->Fill(Jet1->Eta());
    fhJetMass->Fill(Jet1->M());
    fhJetRadius->Fill(TMath::Sqrt((Jet1->Area()/TMath::Pi()))); //Radius of Jets per event
          fhNumberOfJetTracks->Fill(Jet1->GetNumberOfTracks());

    Int_t FJ_Algorithm=9; //KT=0, CA=1, AKT_R02=2, WTA_KT=3, WTA_CA=4, OP_KT=5, OP_CA=6, OP_AKT_R02=7, OP_WTA_KT=8, OP_WTA_CA=9, MIN=10
    Double_t FJ_Beta=1.0;
    /*  fhSubJettiness1CheckRatio_FJ_KT->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1CheckRatio_FJ_CA->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,1,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1CheckRatio_FJ_AKT->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,2,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1CheckRatio_FJ_WTA_KT->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,3,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1CheckRatio_FJ_WTA_CA->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,4,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1CheckRatio_FJ_OP_KT->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,5,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1CheckRatio_FJ_OP_CA->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,6,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1CheckRatio_FJ_OP_AKT->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,7,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1CheckRatio_FJ_OP_WTA_KT->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,8,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1CheckRatio_FJ_OP_WTA_CA->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,9,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1CheckRatio_FJ_MIN->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,1,10,FJ_Beta,0),fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_KT->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_CA->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,1,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_AKT->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,2,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_WTA_KT->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,3,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_WTA_CA->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,4,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_OP_KT->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,5,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_OP_CA->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,6,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_OP_AKT->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,7,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_OP_WTA_KT->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,8,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_OP_WTA_CA->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,9,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2CheckRatio_FJ_MIN->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)-fjNSubJettiness(Jet1,0,2,10,FJ_Beta,0),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));

    fhSubJettiness2to1CheckRatio_FJ_KT->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1CheckRatio_FJ_CA->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,1,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,1,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1CheckRatio_FJ_AKT->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,2,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,2,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1CheckRatio_FJ_WTA_KT->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,3,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,3,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1CheckRatio_FJ_WTA_CA->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,4,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,4,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1CheckRatio_FJ_OP_KT->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,5,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,5,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1CheckRatio_FJ_OP_CA->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,6,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,6,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1CheckRatio_FJ_OP_AKT->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,7,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,7,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1CheckRatio_FJ_OP_WTA_KT->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,8,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,8,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1CheckRatio_FJ_OP_WTA_CA->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,9,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,9,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1CheckRatio_FJ_MIN->Fill((fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0))-(fjNSubJettiness(Jet1,0,2,10,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,10,FJ_Beta,0)),fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));


    fhSubJettiness1_FJ_KT->Fill(fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness1_FJ_CA->Fill(fjNSubJettiness(Jet1,0,1,1,FJ_Beta,0));
    fhSubJettiness1_FJ_AKT->Fill(fjNSubJettiness(Jet1,0,1,2,FJ_Beta,0));
    fhSubJettiness1_FJ_WTA_KT->Fill(fjNSubJettiness(Jet1,0,1,3,FJ_Beta,0));
    fhSubJettiness1_FJ_WTA_CA->Fill(fjNSubJettiness(Jet1,0,1,4,FJ_Beta,0));
    fhSubJettiness1_FJ_OP_KT->Fill(fjNSubJettiness(Jet1,0,1,5,FJ_Beta,0));
    fhSubJettiness1_FJ_OP_CA->Fill(fjNSubJettiness(Jet1,0,1,6,FJ_Beta,0));
    fhSubJettiness1_FJ_OP_AKT->Fill(fjNSubJettiness(Jet1,0,1,7,FJ_Beta,0));
    fhSubJettiness1_FJ_OP_WTA_KT->Fill(fjNSubJettiness(Jet1,0,1,8,FJ_Beta,0));
    fhSubJettiness1_FJ_OP_WTA_CA->Fill(fjNSubJettiness(Jet1,0,1,9,FJ_Beta,0));
    fhSubJettiness1_FJ_MIN->Fill(fjNSubJettiness(Jet1,0,1,10,FJ_Beta,0));
    fhSubJettiness2_FJ_KT->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0));
    fhSubJettiness2_FJ_CA->Fill(fjNSubJettiness(Jet1,0,2,1,FJ_Beta,0));
    fhSubJettiness2_FJ_AKT->Fill(fjNSubJettiness(Jet1,0,2,2,FJ_Beta,0)); //because in this case we aren't garantueed to get 2 subjets
    fhSubJettiness2_FJ_WTA_KT->Fill(fjNSubJettiness(Jet1,0,2,3,FJ_Beta,0));
    fhSubJettiness2_FJ_WTA_CA->Fill(fjNSubJettiness(Jet1,0,2,4,FJ_Beta,0));
    fhSubJettiness2_FJ_OP_KT->Fill(fjNSubJettiness(Jet1,0,2,5,FJ_Beta,0));
    fhSubJettiness2_FJ_OP_CA->Fill(fjNSubJettiness(Jet1,0,2,6,FJ_Beta,0));
    fhSubJettiness2_FJ_OP_AKT->Fill(fjNSubJettiness(Jet1,0,2,7,FJ_Beta,0));
    fhSubJettiness2_FJ_OP_WTA_KT->Fill(fjNSubJettiness(Jet1,0,2,8,FJ_Beta,0));
    fhSubJettiness2_FJ_OP_WTA_CA->Fill(fjNSubJettiness(Jet1,0,2,9,FJ_Beta,0));
    fhSubJettiness2_FJ_MIN->Fill(fjNSubJettiness(Jet1,0,2,10,FJ_Beta,0));

    fhSubJettiness2to1_FJ_KT->Fill(fjNSubJettiness(Jet1,0,2,0,FJ_Beta,0)/fjNSubJettiness(Jet1,0,1,0,FJ_Beta,0));
    fhSubJettiness2to1_FJ_CA->Fill(fjNSubJettiness(Jet1,0,2,1,FJ_Beta,0)/fjNSubJettiness(Jet1,0,2,1,FJ_Beta,0));
    fhSubJettiness2to1_FJ_AKT->Fill(fjNSubJettiness(Jet1,0,2,2,FJ_Beta,0)/fjNSubJettiness(Jet1,0,2,2,FJ_Beta,0)); //because in this case we aren't garantueed to get 2 subjets
    fhSubJettiness2to1_FJ_WTA_KT->Fill(fjNSubJettiness(Jet1,0,2,3,FJ_Beta,0)/fjNSubJettiness(Jet1,0,2,3,FJ_Beta,0));
    fhSubJettiness2to1_FJ_WTA_CA->Fill(fjNSubJettiness(Jet1,0,2,4,FJ_Beta,0)/fjNSubJettiness(Jet1,0,2,4,FJ_Beta,0));
    fhSubJettiness2to1_FJ_OP_KT->Fill(fjNSubJettiness(Jet1,0,2,5,FJ_Beta,0)/fjNSubJettiness(Jet1,0,2,5,FJ_Beta,0));
    fhSubJettiness2to1_FJ_OP_CA->Fill(fjNSubJettiness(Jet1,0,2,6,FJ_Beta,0)/fjNSubJettiness(Jet1,0,2,6,FJ_Beta,0));
    fhSubJettiness2to1_FJ_OP_AKT->Fill(fjNSubJettiness(Jet1,0,2,7,FJ_Beta,0)/fjNSubJettiness(Jet1,0,2,7,FJ_Beta,0));
    fhSubJettiness2to1_FJ_OP_WTA_KT->Fill(fjNSubJettiness(Jet1,0,2,8,FJ_Beta,0)/fjNSubJettiness(Jet1,0,2,8,FJ_Beta,0));
    fhSubJettiness2to1_FJ_OP_WTA_CA->Fill(fjNSubJettiness(Jet1,0,2,9,FJ_Beta,0)/fjNSubJettiness(Jet1,0,2,9,FJ_Beta,0));
    fhSubJettiness2to1_FJ_MIN->Fill(fjNSubJettiness(Jet1,0,2,10,FJ_Beta,0)/fjNSubJettiness(Jet1,0,2,10,FJ_Beta,0));
    */
    if(fJetShapeSub==kNoSub || fJetShapeSub==kDerivSub) fShapesVar[0]= Jet1->Pt()-(GetRhoVal(0)*Jet1->Area());
    else fShapesVar[0]=Jet1->Pt(); 
    fShapesVar[2]=fjNSubJettiness(Jet1,0,1,0,1,0);
    fShapesVar[4]=fjNSubJettiness(Jet1,0,2,0,1,0);
    fShapesVar[6]=fjNSubJettiness(Jet1,0,2,0,1,8);
    fShapesVar[8]=fjNSubJettiness(Jet1,0,2,0,1,1);
    // fShapesVar[10]=Jet1->GetNumberOfTracks();
    fShapesVar[10]=fjNSubJettiness(Jet1,0,2,0,1,9);
    fShapesVar[12]=fjNSubJettiness(Jet1,0,2,0,1,3,fBeta_SD,fZCut);
    fShapesVar[14]=fjNSubJettiness(Jet1,0,2,0,1,5,fBeta_SD,fZCut);
    fShapesVar[16]=Jet1->GetLeadingTrack(JetCont->GetParticleContainer()->GetArray())->Pt();
    fShapesVar[18]=-2;
    fShapesVar[20]=fjNSubJettiness(Jet1,0,2,0,1,6,fBeta_SD,fZCut);
    AliEmcalJetFinder *Reclusterer1 = Recluster(Jet1, 0, fSubJetRadius, fSubJetMinPt, fSubJetAlgorithm, "SubJetFinder");
    if (fFullTree){
      fShapesVar[22]=fjNSubJettiness(Jet1,0,2,0,1,2);
      fShapesVar[24]=SubJetFraction(Jet1, Reclusterer1, 1, 0, kTRUE, kFALSE);
      fShapesVar[26]=SubJetFraction(Jet1, Reclusterer1, 2, 0, kTRUE, kFALSE);
    }
    fShapesVar[1]=-2;
    fShapesVar[3]=-2;
    fShapesVar[5]=-2;
    fShapesVar[7]=-2;
    fShapesVar[9]=-2;
    fShapesVar[11]=-2;
    fShapesVar[13]=-2;
    fShapesVar[15]=-2;
    fShapesVar[17]=-2;
    fShapesVar[19]=-2;
    fShapesVar[21]=-2;
    if (fFullTree){
      fShapesVar[23]=-2;
      fShapesVar[25]=-2;
      fShapesVar[27]=-2;
    }
    fTreeResponseMatrixAxis->Fill();
    
    fhSubJetCounter->Fill(Reclusterer1->GetNumberOfJets());
    for (Int_t i= 0; i<Reclusterer1->GetNumberOfJets(); i++){
      fhEventCounter->Fill(6); //Number of overall subjets in all events 
      fhSubJetPt->Fill(Reclusterer1->GetJet(i)->Pt());
      fhSubJetMass->Fill(Reclusterer1->GetJet(i)->M());
      fhNumberOfSubJetTracks->Fill(Reclusterer1->GetJet(i)->GetNumberOfTracks());                                                                            
      fhSubJetRadius->Fill(TMath::Sqrt((Reclusterer1->GetJet(i)->Area()/TMath::Pi()))); //Radius of SubJets per event   
    } 
  }    
      }
      fhJetCounter->Fill(JetCounter); //Number of Jets in Each Event
    }
    //else {fhEventCounter->Fill(2);} //Events with no jet container
  }
  return kTRUE;
}
//________________________________________________________________________
Double_t AliAnalysisTaskSubJetFraction::RelativePhiEventPlane(Double_t EventPlane, Double_t Phi){

  if(Phi < -1*TMath::Pi()) Phi += (2*TMath::Pi());
  else if (Phi > TMath::Pi()) Phi -= (2*TMath::Pi());
  Double_t DeltaPhi=Phi-EventPlane;
  if(DeltaPhi < -1*TMath::Pi()) DeltaPhi += (2*TMath::Pi());
  else if (DeltaPhi > TMath::Pi()) DeltaPhi -= (2*TMath::Pi());
  return DeltaPhi;
}
//________________________________________________________________________
Double_t AliAnalysisTaskSubJetFraction::RelativePhi(Double_t Phi1, Double_t Phi2){

  if(Phi1 < -1*TMath::Pi()) Phi1 += (2*TMath::Pi()); // Turns the range of 0to2Pi into -PitoPi ???????????                                                             
  else if (Phi1 > TMath::Pi()) Phi1 -= (2*TMath::Pi());
  if(Phi2 < -1*TMath::Pi()) Phi2 += (2*TMath::Pi());
  else if (Phi2 > TMath::Pi()) Phi2 -= (2*TMath::Pi());
  Double_t DeltaPhi=Phi2-Phi1;
  if(DeltaPhi < -1*TMath::Pi()) DeltaPhi += (2*TMath::Pi());
  else if (DeltaPhi > TMath::Pi()) DeltaPhi -= (2*TMath::Pi());
  return DeltaPhi;
}


//--------------------------------------------------------------------------
Int_t AliAnalysisTaskSubJetFraction::SelectTriggerHadron(Float_t PtMin, Float_t PtMax){

  AliTrackContainer *PartCont = NULL;
  AliParticleContainer *PartContMC = NULL;


  if (fJetShapeSub==kConstSub){
    if (fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly) PartContMC = GetParticleContainer(1);
    else PartCont = GetTrackContainer(1);
  }
  else{
    if (fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly) PartContMC = GetParticleContainer(0);
    else PartCont = GetTrackContainer(0);
  }
  
  TClonesArray *TracksArray = NULL;
  TClonesArray *TracksArrayMC = NULL;
  if (fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly) TracksArrayMC = PartContMC->GetArray();
  else TracksArray = PartCont->GetArray();
 
  if (fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly){
    if(!PartContMC || !TracksArrayMC) return -99999;
  }
  else {
    if(!PartCont || !TracksArray) return -99999;
  }
    
  AliAODTrack *Track = 0x0;
  Int_t Trigger_Index[100];
  for (Int_t i=0; i<100; i++) Trigger_Index[i] = 0;
  Int_t Trigger_Counter = 0;
  Int_t NTracks=0;
  if (fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly) NTracks = TracksArrayMC->GetEntriesFast();
  else NTracks = TracksArray->GetEntriesFast();
  for(Int_t i=0; i < NTracks; i++){
    if (fJetShapeType == AliAnalysisTaskSubJetFraction::kGenOnTheFly){
      if((Track = static_cast<AliAODTrack*>(PartContMC->GetAcceptParticle(i)))){
  if (!Track) continue;
  if(TMath::Abs(Track->Eta())>0.9) continue;
  if (Track->Pt()<0.15) continue;
  if ((Track->Pt() >= PtMin) && (Track->Pt()< PtMax)) {
    Trigger_Index[Trigger_Counter] = i;
    Trigger_Counter++;
  }
      }
    }
    else{ 
      if((Track = static_cast<AliAODTrack*>(PartCont->GetAcceptTrack(i)))){
  if (!Track) continue;
  if(TMath::Abs(Track->Eta())>0.9) continue;
  if (Track->Pt()<0.15) continue;
  if ((Track->Pt() >= PtMin) && (Track->Pt()< PtMax)) {
    Trigger_Index[Trigger_Counter] = i;
    Trigger_Counter++;
  }
      }
    } 
  }
  if (Trigger_Counter == 0) return -99999;
  Int_t RandomNumber = 0, Index = 0 ; 
  TRandom3* Random = new TRandom3(0); 
  RandomNumber = Random->Integer(Trigger_Counter);
  Index = Trigger_Index[RandomNumber];
  return Index; 
}


//--------------------------------------------------------------------------
Double_t AliAnalysisTaskSubJetFraction::Angularity(AliEmcalJet *Jet, Int_t JetContNb){
  
  AliJetContainer *JetCont = GetJetContainer(JetContNb);
  Double_t Angularity_Numerator=0;  //Reset these values                                                                            
  Double_t Angularity_Denominator=0;
  AliVParticle *Particle=0x0;
  Double_t DeltaPhi=0;


  for (Int_t i=0; i< Jet->GetNumberOfTracks(); i++){  //loops through all tracks (particles in the jet                                                                              
    Particle = static_cast<AliVParticle*>(Jet->TrackAt(i, JetCont->GetParticleContainer()->GetArray()));                                                                 
    if(!Particle) continue;
    DeltaPhi=RelativePhi(Jet->Phi(),Particle->Phi());
    Angularity_Numerator=Angularity_Numerator+(Particle->Pt()*TMath::Sqrt(((Particle->Eta()-Jet->Eta())*(Particle->Eta()-Jet->Eta()))+(DeltaPhi*DeltaPhi)));
    Angularity_Denominator= Angularity_Denominator+Particle->Pt();
  }
  if(Angularity_Denominator!=0) return Angularity_Numerator/Angularity_Denominator;
  else return -1;

}



//--------------------------------------------------------------------------                                                                                                         
Double_t AliAnalysisTaskSubJetFraction::PTD(AliEmcalJet *Jet, Int_t JetContNb){

  AliJetContainer *JetCont = GetJetContainer(JetContNb);
  Double_t PTD_Numerator=0;  //Reset these values                                                                                                                            
  Double_t PTD_Denominator=0;
  AliVParticle *Particle=0x0;
  Double_t DeltaPhi=0;
  for (Int_t i=0; i< Jet->GetNumberOfTracks(); i++){  //loops through all tracks (particles in the jet                                                                            
    Particle = static_cast<AliVParticle*>(Jet->TrackAt(i, JetCont->GetParticleContainer()->GetArray()));
    if(!Particle) continue;
    PTD_Numerator=PTD_Numerator+(Particle->Pt()*Particle->Pt());
    PTD_Denominator=PTD_Denominator+Particle->Pt();
  }
  if(PTD_Denominator!=0) return TMath::Sqrt(PTD_Numerator)/PTD_Denominator;
  else return -1;

}


//----------------------------------------------------------------------
AliEmcalJetFinder *AliAnalysisTaskSubJetFraction::Recluster(AliEmcalJet *Jet, Int_t JetContNb, Double_t SubJetRadius, Double_t SubJetMinPt, Int_t Algorithm, const char* Name){

  AliJetContainer *JetCont = GetJetContainer(JetContNb);
  AliEmcalJetFinder *Reclusterer = new AliEmcalJetFinder(Name); //JetFinder Object for reclustered jets                                                                 
  Reclusterer->SetRadius(SubJetRadius); 
  Reclusterer->SetJetMinPt(SubJetMinPt);
  Reclusterer->SetJetAlgorithm(Algorithm); //0 for anti-kt     1 for kt
  Reclusterer->SetJetMaxEta(0.9);
  Reclusterer->SetRecombSheme(0);
  if(fJetShapeType != AliAnalysisTaskSubJetFraction::kGenOnTheFly){
    const AliVVertex *vert = InputEvent()->GetPrimaryVertex();
    Double_t dVtx[3]={vert->GetX(),vert->GetY(),vert->GetZ()};
    if(Reclusterer->AliEmcalJetFinder::Filter(Jet, JetCont, dVtx)){;}  //reclustering jet1 using the jetfinderobject Reclusterer
  }
  else{
    Double_t dVtx[3]={1,1,1};
    if(Reclusterer->AliEmcalJetFinder::Filter(Jet, JetCont, dVtx)){;}  //reclustering jet1 using the jetfinderobject Reclusterer
  }
  return Reclusterer;
  
}



//----------------------------------------------------------------------
Double_t AliAnalysisTaskSubJetFraction::SubJetOrdering(AliEmcalJet *Jet, AliEmcalJetFinder *Reclusterer, Int_t N, Int_t Type, Bool_t Index){
  AliEmcalJet *SubJet=NULL;
  Double_t SortingVariable;
  Int_t ArraySize =N+1;
  TArrayD *JetSorter = new TArrayD(ArraySize);
  TArrayD *JetIndexSorter = new TArrayD(ArraySize);
  for (Int_t i=0; i<ArraySize; i++){
    JetSorter->SetAt(0,i);
  }
  for (Int_t i=0; i<ArraySize; i++){
    JetIndexSorter->SetAt(0,i);
  }
  if(Reclusterer->GetNumberOfJets()<N) return -999;
  for (Int_t i=0; i<Reclusterer->GetNumberOfJets(); i++){
    SubJet=Reclusterer->GetJet(i);
    if (Type==0) SortingVariable=SubJet->Pt();
    else if (Type==1) SortingVariable=SubJet->E();
    else if (Type==2) SortingVariable=SubJet->M();
    for (Int_t j=0; j<N; j++){
      if (SortingVariable>JetSorter->GetAt(j)){
  for (Int_t k=N-1; k>=j; k--){
    JetSorter->SetAt(JetSorter->GetAt(k),k+1);
    JetIndexSorter->SetAt(JetIndexSorter->GetAt(k),k+1);
  }
  JetSorter->SetAt(SortingVariable,j);
  JetIndexSorter->SetAt(i,j);
  break;
      }
    }
  }
  if (!Index) return JetSorter->GetAt(N-1);
  else return JetIndexSorter->GetAt(N-1);
}



//returns -1 if the Nth hardest jet is requested where N>number of available jets
//type:  0=Pt  1=E  2=M 
//Index TRUE=returns index   FALSE=returns value of quantatiy in question







//----------------------------------------------------------------------                                                                                                        
Double_t AliAnalysisTaskSubJetFraction::SubJetFraction(AliEmcalJet *Jet, AliEmcalJetFinder *Reclusterer, Int_t N, Int_t Type, Bool_t Add, Bool_t Loss){
  AliEmcalJet *SubJet=NULL;
  Double_t Observable=0;
  Double_t Fraction_Numerator=0;
  Bool_t Error=kFALSE;
  if (!Jet->GetNumberOfTracks())    return -2;
  if (Add){
    for (Int_t i=1; i<=N; i++){
      Observable=SubJetOrdering(Jet,Reclusterer,i,Type,kFALSE);
      if(Observable==-999){
  Error = kTRUE;
  return -2;
      }
      Fraction_Numerator=Fraction_Numerator+Observable;
  }
  }
  else {
    Fraction_Numerator=SubJetOrdering(Jet,Reclusterer,N,Type,kFALSE);
    if (Fraction_Numerator==-999) return -2;
  }
  if (Type==0){
    if(Loss) return (Jet->Pt()-Fraction_Numerator)/Jet->Pt();
    else return Fraction_Numerator/Jet->Pt();
  }
  else if (Type==1){
    if(Loss) return (Jet->E()-Fraction_Numerator)/Jet->E();
    else return Fraction_Numerator/Jet->E();
  }
  else { //change to else if if you want to add more later 
    if(Loss) return (Jet->M()-Fraction_Numerator)/Jet->M();
    else return Fraction_Numerator/Jet->M();
  }
}
//N number of hardest subjets involved
//Type 0=Pt 1=E 2=M
// Add TRUE: Add 1 to Nth hardest subjets together/total jet   False: Nth hardest Jet/toal jet
//Loss TRUE: Jet-Subjet(s)/Jet FALSE: Subjet(s)/Jet 


//----------------------------------------------------------------------
Double_t AliAnalysisTaskSubJetFraction::NSubJettiness(AliEmcalJet *Jet, Int_t JetContNb, Double_t JetRadius,  AliEmcalJetFinder *Reclusterer, Int_t N, Int_t A, Int_t B){
  AliJetContainer *JetCont = GetJetContainer(JetContNb);
  AliEmcalJet *SubJet=NULL;
  Double_t DeltaR1=0;
  Double_t DeltaR2=0;
  AliVParticle *JetParticle=0x0;
  Double_t SubJetiness_Numerator = 0;
  Double_t SubJetiness_Denominator = 0;
  Double_t Index=-2;
  Bool_t Error=kFALSE;
  //  JetRadius=TMath::Sqrt((Jet->Area()/TMath::Pi())); //comment out later
  if (!Jet->GetNumberOfTracks())    return -2;                                                                     
  if (Reclusterer->GetNumberOfJets() < N) return -2;
  for (Int_t i=0; i< Jet->GetNumberOfTracks(); i++){  //loops through all tracks (particles in the jet
    JetParticle = static_cast<AliVParticle*>(Jet->TrackAt(i, JetCont->GetParticleContainer()->GetArray()));       
    for (Int_t j=1; j<=N; j++){
      Index=SubJetOrdering(Jet,Reclusterer,j,0,kTRUE);
      if(Index==-999){
  Error = kTRUE;
  i=Jet->GetNumberOfTracks();
  break;
      }
      if(j==1){
  DeltaR1=TMath::Power((Reclusterer->GetJet(Index)->Pt()),A)*TMath::Power((TMath::Sqrt((((JetParticle->Eta())-(Reclusterer->GetJet(Index)->Eta()))*((JetParticle->Eta())- (Reclusterer->GetJet(Index)->Eta())))+((RelativePhi((Reclusterer->GetJet(Index)->Phi()),JetParticle->Phi()))*(RelativePhi((Reclusterer->GetJet(Index)->Phi()),JetParticle->Phi()))))),B);
      }
      else{
  DeltaR2=TMath::Power((Reclusterer->GetJet(Index)->Pt()),A)*TMath::Power((TMath::Sqrt((((JetParticle->Eta())-(Reclusterer->GetJet(Index)->Eta()))*((JetParticle->Eta())- (Reclusterer->GetJet(Index)->Eta())))+((RelativePhi((Reclusterer->GetJet(Index)->Phi()),JetParticle->Phi()))*(RelativePhi((Reclusterer->GetJet(Index)->Phi()),JetParticle->Phi()))))),B);
  if (DeltaR2<DeltaR1) DeltaR1=DeltaR2;
      }
    }
    SubJetiness_Numerator=SubJetiness_Numerator+(JetParticle->Pt()*DeltaR1);    
    if (A>=0) SubJetiness_Denominator=SubJetiness_Denominator+(TMath::Power((Reclusterer->GetJet(SubJetOrdering(Jet,Reclusterer,1,0,kTRUE))->Pt()),A)*JetParticle->Pt()*TMath::Power(JetRadius,B));       
    else  SubJetiness_Denominator=SubJetiness_Denominator+(TMath::Power((Reclusterer->GetJet(SubJetOrdering(Jet,Reclusterer,N,0,kTRUE))->Pt()),A)*JetParticle->Pt()*TMath::Power(JetRadius,B));  
  }
  if (SubJetiness_Denominator!=0 && !Error){
    // if (SubJetiness_Numerator/SubJetiness_Denominator>1.0) cout << JetRadius<<endl;
    return SubJetiness_Numerator/SubJetiness_Denominator;                                                                                  }
  else return -2;
}


//______________________________________________________________________________________
Double_t AliAnalysisTaskSubJetFraction::fjNSubJettiness(AliEmcalJet *Jet, Int_t JetContNb,Int_t N, Int_t Algorithm, Double_t Beta, Int_t Option, Double_t Beta_SD, Double_t ZCut){

  //WARNING!!! Only works for parent jets that are clustered with Anti-Kt! To change go to AliEmcalJetFinder.cxx and look at the Nsubjettiness() function

  //Algorithm==0 -> kt_axes;
  // Algorithm==1 -> ca_axes;
  //Algorithm==2 -> antikt_0p2_axes;
  //Algorithm==3 -> wta_kt_axes;
  //Algorithm==4 -> wta_ca_axes;
  //Algorithm==5 -> onepass_kt_axes;
  //Algorithm==6 -> onepass_ca_axes;
  //Algorithm==7 -> onepass_antikt_0p2_axes;
  //Algorithm==8 -> onepass_wta_kt_axes;
  //Algorithm==9 -> onepass_wta_ca_axes;
  //Algorithm==10 -> min_axes;


  //Option==0 returns Nsubjettiness Value
  //Option==1 && N==2 returns opening angle between two subjet axes(Delta R?)
  //Option==2 && N==2 returns Delta R
  //Option==3 returns first splitting distance for soft dropped jet
  //Option==4 returns Symmetry measure (Zg) for soft dropped jet
  //Option==5 returns Pt of Subjet1
  //Option==6 returns Pt of Subjet2
  //Options==7 trutns deltaR of subjets...Is this different to before??
  //Option==8 Subjet1 Leading track Pt
  //Option==9 Subjet1 Leading track Pt
  if (Jet->GetNumberOfTracks()>=N){
    if((fJetShapeSub==kDerivSub) && (JetContNb==0) && (N==1) && (Algorithm==0) && (Beta==1.0) && (Option==0)){
      if (fDerivSubtrOrder == kFirstOrder) return Jet->GetShapeProperties()->GetFirstOrderSubtracted1subjettiness_kt();
      else return Jet->GetShapeProperties()->GetSecondOrderSubtracted1subjettiness_kt();
    }
    else if((fJetShapeSub==kDerivSub) && (JetContNb==0) && (N==2) && (Algorithm==0) && (Beta==1.0) && (Option==0)){
      if (fDerivSubtrOrder == kFirstOrder) return Jet->GetShapeProperties()->GetFirstOrderSubtracted2subjettiness_kt();
      else return Jet->GetShapeProperties()->GetSecondOrderSubtracted2subjettiness_kt();
    }
    else if((fJetShapeSub==kDerivSub) && (JetContNb==0) && (N==3) && (Algorithm==0) && (Beta==1.0) && (Option==0)){
      if (fDerivSubtrOrder == kFirstOrder) return Jet->GetShapeProperties()->GetFirstOrderSubtracted3subjettiness_kt();
      else return Jet->GetShapeProperties()->GetSecondOrderSubtracted3subjettiness_kt();
    }
    else if((fJetShapeSub==kDerivSub) && (JetContNb==0) && (N==2) && (Algorithm==0) && (Beta==1.0) && (Option==1)){
      if (fDerivSubtrOrder == kFirstOrder) return Jet->GetShapeProperties()->GetFirstOrderSubtractedOpeningAngle_kt();
      else return Jet->GetShapeProperties()->GetSecondOrderSubtractedOpeningAngle_kt();
    }
    else{
      if (fJetShapeType != AliAnalysisTaskSubJetFraction::kGenOnTheFly) Algorithm=fReclusteringAlgorithm;   //Lazy programming!! Change this later, just a quick fix for now...it stops you being able to fill tree with two different reclutering algorithms or change algortihm inside this .cxx  (can only be changed via the external setter).
      AliJetContainer *JetCont = GetJetContainer(JetContNb);
      AliEmcalJetFinder *JetFinder=new AliEmcalJetFinder("Nsubjettiness");
      JetFinder->SetJetMaxEta(0.9-fJetRadius);
      JetFinder->SetRadius(fJetRadius); 
      JetFinder->SetJetAlgorithm(0); //0 for anti-kt     1 for kt  //this is for the JET!!!!!!!!!! Not the SubJets
      JetFinder->SetRecombSheme(0);
      JetFinder->SetJetMinPt(Jet->Pt());
      if(fJetShapeType != AliAnalysisTaskSubJetFraction::kGenOnTheFly){
  const AliVVertex *vert = InputEvent()->GetPrimaryVertex();
  Double_t dVtx[3]={vert->GetX(),vert->GetY(),vert->GetZ()};
  return JetFinder->Nsubjettiness(Jet,JetCont,dVtx,N,Algorithm,fSubJetRadius,Beta,Option,0,Beta_SD,ZCut);
      }
      else{
  Double_t dVtx[3]={1,1,1};
  if (!fNsubMeasure){
    return JetFinder->Nsubjettiness(Jet,JetCont,dVtx,N,Algorithm,fSubJetRadius,Beta,Option,0,Beta_SD,ZCut);
  }
  else{
    if (Option==3) return JetFinder->Nsubjettiness(Jet,JetCont,dVtx,N,Algorithm,fSubJetRadius,Beta,Option,0,Beta_SD,ZCut);
    else return JetFinder->Nsubjettiness(Jet,JetCont,dVtx,N,Algorithm,fSubJetRadius,Beta,Option,1);
  }
      }
    }
  }
  else return -2;
}


//________________________________________________________________________
Bool_t AliAnalysisTaskSubJetFraction::RetrieveEventObjects() {
  //
  // retrieve event objects
  //
  if (!AliAnalysisTaskEmcalJet::RetrieveEventObjects())
    return kFALSE;

  return kTRUE;
}


//_______________________________________________________________________
void AliAnalysisTaskSubJetFraction::Terminate(Option_t *) 
{
  // Called once at the end of the analysis.
  if (fJetShapeType==AliAnalysisTaskSubJetFraction::kData){

    /*
    for (int i=1; i<=(XBinsJetPtSize)-1; i++){ //Rescales the fhJetPt Histograms according to the with of the variable bins and number of events
      fhJetPt->SetBinContent(i,((1.0/(XBinsJetPt[i]-XBinsJetPt[i-1]))*((fhJetPt->GetBinContent(i))*(1.0/(fhEventCounter->GetBinContent(1))))));      
      fhSubJetPt->SetBinContent(i,((1.0/(XBinsJetPt[i]-XBinsJetPt[i-1]))*((fhSubJetPt->GetBinContent(i))*(1.0/(fhEventCounter->GetBinContent(5))))));
      
      //fhJetPt->SetBinContent(i,((1.0/(fhPt->GetBinWidth(i)))*((fhJetPt->GetBinContent(i))*(fhEventCounter->GetBinContent(1)))));   
      // fhJetPt->SetBinContent(i,((1.0/((fhPt->GetLowEdge(i+1))-(fhJetPt->GetLowEdge(i))))*((fhPt->GetBinContent(i))*(fhEventCounter->GetBinContent(1)))));
    }
    for (int i=1; i<=(XBinsJetMassSize)-1; i++){ //Rescales the fhPt Histograms according to the with of the variable bins and number of events                     
      fhJetMass->SetBinContent(i,((1.0/(XBinsJetMass[i]-XBinsJetMass[i-1]))*((fhJetMass->GetBinContent(i))*(1.0/(fhEventCounter->GetBinContent(1))))));                                                                            
    }
    
    fhJetPhi->Scale(Phi_Bins/((Phi_Up-Phi_Low)*((fhEventCounter->GetBinContent(1)))));
    fhJetEta->Scale(Eta_Bins/((Eta_Up-Eta_Low)*((fhEventCounter->GetBinContent(1)))));
    fhJetRadius->Scale(100/(fhEventCounter->GetBinContent(4)));  //should this and JetAngularity be divided by Bin 1 or 4???? 
    fhNumberOfJetTracks->Scale(1.0/(fhEventCounter->GetBinContent(4)));

    fhJetCounter->Scale(1.0/(fhEventCounter->GetBinContent(1)));  //is the first bin the correct one to look at?
   

 fhSubJetCounter->Scale(1.0/(fhEventCounter->GetBinContent(5)));

    */
    /*  

  fhJetPt->Scale(1.0/(fhEventCounter->GetBinContent(1)));                                      
  fhSubJetPt->Scale(1.0/(fhEventCounter->GetBinContent(5)));                                
  fhJetMass->Scale(1.0/(fhEventCounter->GetBinContent(1)));                                                                                                                     
  fhJetPhi->Scale(1.0/(fhEventCounter->GetBinContent(1)));                                                                                               
  fhJetEta->Scale(1.0/(fhEventCounter->GetBinContent(1)));                                                                                               
  fhJetRadius->Scale(1.0/(fhEventCounter->GetBinContent(4)));  //should this and JetAngularity be divided by Bin 1 or 4????                                                                                                                                                                                                                                           
  fhNumberOfJetTracks->Scale(1.0/(fhEventCounter->GetBinContent(4)));                                                                                                                                                                                                                           
  fhJetCounter->Scale(1.0/(fhEventCounter->GetBinContent(1)));  //is the first bin the correct one to look at?                                                                     
  fhSubJetCounter->Scale(1.0/(fhEventCounter->GetBinContent(5)));            
    */
  }
  
}