Plotting/Modules/SUSYScan.C

#include <iostream>
#include <vector>
#include <sys/stat.h>
#include <fstream>
#include <pthread.h>

#include <TCut.h>
#include <TROOT.h>
#include <TCanvas.h>
#include <TMath.h>
#include <TColor.h>
#include <TPaveText.h>
#include <TRandom.h>
#include <TH1.h>
#include <TH2.h>
#include <TF1.h>
#include <TSQLResult.h>
#include <TProfile.h>

//#include "TTbar_stuff.C"
using namespace std;

using namespace PlottingSetup;

void susy_scan_axis_labeling(TH2F *histo) {
  histo->GetXaxis()->SetTitle("#Chi_{2}^{0}-LSP");
  histo->GetXaxis()->CenterTitle();
  histo->GetYaxis()->SetTitle("m_{#tilde{q}}");
  histo->GetYaxis()->CenterTitle();
}

void scan_susy_space(string mcjzb, string datajzb) {
  TCanvas *c3 = new TCanvas("c3","c3");
  vector<float> binning;
  binning=allsamples.get_optimal_binsize(mcjzb,cutmass&&cutOSSF&&cutnJets,20,50,800);
  float arrbinning[binning.size()];
  for(int i=0;i<binning.size();i++) arrbinning[i]=binning[i];
  TH1F *puredata   = allsamples.Draw("puredata",  datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
  puredata->SetMarkerSize(DataMarkerSize);
  TH1F *allbgs   = allsamples.Draw("allbgs",  "-"+datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
  TH1F *allbgsb   = allsamples.Draw("allbgsb",  "-"+datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,luminosity);
  TH1F *allbgsc   = allsamples.Draw("allbgsc",  datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,luminosity);
  allbgs->Add(allbgsb,-1);
  allbgs->Add(allbgsc);
  int ndata=puredata->Integral();
  ofstream myfile;
  myfile.open ("susyscan_log.txt");
  TFile *susyscanfile = new TFile("/scratch/fronga/SMS/T5z_SqSqToQZQZ_38xFall10.root");
  TTree *suevents = (TTree*)susyscanfile->Get("events");
  TH2F *exclusionmap = new TH2F("exclusionmap","",20,0,500,20,0,1000);
  TH2F *exclusionmap1s = new TH2F("exclusionmap1s","",20,0,500,20,0,1000);
  TH2F *exclusionmap2s = new TH2F("exclusionmap2s","",20,0,500,20,0,1000);
  TH2F *exclusionmap3s = new TH2F("exclusionmap3s","",20,0,500,20,0,1000);
  
  susy_scan_axis_labeling(exclusionmap);
  susy_scan_axis_labeling(exclusionmap1s);
  susy_scan_axis_labeling(exclusionmap2s);
  susy_scan_axis_labeling(exclusionmap3s);
  
  Int_t MyPalette[100];
  Double_t r[]    = {0., 0.0, 1.0, 1.0, 1.0};
  Double_t g[]    = {0., 0.0, 0.0, 1.0, 1.0};
  Double_t b[]    = {0., 1.0, 0.0, 0.0, 1.0};
  Double_t stop[] = {0., .25, .50, .75, 1.0};
  Int_t FI = TColor::CreateGradientColorTable(5, stop, r, g, b, 100);
  for (int i=0;i<100;i++) MyPalette[i] = FI+i;
   
  gStyle->SetPalette(100, MyPalette);
  
  for(int m23=50;m23<500;m23+=25) {
    for (int m0=(2*(m23-50)+150);m0<=1000;m0+=50)
    {
      c3->cd();
      stringstream drawcondition;
      drawcondition << "pfJetGoodNum>=3&&(TMath::Abs(masses[0]-"<<m0<<")<10&&TMath::Abs(masses[2]-masses[3]-"<<m23<<")<10)&&mll>5&&id1==id2";
      TH1F *puresignal = new TH1F("puresignal","puresignal",binning.size()-1,arrbinning);
      TH1F *puresignall= new TH1F("puresignall","puresignal",binning.size()-1,arrbinning);
      stringstream drawvar,drawvar2;
      drawvar<<mcjzb<<">>puresignal";
      drawvar2<<"-"<<mcjzb<<">>puresignall";
      suevents->Draw(drawvar.str().c_str(),drawcondition.str().c_str());
      suevents->Draw(drawvar2.str().c_str(),drawcondition.str().c_str());
      if(puresignal->Integral()<60) {
        delete puresignal;
        continue;
      }
      puresignal->Add(puresignall,-1);//we need to correct for the signal contamination - we effectively only see (JZB>0)-(JZB<0) !!
      puresignal->Scale(ndata/(20*puresignal->Integral()));//normalizing it to 5% of the data
      stringstream saveas;
      saveas<<"Model_Scan/m0_"<<m0<<"__m23_"<<m23;
      dout << "PLEASE KEEP IN MIND THAT SIGNAL CONTAMINATION IS NOT REALLY TAKEN CARE OF YET DUE TO LOW STATISTICS! SHOULD BE SOMETHING LIKE THIS : "<< endl;
//        TH1F *signalpredlo   = allsamples.Draw("signalpredlo",  "-"+mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc,  luminosity,allsamples.FindSample("LM4"));
//        TH1F *signalpredro   = allsamples.Draw("signalpredro",      mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc,  luminosity,allsamples.FindSample("LM4"));
//        TH1F *puredata       = allsamples.Draw("puredata",          datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
//        signalpred->Add(signalpredlo,-1);
//        signalpred->Add(signalpredro);
//        puresignal->Add(signalpred,-1);//subtracting signal contamination
//---------------------
//      dout << "(m0,m23)=("<<m0<<","<<m23<<") contains " << puresignal->Integral() << endl;
//    TH1F *puresignal = allsamples.Draw("puresignal",mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc,  luminosity,allsamples.FindSample("LM4"));
      vector<float> results=establish_upper_limits(puredata,allbgs,puresignal,saveas.str(),myfile);  
      if(results.size()==0) {
        delete puresignal;
        continue;
      }
      exclusionmap->Fill(m23,m0,results[0]);
      exclusionmap1s->Fill(m23,m0,results[1]);
      exclusionmap2s->Fill(m23,m0,results[2]);
      exclusionmap3s->Fill(m23,m0,results[3]);
      delete puresignal;
      dout << "(m0,m23)=("<<m0<<","<<m23<<") : 3 sigma at " << results[3] << endl;
    }
  }//end of model scan for loop
  
  dout << "Exclusion Map contains" << exclusionmap->Integral() << " (integral) and entries: " << exclusionmap->GetEntries() << endl;
  c3->cd();
  exclusionmap->Draw("CONTZ");
  CompleteSave(c3,"Model_Scan/CONT/Model_Scan_Mean_values");
  exclusionmap->Draw("COLZ");
  CompleteSave(c3,"Model_Scan/COL/Model_Scan_Mean_values");
  
  exclusionmap1s->Draw("CONTZ");
  CompleteSave(c3,"Model_Scan/CONT/Model_Scan_1sigma_values");
  exclusionmap1s->Draw("COLZ");
  CompleteSave(c3,"Model_Scan/COL/Model_Scan_1sigma_values");
  
  exclusionmap2s->Draw("CONTZ");
  CompleteSave(c3,"Model_Scan/CONT/Model_Scan_2sigma_values");
  exclusionmap2s->Draw("COLZ");
  CompleteSave(c3,"Model_Scan/COL/Model_Scan_2sigma_values");
  
  exclusionmap3s->Draw("CONTZ");
  CompleteSave(c3,"Model_Scan/CONT/Model_Scan_3sigma_values");
  exclusionmap3s->Draw("COLZ");
  CompleteSave(c3,"Model_Scan/COL/Model_Scan_3sigma_values");
  
  TFile *exclusion_limits = new TFile("exclusion_limits.root","RECREATE");
  exclusionmap->Write();
  exclusionmap1s->Write();
  exclusionmap2s->Write();
  exclusionmap3s->Write();
  exclusion_limits->Close();
  susyscanfile->Close();
  
  myfile.close();
}

void efficiency_scan_in_susy_space(string mcjzb, string datajzb, bool requireZ, float peakerror) {
  dout << "Doing efficiency scan using " << (scansample.collection)[0].filename << endl;
  geqleq="geq";
  automatized=true;
  mcjzbexpression=mcjzb;
  
  string massgluname="MassGlu";
  string massLSPname="MassLSP";
  
  Int_t MyPalette[100];
  Double_t r[]    = {0., 0.0, 1.0, 1.0, 1.0};
  Double_t g[]    = {0., 0.0, 0.0, 1.0, 1.0};
  Double_t b[]    = {0., 1.0, 0.0, 0.0, 1.0};
  Double_t stop[] = {0., .25, .50, .75, 1.0};
  Int_t FI = TColor::CreateGradientColorTable(5, stop, r, g, b, 110);
  for (int i=0;i<100;i++) MyPalette[i] = FI+i;
   
  gStyle->SetPalette(100, MyPalette);
  
  TH2F *efficiencymap = new TH2F("efficiencymap","",(mgluend-mglustart)/mglustep+1,mglustart-0.5*mglustep,mgluend+0.5*mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5*mLSPstep,mLSPend+0.5*mLSPstep);
  TH2F *Neventsmap    = new TH2F("Neventsmap","",   (mgluend-mglustart)/mglustep+1,mglustart-0.5*mglustep,mgluend+0.5*mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5*mLSPstep,mLSPend+0.5*mLSPstep);
  
  float rightmargin=gStyle->GetPadRightMargin();
  gStyle->SetPadRightMargin(0.14);
  
  TCanvas *effcanvas = new TCanvas("effcanvas","Efficiency canvas");
  
  for(int mglu=mglustart;mglu<=mgluend;mglu+=mglustep) {
    for (int mlsp=mLSPstart;mlsp<=mLSPend&&mlsp<=mglu;mlsp+=mLSPstep)
    {
      float result,resulterr;
      stringstream addcut;
      addcut << "(TMath::Abs("<<massgluname<<"-"<<mglu<<")<5)&&(TMath::Abs("<<massLSPname<<"-"<<mlsp<<")<5)";
      MCefficiency((scansample.collection)[0].events,result,resulterr,mcjzb,requireZ,addcut.str());
      if(result!=result||isanyinf(result)) {
        dout << "Watch out the result for mlsp=" << mlsp << " and mglu=" << mglu << " (" << result << ") has been detected as being not a number (nan) or infinity (inf) !" << endl;
        result=0; // kicking nan and inf errors
      }
      else {
        efficiencymap->Fill(mglu,mlsp,result);
        dout << "      ok! Added efficiency " << result << " for mlsp=" << mlsp << " and mglu=" << mglu << endl;
      }
      
      (scansample.collection)[0].events->Draw(mcjzb.c_str(),addcut.str().c_str(),"goff");
      float nevents = (scansample.collection)[0].events->GetSelectedRows();
      Neventsmap->Fill(mglu,mlsp,nevents);
    }
  }
  
  efficiencymap->GetXaxis()->SetTitle("m_{glu}");
  efficiencymap->GetXaxis()->CenterTitle();
  efficiencymap->GetYaxis()->SetTitle("m_{LSP}");
  efficiencymap->GetYaxis()->CenterTitle();
  
  Neventsmap->GetXaxis()->SetTitle("m_{glu}");
  Neventsmap->GetXaxis()->CenterTitle();
  Neventsmap->GetYaxis()->SetTitle("m_{LSP}");
  Neventsmap->GetYaxis()->CenterTitle();
    
  efficiencymap->Draw("COLZ");
  TText *title = write_title("Efficiency in LSP-Glu plane");
  title->Draw();
  CompleteSave(effcanvas,"SUSYScan/Efficency");
  
  Neventsmap->Draw("COLZ");
  TText *title2 = write_title("Number of events in LSP-Glu plane");
  title2->Draw();
  CompleteSave(effcanvas,"SUSYScan/Nevents");
}

bool isThreadActive=false;

struct limit_args {
  float mceff;
  float toterr;
  int ibin;
  string mcjzb;
  vector<float> sigmas;
}; 

void* compute_one_upper_limit_wrapper(void* data) {
  isThreadActive=true;
  limit_args* args = (limit_args*) data;
  std::cout << "Thread to compute limits has been started" << std::endl;
  args->sigmas=compute_one_upper_limit(args->mceff,args->toterr,args->ibin,args->mcjzb);
  std::cout << "Thread to compute limits has finished" << std::endl;
  isThreadActive=false;
  return NULL; // oder in C++: return 0;// Damit kann man Werte zurückgeben
}

void do_limit_wrapper(float mceff,float toterr,int ibin,string mcjzb,vector<float> &sigmas) {
  pthread_t limitthread;
  limit_args limargs={mceff,toterr,ibin,mcjzb,sigmas};
  pthread_create( &limitthread, NULL, compute_one_upper_limit_wrapper, (void*) &limargs);
  int counter=0;
  sleep(1); //waiting a second for the process to become active
  while(counter<limitpatience*60 && isThreadActive) {
    std::cout << "Checking round " << counter << std::endl;
    counter++;
    sleep(1);
  }

  if(!isThreadActive) {
    cout << "Thread finished sucessfully" << endl;
    pthread_join( limitthread, NULL );
    std::cout<< __FUNCTION__ << " : going to save sigmas " << std::endl;
    sigmas=limargs.sigmas;
  } else {
    pthread_cancel(limitthread);
    std::cout << "DID NOT TERMINATE IN TIME - ABORTED!" << std::endl;
    sigmas.push_back(-1);sigmas.push_back(-1);sigmas.push_back(-1);
  }
}

void prepare_scan_axis(TH2 *variablemap) {
  variablemap->GetXaxis()->SetTitle("m_{glu}");
  variablemap->GetXaxis()->CenterTitle();
  variablemap->GetYaxis()->SetTitle("m_{LSP}");
  variablemap->GetYaxis()->CenterTitle();
  
  variablemap->GetXaxis()->SetTitle("m_{glu}");
  variablemap->GetXaxis()->CenterTitle();
  variablemap->GetYaxis()->SetTitle("m_{LSP}");
  variablemap->GetYaxis()->CenterTitle();
}

void scan_SUSY_parameter_space(string mcjzb,string datajzb,vector<float> jzb_cut,bool requireZ, float peakerror, int ibin,float njobs=-1, float jobnumber=-1, bool systematicsonly=false) {
  bool runninglocally=true;
  if(njobs>-1&&jobnumber>-1) {
    runninglocally=false;
    dout << "Running on the GRID (this is job " << jobnumber << "/" << njobs << ")" << endl;
  } else {
    dout << "Running locally " << endl;
    dout << "This will take a really, really long time - if  you want to see the results THIS week try running the LimitWorkerScript on the grid (DistributedModelCalculation/Limits/)" << endl;
  }
  
  jzbSel=jzb_cut[ibin];
  geqleq="geq";
  automatized=true;
  mcjzbexpression=mcjzb;
  
  string massgluname="MassGlu";
  string massLSPname="MassLSP";
  
  Int_t MyPalette[100];
  Double_t r[]    = {0., 0.0, 1.0, 1.0, 1.0};
  Double_t g[]    = {0., 0.0, 0.0, 1.0, 1.0};
  Double_t b[]    = {0., 1.0, 0.0, 0.0, 1.0};
  Double_t stop[] = {0., .25, .50, .75, 1.0};
  Int_t FI = TColor::CreateGradientColorTable(5, stop, r, g, b, 110);
  for (int i=0;i<100;i++) MyPalette[i] = FI+i;
   
  gStyle->SetPalette(100, MyPalette);
  
  TH2F *limitmap  = new TH2F(("limitmap"+any2string(jzbSel)).c_str(), "",(mgluend-mglustart)/mglustep+1,mglustart-0.5*mglustep,mgluend+0.5*mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5*mLSPstep,mLSPend+0.5*mLSPstep);
  TH2F *sysjesmap = new TH2F(("sysjes"+any2string(jzbSel)).c_str(),   "",(mgluend-mglustart)/mglustep+1,mglustart-0.5*mglustep,mgluend+0.5*mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5*mLSPstep,mLSPend+0.5*mLSPstep);
  TH2F *sysjsumap = new TH2F(("sysjsu"+any2string(jzbSel)).c_str(),   "",(mgluend-mglustart)/mglustep+1,mglustart-0.5*mglustep,mgluend+0.5*mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5*mLSPstep,mLSPend+0.5*mLSPstep);
  TH2F *sysresmap = new TH2F(("sysresmap"+any2string(jzbSel)).c_str(),"",(mgluend-mglustart)/mglustep+1,mglustart-0.5*mglustep,mgluend+0.5*mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5*mLSPstep,mLSPend+0.5*mLSPstep);
  
  float rightmargin=gStyle->GetPadRightMargin();
  gStyle->SetPadRightMargin(0.15);
  
  TCanvas *limcanvas = new TCanvas("limcanvas","Limit canvas");
  
  
  int Npoints=0;
  for(int mglu=mglustart;mglu<=mgluend;mglu+=mglustep) {
    for (int mlsp=mLSPstart;mlsp<=mLSPend&&mlsp<=mglu;mlsp+=mLSPstep) Npoints++;
  }
  
  int ipoint=-1;
  for(int mglu=mglustart;mglu<=mgluend;mglu+=mglustep) {
    for (int mlsp=mLSPstart;mlsp<=mLSPend&&mlsp<=mglu;mlsp+=mLSPstep)
    {
      ipoint++;
      if(!runninglocally&&!do_this_point(ipoint,Npoints,jobnumber,njobs)) continue;
      float result,resulterr;
      stringstream addcut;
      addcut << "(TMath::Abs("<<massgluname<<"-"<<mglu<<")<5)&&(TMath::Abs("<<massLSPname<<"-"<<mlsp<<")<5)";
      vector<vector<float> > systematics;
      MCefficiency((scansample.collection)[0].events,result,resulterr,mcjzb,requireZ,addcut.str());
      if(result!=result||resulterr!=resulterr) {
        dout << "Limits can't be calculated for this configuration (mglu="<<mglu<<" , mlsp="<<mlsp << ") as either the efficiency or its error are not numbers! (result="<<result<<" and resulterr="<<resulterr<<")"<< endl;
        continue;
      } else {
        dout << "Configuration (mglu="<<mglu<<" , mlsp="<<mlsp << ") passed the mcefficiency test; will compute systematics and limits now." << endl;
      }
      do_systematics_for_one_file((scansample.collection)[0].events,"SUSY SCAN", systematics,mcjzb,datajzb,peakerror,requireZ, addcut.str());
      float JZBcutat = systematics[0][0];
      float mceff    = systematics[0][1];
      float toterr   = systematics[0][4];
      float sys_jes  = systematics[0][5]; // Jet Energy Scale
      float sys_jsu  = systematics[0][6]; // JZB scale uncertainty
      float sys_res  = systematics[0][7]; // resolution
      
      cout << "EXTRACTED THE FOLLOWING INFORMATION: mceff=" << mceff << " , toterr=" << toterr << " , sys_jes=" << sys_jes << " , sys_jsu=" << sys_jsu << " , sys_res = " << sys_res << endl;
      
      if(mceff!=mceff||toterr!=toterr) {
        dout << "Limits can't be calculated for this configuration (mglu="<<mglu<<" , mlsp="<<mlsp << ") as either the efficiency or its error are not numbers! (mceff="<<mceff<<" and toterr="<<toterr<<")"<< endl;
        continue;
      } else {
        if(!systematicsonly) {
          dout << "Calculating limit now for m_{glu}="<<mglu << " and m_{lsp}="<<mlsp<<endl;
          vector<float> sigmas;
          do_limit_wrapper(mceff,toterr,ibin,mcjzb,sigmas);
          cout << "back in " << __FUNCTION__ << endl;
          if(sigmas[0]>-0.5) { // negative sigmas are the error signature of do_limit_wrapper, so we want to exclude them.
            limitmap->Fill(mglu,mlsp,sigmas[0]);
            dout << "A limit has been added at " << sigmas[0] << " for m_{glu}="<<mglu << " and m_{lsp}="<<mlsp<<endl;
          } //end of if sigma is positive
        //end of not systematics only condition
        } else { 
            sysjesmap->Fill(mglu,mlsp,sys_jes);
            sysjsumap->Fill(mglu,mlsp,sys_jsu);
            sysresmap->Fill(mglu,mlsp,sys_res);
        }
      }
    }
  }
  
  prepare_scan_axis(limitmap);
  prepare_scan_axis(sysjesmap);
  prepare_scan_axis(sysjsumap);
  prepare_scan_axis(sysresmap);
  
  if(!systematicsonly) {
    limcanvas->cd();
    limitmap->Draw("COLZ");
    TText *title = write_title("Limits in LSP-Glu plane");
    title->Draw();
    if(runninglocally) {
      CompleteSave(limcanvas,"SUSYScan/Limits_JZB_geq"+any2string(jzb_cut[ibin]));
    } else {
      TFile *outputfile;
      if(systematicsonly) outputfile=new TFile(("output/DistributedSystematics_job"+string(any2string(jobnumber))+"_of_"+string(any2string(njobs))+".root").c_str(),"UPDATE");//needs to be "UPDATE" as we can get to this point for different JZB cuts and don't want to erase the previous data :-)
        else outputfile=new TFile(("output/DistributedLimits_job"+string(any2string(jobnumber))+"_of_"+string(any2string(njobs))+".root").c_str(),"UPDATE");//needs to be "UPDATE" as we can get to this point for
      limitmap->Write();
      outputfile->Close();
    }
  } else { // systematics only :
    limcanvas->cd();
    sysjesmap->Draw("COLZ");
    TText *title = write_title("Jet Energy scale in LSP-Glu plane");
    title->Draw();
    if(runninglocally) {
      CompleteSave(limcanvas,"SUSYScan/JES_geq"+any2string(jzb_cut[ibin]));
    }
    sysjsumap->Draw("COLZ");
    TText *title2 = write_title("JZB Scale Uncertainty in LSP-Glu plane");
    title2->Draw();
    if(runninglocally) {
      CompleteSave(limcanvas,"SUSYScan/JSU_geq"+any2string(jzb_cut[ibin]));
    }
    sysresmap->Draw("COLZ");
    TText *title3 = write_title("Resolution in LSP-Glu plane");
    title3->Draw();
    if(runninglocally) {
      CompleteSave(limcanvas,"SUSYScan/Resolution_geq"+any2string(jzb_cut[ibin]));
    }
    
    if(!runninglocally) {
      TFile *outputfile=new TFile(("output/DistributedSystematics_job"+string(any2string(jobnumber))+"_of_"+string(any2string(njobs))+".root").c_str(),"UPDATE");
      sysjesmap->Write();
      sysjsumap->Write();
      sysresmap->Write();
      outputfile->Close();
    }
  }//end of systematics only
}

void scan_SUSY_parameter_space(string mcjzb,string datajzb,vector<float> jzb_cut,bool requireZ, float peakerror, float njobs=-1, float jobnumber=-1, bool systonly=false) {
  dout << "Starting the SUSY scan now with all " << jzb_cut.size() << " bin(s)" << endl;
  for(int ibin=0;ibin<jzb_cut.size();ibin++) {
    scan_SUSY_parameter_space(mcjzb,datajzb,jzb_cut,requireZ, peakerror, ibin, njobs, jobnumber,systonly);
  }
}
Revision:	1.12
Committed:	Mon Aug 15 12:38:15 2011 UTC (13 years, 8 months ago) by buchmann
Content type:	text/plain
Branch:	MAIN
Changes since 1.11:	+3 -1 lines
Log Message:	Adapted name for systematics only calculation
#	Content
1	#include <iostream>
2	#include <vector>
3	#include <sys/stat.h>
4	#include <fstream>
5	#include <pthread.h>
6
7	#include <TCut.h>
8	#include <TROOT.h>
9	#include <TCanvas.h>
10	#include <TMath.h>
11	#include <TColor.h>
12	#include <TPaveText.h>
13	#include <TRandom.h>
14	#include <TH1.h>
15	#include <TH2.h>
16	#include <TF1.h>
17	#include <TSQLResult.h>
18	#include <TProfile.h>
19
20	//#include "TTbar_stuff.C"
21	using namespace std;
22
23	using namespace PlottingSetup;
24
25	void susy_scan_axis_labeling(TH2F *histo) {
26	histo->GetXaxis()->SetTitle("#Chi_{2}^{0}-LSP");
27	histo->GetXaxis()->CenterTitle();
28	histo->GetYaxis()->SetTitle("m_{#tilde{q}}");
29	histo->GetYaxis()->CenterTitle();
30	}
31
32	void scan_susy_space(string mcjzb, string datajzb) {
33	TCanvas *c3 = new TCanvas("c3","c3");
34	vector<float> binning;
35	binning=allsamples.get_optimal_binsize(mcjzb,cutmass&&cutOSSF&&cutnJets,20,50,800);
36	float arrbinning[binning.size()];
37	for(int i=0;i<binning.size();i++) arrbinning[i]=binning[i];
38	TH1F *puredata = allsamples.Draw("puredata", datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
39	puredata->SetMarkerSize(DataMarkerSize);
40	TH1F *allbgs = allsamples.Draw("allbgs", "-"+datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
41	TH1F *allbgsb = allsamples.Draw("allbgsb", "-"+datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,luminosity);
42	TH1F *allbgsc = allsamples.Draw("allbgsc", datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,luminosity);
43	allbgs->Add(allbgsb,-1);
44	allbgs->Add(allbgsc);
45	int ndata=puredata->Integral();
46	ofstream myfile;
47	myfile.open ("susyscan_log.txt");
48	TFile *susyscanfile = new TFile("/scratch/fronga/SMS/T5z_SqSqToQZQZ_38xFall10.root");
49	TTree suevents = (TTree)susyscanfile->Get("events");
50	TH2F *exclusionmap = new TH2F("exclusionmap","",20,0,500,20,0,1000);
51	TH2F *exclusionmap1s = new TH2F("exclusionmap1s","",20,0,500,20,0,1000);
52	TH2F *exclusionmap2s = new TH2F("exclusionmap2s","",20,0,500,20,0,1000);
53	TH2F *exclusionmap3s = new TH2F("exclusionmap3s","",20,0,500,20,0,1000);
54
55	susy_scan_axis_labeling(exclusionmap);
56	susy_scan_axis_labeling(exclusionmap1s);
57	susy_scan_axis_labeling(exclusionmap2s);
58	susy_scan_axis_labeling(exclusionmap3s);
59
60	Int_t MyPalette[100];
61	Double_t r[] = {0., 0.0, 1.0, 1.0, 1.0};
62	Double_t g[] = {0., 0.0, 0.0, 1.0, 1.0};
63	Double_t b[] = {0., 1.0, 0.0, 0.0, 1.0};
64	Double_t stop[] = {0., .25, .50, .75, 1.0};
65	Int_t FI = TColor::CreateGradientColorTable(5, stop, r, g, b, 100);
66	for (int i=0;i<100;i++) MyPalette[i] = FI+i;
67
68	gStyle->SetPalette(100, MyPalette);
69
70	for(int m23=50;m23<500;m23+=25) {
71	for (int m0=(2*(m23-50)+150);m0<=1000;m0+=50)
72	{
73	c3->cd();
74	stringstream drawcondition;
75	drawcondition << "pfJetGoodNum>=3&&(TMath::Abs(masses[0]-"<<m0<<")<10&&TMath::Abs(masses[2]-masses[3]-"<<m23<<")<10)&&mll>5&&id1==id2";
76	TH1F *puresignal = new TH1F("puresignal","puresignal",binning.size()-1,arrbinning);
77	TH1F *puresignall= new TH1F("puresignall","puresignal",binning.size()-1,arrbinning);
78	stringstream drawvar,drawvar2;
79	drawvar<<mcjzb<<">>puresignal";
80	drawvar2<<"-"<<mcjzb<<">>puresignall";
81	suevents->Draw(drawvar.str().c_str(),drawcondition.str().c_str());
82	suevents->Draw(drawvar2.str().c_str(),drawcondition.str().c_str());
83	if(puresignal->Integral()<60) {
84	delete puresignal;
85	continue;
86	}
87	puresignal->Add(puresignall,-1);//we need to correct for the signal contamination - we effectively only see (JZB>0)-(JZB<0) !!
88	puresignal->Scale(ndata/(20*puresignal->Integral()));//normalizing it to 5% of the data
89	stringstream saveas;
90	saveas<<"Model_Scan/m0_"<<m0<<"__m23_"<<m23;
91	dout << "PLEASE KEEP IN MIND THAT SIGNAL CONTAMINATION IS NOT REALLY TAKEN CARE OF YET DUE TO LOW STATISTICS! SHOULD BE SOMETHING LIKE THIS : "<< endl;
92	// TH1F *signalpredlo = allsamples.Draw("signalpredlo", "-"+mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc, luminosity,allsamples.FindSample("LM4"));
93	// TH1F *signalpredro = allsamples.Draw("signalpredro", mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc, luminosity,allsamples.FindSample("LM4"));
94	// TH1F *puredata = allsamples.Draw("puredata", datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
95	// signalpred->Add(signalpredlo,-1);
96	// signalpred->Add(signalpredro);
97	// puresignal->Add(signalpred,-1);//subtracting signal contamination
98	//---------------------
99	// dout << "(m0,m23)=("<<m0<<","<<m23<<") contains " << puresignal->Integral() << endl;
100	// TH1F *puresignal = allsamples.Draw("puresignal",mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc, luminosity,allsamples.FindSample("LM4"));
101	vector<float> results=establish_upper_limits(puredata,allbgs,puresignal,saveas.str(),myfile);
102	if(results.size()==0) {
103	delete puresignal;
104	continue;
105	}
106	exclusionmap->Fill(m23,m0,results[0]);
107	exclusionmap1s->Fill(m23,m0,results[1]);
108	exclusionmap2s->Fill(m23,m0,results[2]);
109	exclusionmap3s->Fill(m23,m0,results[3]);
110	delete puresignal;
111	dout << "(m0,m23)=("<<m0<<","<<m23<<") : 3 sigma at " << results[3] << endl;
112	}
113	}//end of model scan for loop
114
115	dout << "Exclusion Map contains" << exclusionmap->Integral() << " (integral) and entries: " << exclusionmap->GetEntries() << endl;
116	c3->cd();
117	exclusionmap->Draw("CONTZ");
118	CompleteSave(c3,"Model_Scan/CONT/Model_Scan_Mean_values");
119	exclusionmap->Draw("COLZ");
120	CompleteSave(c3,"Model_Scan/COL/Model_Scan_Mean_values");
121
122	exclusionmap1s->Draw("CONTZ");
123	CompleteSave(c3,"Model_Scan/CONT/Model_Scan_1sigma_values");
124	exclusionmap1s->Draw("COLZ");
125	CompleteSave(c3,"Model_Scan/COL/Model_Scan_1sigma_values");
126
127	exclusionmap2s->Draw("CONTZ");
128	CompleteSave(c3,"Model_Scan/CONT/Model_Scan_2sigma_values");
129	exclusionmap2s->Draw("COLZ");
130	CompleteSave(c3,"Model_Scan/COL/Model_Scan_2sigma_values");
131
132	exclusionmap3s->Draw("CONTZ");
133	CompleteSave(c3,"Model_Scan/CONT/Model_Scan_3sigma_values");
134	exclusionmap3s->Draw("COLZ");
135	CompleteSave(c3,"Model_Scan/COL/Model_Scan_3sigma_values");
136
137	TFile *exclusion_limits = new TFile("exclusion_limits.root","RECREATE");
138	exclusionmap->Write();
139	exclusionmap1s->Write();
140	exclusionmap2s->Write();
141	exclusionmap3s->Write();
142	exclusion_limits->Close();
143	susyscanfile->Close();
144
145	myfile.close();
146	}
147
148	void efficiency_scan_in_susy_space(string mcjzb, string datajzb, bool requireZ, float peakerror) {
149	dout << "Doing efficiency scan using " << (scansample.collection)[0].filename << endl;
150	geqleq="geq";
151	automatized=true;
152	mcjzbexpression=mcjzb;
153
154	string massgluname="MassGlu";
155	string massLSPname="MassLSP";
156
157	Int_t MyPalette[100];
158	Double_t r[] = {0., 0.0, 1.0, 1.0, 1.0};
159	Double_t g[] = {0., 0.0, 0.0, 1.0, 1.0};
160	Double_t b[] = {0., 1.0, 0.0, 0.0, 1.0};
161	Double_t stop[] = {0., .25, .50, .75, 1.0};
162	Int_t FI = TColor::CreateGradientColorTable(5, stop, r, g, b, 110);
163	for (int i=0;i<100;i++) MyPalette[i] = FI+i;
164
165	gStyle->SetPalette(100, MyPalette);
166
167	TH2F efficiencymap = new TH2F("efficiencymap","",(mgluend-mglustart)/mglustep+1,mglustart-0.5mglustep,mgluend+0.5mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5mLSPstep,mLSPend+0.5*mLSPstep);
168	TH2F Neventsmap = new TH2F("Neventsmap","", (mgluend-mglustart)/mglustep+1,mglustart-0.5mglustep,mgluend+0.5mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5mLSPstep,mLSPend+0.5*mLSPstep);
169
170	float rightmargin=gStyle->GetPadRightMargin();
171	gStyle->SetPadRightMargin(0.14);
172
173	TCanvas *effcanvas = new TCanvas("effcanvas","Efficiency canvas");
174
175	for(int mglu=mglustart;mglu<=mgluend;mglu+=mglustep) {
176	for (int mlsp=mLSPstart;mlsp<=mLSPend&&mlsp<=mglu;mlsp+=mLSPstep)
177	{
178	float result,resulterr;
179	stringstream addcut;
180	addcut << "(TMath::Abs("<<massgluname<<"-"<<mglu<<")<5)&&(TMath::Abs("<<massLSPname<<"-"<<mlsp<<")<5)";
181	MCefficiency((scansample.collection)[0].events,result,resulterr,mcjzb,requireZ,addcut.str());
182	if(result!=result\|\|isanyinf(result)) {
183	dout << "Watch out the result for mlsp=" << mlsp << " and mglu=" << mglu << " (" << result << ") has been detected as being not a number (nan) or infinity (inf) !" << endl;
184	result=0; // kicking nan and inf errors
185	}
186	else {
187	efficiencymap->Fill(mglu,mlsp,result);
188	dout << " ok! Added efficiency " << result << " for mlsp=" << mlsp << " and mglu=" << mglu << endl;
189	}
190
191	(scansample.collection)[0].events->Draw(mcjzb.c_str(),addcut.str().c_str(),"goff");
192	float nevents = (scansample.collection)[0].events->GetSelectedRows();
193	Neventsmap->Fill(mglu,mlsp,nevents);
194	}
195	}
196
197	efficiencymap->GetXaxis()->SetTitle("m_{glu}");
198	efficiencymap->GetXaxis()->CenterTitle();
199	efficiencymap->GetYaxis()->SetTitle("m_{LSP}");
200	efficiencymap->GetYaxis()->CenterTitle();
201
202	Neventsmap->GetXaxis()->SetTitle("m_{glu}");
203	Neventsmap->GetXaxis()->CenterTitle();
204	Neventsmap->GetYaxis()->SetTitle("m_{LSP}");
205	Neventsmap->GetYaxis()->CenterTitle();
206
207	efficiencymap->Draw("COLZ");
208	TText *title = write_title("Efficiency in LSP-Glu plane");
209	title->Draw();
210	CompleteSave(effcanvas,"SUSYScan/Efficency");
211
212	Neventsmap->Draw("COLZ");
213	TText *title2 = write_title("Number of events in LSP-Glu plane");
214	title2->Draw();
215	CompleteSave(effcanvas,"SUSYScan/Nevents");
216	}
217
218	bool isThreadActive=false;
219
220	struct limit_args {
221	float mceff;
222	float toterr;
223	int ibin;
224	string mcjzb;
225	vector<float> sigmas;
226	};
227
228	void* compute_one_upper_limit_wrapper(void* data) {
229	isThreadActive=true;
230	limit_args* args = (limit_args*) data;
231	std::cout << "Thread to compute limits has been started" << std::endl;
232	args->sigmas=compute_one_upper_limit(args->mceff,args->toterr,args->ibin,args->mcjzb);
233	std::cout << "Thread to compute limits has finished" << std::endl;
234	isThreadActive=false;
235	return NULL; // oder in C++: return 0;// Damit kann man Werte zurückgeben
236	}
237
238	void do_limit_wrapper(float mceff,float toterr,int ibin,string mcjzb,vector<float> &sigmas) {
239	pthread_t limitthread;
240	limit_args limargs={mceff,toterr,ibin,mcjzb,sigmas};
241	pthread_create( &limitthread, NULL, compute_one_upper_limit_wrapper, (void*) &limargs);
242	int counter=0;
243	sleep(1); //waiting a second for the process to become active
244	while(counter<limitpatience*60 && isThreadActive) {
245	std::cout << "Checking round " << counter << std::endl;
246	counter++;
247	sleep(1);
248	}
249
250	if(!isThreadActive) {
251	cout << "Thread finished sucessfully" << endl;
252	pthread_join( limitthread, NULL );
253	std::cout<< __FUNCTION__ << " : going to save sigmas " << std::endl;
254	sigmas=limargs.sigmas;
255	} else {
256	pthread_cancel(limitthread);
257	std::cout << "DID NOT TERMINATE IN TIME - ABORTED!" << std::endl;
258	sigmas.push_back(-1);sigmas.push_back(-1);sigmas.push_back(-1);
259	}
260	}
261
262	void prepare_scan_axis(TH2 *variablemap) {
263	variablemap->GetXaxis()->SetTitle("m_{glu}");
264	variablemap->GetXaxis()->CenterTitle();
265	variablemap->GetYaxis()->SetTitle("m_{LSP}");
266	variablemap->GetYaxis()->CenterTitle();
267
268	variablemap->GetXaxis()->SetTitle("m_{glu}");
269	variablemap->GetXaxis()->CenterTitle();
270	variablemap->GetYaxis()->SetTitle("m_{LSP}");
271	variablemap->GetYaxis()->CenterTitle();
272	}
273
274	void scan_SUSY_parameter_space(string mcjzb,string datajzb,vector<float> jzb_cut,bool requireZ, float peakerror, int ibin,float njobs=-1, float jobnumber=-1, bool systematicsonly=false) {
275	bool runninglocally=true;
276	if(njobs>-1&&jobnumber>-1) {
277	runninglocally=false;
278	dout << "Running on the GRID (this is job " << jobnumber << "/" << njobs << ")" << endl;
279	} else {
280	dout << "Running locally " << endl;
281	dout << "This will take a really, really long time - if you want to see the results THIS week try running the LimitWorkerScript on the grid (DistributedModelCalculation/Limits/)" << endl;
282	}
283
284	jzbSel=jzb_cut[ibin];
285	geqleq="geq";
286	automatized=true;
287	mcjzbexpression=mcjzb;
288
289	string massgluname="MassGlu";
290	string massLSPname="MassLSP";
291
292	Int_t MyPalette[100];
293	Double_t r[] = {0., 0.0, 1.0, 1.0, 1.0};
294	Double_t g[] = {0., 0.0, 0.0, 1.0, 1.0};
295	Double_t b[] = {0., 1.0, 0.0, 0.0, 1.0};
296	Double_t stop[] = {0., .25, .50, .75, 1.0};
297	Int_t FI = TColor::CreateGradientColorTable(5, stop, r, g, b, 110);
298	for (int i=0;i<100;i++) MyPalette[i] = FI+i;
299
300	gStyle->SetPalette(100, MyPalette);
301
302	TH2F limitmap = new TH2F(("limitmap"+any2string(jzbSel)).c_str(), "",(mgluend-mglustart)/mglustep+1,mglustart-0.5mglustep,mgluend+0.5mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5mLSPstep,mLSPend+0.5*mLSPstep);
303	TH2F sysjesmap = new TH2F(("sysjes"+any2string(jzbSel)).c_str(), "",(mgluend-mglustart)/mglustep+1,mglustart-0.5mglustep,mgluend+0.5mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5mLSPstep,mLSPend+0.5*mLSPstep);
304	TH2F sysjsumap = new TH2F(("sysjsu"+any2string(jzbSel)).c_str(), "",(mgluend-mglustart)/mglustep+1,mglustart-0.5mglustep,mgluend+0.5mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5mLSPstep,mLSPend+0.5*mLSPstep);
305	TH2F sysresmap = new TH2F(("sysresmap"+any2string(jzbSel)).c_str(),"",(mgluend-mglustart)/mglustep+1,mglustart-0.5mglustep,mgluend+0.5mglustep,(mLSPend-mLSPstart)/mLSPstep+1,mLSPstart-0.5mLSPstep,mLSPend+0.5*mLSPstep);
306
307	float rightmargin=gStyle->GetPadRightMargin();
308	gStyle->SetPadRightMargin(0.15);
309
310	TCanvas *limcanvas = new TCanvas("limcanvas","Limit canvas");
311
312
313	int Npoints=0;
314	for(int mglu=mglustart;mglu<=mgluend;mglu+=mglustep) {
315	for (int mlsp=mLSPstart;mlsp<=mLSPend&&mlsp<=mglu;mlsp+=mLSPstep) Npoints++;
316	}
317
318	int ipoint=-1;
319	for(int mglu=mglustart;mglu<=mgluend;mglu+=mglustep) {
320	for (int mlsp=mLSPstart;mlsp<=mLSPend&&mlsp<=mglu;mlsp+=mLSPstep)
321	{
322	ipoint++;
323	if(!runninglocally&&!do_this_point(ipoint,Npoints,jobnumber,njobs)) continue;
324	float result,resulterr;
325	stringstream addcut;
326	addcut << "(TMath::Abs("<<massgluname<<"-"<<mglu<<")<5)&&(TMath::Abs("<<massLSPname<<"-"<<mlsp<<")<5)";
327	vector<vector<float> > systematics;
328	MCefficiency((scansample.collection)[0].events,result,resulterr,mcjzb,requireZ,addcut.str());
329	if(result!=result\|\|resulterr!=resulterr) {
330	dout << "Limits can't be calculated for this configuration (mglu="<<mglu<<" , mlsp="<<mlsp << ") as either the efficiency or its error are not numbers! (result="<<result<<" and resulterr="<<resulterr<<")"<< endl;
331	continue;
332	} else {
333	dout << "Configuration (mglu="<<mglu<<" , mlsp="<<mlsp << ") passed the mcefficiency test; will compute systematics and limits now." << endl;
334	}
335	do_systematics_for_one_file((scansample.collection)[0].events,"SUSY SCAN", systematics,mcjzb,datajzb,peakerror,requireZ, addcut.str());
336	float JZBcutat = systematics[0][0];
337	float mceff = systematics[0][1];
338	float toterr = systematics[0][4];
339	float sys_jes = systematics[0][5]; // Jet Energy Scale
340	float sys_jsu = systematics[0][6]; // JZB scale uncertainty
341	float sys_res = systematics[0][7]; // resolution
342
343	cout << "EXTRACTED THE FOLLOWING INFORMATION: mceff=" << mceff << " , toterr=" << toterr << " , sys_jes=" << sys_jes << " , sys_jsu=" << sys_jsu << " , sys_res = " << sys_res << endl;
344
345	if(mceff!=mceff\|\|toterr!=toterr) {
346	dout << "Limits can't be calculated for this configuration (mglu="<<mglu<<" , mlsp="<<mlsp << ") as either the efficiency or its error are not numbers! (mceff="<<mceff<<" and toterr="<<toterr<<")"<< endl;
347	continue;
348	} else {
349	if(!systematicsonly) {
350	dout << "Calculating limit now for m_{glu}="<<mglu << " and m_{lsp}="<<mlsp<<endl;
351	vector<float> sigmas;
352	do_limit_wrapper(mceff,toterr,ibin,mcjzb,sigmas);
353	cout << "back in " << __FUNCTION__ << endl;
354	if(sigmas[0]>-0.5) { // negative sigmas are the error signature of do_limit_wrapper, so we want to exclude them.
355	limitmap->Fill(mglu,mlsp,sigmas[0]);
356	dout << "A limit has been added at " << sigmas[0] << " for m_{glu}="<<mglu << " and m_{lsp}="<<mlsp<<endl;
357	} //end of if sigma is positive
358	//end of not systematics only condition
359	} else {
360	sysjesmap->Fill(mglu,mlsp,sys_jes);
361	sysjsumap->Fill(mglu,mlsp,sys_jsu);
362	sysresmap->Fill(mglu,mlsp,sys_res);
363	}
364	}
365	}
366	}
367
368	prepare_scan_axis(limitmap);
369	prepare_scan_axis(sysjesmap);
370	prepare_scan_axis(sysjsumap);
371	prepare_scan_axis(sysresmap);
372
373	if(!systematicsonly) {
374	limcanvas->cd();
375	limitmap->Draw("COLZ");
376	TText *title = write_title("Limits in LSP-Glu plane");
377	title->Draw();
378	if(runninglocally) {
379	CompleteSave(limcanvas,"SUSYScan/Limits_JZB_geq"+any2string(jzb_cut[ibin]));
380	} else {
381	TFile *outputfile;
382	if(systematicsonly) outputfile=new TFile(("output/DistributedSystematics_job"+string(any2string(jobnumber))+"_of_"+string(any2string(njobs))+".root").c_str(),"UPDATE");//needs to be "UPDATE" as we can get to this point for different JZB cuts and don't want to erase the previous data :-)
383	else outputfile=new TFile(("output/DistributedLimits_job"+string(any2string(jobnumber))+"_of_"+string(any2string(njobs))+".root").c_str(),"UPDATE");//needs to be "UPDATE" as we can get to this point for
384	limitmap->Write();
385	outputfile->Close();
386	}
387	} else { // systematics only :
388	limcanvas->cd();
389	sysjesmap->Draw("COLZ");
390	TText *title = write_title("Jet Energy scale in LSP-Glu plane");
391	title->Draw();
392	if(runninglocally) {
393	CompleteSave(limcanvas,"SUSYScan/JES_geq"+any2string(jzb_cut[ibin]));
394	}
395	sysjsumap->Draw("COLZ");
396	TText *title2 = write_title("JZB Scale Uncertainty in LSP-Glu plane");
397	title2->Draw();
398	if(runninglocally) {
399	CompleteSave(limcanvas,"SUSYScan/JSU_geq"+any2string(jzb_cut[ibin]));
400	}
401	sysresmap->Draw("COLZ");
402	TText *title3 = write_title("Resolution in LSP-Glu plane");
403	title3->Draw();
404	if(runninglocally) {
405	CompleteSave(limcanvas,"SUSYScan/Resolution_geq"+any2string(jzb_cut[ibin]));
406	}
407
408	if(!runninglocally) {
409	TFile *outputfile=new TFile(("output/DistributedSystematics_job"+string(any2string(jobnumber))+"_of_"+string(any2string(njobs))+".root").c_str(),"UPDATE");
410	sysjesmap->Write();
411	sysjsumap->Write();
412	sysresmap->Write();
413	outputfile->Close();
414	}
415	}//end of systematics only
416	}
417
418	void scan_SUSY_parameter_space(string mcjzb,string datajzb,vector<float> jzb_cut,bool requireZ, float peakerror, float njobs=-1, float jobnumber=-1, bool systonly=false) {
419	dout << "Starting the SUSY scan now with all " << jzb_cut.size() << " bin(s)" << endl;
420	for(int ibin=0;ibin<jzb_cut.size();ibin++) {
421	scan_SUSY_parameter_space(mcjzb,datajzb,jzb_cut,requireZ, peakerror, ibin, njobs, jobnumber,systonly);
422	}
423	}