1 | /***********************************************************************
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2 | ** **
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3 | ** /----------------------------------------------\ **
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4 | ** | Delphes, a framework for the fast simulation | **
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5 | ** | of a generic collider experiment | **
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6 | ** \----------------------------------------------/ **
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7 | ** **
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8 | ** **
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9 | ** This package uses: **
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10 | ** ------------------ **
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11 | ** FastJet algorithm: Phys. Lett. B641 (2006) [hep-ph/0512210] **
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12 | ** Hector: JINST 2:P09005 (2007) [physics.acc-ph:0707.1198v2] **
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13 | ** FROG: [hep-ex/0901.2718v1] **
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14 | ** **
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15 | ** ------------------------------------------------------------------ **
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16 | ** **
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17 | ** Main authors: **
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18 | ** ------------- **
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19 | ** **
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20 | ** Severine Ovyn Xavier Rouby **
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21 | ** severine.ovyn@uclouvain.be xavier.rouby@cern **
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22 | ** **
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23 | ** Center for Particle Physics and Phenomenology (CP3) **
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24 | ** Universite catholique de Louvain (UCL) **
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25 | ** Louvain-la-Neuve, Belgium **
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26 | ** **
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27 | ** Copyright (C) 2008-2009, **
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28 | ** All rights reserved. **
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29 | ** **
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30 | ***********************************************************************/
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31 |
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32 |
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33 | #include "Examples/interface/Analysis_Ex.h"
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34 | #include <iostream>
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35 | #include <sstream>
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36 | #include <fstream>
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37 | #include <iomanip>
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38 |
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39 | using namespace std;
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40 |
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41 | //******************************Debut de l'analyse****************************************
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42 | //*****************************************************************************************
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43 |
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44 | Analysis_Ex::Analysis_Ex(string CardWithCuts,string LogName)
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45 | {
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46 | string temp_string;
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47 | istringstream curstring;
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48 |
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49 | ifstream fichier_a_lire(CardWithCuts.c_str());
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50 | if(!fichier_a_lire.good()) {
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51 | cout << "DataCardname " << CardWithCuts << " not found, use default values" << endl;
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52 | return;
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53 | }
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54 |
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55 | while (getline(fichier_a_lire,temp_string)) {
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56 | curstring.clear(); // needed when using several times istringstream::str(string)
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57 | curstring.str(temp_string);
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58 | string varname;
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59 | float value;
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60 |
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61 | if(strstr(temp_string.c_str(),"#")) { }//remove comments
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62 | else if(strstr(temp_string.c_str(),"PT_ELEC")){curstring >> varname >> value; PT_ELEC = value;}
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63 | else if(strstr(temp_string.c_str(),"PT_MUON")){curstring >> varname >> value; PT_MUON = value;}
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64 | else if(strstr(temp_string.c_str(),"INV_MASS_LL")){curstring >> varname >> value; INV_MASS_LL = value;}
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65 | }
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66 |
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67 | ofstream f_out(LogName.c_str(),ofstream::app);
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68 |
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69 | f_out<<"*******************************************************************"<<endl;
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70 | f_out << left << setw(30) <<"Cut values used in the analysis: "<<""
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71 | << right << setw(37) <<"-------------------------------------"<<"\n";
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72 | f_out << left <<setw(50) << "Invariant mass of the leptons: "<<""
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73 | << right <<setw(17) << INV_MASS_LL <<"\n";
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74 | f_out<<"*******************************************************************"<<endl;
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75 |
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76 | }
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77 |
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78 | Analysis_Ex::~Analysis_Ex()
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79 | {
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80 | }
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81 |
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82 | void Analysis_Ex::Run(ExRootTreeReader *treeReaderGen, ExRootTreeReader *treeReaderRec, ExRootTreeReader *treeReaderTrig, ExRootTreeWriter *treeWriter)
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83 | {
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84 | total=0;//initialisation of total number of events
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85 | cut_trig=0;
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86 | cut_1=0;//initialisation of counter for cut 1
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87 | cut_2=0;
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88 | //access the branches************************
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89 | //to get the generator level information
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90 | const TClonesArray *GEN = treeReaderGen->UseBranch("Particle");
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91 |
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92 | //to get the reconstructed level information
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93 | const TClonesArray *JET = treeReaderRec->UseBranch("Jet");
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94 | const TClonesArray *TAUJET = treeReaderRec->UseBranch("TauJet");
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95 | const TClonesArray *PHOTO = treeReaderRec->UseBranch("Photon");
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96 | const TClonesArray *ELEC = treeReaderRec->UseBranch("Electron");
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97 | const TClonesArray *MUON = treeReaderRec->UseBranch("Muon");
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98 | const TClonesArray *TRACKS = treeReaderRec->UseBranch("Tracks");
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99 | const TClonesArray *CALO = treeReaderRec->UseBranch("CaloTower");
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100 |
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101 | //to get the VFD reconstructed level information
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102 | const TClonesArray *ZDC = treeReaderRec->UseBranch("ZDChits");
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103 | const TClonesArray *RP220 = treeReaderRec->UseBranch("RP220hits");
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104 | const TClonesArray *FP420 = treeReaderRec->UseBranch("FP420hits");
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105 |
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106 | //to get the trigger information
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107 | const TClonesArray *TRIGGER = treeReaderTrig->UseBranch("TrigResult");
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108 |
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109 | //Define the branches that will be filled during the analysis
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110 | ExRootTreeBranch *INVMASS = treeWriter->NewBranch("INVMass", TRootInvm::Class());
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111 | TRootInvm *inv_mass;
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112 | //*******************************************
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113 |
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114 | //run on the events
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115 | Long64_t entry, allEntries = treeReaderRec->GetEntries();
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116 | cout << "** Chain contains " << allEntries << " events" << endl;
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117 | total=allEntries;
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118 |
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119 | //general information
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120 | float E,Px,Py,Pz;
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121 | float PT,Eta,Phi;
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122 |
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123 | //lepton information
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124 | bool IsolFlag;
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125 |
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126 | //bjet information
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127 | bool Btag;
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128 |
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129 | //Particle level information
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130 | int PID, Status, M1,M2,D1,D2;
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131 | float Charge, T, X, Y, Z, M;
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132 |
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133 | //VFD information
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134 | float S,q2,Tx,Ty;
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135 | int side;
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136 |
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137 | for(entry = 0; entry < allEntries; ++entry)
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138 | {
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139 | treeReaderGen->ReadEntry(entry);//access information of generated information
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140 | treeReaderRec->ReadEntry(entry);//access information of reconstructed information
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141 | treeReaderTrig->ReadEntry(entry);//access information of Trigger information
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142 |
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143 | //*****************************************************
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144 | //Example how to run on the generator level information
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145 | //*****************************************************
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146 | TIter itGen((TCollection*)GEN);
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147 | TRootGenParticle *gen;
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148 | itGen.Reset();
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149 | while( (gen = (TRootGenParticle*) itGen.Next()) )
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150 | {
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151 | PID = gen->PID; // particle HEP ID number
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152 | Status = gen->Status; // particle status
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153 | M1 = gen->M1; // particle 1st mother
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154 | M2 = gen->M2; // particle 2nd mother
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155 | D1 = gen->D1; // particle 1st daughter
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156 | D2 = gen->D2; // particle 2nd daughter
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157 | Charge = gen->getCharge(); // electrical charge
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158 |
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159 | T = gen->T; // particle vertex position (t component)
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160 | X = gen->X; // particle vertex position (x component)
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161 | Y = gen->Y; // particle vertex position (y component)
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162 | Z = gen->Z; // particle vertex position (z component)
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163 | M = gen->M; // particle mass
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164 | }
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165 |
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166 |
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167 | //***********************************************
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168 | //Example how to run on the reconstructed objects
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169 | //***********************************************
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170 |
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171 | //access the Electron branch
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172 | TIter itElec((TCollection*)ELEC);
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173 | TRootElectron *elec;
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174 | itElec.Reset();
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175 | while( (elec = (TRootElectron*) itElec.Next()) )
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176 | {
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177 | E = elec->E; // particle energy in GeV
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178 | Px = elec->Px; // particle momentum vector (x component) in GeV
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179 | Py = elec->Py; // particle momentum vector (y component) in GeV
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180 | Pz = elec->Pz; // particle momentum vector (z component) in GeV
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181 |
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182 | PT = elec->PT; // particle transverse momentum in GeV
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183 | Eta = elec->Eta; // particle pseudorapidity
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184 | Phi = elec->Phi; // particle azimuthal angle in rad
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185 | IsolFlag = elec->IsolFlag; // is the particule isolated?
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186 | }
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187 | //Running on the muon branch is identical:
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188 | TIter itMuon((TCollection*)MUON);
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189 | TRootMuon *muon;
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190 | itMuon.Reset();
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191 | while( (muon = (TRootMuon*) itMuon.Next()) ){}
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192 |
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193 | //access the Photon branch
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194 | TIter itGam((TCollection*)PHOTO);
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195 | TRootPhoton *gam;
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196 | itGam.Reset();
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197 | while( (gam = (TRootPhoton*) itGam.Next()) )
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198 | {
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199 | E = gam->E; // particle energy in GeV
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200 | Px = gam->Px; // particle momentum vector (x component) in GeV
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201 | Py = gam->Py; // particle momentum vector (y component) in GeV
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202 | Pz = gam->Pz; // particle momentum vector (z component) in GeV
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203 |
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204 | PT = gam->PT; // particle transverse momentum in GeV
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205 | Eta = gam->Eta; // particle pseudorapidity
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206 | Phi = gam->Phi; // particle azimuthal angle in rad
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207 | }
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208 |
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209 | //access the jet branch
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210 | TIter itJet((TCollection*)JET);
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211 | TRootJet *jet;
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212 | itJet.Reset();
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213 | while( (jet = (TRootJet*) itJet.Next()) )
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214 | {
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215 | E = jet->E; // particle energy in GeV
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216 | Px = jet->Px; // particle momentum vector (x component) in GeV
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217 | Py = jet->Py; // particle momentum vector (y component) in GeV
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218 | Pz = jet->Pz; // particle momentum vector (z component) in GeV
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219 |
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220 | PT = jet->PT; // particle transverse momentum in GeV
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221 | Eta = jet->Eta; // particle pseudorapidity
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222 | Phi = jet->Phi; // particle azimuthal angle in rad
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223 | Btag = jet->Btag; // is the jet BTagged
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224 | }
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225 | //Running on the tau-jet branch is identical:
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226 | TIter itTaujet((TCollection*)TAUJET);
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227 | TRootTauJet *taujet;
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228 | itTaujet.Reset();
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229 | while( (taujet = (TRootTauJet*) itTaujet.Next()) ){}
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230 |
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231 | //access the track branch
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232 | TIter itTrack((TCollection*)TRACKS);
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233 | TRootTracks *tracks;
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234 | itTrack.Reset();
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235 | while( (tracks = (TRootTracks*) itTrack.Next()) )
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236 | {
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237 | E = tracks->E; // particle energy in GeV
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238 | Px = tracks->Px; // particle momentum vector (x component) in GeV
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239 | Py = tracks->Py; // particle momentum vector (y component) in GeV
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240 | Pz = tracks->Pz; // particle momentum vector (z component) in GeV
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241 |
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242 | PT = tracks->PT; // particle transverse momentum in GeV
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243 | Eta = tracks->Eta; // particle pseudorapidity
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244 | Phi = tracks->Phi; // particle azimuthal angle in rad
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245 | }
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246 |
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247 | //Running on the calo branch is identical:
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248 | TIter itCalo((TCollection*)CALO);
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249 | TRootCalo *calo;
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250 | itCalo.Reset();
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251 | while( (calo = (TRootCalo*) itCalo.Next()) ){}
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252 |
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253 | //***************************************************
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254 | //Example how to run on the VFD reconstructed objects
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255 | //***************************************************
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256 |
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257 | //access the ZDC branch
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258 | TIter itZdc((TCollection*)ZDC);
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259 | TRootZdcHits *zdc;
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260 | itZdc.Reset();
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261 | while( (zdc = (TRootZdcHits*) itZdc.Next()) )
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262 | {
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263 | E = zdc->E; // particle energy in GeV
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264 | Px = zdc->Px; // particle momentum vector (x component) in GeV
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265 | Py = zdc->Py; // particle momentum vector (y component) in GeV
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266 | Pz = zdc->Pz; // particle momentum vector (z component) in GeV
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267 |
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268 | PT = zdc->PT; // particle transverse momentum in GeV
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269 | Eta = zdc->Eta; // particle pseudorapidity
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270 | Phi = zdc->Phi; // particle azimuthal angle in rad
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271 |
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272 | T = zdc->T; // time of flight [s]
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273 | side = zdc->side; // -1 or +1
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274 | }
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275 |
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276 | //access the RP220 branch
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277 | TIter itRp220((TCollection*)RP220);
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278 | TRootRomanPotHits *rp220;
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279 | itRp220.Reset();
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280 | //TRootRomanPotHits.MakeClass("test_xav");
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281 | while( (rp220 = (TRootRomanPotHits*) itRp220.Next()) )
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282 | {
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283 | T = rp220->T; // time of flight to the detector [s]
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284 | S = rp220->S; // distance to the IP [m]
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285 | E = rp220->E; // reconstructed energy [GeV]
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286 | q2 = rp220->q2; // reconstructed squared momentum transfer [GeV^2]
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287 |
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288 | X = rp220->X; // horizontal distance to the beam [um]
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289 | Y = rp220->Y; // vertical distance to the beam [um]
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290 |
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291 | Tx = rp220->Tx; // angle of the momentum in the horizontal (x,z) plane [urad]
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292 | Ty = rp220->Ty; // angle of the momentum in the verical (y,z) plane [urad]
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293 |
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294 | side = rp220->side; // -1 or 1
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295 | }
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296 | //running on FP420 branch is identical
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297 | TIter itFp420((TCollection*)FP420);
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298 | TRootRomanPotHits *fp420;
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299 | itFp420.Reset();
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300 | while( (fp420 = (TRootRomanPotHits*) itFp420.Next()) ){}
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301 |
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302 | //*********************************************
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303 | //Example how to run on the trigger information
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304 | //*********************************************
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305 |
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306 | TRootTrigger *trig;
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307 | int NumTrigBit = TRIGGER->GetEntries();
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308 | //get the global response of the trigger
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309 |
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310 | bool GlobalResponse=false;
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311 | if(NumTrigBit!=0)GlobalResponse=true;
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312 | cout<<"GlobalResponse "<<GlobalResponse<<endl;
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313 | for(int i=0; i < NumTrigBit-1; i++){
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314 | trig = (TRootTrigger*)TRIGGER->At(i);
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315 | cout<<"The event has been accepted by the trigger number: "<<trig->Accepted<<endl;
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316 | }
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317 |
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318 | //********************************
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319 | //Example of a very small analysis
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320 | //********************************
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321 |
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322 | TLorentzVector Lept[2];
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323 |
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324 | if(NumTrigBit==0)continue; //event not accepted by the trigger
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325 | cut_trig++;//event accepted
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326 |
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327 | TSimpleArray<TRootElectron> el=SubArrayEl(ELEC,PT_ELEC);//the central isolated electrons, pt > PT_ELEC GeV
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328 | TSimpleArray<TRootMuon> mu=SubArrayMu(MUON,PT_MUON);//the central isolated electrons, pt > PT_MUON GeV
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329 |
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330 | Int_t numElec=el.GetEntries();
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331 |
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332 | if(el.GetEntries()+mu.GetEntries()!=2)continue;//Exactly 2 isolated leptons are needed
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333 | cut_1++;//event accepted
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334 | for(Int_t i=0;i < numElec; i++)Lept[i].SetPxPyPzE(el[i]->Px,el[i]->Py,el[i]->Pz,el[i]->E);
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335 | for(Int_t k = numElec; k < (numElec+mu.GetEntries()); k++)Lept[k].SetPxPyPzE(mu[k-numElec]->Px,mu[k-numElec]->Py,mu[k-numElec]->Pz,mu[k-numElec]->E);
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336 | cout<<"normalement il y a quelque chose... "<<endl;
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337 | //Example how to white a branch in the output file
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338 | inv_mass=(TRootInvm*) INVMASS->NewEntry();
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339 | inv_mass->M=(Lept[0]+Lept[1]).M();
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340 |
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341 | if((Lept[0]+Lept[1]).M() > INV_MASS_LL )continue;// the invariant mass should be < INV_MASS_LL
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342 | cut_2++;//event accepted
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343 |
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344 | treeWriter->Fill();
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345 | }
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346 | treeWriter->Write();
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347 |
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348 | }
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349 |
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350 | void Analysis_Ex::WriteOutput(string LogName)
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351 | {
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352 | ofstream f_out(LogName.c_str(),ofstream::app);
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353 |
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354 | f_out<<"*******************************************************************"<<endl;
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355 | f_out << left << setw(20) << "Numer of Events "<<""
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356 | << right << setw(15) << total <<"\n";
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357 | f_out << left << setw(17) << " Accepted by the trigger "<<""
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358 | << right << setw(20) << cut_trig <<"\n";
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359 | f_out << left << setw(17) <<" 2 leptons "<< ""
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360 | << right << setw(20) << cut_1 << ""
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361 | << right << setw(15) << cut_1/total << "\n";
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362 | f_out << left << setw(17) <<" Invariant mass "<< ""
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363 | << right << setw(20) << cut_2 << ""
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364 | << right << setw(15) << cut_2/total << "\n";
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365 | f_out<<"*******************************************************************"<<endl;
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366 | f_out<<" "<<endl;
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367 |
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368 | }
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369 |
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370 | TSimpleArray<TRootElectron> Analysis_Ex::SubArrayEl(const TClonesArray *ELEC,float pt)
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371 | {
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372 | TIter itElec((TCollection*)ELEC);
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373 | TRootElectron *elec;
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374 | itElec.Reset();
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375 | TSimpleArray<TRootElectron> array;
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376 | while( (elec = (TRootElectron*) itElec.Next()) )
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377 | {
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378 | if(elec->PT<pt)continue;
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379 | array.Add(elec);
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380 | }
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381 | return array;
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382 | }
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383 |
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384 | TSimpleArray<TRootMuon> Analysis_Ex::SubArrayMu(const TClonesArray *MUON,float pt)
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385 | {
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386 | TIter itMuon((TCollection*)MUON);
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387 | TRootMuon *muon;
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388 | itMuon.Reset();
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389 | TSimpleArray<TRootMuon> array;
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390 | while( (muon = (TRootMuon*) itMuon.Next()) )
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391 | {
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392 | if(muon->PT<pt)continue;
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393 | array.Add(muon);
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394 | }
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395 | return array;
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396 | }
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397 |
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