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HbbHbb_LMRSelection_chi2_150.cc
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HbbHbb_LMRSelection_chi2_150.cc
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#include <TH1F.h>
#include <TH2F.h>
#include <TFile.h>
#include <TTree.h>
#include <TChain.h>
#include <TSystem.h>
#include <TROOT.h>
#include <TLorentzVector.h>
#include <iostream>
#include <vector>
//#include "PDFs/BtagCalibrationStandalone.cc"
#include "HbbHbb_Component_SignalPurity.cc"
#include "HbbHbb_Component_KinFit.cc"
double jet_pT_cut1=30.;
double mean_H1_mass_=150;
double sigma_H1_mass_=20;
double mean_H2_mass_=150;
double sigma_H2_mass_=20;
float mass_mean( int mass )
{
if( mass == 260 ) return 243;
else if( mass == 300 ) return 276;
else if( mass == 350 ) return 318;
else if( mass == 400 ) return 363;
else if( mass == 450 ) return 413;
else if( mass == 500 ) return 463;
else if( mass == 550 ) return 530;
else return mass;
}
float mass_mean_reg( int mass )
{
if( mass == 260 ) return 257;
else if( mass == 300 ) return 291;
else if( mass == 350 ) return 336;
else if( mass == 400 ) return 387;
else if( mass == 450 ) return 433;
else if( mass == 500 ) return 481;
else if( mass == 550 ) return 531;
else return mass;
}
float mass_sigma( int mass )
{
if( mass == 260 ) return 20;
else if( mass == 300 ) return 25;
else if( mass == 350 ) return 31;
else if( mass == 400 ) return 36;
else if( mass == 450 ) return 32;
else if( mass == 500 ) return 35;
else if( mass == 550 ) return 35;
else return 30;
}
float mass_sigma_reg( int mass )
{
if( mass == 260 ) return 18;
else if( mass == 300 ) return 22;
else if( mass == 350 ) return 26;
else if( mass == 400 ) return 24;
else if( mass == 450 ) return 27;
else if( mass == 500 ) return 31;
else if( mass == 550 ) return 30;
else return 30;
}
TLorentzVector fillTLorentzVector(double pT, double eta, double phi, double M)
{
TLorentzVector jet_p4;
jet_p4.SetPtEtaPhiM(pT, eta, phi, M);
return jet_p4;
}
void HbbHbb_LMRSelection_chi2_150(std::string type, std::string sample, int signal_mass = 300, bool reg = false )
{
std::string inputfilename="../PreSelected_"+sample+".root";
TChain *tree=new TChain("tree");
tree->Add(inputfilename.c_str());
//std::cout<<"Opened input file "<<inputfilename<<std::endl;
// Book variables
int evt;
float eventWeight;
int nJets, nGenBQuarkFromH;
float jet_btagCSV[100];
float jet_pT[100], jet_eta[100], jet_phi[100], jet_mass[100];
float genBQuarkFromH_pT[100],genBQuarkFromH_eta[100],genBQuarkFromH_phi[100],genBQuarkFromH_mass[100];
float jet_regressed_pT[100], jet_flavor[100];
std::vector<unsigned int> *jetIndex_CentralpT40btag_deepCSVOrder=0;
// Retrieve variables
tree->SetBranchAddress("evt", &evt);
tree->SetBranchAddress("eventWeight", &(eventWeight));
tree->SetBranchAddress("nJet", &(nJets));
tree->SetBranchAddress("Jet_btagCSV", &(jet_btagCSV));
tree->SetBranchAddress("Jet_pt", &(jet_pT));
tree->SetBranchAddress("Jet_eta", &(jet_eta));
tree->SetBranchAddress("Jet_phi", &(jet_phi));
tree->SetBranchAddress("Jet_mass", &(jet_mass));
tree->SetBranchAddress("Jet_regressed_pt", &(jet_regressed_pT));
tree->SetBranchAddress("jetIndex_CentralpT40btag_deepCSVOrder", &(jetIndex_CentralpT40btag_deepCSVOrder));
if(type!="Data"){
tree->SetBranchAddress("nGenBQuarkFromH", &(nGenBQuarkFromH));
tree->SetBranchAddress("GenBQuarkFromH_pt", &(genBQuarkFromH_pT));
tree->SetBranchAddress("GenBQuarkFromH_eta", &(genBQuarkFromH_eta));
tree->SetBranchAddress("GenBQuarkFromH_phi", &(genBQuarkFromH_phi));
tree->SetBranchAddress("GenBQuarkFromH_mass", &(genBQuarkFromH_mass));
tree->SetBranchAddress("Jet_mcFlavour", &(jet_flavor));
}
// Book histograms
TH1F *h_H1_mass = new TH1F("h_H1_mass", "; m_{H1} (GeV)", 100, 50., 250.);
TH1F *h_H1_pT = new TH1F("h_H1_pT", "; H1 p_{T} (GeV/c)", 800, 0., 800.);
TH1F *h_H2_mass = new TH1F("h_H2_mass", "; m_{H2} (GeV)", 100, 50., 250.);
TH1F *h_H2_pT = new TH1F("h_H2_pT", "; H2 p_{T} (GeV/c)", 800, 0., 800.);
TH1F *h_HH_balance = new TH1F("h_HH_balance", "; (#vec{p}_{H1} + #vec{p}_{H2} - #vec{p}_{X}^{gen})_{T} GeV", 200, 0, 200.);
TH2F *h_mH1_mH2_asym = new TH2F("h_mH1_mH2_asym", "; m_{H1} (GeV); m_{H2} (GeV)", 300, 0., 300., 300, 0., 300.);
TH1F *h_H1_mass_biasCorrected = new TH1F("h_H1_mass_biasCorrected", "; Bias Corrected m_{H1} (GeV)", 300, 0., 300.);
TH1F *h_H1_pT_biasCorrected = new TH1F("h_H1_pT_biasCorrected", "; H1 p_{T} (GeV/c)", 800, 0., 800.);
TH1F *h_H2_mass_biasCorrected = new TH1F("h_H2_mass_biasCorrected", "; Bias Corrected m_{H2} (GeV)", 300, 0., 300.);
TH1F *h_H2_pT_biasCorrected = new TH1F("h_H2_pT_biasCorrected", "; H2 p_{T} (GeV/c)", 800, 0., 800.);
TH1F *h_HH_balance_biasCorrected = new TH1F("h_HH_balance_biasCorrected", "; (#vec{p}_{H1} + #vec{p}_{H2} - #vec{p}_{X}^{gen})_{T} GeV", 200, 0, 200.);
TH2F *h_mH1_mH2_asym_biasCorrected = new TH2F("h_mH1_mH2_asym_biasCorrected", "; m_{H1} (GeV); m_{H2} (GeV)", 300, 0., 300., 300, 0., 300.);
TH1F *h_GenX_pT = new TH1F("h_GenX_pT", "; (#vec{p}_{H1} + #vec{p}_{H2})_{T} GeV", 200, 0., 800.);
TH1F *h_kinFitchi2=new TH1F("h_kinFitchi2", "; Event 4 jet kinematic #chi^2", 200, 0., 10.);
TH1F *h_chi=new TH1F("h_chi", "; HH #chi", 100, 0, 100);
TH1F *h_chi_biasCorrected=new TH1F("h_chi_biasCorrected", "; HH #chi", 100, 0, 100);
TH1F *h_mX_SR = new TH1F("h_mX_SR", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR->Sumw2();
TH1F *h_mX_SR_purity0 = new TH1F("h_mX_SR_purity0", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_purity0->Sumw2();
TH1F *h_mX_SR_purity1 = new TH1F("h_mX_SR_purity1", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_purity1->Sumw2();
TH1F *h_mX_SR_purity2 = new TH1F("h_mX_SR_purity2", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_purity2->Sumw2();
TH1F *h_mX_SR_purity3 = new TH1F("h_mX_SR_purity3", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_purity3->Sumw2();
TH1F *h_mX_SR_purity4 = new TH1F("h_mX_SR_purity4", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_purity4->Sumw2();
TH1F *h_mX_SR_purity5 = new TH1F("h_mX_SR_purity5", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_purity5->Sumw2();
TH1F *h_mX_SR_biasCorrected = new TH1F("h_mX_SR_biasCorrected", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_biasCorrected->Sumw2();
TH1F *h_mX_SR_kinFit = new TH1F("h_mX_SR_kinFit", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_kinFit->Sumw2();
TH1F *h_mX_SR_kinFit_purity0 = new TH1F("h_mX_SR_kinFit_purity0", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_kinFit_purity0->Sumw2();
TH1F *h_mX_SR_kinFit_purity1 = new TH1F("h_mX_SR_kinFit_purity1", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_kinFit_purity1->Sumw2();
TH1F *h_mX_SR_kinFit_purity2 = new TH1F("h_mX_SR_kinFit_purity2", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_kinFit_purity2->Sumw2();
TH1F *h_mX_SR_kinFit_purity3 = new TH1F("h_mX_SR_kinFit_purity3", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_kinFit_purity3->Sumw2();
TH1F *h_mX_SR_kinFit_purity4 = new TH1F("h_mX_SR_kinFit_purity4", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_kinFit_purity4->Sumw2();
TH1F *h_mX_SR_kinFit_purity5 = new TH1F("h_mX_SR_kinFit_purity5", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SR_kinFit_purity5->Sumw2();
TH1F *h_HH_balance_kinFit = new TH1F("h_HH_balance_kinFit", "; (#vec{p}_{H1} + #vec{p}_{H2} - #vec{p}_{X}^{gen})_{T} GeV", 200, 0, 200.);
TH1F *h_mX_SB = new TH1F("h_mX_SB", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SB->Sumw2();
TH1F *h_mX_SB_biasCorrected = new TH1F("h_mX_SB_biasCorrected", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SB_biasCorrected->Sumw2();
TH1F *h_mX_SB_kinFit = new TH1F("h_mX_SB_kinFit", "; m_{X} (GeV)", 3000, 0., 3000.); h_mX_SB_kinFit->Sumw2();
std::string Old_histfilename="../Histograms_Preselected_"+sample+".root";
std::string histfilename="Histograms_LMR_150"+sample+".root";
gSystem->Exec(("cp "+Old_histfilename+" "+histfilename).c_str());
TFile *tFile1=new TFile((Old_histfilename).c_str(), "READ");
TH1F h_Cuts=*((TH1F*)((TH1F*)tFile1->Get("h_Cuts"))->Clone("h_Cuts"));
tFile1->Close();
float SR_tot=0, SB_tot=0;
int masses[]={260,300,350,400,450,500,550};
std::map<int,float> SB_m, SR_m;
for( auto m : masses ){ SR_m[m]=0; SB_m[m]=0; }
// Event loop
int nEvents=tree->GetEntries();
double nCut4=0, nCut5=0, nCutGen=0;
for (int i=0; i<tree->GetEntries(); ++i)
{
tree->GetEvent(i);
bool foundHH=false;
double chi2_old=200.;
double m_diff_old=100.;
int H1jet1_i=-1, H1jet2_i=-1;
int H2jet1_i=-1, H2jet2_i=-1;
for (unsigned int j=0; j<jetIndex_CentralpT40btag_deepCSVOrder->size(); ++j)
{
unsigned int j_jetIndex=jetIndex_CentralpT40btag_deepCSVOrder->at(j);
TLorentzVector jet1_p4, jet2_p4, jet3_p4, jet4_p4;
jet1_p4=fillTLorentzVector(jet_regressed_pT[j_jetIndex], jet_eta[j_jetIndex], jet_phi[j_jetIndex], jet_mass[j_jetIndex]);
if (jet1_p4.Pt()>jet_pT_cut1)
{
for (unsigned int k=0; k<jetIndex_CentralpT40btag_deepCSVOrder->size(); ++k)
{
unsigned int k_jetIndex=jetIndex_CentralpT40btag_deepCSVOrder->at(k);
jet2_p4=fillTLorentzVector(jet_regressed_pT[k_jetIndex], jet_eta[k_jetIndex], jet_phi[k_jetIndex], jet_mass[k_jetIndex]);
if (k_jetIndex!=j_jetIndex && jet2_p4.Pt()>jet_pT_cut1)
{
for (unsigned int l=0; l<jetIndex_CentralpT40btag_deepCSVOrder->size(); ++l)
{
unsigned int l_jetIndex=jetIndex_CentralpT40btag_deepCSVOrder->at(l);
jet3_p4=fillTLorentzVector(jet_regressed_pT[l_jetIndex], jet_eta[l_jetIndex], jet_phi[l_jetIndex], jet_mass[l_jetIndex]);
if (l_jetIndex!=k_jetIndex && l_jetIndex!=j_jetIndex && jet3_p4.Pt()>jet_pT_cut1)
{
for (unsigned int m=0; m<jetIndex_CentralpT40btag_deepCSVOrder->size(); ++m)
{
unsigned int m_jetIndex=jetIndex_CentralpT40btag_deepCSVOrder->at(m);
jet4_p4=fillTLorentzVector(jet_regressed_pT[m_jetIndex], jet_eta[m_jetIndex], jet_phi[m_jetIndex], jet_mass[m_jetIndex]);
if (m_jetIndex!=j_jetIndex && m_jetIndex!=k_jetIndex && m_jetIndex!=l_jetIndex && jet4_p4.Pt()>jet_pT_cut1)
{
// swap if H pT is odd in second decimal place
if (int((jet1_p4+jet2_p4).Pt()*100.) % 2 == 1)
{
swap(j_jetIndex, l_jetIndex);
swap(k_jetIndex, m_jetIndex);
swap(jet1_p4, jet3_p4);
swap(jet2_p4, jet4_p4);
}
double deltaR1=jet1_p4.DeltaR(jet2_p4);
double deltaR2=jet3_p4.DeltaR(jet4_p4);
TLorentzVector diJet1_p4=jet1_p4+jet2_p4;
TLorentzVector diJet2_p4=jet3_p4+jet4_p4;
double mH1=diJet1_p4.M();
double mH2=diJet2_p4.M();
double m_diff=fabs(mH1-mH2);
double chi2=pow((mH1-mean_H1_mass_)/sigma_H1_mass_, 2)+pow((mH2-mean_H2_mass_)/sigma_H2_mass_, 2);
if (chi2< chi2_old && ((110.<mH1 && mH1<190.) && (110.<mH2 && mH2<190.)))
{
H1jet1_i=j_jetIndex;
H1jet2_i=k_jetIndex;
H2jet1_i=l_jetIndex;
H2jet2_i=m_jetIndex;
chi2_old=chi2;
m_diff_old=m_diff;
foundHH=true;
}
} // Conditions on 4th jet
} // Loop over 4th jet
} // Conditions on 3rd jet
} // Loop over 3rd jet
} // Conditions on 2nd jet
} // Loop over 2nd jet
} // Condition of 1st jet
} // Loop over 1st jet
if (foundHH)
{
nCut4+=eventWeight;
double chi=pow(chi2_old, 0.5);
h_chi->Fill(chi, eventWeight);
TLorentzVector jet1_p4=fillTLorentzVector(jet_regressed_pT[H1jet1_i], jet_eta[H1jet1_i], jet_phi[H1jet1_i], jet_mass[H1jet1_i]);
TLorentzVector jet2_p4=fillTLorentzVector(jet_regressed_pT[H1jet2_i], jet_eta[H1jet2_i], jet_phi[H1jet2_i], jet_mass[H1jet2_i]);
TLorentzVector jet3_p4=fillTLorentzVector(jet_regressed_pT[H2jet1_i], jet_eta[H2jet1_i], jet_phi[H2jet1_i], jet_mass[H2jet1_i]);
TLorentzVector jet4_p4=fillTLorentzVector(jet_regressed_pT[H2jet2_i], jet_eta[H2jet2_i], jet_phi[H2jet2_i], jet_mass[H2jet2_i]);
TLorentzVector jet1_p4_unregressed=fillTLorentzVector(jet_pT[H1jet1_i], jet_eta[H1jet1_i], jet_phi[H1jet1_i], jet_mass[H1jet1_i]);
TLorentzVector jet2_p4_unregressed=fillTLorentzVector(jet_pT[H1jet2_i], jet_eta[H1jet2_i], jet_phi[H1jet2_i], jet_mass[H1jet2_i]);
TLorentzVector jet3_p4_unregressed=fillTLorentzVector(jet_pT[H2jet1_i], jet_eta[H2jet1_i], jet_phi[H2jet1_i], jet_mass[H2jet1_i]);
TLorentzVector jet4_p4_unregressed=fillTLorentzVector(jet_pT[H2jet2_i], jet_eta[H2jet2_i], jet_phi[H2jet2_i], jet_mass[H2jet2_i]);
// Fill histograms before bias correction
TLorentzVector H1_p4=jet1_p4+jet2_p4;
TLorentzVector H2_p4=jet3_p4+jet4_p4;
TLorentzVector X_p4=H1_p4+H2_p4;
double pTH1=H1_p4.Pt();
double pTH2=H2_p4.Pt();
double mH1=H1_p4.M();
double mH2=H2_p4.M();
h_H1_mass->Fill(mH1, eventWeight);
h_H1_pT->Fill(pTH1, eventWeight);
h_H2_mass->Fill(mH2, eventWeight);
h_H2_pT->Fill(pTH2, eventWeight);
h_mH1_mH2_asym->Fill(mH1, mH2, eventWeight);
// Apply bias correction
TLorentzVector jet1_p4_biasCorrected=biasEt_signal(jet1_p4_unregressed);
TLorentzVector jet2_p4_biasCorrected=biasEt_signal(jet2_p4_unregressed);
TLorentzVector jet3_p4_biasCorrected=biasEt_signal(jet3_p4_unregressed);
TLorentzVector jet4_p4_biasCorrected=biasEt_signal(jet4_p4_unregressed);
// Fill histograms after bias correction
TLorentzVector H1_p4_biasCorrected=jet1_p4_biasCorrected+jet2_p4_biasCorrected;
TLorentzVector H2_p4_biasCorrected=jet3_p4_biasCorrected+jet4_p4_biasCorrected;
TLorentzVector X_p4_biasCorrected=H1_p4_biasCorrected+H2_p4_biasCorrected;
double pTH1_biasCorrected=H1_p4_biasCorrected.Pt();
double pTH2_biasCorrected=H2_p4_biasCorrected.Pt();
double mH1_biasCorrected=H1_p4_biasCorrected.M();
double mH2_biasCorrected=H2_p4_biasCorrected.M();
h_H1_mass_biasCorrected->Fill(mH1_biasCorrected, eventWeight);
h_H1_pT_biasCorrected->Fill(pTH1_biasCorrected, eventWeight);
h_H2_mass_biasCorrected->Fill(mH2_biasCorrected, eventWeight);
h_H2_pT_biasCorrected->Fill(pTH2_biasCorrected, eventWeight);
h_mH1_mH2_asym_biasCorrected->Fill(mH1_biasCorrected, mH2_biasCorrected, eventWeight);
// Check purity of jet selection here // FIX THIS to check against kin fit reco jets.
TLorentzVector b1_p4;
TLorentzVector b2_p4;
TLorentzVector b3_p4;
TLorentzVector b4_p4;
int purity=-3;
if (type=="Signal")
{
if (nGenBQuarkFromH==4)
{
b1_p4=fillTLorentzVector(genBQuarkFromH_pT[0], genBQuarkFromH_eta[0], genBQuarkFromH_phi[0], genBQuarkFromH_mass[0]);
b2_p4=fillTLorentzVector(genBQuarkFromH_pT[1], genBQuarkFromH_eta[1], genBQuarkFromH_phi[1], genBQuarkFromH_mass[1]);
b3_p4=fillTLorentzVector(genBQuarkFromH_pT[2], genBQuarkFromH_eta[2], genBQuarkFromH_phi[2], genBQuarkFromH_mass[2]);
b4_p4=fillTLorentzVector(genBQuarkFromH_pT[3], genBQuarkFromH_eta[3], genBQuarkFromH_phi[3], genBQuarkFromH_mass[3]);
TLorentzVector j[4]={jet1_p4, jet2_p4, jet3_p4, jet4_p4};
TLorentzVector b[4]={b1_p4, b2_p4, b3_p4, b4_p4};
int jMatchedbindex[4]={-1, -1, -1, -1};
purity=purityTest(j, b, jMatchedbindex);
}
else
{
std::cout<<"ERROR: This is a signal sample without 4 gen b from H."<<std::endl;
}
}
double oppSign=(mH1-mean_H1_mass_)*(mH2-mean_H2_mass_);
if (chi<=1) // Signal Region
{
nCut5+=eventWeight;
SR_tot++;
for( auto m : masses )
{
if( !reg && X_p4.M() > mass_mean(m)-mass_sigma(m)*3 && X_p4.M() < mass_mean(m)+mass_sigma(m)*3 ) SR_m[m]++;
else if( reg && X_p4.M() > mass_mean_reg(m)-mass_sigma_reg(m)*3 && X_p4.M() < mass_mean_reg(m)+mass_sigma_reg(m)*3 ) SR_m[m]++;
}
// Apply kinematic constraint
// jet1_p4, jet2_p4, jet3_p4, jet4_p4 will change values
double kinFitchi2=constrainHH_signalMeasurement(&jet1_p4, &jet2_p4, &jet3_p4, &jet4_p4);
// double kinFitchi2=constrainHH_afterRegression(&jet1_p4, &jet2_p4, &jet3_p4, &jet4_p4);
h_kinFitchi2->Fill(kinFitchi2, eventWeight);
TLorentzVector X_p4_kinFit=(jet1_p4+jet2_p4+jet3_p4+jet4_p4);
h_mX_SR->Fill(X_p4.M(), eventWeight);
h_mX_SR_biasCorrected->Fill(X_p4_biasCorrected.M(), eventWeight);
h_mX_SR_kinFit->Fill(X_p4_kinFit.M(), eventWeight);
if (purity==-1)
{
h_mX_SR_purity5->Fill(X_p4.M(), eventWeight);
h_mX_SR_kinFit_purity5->Fill(X_p4_kinFit.M(), eventWeight);
}
else if (purity==0)
{
h_mX_SR_purity0->Fill(X_p4.M(), eventWeight);
h_mX_SR_kinFit_purity0->Fill(X_p4_kinFit.M(), eventWeight);
}
else if (purity==1)
{
h_mX_SR_purity1->Fill(X_p4.M(), eventWeight);
h_mX_SR_kinFit_purity1->Fill(X_p4_kinFit.M(), eventWeight);
}
else if (purity==2)
{
h_mX_SR_purity2->Fill(X_p4.M(), eventWeight);
h_mX_SR_kinFit_purity2->Fill(X_p4_kinFit.M(), eventWeight);
}
else if (purity==3)
{
h_mX_SR_purity3->Fill(X_p4.M(), eventWeight);
h_mX_SR_kinFit_purity3->Fill(X_p4_kinFit.M(), eventWeight);
}
else if (purity==4)
{
h_mX_SR_purity4->Fill(X_p4.M(), eventWeight);
h_mX_SR_kinFit_purity4->Fill(X_p4_kinFit.M(), eventWeight);
}
// Fill HH pT balancing histograms
if (type=="Signal" && nGenBQuarkFromH==4)
{
TLorentzVector gen_X_p4 = b1_p4 + b2_p4 + b3_p4 + b4_p4;
h_HH_balance->Fill((X_p4 - gen_X_p4).Pt(), eventWeight);
h_HH_balance_biasCorrected->Fill((X_p4_biasCorrected - gen_X_p4).Pt(), eventWeight);
h_HH_balance_kinFit->Fill((X_p4_kinFit - gen_X_p4).Pt(), eventWeight);
}
}
else if (1<chi && chi<2. && oppSign<0) // Sideband Region
{
SB_tot++;
for( auto m : masses )
{
if( !reg && X_p4.M() > mass_mean(m)-mass_sigma(m)*3 && X_p4.M() < mass_mean(m)+mass_sigma(m)*3 ) SB_m[m]++;
else if( reg && X_p4.M() > mass_mean_reg(m)-mass_sigma_reg(m)*3 && X_p4.M() < mass_mean_reg(m)+mass_sigma_reg(m)*3 ) SB_m[m]++;
}
// Apply kinematic constraint
// jet1_p4, jet2_p4, jet3_p4, jet4_p4 will change values
double kinFitchi2=constrainHH_signalMeasurement(&jet1_p4, &jet2_p4, &jet3_p4, &jet4_p4);
TLorentzVector X_p4_kinFit=(jet1_p4+jet2_p4+jet3_p4+jet4_p4);
h_mX_SB->Fill(X_p4.M(), eventWeight);
h_mX_SB_biasCorrected->Fill(X_p4_biasCorrected.M(), eventWeight);
h_mX_SB_kinFit->Fill(X_p4_kinFit.M(), eventWeight);
}
}
if (i%(nEvents/10)==0) std::cout<<int(i*100./nEvents)+1<<"% of "<<nEvents<<" events have been processed."<<std::endl;
} // Event loop
if(type!="Data") std::cout << signal_mass << " " << SR_m[signal_mass] << std::endl;
else for( auto m : masses ) std::cout << m << " " << SB_m[m]*SR_tot/SB_tot << std::endl;
h_Cuts.Fill(9, nCut4); // HH Candidates
h_Cuts.Fill(11, nCut5); // SR
TFile *tFile2=new TFile(histfilename.c_str(), "UPDATE");
tFile2->Delete("h_Cuts;1");
h_H1_mass->Write();
h_H1_pT->Write();
h_H2_mass->Write();
h_H2_pT->Write();
h_HH_balance->Write();
h_mH1_mH2_asym->Write();
h_H1_mass_biasCorrected->Write();
h_H1_pT_biasCorrected->Write();
h_H2_mass_biasCorrected->Write();
h_H2_pT_biasCorrected->Write();
h_HH_balance_biasCorrected->Write();
h_mH1_mH2_asym_biasCorrected->Write();
h_GenX_pT->Write();
h_kinFitchi2->Write();
h_chi->Write();
h_chi_biasCorrected->Write();
if(type!="Data"){ h_mX_SR->Write();
h_mX_SR_biasCorrected->Write();
h_mX_SR_purity5->Write();
h_mX_SR_purity0->Write();
h_mX_SR_purity1->Write();
h_mX_SR_purity2->Write();
h_mX_SR_purity3->Write();
h_mX_SR_purity4->Write();
//h_mX_SR_kinFit->Write();
}
h_HH_balance_kinFit->Write();
if(type!="Data"){ h_mX_SR_kinFit_purity0->Write();
h_mX_SR_kinFit_purity1->Write();
h_mX_SR_kinFit_purity2->Write();
h_mX_SR_kinFit_purity3->Write();
h_mX_SR_kinFit_purity4->Write();
h_mX_SR_kinFit_purity5->Write(); }
h_mX_SB->Write();
h_mX_SB_biasCorrected->Write();
h_Cuts.Write();
h_mX_SB_kinFit->Write();
h_mX_SR_kinFit->Write();
tFile2->Write();
tFile2->Close();
std::cout<<"Wrote output file "<<histfilename<<std::endl;
std::cout<<"=== Cut Efficiencies === "<<std::endl;
std::cout<<"Number of events after finding HH candidate (btag && pT>40 GeV && |eta|<2.5) = "<<nCut4<<std::endl;
std::cout<<"Number of events in SR = "<<nCut5<<std::endl;
std::cout<<"========================"<<std::endl;
delete h_H1_mass;
delete h_H1_pT;
delete h_H2_mass;
delete h_H2_pT;
delete h_HH_balance;
delete h_mH1_mH2_asym;
delete h_H1_mass_biasCorrected;
delete h_H1_pT_biasCorrected;
delete h_H2_mass_biasCorrected;
delete h_H2_pT_biasCorrected;
delete h_HH_balance_biasCorrected;
delete h_mH1_mH2_asym_biasCorrected;
delete h_GenX_pT;
delete h_kinFitchi2;
delete h_chi;
delete h_chi_biasCorrected;
delete h_mX_SR;
delete h_mX_SR_biasCorrected;
delete h_mX_SR_purity5;
delete h_mX_SR_purity0;
delete h_mX_SR_purity1;
delete h_mX_SR_purity2;
delete h_mX_SR_purity3;
delete h_mX_SR_purity4;
delete h_mX_SR_kinFit;
delete h_HH_balance_kinFit;
delete h_mX_SR_kinFit_purity0;
delete h_mX_SR_kinFit_purity1;
delete h_mX_SR_kinFit_purity2;
delete h_mX_SR_kinFit_purity3;
delete h_mX_SR_kinFit_purity4;
delete h_mX_SR_kinFit_purity5;
delete h_mX_SB;
delete h_mX_SB_biasCorrected;
delete h_mX_SB_kinFit;
}