Mods/src/GeneratorMod.cc

// $Id: GeneratorMod.cc,v 1.1 2008/10/14 06:13:52 loizides Exp $

#include "MitPhysics/Mods/interface/GeneratorMod.h"
#include "MitAna/DataTree/interface/Names.h"
#include "MitAna/DataCont/interface/ObjArray.h"
#include "MitCommon/MathTools/interface/MathUtils.h"
#include <TH1D.h>
#include <TH2D.h>


using namespace mithep;

ClassImp(mithep::GeneratorMod)

//--------------------------------------------------------------------------------------------------
  GeneratorMod::GeneratorMod(const char *name, const char *title) : 
  BaseMod(name,title),
  fPrintDebug(false),
  fFillHist(false),
  fIsMC(true),
  fMCPartName(Names::gkMCPartBrn),
  fMCLeptonsName(Names::gkMCLeptonsName),
  fMCTausName(Names::gkMCTausName),
  fMCNeutrinosName(Names::gkMCNeutrinosName),
  fMCQuarksName(Names::gkMCQuarksName),
  fMCqqHsName(Names::gkMCqqHsName),
  fMCBosonsName(Names::gkMCBosonsName),
  fParticles(0),
  fNEventsProcessed(0)
{
  // Constructor.
}

//--------------------------------------------------------------------------------------------------
void GeneratorMod::Begin()
{
  // Run startup code on the client machine. For this module, we dont do
  // anything here.
}

//--------------------------------------------------------------------------------------------------
void GeneratorMod::Process()
{
  // Process entries of the tree
  fNEventsProcessed++;
 
  if (fNEventsProcessed % 1000 == 0 || fPrintDebug) {
    time_t systime;
    systime = time(NULL);
    cerr << endl << "GeneratorMod : Process Event " << fNEventsProcessed << "  Time: " 
         << ctime(&systime) << endl;  
  }  

  // These arrays will be filled in the loop of particles
  ObjArray<MCParticle> *GenLeptons   = new ObjArray<MCParticle>;
  ObjArray<MCParticle> *GenTaus      = new ObjArray<MCParticle>; GenTaus->SetOwner(true);
  ObjArray<MCParticle> *GenNeutrinos = new ObjArray<MCParticle>;
  ObjArray<MCParticle> *GenQuarks    = new ObjArray<MCParticle>;
  ObjArray<MCParticle> *GenqqHs      = new ObjArray<MCParticle>;
  ObjArray<MCParticle> *GenBosons    = new ObjArray<MCParticle>;

  if(fIsMC == true){
    // Get Generator Level information branch
    LoadBranch(fMCPartName);
    bool isqqH = false;
    for (UInt_t i=0; i<fParticles->GetEntries(); ++i) {
      MCParticle* p = fParticles->At(i);

      if(!p->IsGenerated()) continue;

      // muons/electrons from W/Z decays
      if((p->AbsPdgId() == 11 || p->AbsPdgId() == 13) && p->Status() == 1){
        bool isGoodLepton = false;
        MCParticle* pm = p;
        while (pm->HasMother() && isGoodLepton == false){
          if     (pm->Mother()->AbsPdgId() == 23 || pm->Mother()->AbsPdgId() == 24){
            GenLeptons->Add(p);
            isGoodLepton = true;
          }
          else if(pm->Mother()->AbsPdgId() == 111 || pm->Mother()->AbsPdgId() == 221){
            // This is fake, but it is a trick to get rid of these cases
            isGoodLepton = true;
          }
          else {
            pm = (MCParticle *)pm->Mother();
          }
        }
      }

      // taus
      else if(p->AbsPdgId() == 16 && p->Status() == 1){
        if(p->DistinctMother()){
          MCParticle* pm = (mithep::MCParticle*)p->DistinctMother();
          if(pm->AbsPdgId() == 15){
            MCParticle* pm_f = new MCParticle(*pm);
            pm_f->SetMom(pm->Px()-p->Px(), pm->Py()-p->Py(),
                         pm->Pz()-p->Pz(), pm->E()-p->E());
            GenTaus->Add(pm_f);
          }
        }
      }

      // neutrinos
      else if(p->Status() == 1 &&
         (p->AbsPdgId() == 12 || p->AbsPdgId() == 14 || p->AbsPdgId() == 16)){
        GenNeutrinos->Add(p);
      }

      // quarks from W/Z decays or top particles
      else if(p->AbsPdgId() >=1 && p->AbsPdgId() <=6 && p->HasMother()){
        if(p->Mother()->AbsPdgId() == 23 || p->Mother()->AbsPdgId() == 24 ||
           p->AbsPdgId() == 6 || p->Mother()->AbsPdgId() == 6){
          GenQuarks->Add(p);
        }
      }

      // qqH, information about the forward jets
      else if(isqqH == false && p->AbsPdgId() == 25){
        isqqH = true;
        MCParticle* pq1 = fParticles->At(i-1);
        MCParticle* pq2 = fParticles->At(i-2);

        if(pq1->HasMother() && pq2->HasMother() &&
           pq1->Mother()->PdgId() == p->Mother()->PdgId() &&
           pq2->Mother()->PdgId() == p->Mother()->PdgId() &&
           pq1->AbsPdgId() < 7 &&  pq2->AbsPdgId() < 7 &&
           pq1->AbsPdgId() > 0 &&  pq2->AbsPdgId() > 0){
          GenqqHs->Add(pq1);
          GenqqHs->Add(pq2);
        }
      }

      // information about bosons: W, Z, h, Z', W', H0, A0, H+
      else if(p->Status() == 2 &&
         (p->AbsPdgId() == 23 || p->AbsPdgId() == 24 || p->AbsPdgId() == 25 ||
          p->AbsPdgId() == 32 || p->AbsPdgId() == 34 ||
          p->AbsPdgId() == 35 || p->AbsPdgId() == 36 || p->AbsPdgId() == 37)){
        GenBosons->Add(p);
      }
    }
  } // IsMC?

  //Save Objects for Other Modules to use
  AddObjThisEvt(GenLeptons,  fMCLeptonsName.Data());  
  AddObjThisEvt(GenTaus,     fMCTausName.Data());  
  AddObjThisEvt(GenNeutrinos,fMCNeutrinosName.Data());  
  AddObjThisEvt(GenQuarks,   fMCQuarksName.Data());  
  AddObjThisEvt(GenqqHs,     fMCqqHsName.Data());  
  AddObjThisEvt(GenBosons,   fMCBosonsName.Data());
  
  // Fill histograms
  if(fFillHist == true){
    // Leptons
    hDGenLeptons[0]->Fill(GenLeptons->GetEntries());
    int   idxMaxLep[2] = {-1, -1};
    double ptMaxLep[2] = {-1.0, -1.0};
    for(UInt_t i=0; i<GenLeptons->GetEntries(); i++){
      hDGenLeptons[1]->Fill(GenLeptons->At(i)->Pt());
      hDGenLeptons[2]->Fill(fabs(GenLeptons->At(i)->Eta()));
      hDGenLeptons[3]->Fill(GenLeptons->At(i)->Phi() * 180. / TMath::Pi());
      for(UInt_t j=i+1; j<GenLeptons->GetEntries(); j++){
        CompositeParticle *dilepton = new CompositeParticle();
        dilepton->AddDaughter(GenLeptons->At(i));
        dilepton->AddDaughter(GenLeptons->At(j));
        hDGenLeptons[4]->Fill(dilepton->Mass());
        delete dilepton;
      }
      // Selecting the two highest Pt leptons
      if     (GenLeptons->At(i)->Pt() > ptMaxLep[0]){
        ptMaxLep[1]  = ptMaxLep[0];
        idxMaxLep[1] = idxMaxLep[0];
        ptMaxLep[0]  = GenLeptons->At(i)->Pt();
        idxMaxLep[0] = i;
      }
      else if(GenLeptons->At(i)->Pt() > ptMaxLep[1]){
        ptMaxLep[1]  = GenLeptons->At(i)->Pt();
        idxMaxLep[1] = i;
      }
    }
    // Looking at events with at least two leptons
    if(ptMaxLep[0] > 0 && ptMaxLep[1] > 0){
      hDGenLeptons[5]->Fill(TMath::Min(TMath::Max(fabs(GenLeptons->At(idxMaxLep[0])->Eta()),
                                                  fabs(GenLeptons->At(idxMaxLep[1])->Eta())),4.999));
      hDGenLeptons[6]->Fill(TMath::Min(TMath::Min(fabs(GenLeptons->At(idxMaxLep[0])->Eta()),
                                                  fabs(GenLeptons->At(idxMaxLep[1])->Eta())),4.999));
      if(fabs(GenLeptons->At(idxMaxLep[0])->Eta()) < 2.5 &&
         fabs(GenLeptons->At(idxMaxLep[1])->Eta()) < 2.5){
        hDGenLeptons[7]->Fill(TMath::Min(GenLeptons->At(idxMaxLep[0])->Pt(),199.999));
        if(GenLeptons->At(idxMaxLep[0])->Pt() > 20.0){
          hDGenLeptons[8]->Fill(TMath::Min(GenLeptons->At(idxMaxLep[1])->Pt(),199.999));
          if(GenLeptons->At(idxMaxLep[1])->Pt() > 10.0){
            CompositeParticle *dilepton = new CompositeParticle();
            dilepton->AddDaughter(GenLeptons->At(idxMaxLep[0]));
            dilepton->AddDaughter(GenLeptons->At(idxMaxLep[1]));
            hDGenLeptons[9]->Fill(TMath::Min(dilepton->Mass(),999.999));
            hDGenLeptons[10]->Fill(MathUtils::DeltaPhi(GenLeptons->At(idxMaxLep[0])->Phi(),
                                                       GenLeptons->At(idxMaxLep[1])->Phi())
                                                       * 180./ TMath::Pi());
            delete dilepton;
          }
        }
      }
    }

    // Taus
    hDGenTaus[0]->Fill(GenTaus->GetEntries());
    for(UInt_t i=0; i<GenTaus->GetEntries(); i++){
      hDGenTaus[1]->Fill(GenTaus->At(i)->Pt());
      hDGenTaus[2]->Fill(GenTaus->At(i)->Eta());
      hDGenTaus[3]->Fill(GenTaus->At(i)->Phi() * 180. / TMath::Pi());
    }

    // Neutrinos
    hDGenNeutrinos[0]->Fill(GenNeutrinos->GetEntries());
    CompositeParticle *neutrinoTotal = new CompositeParticle();
    for(UInt_t i=0; i<GenNeutrinos->GetEntries(); i++){
      if(GenNeutrinos->At(i)->HasMother())
        neutrinoTotal->AddDaughter(GenNeutrinos->At(i));
    }
    if(GenNeutrinos->GetEntries() > 0){
      hDGenNeutrinos[1]->Fill(neutrinoTotal->Pt());
      hDGenNeutrinos[2]->Fill(neutrinoTotal->Eta());
      hDGenNeutrinos[3]->Fill(neutrinoTotal->Phi() * 180./ TMath::Pi());    
    }
    delete neutrinoTotal;
    
    // Quarks
    hDGenQuarks[0]->Fill(GenQuarks->GetEntries());
    for(UInt_t i=0; i<GenQuarks->GetEntries(); i++){
      for(UInt_t j=i+1; j<GenQuarks->GetEntries(); j++){
        CompositeParticle *dijet = new CompositeParticle();
        dijet->AddDaughter(GenQuarks->At(i));
        dijet->AddDaughter(GenQuarks->At(j));
        hDGenQuarks[1]->Fill(dijet->Pt());
        hDGenQuarks[2]->Fill(dijet->Mass());
        if(fabs(GenQuarks->At(i)->Eta()) < 2.5 && fabs(GenQuarks->At(j)->Eta()) < 2.5){
          hDGenQuarks[3]->Fill(dijet->Pt());
          hDGenQuarks[4]->Fill(dijet->Mass());
        }
        delete dijet;
      }
    }

    // WBF
    if(GenqqHs->GetEntries() == 2){
      hDGenWBF[0]->Fill(MathUtils::DeltaPhi(GenqqHs->At(0)->Phi(),
                                            GenqqHs->At(1)->Phi()) * 180./ TMath::Pi());
      hDGenWBF[1]->Fill(fabs(GenqqHs->At(0)->Eta()-GenqqHs->At(1)->Eta()));
      hDGenWBF[2]->Fill(TMath::Max(GenqqHs->At(0)->Pt(),GenqqHs->At(1)->Pt()));
      hDGenWBF[3]->Fill(TMath::Min(GenqqHs->At(0)->Pt(),GenqqHs->At(1)->Pt()));
      CompositeParticle *diqq = new CompositeParticle();
      diqq->AddDaughter(GenqqHs->At(0));
      diqq->AddDaughter(GenqqHs->At(1));
      hDGenWBF[4]->Fill(diqq->Mass());
      delete diqq;
    }

    // Bosons
    hDGenBosons[0]->Fill(GenBosons->GetEntries());
    for(UInt_t i=0; i<GenBosons->GetEntries(); i++){
      hDGenBosons[1]->Fill(GenBosons->At(i)->Pt());
      hDGenBosons[2]->Fill(GenBosons->At(i)->Eta());
      hDGenBosons[3]->Fill(GenBosons->At(i)->Mass());
    } 
  }

}

//--------------------------------------------------------------------------------------------------
void GeneratorMod::SlaveBegin()
{
  // Run startup code on the computer (slave) doing the actual analysis. Here,
  // we typically initialize histograms and other analysis objects and request
  // branches. For this module, we request a branch of the MitTree.
  ReqBranch(fMCPartName, fParticles);

  // Fill histograms
  if(fFillHist == true){
    char sb[200];
    sprintf(sb,"hDGenLeptons_%d", 0);  hDGenLeptons[0]  = new TH1D(sb,sb,10,-0.5,9.5); 
    sprintf(sb,"hDGenLeptons_%d", 1);  hDGenLeptons[1]  = new TH1D(sb,sb,100,0.0,200.0); 
    sprintf(sb,"hDGenLeptons_%d", 2);  hDGenLeptons[2]  = new TH1D(sb,sb,50,0.0,5.0); 
    sprintf(sb,"hDGenLeptons_%d", 3);  hDGenLeptons[3]  = new TH1D(sb,sb,90,0.0,180.0); 
    sprintf(sb,"hDGenLeptons_%d", 4);  hDGenLeptons[4]  = new TH1D(sb,sb,1000,0.0,1000.0); 
    sprintf(sb,"hDGenLeptons_%d", 5);  hDGenLeptons[5]  = new TH1D(sb,sb,50,0.0,5.0); 
    sprintf(sb,"hDGenLeptons_%d", 6);  hDGenLeptons[6]  = new TH1D(sb,sb,50,0.0,5.0); 
    sprintf(sb,"hDGenLeptons_%d", 7);  hDGenLeptons[7]  = new TH1D(sb,sb,100,0.0,200.0); 
    sprintf(sb,"hDGenLeptons_%d", 8);  hDGenLeptons[8]  = new TH1D(sb,sb,100,0.0,200.0); 
    sprintf(sb,"hDGenLeptons_%d", 9);  hDGenLeptons[9]  = new TH1D(sb,sb,1000,0.0,1000.0); 
    sprintf(sb,"hDGenLeptons_%d",10);  hDGenLeptons[10] = new TH1D(sb,sb,90,0.0,180.0); 
    for(int i=0; i<11; i++) AddOutput(hDGenLeptons[i]);

    // Taus
    sprintf(sb,"hDGenTaus_%d", 0);  hDGenTaus[0]  = new TH1D(sb,sb,10,-0.5,9.5); 
    sprintf(sb,"hDGenTaus_%d", 1);  hDGenTaus[1]  = new TH1D(sb,sb,100,0.0,200.0); 
    sprintf(sb,"hDGenTaus_%d", 2);  hDGenTaus[2]  = new TH1D(sb,sb,100,-5.0,5.0); 
    sprintf(sb,"hDGenTaus_%d", 3);  hDGenTaus[3]  = new TH1D(sb,sb,90,0.0,180.0); 
    for(int i=0; i<4; i++) AddOutput(hDGenTaus[i]);

    // Neutrinos
    sprintf(sb,"hDGenNeutrinos_%d", 0);  hDGenNeutrinos[0]  = new TH1D(sb,sb,10,-0.5,9.5); 
    sprintf(sb,"hDGenNeutrinos_%d", 1);  hDGenNeutrinos[1]  = new TH1D(sb,sb,100,0.0,200.0); 
    sprintf(sb,"hDGenNeutrinos_%d", 2);  hDGenNeutrinos[2]  = new TH1D(sb,sb,100,-5.0,5.0); 
    sprintf(sb,"hDGenNeutrinos_%d", 3);  hDGenNeutrinos[3]  = new TH1D(sb,sb,90,0.0,180.0); 
    for(int i=0; i<4; i++) AddOutput(hDGenNeutrinos[i]);

    // Quarks
    sprintf(sb,"hDGenQuarks_%d", 0);  hDGenQuarks[0]  = new TH1D(sb,sb,10,-0.5,9.5); 
    sprintf(sb,"hDGenQuarks_%d", 1);  hDGenQuarks[1]  = new TH1D(sb,sb,200,0.0,400.); 
    sprintf(sb,"hDGenQuarks_%d", 2);  hDGenQuarks[2]  = new TH1D(sb,sb,2000,0.0,2000.);
    sprintf(sb,"hDGenQuarks_%d", 3);  hDGenQuarks[3]  = new TH1D(sb,sb,200,0.0,400.); 
    sprintf(sb,"hDGenQuarks_%d", 4);  hDGenQuarks[4]  = new TH1D(sb,sb,2000,0.0,2000.);
    for(int i=0; i<5; i++) AddOutput(hDGenQuarks[i]);

    // qqH
    sprintf(sb,"hDGenWBF_%d", 0);  hDGenWBF[0]  = new TH1D(sb,sb,90,0.0,180.);
    sprintf(sb,"hDGenWBF_%d", 1);  hDGenWBF[1]  = new TH1D(sb,sb,100,0.0,10.);   
    sprintf(sb,"hDGenWBF_%d", 2);  hDGenWBF[2]  = new TH1D(sb,sb,200,0.0,400.); 
    sprintf(sb,"hDGenWBF_%d", 3);  hDGenWBF[3]  = new TH1D(sb,sb,200,0.0,400.);
    sprintf(sb,"hDGenWBF_%d", 4);  hDGenWBF[4]  = new TH1D(sb,sb,200,0.0,4000.);
    for(int i=0; i<5; i++) AddOutput(hDGenWBF[i]);

    // Bosons
    sprintf(sb,"hDGenBosons_%d", 0);  hDGenBosons[0]  = new TH1D(sb,sb,10,-0.5,9.5); 
    sprintf(sb,"hDGenBosons_%d", 1);  hDGenBosons[1]  = new TH1D(sb,sb,200,0.0,400.0); 
    sprintf(sb,"hDGenBosons_%d", 2);  hDGenBosons[2]  = new TH1D(sb,sb,100,-5.0,5.0); 
    sprintf(sb,"hDGenBosons_%d", 3);  hDGenBosons[3]  = new TH1D(sb,sb,2000,0.0,2000.0); 
    for(int i=0; i<4; i++) AddOutput(hDGenBosons[i]);
  }
}

//--------------------------------------------------------------------------------------------------
void GeneratorMod::SlaveTerminate()
{
  // Run finishing code on the computer (slave) that did the analysis. For this
  // module, we dont do anything here.

}

//--------------------------------------------------------------------------------------------------
void GeneratorMod::Terminate()
{
  // Run finishing code on the client computer. For this module, we dont do
  // anything here.
}
Revision:	1.1
Committed:	Wed Oct 15 06:05:00 2008 UTC (16 years, 6 months ago) by loizides
Content type:	text/plain
Branch:	MAIN
Log Message:	Added MitPhysics.
#	User	Rev	Content
1	loizides	1.1	// $Id: GeneratorMod.cc,v 1.1 2008/10/14 06:13:52 loizides Exp $
2
3			#include "MitPhysics/Mods/interface/GeneratorMod.h"
4			#include "MitAna/DataTree/interface/Names.h"
5			#include "MitAna/DataCont/interface/ObjArray.h"
6			#include "MitCommon/MathTools/interface/MathUtils.h"
7			#include <TH1D.h>
8			#include <TH2D.h>
9
10
11			using namespace mithep;
12
13			ClassImp(mithep::GeneratorMod)
14
15			//--------------------------------------------------------------------------------------------------
16			GeneratorMod::GeneratorMod(const char name, const char title) :
17			BaseMod(name,title),
18			fPrintDebug(false),
19			fFillHist(false),
20			fIsMC(true),
21			fMCPartName(Names::gkMCPartBrn),
22			fMCLeptonsName(Names::gkMCLeptonsName),
23			fMCTausName(Names::gkMCTausName),
24			fMCNeutrinosName(Names::gkMCNeutrinosName),
25			fMCQuarksName(Names::gkMCQuarksName),
26			fMCqqHsName(Names::gkMCqqHsName),
27			fMCBosonsName(Names::gkMCBosonsName),
28			fParticles(0),
29			fNEventsProcessed(0)
30			{
31			// Constructor.
32			}
33
34			//--------------------------------------------------------------------------------------------------
35			void GeneratorMod::Begin()
36			{
37			// Run startup code on the client machine. For this module, we dont do
38			// anything here.
39			}
40
41			//--------------------------------------------------------------------------------------------------
42			void GeneratorMod::Process()
43			{
44			// Process entries of the tree
45			fNEventsProcessed++;
46
47			if (fNEventsProcessed % 1000 == 0 \|\| fPrintDebug) {
48			time_t systime;
49			systime = time(NULL);
50			cerr << endl << "GeneratorMod : Process Event " << fNEventsProcessed << " Time: "
51			<< ctime(&systime) << endl;
52			}
53
54			// These arrays will be filled in the loop of particles
55			ObjArray<MCParticle> *GenLeptons = new ObjArray<MCParticle>;
56			ObjArray<MCParticle> *GenTaus = new ObjArray<MCParticle>; GenTaus->SetOwner(true);
57			ObjArray<MCParticle> *GenNeutrinos = new ObjArray<MCParticle>;
58			ObjArray<MCParticle> *GenQuarks = new ObjArray<MCParticle>;
59			ObjArray<MCParticle> *GenqqHs = new ObjArray<MCParticle>;
60			ObjArray<MCParticle> *GenBosons = new ObjArray<MCParticle>;
61
62			if(fIsMC == true){
63			// Get Generator Level information branch
64			LoadBranch(fMCPartName);
65			bool isqqH = false;
66			for (UInt_t i=0; i<fParticles->GetEntries(); ++i) {
67			MCParticle* p = fParticles->At(i);
68
69			if(!p->IsGenerated()) continue;
70
71			// muons/electrons from W/Z decays
72			if((p->AbsPdgId() == 11 \|\| p->AbsPdgId() == 13) && p->Status() == 1){
73			bool isGoodLepton = false;
74			MCParticle* pm = p;
75			while (pm->HasMother() && isGoodLepton == false){
76			if (pm->Mother()->AbsPdgId() == 23 \|\| pm->Mother()->AbsPdgId() == 24){
77			GenLeptons->Add(p);
78			isGoodLepton = true;
79			}
80			else if(pm->Mother()->AbsPdgId() == 111 \|\| pm->Mother()->AbsPdgId() == 221){
81			// This is fake, but it is a trick to get rid of these cases
82			isGoodLepton = true;
83			}
84			else {
85			pm = (MCParticle *)pm->Mother();
86			}
87			}
88			}
89
90			// taus
91			else if(p->AbsPdgId() == 16 && p->Status() == 1){
92			if(p->DistinctMother()){
93			MCParticle* pm = (mithep::MCParticle*)p->DistinctMother();
94			if(pm->AbsPdgId() == 15){
95			MCParticle* pm_f = new MCParticle(*pm);
96			pm_f->SetMom(pm->Px()-p->Px(), pm->Py()-p->Py(),
97			pm->Pz()-p->Pz(), pm->E()-p->E());
98			GenTaus->Add(pm_f);
99			}
100			}
101			}
102
103			// neutrinos
104			else if(p->Status() == 1 &&
105			(p->AbsPdgId() == 12 \|\| p->AbsPdgId() == 14 \|\| p->AbsPdgId() == 16)){
106			GenNeutrinos->Add(p);
107			}
108
109			// quarks from W/Z decays or top particles
110			else if(p->AbsPdgId() >=1 && p->AbsPdgId() <=6 && p->HasMother()){
111			if(p->Mother()->AbsPdgId() == 23 \|\| p->Mother()->AbsPdgId() == 24 \|\|
112			p->AbsPdgId() == 6 \|\| p->Mother()->AbsPdgId() == 6){
113			GenQuarks->Add(p);
114			}
115			}
116
117			// qqH, information about the forward jets
118			else if(isqqH == false && p->AbsPdgId() == 25){
119			isqqH = true;
120			MCParticle* pq1 = fParticles->At(i-1);
121			MCParticle* pq2 = fParticles->At(i-2);
122
123			if(pq1->HasMother() && pq2->HasMother() &&
124			pq1->Mother()->PdgId() == p->Mother()->PdgId() &&
125			pq2->Mother()->PdgId() == p->Mother()->PdgId() &&
126			pq1->AbsPdgId() < 7 && pq2->AbsPdgId() < 7 &&
127			pq1->AbsPdgId() > 0 && pq2->AbsPdgId() > 0){
128			GenqqHs->Add(pq1);
129			GenqqHs->Add(pq2);
130			}
131			}
132
133			// information about bosons: W, Z, h, Z', W', H0, A0, H+
134			else if(p->Status() == 2 &&
135			(p->AbsPdgId() == 23 \|\| p->AbsPdgId() == 24 \|\| p->AbsPdgId() == 25 \|\|
136			p->AbsPdgId() == 32 \|\| p->AbsPdgId() == 34 \|\|
137			p->AbsPdgId() == 35 \|\| p->AbsPdgId() == 36 \|\| p->AbsPdgId() == 37)){
138			GenBosons->Add(p);
139			}
140			}
141			} // IsMC?
142
143			//Save Objects for Other Modules to use
144			AddObjThisEvt(GenLeptons, fMCLeptonsName.Data());
145			AddObjThisEvt(GenTaus, fMCTausName.Data());
146			AddObjThisEvt(GenNeutrinos,fMCNeutrinosName.Data());
147			AddObjThisEvt(GenQuarks, fMCQuarksName.Data());
148			AddObjThisEvt(GenqqHs, fMCqqHsName.Data());
149			AddObjThisEvt(GenBosons, fMCBosonsName.Data());
150
151			// Fill histograms
152			if(fFillHist == true){
153			// Leptons
154			hDGenLeptons[0]->Fill(GenLeptons->GetEntries());
155			int idxMaxLep[2] = {-1, -1};
156			double ptMaxLep[2] = {-1.0, -1.0};
157			for(UInt_t i=0; i<GenLeptons->GetEntries(); i++){
158			hDGenLeptons[1]->Fill(GenLeptons->At(i)->Pt());
159			hDGenLeptons[2]->Fill(fabs(GenLeptons->At(i)->Eta()));
160			hDGenLeptons[3]->Fill(GenLeptons->At(i)->Phi() * 180. / TMath::Pi());
161			for(UInt_t j=i+1; j<GenLeptons->GetEntries(); j++){
162			CompositeParticle *dilepton = new CompositeParticle();
163			dilepton->AddDaughter(GenLeptons->At(i));
164			dilepton->AddDaughter(GenLeptons->At(j));
165			hDGenLeptons[4]->Fill(dilepton->Mass());
166			delete dilepton;
167			}
168			// Selecting the two highest Pt leptons
169			if (GenLeptons->At(i)->Pt() > ptMaxLep[0]){
170			ptMaxLep[1] = ptMaxLep[0];
171			idxMaxLep[1] = idxMaxLep[0];
172			ptMaxLep[0] = GenLeptons->At(i)->Pt();
173			idxMaxLep[0] = i;
174			}
175			else if(GenLeptons->At(i)->Pt() > ptMaxLep[1]){
176			ptMaxLep[1] = GenLeptons->At(i)->Pt();
177			idxMaxLep[1] = i;
178			}
179			}
180			// Looking at events with at least two leptons
181			if(ptMaxLep[0] > 0 && ptMaxLep[1] > 0){
182			hDGenLeptons[5]->Fill(TMath::Min(TMath::Max(fabs(GenLeptons->At(idxMaxLep[0])->Eta()),
183			fabs(GenLeptons->At(idxMaxLep[1])->Eta())),4.999));
184			hDGenLeptons[6]->Fill(TMath::Min(TMath::Min(fabs(GenLeptons->At(idxMaxLep[0])->Eta()),
185			fabs(GenLeptons->At(idxMaxLep[1])->Eta())),4.999));
186			if(fabs(GenLeptons->At(idxMaxLep[0])->Eta()) < 2.5 &&
187			fabs(GenLeptons->At(idxMaxLep[1])->Eta()) < 2.5){
188			hDGenLeptons[7]->Fill(TMath::Min(GenLeptons->At(idxMaxLep[0])->Pt(),199.999));
189			if(GenLeptons->At(idxMaxLep[0])->Pt() > 20.0){
190			hDGenLeptons[8]->Fill(TMath::Min(GenLeptons->At(idxMaxLep[1])->Pt(),199.999));
191			if(GenLeptons->At(idxMaxLep[1])->Pt() > 10.0){
192			CompositeParticle *dilepton = new CompositeParticle();
193			dilepton->AddDaughter(GenLeptons->At(idxMaxLep[0]));
194			dilepton->AddDaughter(GenLeptons->At(idxMaxLep[1]));
195			hDGenLeptons[9]->Fill(TMath::Min(dilepton->Mass(),999.999));
196			hDGenLeptons[10]->Fill(MathUtils::DeltaPhi(GenLeptons->At(idxMaxLep[0])->Phi(),
197			GenLeptons->At(idxMaxLep[1])->Phi())
198			* 180./ TMath::Pi());
199			delete dilepton;
200			}
201			}
202			}
203			}
204
205			// Taus
206			hDGenTaus[0]->Fill(GenTaus->GetEntries());
207			for(UInt_t i=0; i<GenTaus->GetEntries(); i++){
208			hDGenTaus[1]->Fill(GenTaus->At(i)->Pt());
209			hDGenTaus[2]->Fill(GenTaus->At(i)->Eta());
210			hDGenTaus[3]->Fill(GenTaus->At(i)->Phi() * 180. / TMath::Pi());
211			}
212
213			// Neutrinos
214			hDGenNeutrinos[0]->Fill(GenNeutrinos->GetEntries());
215			CompositeParticle *neutrinoTotal = new CompositeParticle();
216			for(UInt_t i=0; i<GenNeutrinos->GetEntries(); i++){
217			if(GenNeutrinos->At(i)->HasMother())
218			neutrinoTotal->AddDaughter(GenNeutrinos->At(i));
219			}
220			if(GenNeutrinos->GetEntries() > 0){
221			hDGenNeutrinos[1]->Fill(neutrinoTotal->Pt());
222			hDGenNeutrinos[2]->Fill(neutrinoTotal->Eta());
223			hDGenNeutrinos[3]->Fill(neutrinoTotal->Phi() * 180./ TMath::Pi());
224			}
225			delete neutrinoTotal;
226
227			// Quarks
228			hDGenQuarks[0]->Fill(GenQuarks->GetEntries());
229			for(UInt_t i=0; i<GenQuarks->GetEntries(); i++){
230			for(UInt_t j=i+1; j<GenQuarks->GetEntries(); j++){
231			CompositeParticle *dijet = new CompositeParticle();
232			dijet->AddDaughter(GenQuarks->At(i));
233			dijet->AddDaughter(GenQuarks->At(j));
234			hDGenQuarks[1]->Fill(dijet->Pt());
235			hDGenQuarks[2]->Fill(dijet->Mass());
236			if(fabs(GenQuarks->At(i)->Eta()) < 2.5 && fabs(GenQuarks->At(j)->Eta()) < 2.5){
237			hDGenQuarks[3]->Fill(dijet->Pt());
238			hDGenQuarks[4]->Fill(dijet->Mass());
239			}
240			delete dijet;
241			}
242			}
243
244			// WBF
245			if(GenqqHs->GetEntries() == 2){
246			hDGenWBF[0]->Fill(MathUtils::DeltaPhi(GenqqHs->At(0)->Phi(),
247			GenqqHs->At(1)->Phi()) * 180./ TMath::Pi());
248			hDGenWBF[1]->Fill(fabs(GenqqHs->At(0)->Eta()-GenqqHs->At(1)->Eta()));
249			hDGenWBF[2]->Fill(TMath::Max(GenqqHs->At(0)->Pt(),GenqqHs->At(1)->Pt()));
250			hDGenWBF[3]->Fill(TMath::Min(GenqqHs->At(0)->Pt(),GenqqHs->At(1)->Pt()));
251			CompositeParticle *diqq = new CompositeParticle();
252			diqq->AddDaughter(GenqqHs->At(0));
253			diqq->AddDaughter(GenqqHs->At(1));
254			hDGenWBF[4]->Fill(diqq->Mass());
255			delete diqq;
256			}
257
258			// Bosons
259			hDGenBosons[0]->Fill(GenBosons->GetEntries());
260			for(UInt_t i=0; i<GenBosons->GetEntries(); i++){
261			hDGenBosons[1]->Fill(GenBosons->At(i)->Pt());
262			hDGenBosons[2]->Fill(GenBosons->At(i)->Eta());
263			hDGenBosons[3]->Fill(GenBosons->At(i)->Mass());
264			}
265			}
266
267			}
268
269			//--------------------------------------------------------------------------------------------------
270			void GeneratorMod::SlaveBegin()
271			{
272			// Run startup code on the computer (slave) doing the actual analysis. Here,
273			// we typically initialize histograms and other analysis objects and request
274			// branches. For this module, we request a branch of the MitTree.
275			ReqBranch(fMCPartName, fParticles);
276
277			// Fill histograms
278			if(fFillHist == true){
279			char sb[200];
280			sprintf(sb,"hDGenLeptons_%d", 0); hDGenLeptons[0] = new TH1D(sb,sb,10,-0.5,9.5);
281			sprintf(sb,"hDGenLeptons_%d", 1); hDGenLeptons[1] = new TH1D(sb,sb,100,0.0,200.0);
282			sprintf(sb,"hDGenLeptons_%d", 2); hDGenLeptons[2] = new TH1D(sb,sb,50,0.0,5.0);
283			sprintf(sb,"hDGenLeptons_%d", 3); hDGenLeptons[3] = new TH1D(sb,sb,90,0.0,180.0);
284			sprintf(sb,"hDGenLeptons_%d", 4); hDGenLeptons[4] = new TH1D(sb,sb,1000,0.0,1000.0);
285			sprintf(sb,"hDGenLeptons_%d", 5); hDGenLeptons[5] = new TH1D(sb,sb,50,0.0,5.0);
286			sprintf(sb,"hDGenLeptons_%d", 6); hDGenLeptons[6] = new TH1D(sb,sb,50,0.0,5.0);
287			sprintf(sb,"hDGenLeptons_%d", 7); hDGenLeptons[7] = new TH1D(sb,sb,100,0.0,200.0);
288			sprintf(sb,"hDGenLeptons_%d", 8); hDGenLeptons[8] = new TH1D(sb,sb,100,0.0,200.0);
289			sprintf(sb,"hDGenLeptons_%d", 9); hDGenLeptons[9] = new TH1D(sb,sb,1000,0.0,1000.0);
290			sprintf(sb,"hDGenLeptons_%d",10); hDGenLeptons[10] = new TH1D(sb,sb,90,0.0,180.0);
291			for(int i=0; i<11; i++) AddOutput(hDGenLeptons[i]);
292
293			// Taus
294			sprintf(sb,"hDGenTaus_%d", 0); hDGenTaus[0] = new TH1D(sb,sb,10,-0.5,9.5);
295			sprintf(sb,"hDGenTaus_%d", 1); hDGenTaus[1] = new TH1D(sb,sb,100,0.0,200.0);
296			sprintf(sb,"hDGenTaus_%d", 2); hDGenTaus[2] = new TH1D(sb,sb,100,-5.0,5.0);
297			sprintf(sb,"hDGenTaus_%d", 3); hDGenTaus[3] = new TH1D(sb,sb,90,0.0,180.0);
298			for(int i=0; i<4; i++) AddOutput(hDGenTaus[i]);
299
300			// Neutrinos
301			sprintf(sb,"hDGenNeutrinos_%d", 0); hDGenNeutrinos[0] = new TH1D(sb,sb,10,-0.5,9.5);
302			sprintf(sb,"hDGenNeutrinos_%d", 1); hDGenNeutrinos[1] = new TH1D(sb,sb,100,0.0,200.0);
303			sprintf(sb,"hDGenNeutrinos_%d", 2); hDGenNeutrinos[2] = new TH1D(sb,sb,100,-5.0,5.0);
304			sprintf(sb,"hDGenNeutrinos_%d", 3); hDGenNeutrinos[3] = new TH1D(sb,sb,90,0.0,180.0);
305			for(int i=0; i<4; i++) AddOutput(hDGenNeutrinos[i]);
306
307			// Quarks
308			sprintf(sb,"hDGenQuarks_%d", 0); hDGenQuarks[0] = new TH1D(sb,sb,10,-0.5,9.5);
309			sprintf(sb,"hDGenQuarks_%d", 1); hDGenQuarks[1] = new TH1D(sb,sb,200,0.0,400.);
310			sprintf(sb,"hDGenQuarks_%d", 2); hDGenQuarks[2] = new TH1D(sb,sb,2000,0.0,2000.);
311			sprintf(sb,"hDGenQuarks_%d", 3); hDGenQuarks[3] = new TH1D(sb,sb,200,0.0,400.);
312			sprintf(sb,"hDGenQuarks_%d", 4); hDGenQuarks[4] = new TH1D(sb,sb,2000,0.0,2000.);
313			for(int i=0; i<5; i++) AddOutput(hDGenQuarks[i]);
314
315			// qqH
316			sprintf(sb,"hDGenWBF_%d", 0); hDGenWBF[0] = new TH1D(sb,sb,90,0.0,180.);
317			sprintf(sb,"hDGenWBF_%d", 1); hDGenWBF[1] = new TH1D(sb,sb,100,0.0,10.);
318			sprintf(sb,"hDGenWBF_%d", 2); hDGenWBF[2] = new TH1D(sb,sb,200,0.0,400.);
319			sprintf(sb,"hDGenWBF_%d", 3); hDGenWBF[3] = new TH1D(sb,sb,200,0.0,400.);
320			sprintf(sb,"hDGenWBF_%d", 4); hDGenWBF[4] = new TH1D(sb,sb,200,0.0,4000.);
321			for(int i=0; i<5; i++) AddOutput(hDGenWBF[i]);
322
323			// Bosons
324			sprintf(sb,"hDGenBosons_%d", 0); hDGenBosons[0] = new TH1D(sb,sb,10,-0.5,9.5);
325			sprintf(sb,"hDGenBosons_%d", 1); hDGenBosons[1] = new TH1D(sb,sb,200,0.0,400.0);
326			sprintf(sb,"hDGenBosons_%d", 2); hDGenBosons[2] = new TH1D(sb,sb,100,-5.0,5.0);
327			sprintf(sb,"hDGenBosons_%d", 3); hDGenBosons[3] = new TH1D(sb,sb,2000,0.0,2000.0);
328			for(int i=0; i<4; i++) AddOutput(hDGenBosons[i]);
329			}
330			}
331
332			//--------------------------------------------------------------------------------------------------
333			void GeneratorMod::SlaveTerminate()
334			{
335			// Run finishing code on the computer (slave) that did the analysis. For this
336			// module, we dont do anything here.
337
338			}
339
340			//--------------------------------------------------------------------------------------------------
341			void GeneratorMod::Terminate()
342			{
343			// Run finishing code on the client computer. For this module, we dont do
344			// anything here.
345			}