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binneddata.cc
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binneddata.cc
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#include "binneddata.hh"
#include "fit.hh"
#include <cassert>
#include <iostream>
#include <fstream>
#include <TFile.h>
#include <TH1D.h>
TH1D* getData(const std::vector<std::string>& filenames, const char* histname, int nbins, double* bins)
{
TH1D* hist=new TH1D("normalized_data", "normalized data", nbins, bins);
unsigned nFiles = filenames.size();
TFile *files[nFiles];
TH1D *hists[nFiles];
// open input files and get input histograms
for(unsigned i=0; i<nFiles; ++i)
{
files[i] = new TFile(filenames[i].c_str());
hists[i] = (TH1D*)files[i]->Get(histname);
}
// normalize the data in the histogram
for(int i=1; i<=hist->GetNbinsX(); ++i)
{
int bin_min = hists[0]->GetXaxis()->FindBin(hist->GetXaxis()->GetBinLowEdge(i)+0.5);
int bin_max = hists[0]->GetXaxis()->FindBin(hist->GetXaxis()->GetBinUpEdge(i)-0.5);
double val=hists[0]->Integral(bin_min,bin_max);
double err=Fitter::histError(val);
double width=hist->GetBinWidth(i);
hist->SetBinContent(i, val/width);
hist->SetBinError(i, err/width);
// for simultaneous fit in 3 distribution (used in di-b-jet analysis, currently commented out)
//if(hist->GetXaxis()->GetBinUpEdge(i)<=5890.)
//{
// double offset = 0.;
// int bin_min = hists[0]->GetXaxis()->FindBin(hist->GetXaxis()->GetBinLowEdge(i)-offset+0.5);
// int bin_max = hists[0]->GetXaxis()->FindBin(hist->GetXaxis()->GetBinUpEdge(i)-offset-0.5);
// double val=hists[0]->Integral(bin_min,bin_max);
// double err=Fitter::histError(val);
// double width=hist->GetBinWidth(i);
// hist->SetBinContent(i, val/width);
// hist->SetBinError(i, err/width);
//}
//else if(hist->GetXaxis()->GetBinUpEdge(i)>5890. && hist->GetXaxis()->GetBinUpEdge(i)<=10890. && nFiles>1)
//{
// double offset = 5000.;
// int bin_min = hists[1]->GetXaxis()->FindBin(hist->GetXaxis()->GetBinLowEdge(i)-offset+0.5);
// int bin_max = hists[1]->GetXaxis()->FindBin(hist->GetXaxis()->GetBinUpEdge(i)-offset-0.5);
// double val=hists[1]->Integral(bin_min,bin_max);
// double err=Fitter::histError(val);
// double width=hist->GetBinWidth(i);
// hist->SetBinContent(i, val/width);
// hist->SetBinError(i, err/width);
//}
//else if(hist->GetXaxis()->GetBinUpEdge(i)>10890. && nFiles>2)
//{
// double offset = 10000.;
// int bin_min = hists[2]->GetXaxis()->FindBin(hist->GetXaxis()->GetBinLowEdge(i)-offset+0.5);
// int bin_max = hists[2]->GetXaxis()->FindBin(hist->GetXaxis()->GetBinUpEdge(i)-offset-0.5);
// double val=hists[2]->Integral(bin_min,bin_max);
// double err=Fitter::histError(val);
// double width=hist->GetBinWidth(i);
// hist->SetBinContent(i, val/width);
// hist->SetBinError(i, err/width);
//}
}
// do some checks
if(hist->GetBinContent(0)>0.0 || hist->GetBinContent(hist->GetNbinsX()+1)>0.0)
{
std::cerr << "There is an underflow/overflow. This should be fixed. Please rebin!" << std::endl;
assert(0);
}
if(hist->GetBinContent(1)<=0.0)
{
std::cerr << "The first data bin is empty. This will give incorrect results. Please rebin!" << std::endl;
assert(0);
}
for(unsigned i=0; i<nFiles; ++i)
{
files[i]->Close();
}
return hist;
}
TH1D* getSignalCDF(const char* filename1, const char* histname1, const char* filename2, const char* histname2, const double BR, const double eff_h, const double eff_l, const std::string& postfix)
{
TH1D* h_pdf=new TH1D("h_pdf", "Resonance Shape", 14000, 0, 14000);
TH1D* h_cdf=new TH1D(("h_cdf"+postfix).c_str(), "Resonance Shape CDF", 14000, 0, 14000);
TFile* histfile1=new TFile(filename1);
TFile* histfile2=new TFile(filename2);
TH1D* hist1=(TH1D*)histfile1->Get(histname1);
TH1D* hist2=(TH1D*)histfile2->Get(histname2);
hist1->Scale(eff_h*BR);
hist2->Scale(eff_l*(1-BR));
hist1->Add(hist2); // this adds together two resonance shapes with appropriate branching fractions and efficiencies
for(int i=1; i<=hist1->GetNbinsX(); i++)
{
int bin_min = h_pdf->GetXaxis()->FindBin(hist1->GetXaxis()->GetBinLowEdge(i)+0.5);
int bin_max = h_pdf->GetXaxis()->FindBin(hist1->GetXaxis()->GetBinUpEdge(i)-0.5);
double bin_content = hist1->GetBinContent(i)/double(bin_max-bin_min+1);
if(bin_content<0.) bin_content=0.; // some extrapolated resonance shapes can have a small negative bin content in some of the bins. this protects against such cases
for(int b=bin_min; b<=bin_max; b++){
h_pdf->SetBinContent(b, bin_content);
}
}
h_pdf->Scale(1./h_pdf->Integral()); // normalize final PDF
// produce CDF from the normalized PDF
for(int i=1; i<=h_cdf->GetNbinsX(); i++)
{
int bin_min = h_pdf->GetXaxis()->FindBin(h_cdf->GetXaxis()->GetBinLowEdge(i)+0.5);
int bin_max = h_pdf->GetXaxis()->FindBin(h_cdf->GetXaxis()->GetBinUpEdge(i)-0.5);
double curr = 0;
for(int b=bin_min; b<=bin_max; b++){
curr+=h_pdf->GetBinContent(b);
}
double prev=h_cdf->GetBinContent(i-1);
h_cdf->SetBinContent(i, prev+curr);
}
histfile1->Close();
histfile2->Close();
delete h_pdf;
return h_cdf;
}